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This is to certify that the

dissertation entitled

The Ecology of a Single-Species-Dominant Forest
and of a Mixed Forest in Zaire, Africa

presented by
Terese Butler Hart
has been accepted towards fulfillment

of the requirements for

Ph.D. degreein Botany and Plant Pathology

 

 

    

Ma r professor

Peter G. Murphy
Date November 14, 1985

 

MS U i: an Affirmative Action/Equal Opportunity Institution 0-12771

 

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THE ECOLOGY OF A SINGLE-SPECIES-DOMINANT FOREST
AND OF A MIXED FOREST IN ZAIRE. AFRICA

BY

Terese Bulter Hart

A DISSERTATION

Submitted to
Michigan State University
in partial fulfillnent of the requirements
for the degree of

DOCTOR OF PHILOSOPHY

Department of Botany and Plant Pathology

 

ABSTRACT

THE ECOLOGY OF A SINGLE-SPECIES-DOMINANT FOREST
AND OF A MIXED FOREST IN ZAIRE. AFRICA.
BY

Terese Butler Hart

Low species diversity and pronounced dominance have been
considered atypical for tropical humid forests. In the Ituri Forest of
Zaire. however, a principal forest type is dominated by a single
species. In mbau forest. Gilbertiodendron dbwevrei accounts for
approximately 90% of the canopy-level trees. A second forest type. the
more species-rich mixed forest, is found at similar altitudes and on
similar topography as mbau forest. The co-occurrence of these two
communities suggests that some factor other than climate determines the
diversity difference between the two forest types.

Pour general hypotheses to account for the differences in
diversity were tested. Each hypothesis offered contrasting predictions
for the two forest types and was tested as follows:

1. Honodominance is symptomatic of early secondary growth.
Forest maturity was inferred from the representation of shade-tolerant
species in the canopy and understory.

2. Low tree species diversity is found on very poor soils.
Soils types were compared for differences in texture and chemical
composition.

3. Frequent and/or large natural disturbances interfere with

the ability of any single species to attain dominance. Treefall size
and frequency was determined.

4. Heavy seed predation under parent trees prevents dominance
by any single species. Seeds of canopy trees were monitored for
survival both near and distant from adult conspecifics.

The results failed to show that any of the proposed hypotheses
account in a major way for the maintenance of the two patterns of
diversity and dominance in the Ituri Forest. Both forest types have
the structure and composition of mature communities and the mbau forest
is not restricted to soils too poor for mixed forest. As predicted.
there were more frequent treefalls in mixed forest than mbau forest;
however, there was great variance in size and frequency of gaps in both
forest types. Finally, the dominance of G. dewevrei cannot be
attributed to a larger proportion of its seeds escaping predators. It
is suggested that natural disturbance of a larger scale and more
ancient than measured by this study may been a determinant of present

forest distributions.

This dissertation is dedicated to the
memory of CHUKIZA. son of ANJIANI, nephew
of KENGE, who enthusiastically shared

his knowledge of the forest

and to the memory of PH. GERARD whose
enjoyment of mbau forest is alive

in his writing.

11

AKNOWLEDGMENTS

The research project in the Ituri Forest of Zaire was made
financially possible by a grant from the United States Man and the
Biosphere Program (federal grant number 4789-6). The project was
facilitated by the cooperation of the Institut Zairois pour la
Conservation de la Nature (IZCN). Financial support during the period
of data analysis and redaction was provided by the African Studies
Center and the Department of Botany and Plant Pathology at Michigan
State University.

Dr. Peter Murphy's confidence and support were the catalyst
for the research proposal and essential to its realization. John A.
Hart has shared in, and contributed substantially to, all phases of
this project. His field assistance. stinulating discussions. and
companionship provided direction and the ability to persevere. as

needed.

Work in the forest would have been many times more difficult
without the enthusiastic assistance of the Mbuti Pygmies of the Epulu
area. notably, Chukiza. Kenge. Atoka. Mayalimingi, Avian, and Amanjau.
Dr. H. Breyne. curator of the national herbarium in Kinshasa, deserves
a special thanks for his logistical support and the identifications of
plant specimens. Many additional identifications were provided by L.
jLiben of the National Botanical gardens in Meise. Belgium.

The dissertation has been greatly improved by the editorial

iii

comments and constructive criticism of Dr. Peter Murphy and my
committee members. Dr. John Beaman. Dr. George Petrides, and Dr. Jean
Stout.

The questions and observations of colleagues have been
incorporated into the conception. realization. and analysis of this
study. In particular I wish to thank Dr. N. Brokaw, Dr. J. Connell,
Dr. D. Hibbs. Dr. D. Livingstone, the ecology group at Kellogg
Biological Station. especially, M. Leibold. Dr. T. Miller, and Dr. A.
Winn, and my fellow students in the laboratory, especially. V. Dunevitz
and Dr. G. Donnelly.

In completing this study, as has been the case for all my
projects. large and small, I feel deep gratitude toward my family. The
encouragment of my parents and parents—in-law has been a constant
source of strength. I owe a very special thanks to my husband, John,
for his unfaltering good humour and his lavish praise, and. also, to
our daughters, Sarah and Rebekah, who never doubted and always provided

welcome distraction.

iv

TABLE OF CONTENTS

List of Tables .................................................
List of Figures ................................................
Introduction ...................................................

Chapter one: The Mbau Forest in Zaire: Edaphic and Successional
Gradients in Relation to Single-Species-Dominance in an

African Tropical Forest ...................................
Introduction ..............................................
Background ................................................
Variation of tropical forest composition with soil
factors and successional stages ......................
Single-species dominant forests in tropical Africa
and other tropical areas .............................
Objectives ................................................
Study site ................................................
Methods ...................................................
Results ...................................................
Forest description ...................................
Major species ........................................
Distribution of shade—tolerant species ...............
Soils ................................................
Forest islands .......................................
Discussion ................................................
The mbau forest in the Ituri study area ..............
Mbau forest in other parts of
GilbertiadEndron dbwevrei's range ....................
A comparison of other single-dominant tropical
forests with the mbau forest of central Africa ........
Footnotes .................................................
Appendices ................................................
List of References ........................................

12
12
16
18
21
27
3O
30
37
4O
42
45

49
49

51

59

65

66

68

Chapter two: A Comparative Study of the Impact of Natural
Disturbance on Forest Composition in Northeastern

Zaire ..................................................... 74
Introduction .............................................. 74
Background and Literature Review .......................... 77
Methods ................................................... 81
Results ................................................... 88
Discussion ................................................ 117

Species diversity relative to size and frequency

of treefall gaps ..................................... 117

Species diversity relative to the variety of gap

microsites ........................................... 119

Contribution of gap-dependent species to overall

forest diversity ..................................... 121.

Distribution of forest types relative to major

past disturbances .................................... 122
Footnotes ................................................. 127
List of References ........................................ 128

Chapter three: Regeneration Patterns of Dominant Trees in

Low and High Diversity Tropical Forests ................... 132
Introduction .............................................. 132
Regeneration-niche hypothesis ........................ 133
Seed/seedling predation hypothesis ................... 138
Methods ................................................... 146
Results ................................................... 158
Phenology ............................................ 158
Pollination experiments .............................. 162
Seed dispersal ....................................... 165
Seed-transplants ..................................... 166
Trap-grids ........................................... 179
Seedling survival .................................... 184
Discussion ................................................ 192
List of References ........................................ 212

vi

LIST OF TABLES

Table
CHAPTER ONE

1 Structure and composition of mixed forest and mbau
forest in the Ituri Forest of Zaire .......................

2 Species richness and stem density for different size
classes in mixed and mbau forest types of the Ituri
Forest. Zaire .............................................

3 Basal area of species accounting for >O.5 x of basal
area in mbau forest and/or mixed forest ...................

4 Size class distribution of dominant and sub-dominant
canopy species in the understories of mbau forest
and mixed forest ..........................................

5 Soil properties in mixed and mbau forest types of the
Ituri Forest. Zaire .......................................

6 Average importance values of Gilbertjodendron dewevrei
in four mbau forest islands ...............................

7 Comparative densities of Gilbertiodendron dewevrei in
mbau forests of the Uele and Ituri regions for different
girth classes .............................................

8 Summary of published information on single-species-
dominant moist tropical forests ...........................

CHAPTER TWO

1 Size and frequency of treefall gaps on 2.5 ha plots in
mixed and mbau forest types ...............................

2 Percent of gaps with specific characteristics relevant
to seedling microsites ....................................

3 Occurrence of common gap-regenerating tree species in
the treefall gaps surveyed ................................

4 Pioneer species germinations in gaps of different size
in mixed and mbau forest types ............................

vii

55

6O

89

91

95

97

10

11

Frequency of old gaps and mature pioneer trees in 2.5 ha
plots in mixed and mbau forest types ...................... 99

Density per 100 m2 of surviving saplings and poles
in treefall gaps .......................................... 101

Large viable seeds (>5 cm length) found in the litter
and uppermost soil layer of mbau and mixed forests ........ 104

Number of seed germinations in soil samples from
three forest types during a wet and a dry season .......... 106

Species richness of different diameter classes in
15 year-old secondary forest, 40 year-old secondary
forest and mature mixed and mbau forests .................. 112

Stem densities of different diameter classes in

15 year-old secondary forest. 40 year—old secondary

forest, and mature mixed and mbau forests ................. 113
Comparative density of saplings and pole-size individuals

of mature forest dominants in the subcanopies of

secondary and mature forests .............................. 116

CHAPTER THREE

Species diversity of mixed and mbau forest types in the
Ituri Forest, Zaire ....................................... 142

Size class distribution of three co-dominant canopy
species in mixed forest ................................... 144

Experimental designs and treatments applied to seed-
transplant plots .......................................... 150

Seed characteristics of the three dominant
caesalpiniaceous tree species ............................. 154

Percent of marked Brachystegia laurentii and
Gilbertiodendron dewevrei trees producing flowers
and fruits, 1981-1983 ..................................... 159

Synchrony of flowering between trees within stands ........ 161

Reproductive status of individual trees on consecutive
years ..................................................... 163

Record of ovary maturation subsequent to hand pollination
if GilbertiodEndron dewevrej. 1982 ........................ 164

Type of seed damage and rodent-check at piles of
GilbertiodEndron dewevrei seeds ........................... 169

viii

10

11

12

13

14

15

16

17

18

Survival of cynometra alexandri seeds and seedlings

in seed—

transplant plots .................................. 171

Survival of Brachystegia Iaurentii seeds and

seedlings in seed-transplant plots ........................ 173
Survival of Gilbertjodendron dewevrei seeds and

seedlings in seed-transplant plots (1981) ................. 176
Survival of Gilbertiodendran dewevrei seeds and

seedlings in seed-transplant plots (1982) ................. 178
Percent total seed mortality due to insects or

mammals at seed-transplant plots .......................... 180
Rodents caught on trap grids during mast and no-mast

seasons in mbau and mixed forest .......................... 182
Density of seedlings in the forest understory ............. 187

Growth and survival of small Gilbertiodendron
dewevrei seedlings in the shaded forest understory ........ 193

The predicted and actual Ituri Forest communities
where effects of three processes perinent to species
diversity were recorded ................................... 207

ix

LIST OF FIGURES

Figure
INTRODUCTION
1 The Ituri Forest. Zaire .................................. 3
CHAPTER ONE
1 The Ituri Forest, Zaire .................................. 11

2 The central Ituri Forest study site showing the
locations of forest types and research areas ............. 23

3 Species-area curves generated for stems >2.5 cm dbh
in mixed and mbau forests ................................ 35

4 Importance values of the dominant species for different
size classes in islands of mbau forests. large areas
of mbau forest and mixed forest .......................... 48

5 Reported occurrences of mbau forest within the

evergreen forest block of Zaire .......................... 53
CHAPTER TWO
1 The Ituri Forest of Zaire ................................ 76

2 The central Ituri Forest study site showing the
locations of forest types and research areas ............. 83

3 The frequency with which individual species occur
as seedlings in treefall gaps ............................ 94

4 Abundance of viable seeds of small-seeded woody species
in the soils of three forest types during the wet
and dry season ........................................... 108
CHAPTER THREE
1 The Ituri Forest of Zaire ................................ 135

2 The central Ituri Forest study site showing the
locations of forest types and research areas ............. 137

Rodents caught on successive nights in snap traps
on two trap grids in mixed and mbau forests .............. 186

The importance of Brachystegia laurentii in
mixed forest and Gilbertiodendron dewevrei in
mbau forest for different size classes ................... 190

Leaf index (leaves and leaf scars) of Gilbertiodendron
dewevrei <1 m in height in the shaded forest
understory ............................................... 195

Percent survival of mixed and mbau forest species as
seeds or seedlings in mast and no-mast areas ............. 200a

Percent seed survival with and without mammal
exclosures in mast and no-mast areas ..................... 204

xi

INTRODUCTION

High tree species diversity is one of the outstanding
characteristics of many tropical forests (Richards 1952. Walter 1973.
Hhitmore 1984). Tropical forests "with an extremely large number of
trees of one predominating species are rare" (Letouzey, 1978).

An exception to the general pattern occurs in the Ituri Forest
of northeastern Zaire (Figure 1). There are two major forest types in

‘the Ituri watershed, each of which covers thousands of contiguous
square kilometers. One of these types, the mbau forest. is dominated
by a single species of tree which commonly comprises 90% or more of
canopy level individuals. The canopy of the mixed forest type, on the
crther hand. is closer to that expected in the tropics. Rarely does a
single species or even a combination of two species account for more
than 50% of the crowns present.

These two forest types co-occur in the southern and western
two thirds of the Ituri Forest, whose total area is approximately
70.000 kmz. The borders between the two types are floristically
abrupt but do not correspond to topographic gradients. Furthermore, as
a result of their widespread co-occurence. both forest types share a
sililar climatic regime. It is thus possible to contrast a
8Pficies-rich tropical forest with a relatively species-poor, single-

8Decies-dominant tropical forest under similar environmental

conditions, allowing a comparative approach in exploring causes of

Figure 1. The Ituri Forest. Zaire.

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species richness in tropical forests.

The principle behind this comparative approach is that
different biotic and/or abiotic factors. having a strong influence on
species distributions and abundances. led to the diversity differences
of the two forest types and continue to maintain these differences. It
should, therefore, be possible to detect mechanisms perpetuating
differences in species richness by comparing the two forests. Relevant

hypotheses tested in this manner include the following:

In chapter one:

1. The species—poor mbau forest developed due to Specific soil
conditions different from those which support relatively species-
rich forests.

2. The mbau forest, dominated by a single species, is part of a
successional sequence leading toward a more species-rich

community.

In chapter two:

3. The greater species diversity of the mixed forest is maintained by
a natural disturbance regime different from that characteristic of
mbau forest (more treefalls. larger gaps. etc.).

4. One forest type is more resilient to damage than the other and is

more likely to become established after major disturbance.

In chapter three:

5. Tree species in the mixed forest may be able to co—exist as a

result of specialization to relatively narrowly defined
"regeneration niches". The single dominant in mbau forest can
produce seed and become established under a broader array of

conditions.

. No single species is able to dominate in mixed forest because of

relatively high seed and seedling mortality, particularly in the
vicinity of parent trees. Conversely, in the mbau forest. the

dominant tree is relatively free of seed predators.

LIST OF REFERENCES

Leigh. E. 6., Jr. 1982. Why are there so many kinds of tropical
trees? pages 63-66 in E. G. Leigh. Jr., A. S. Rand. and D. M.
Windsor, eds. The Ecology of a Tropical Forest: Seasonal
Rhythms and Long-term Changes. Smithsonian Institution Press,
Washington. D. C.

Letouzey, R. 1978. Floristic composition and typology. pages 91—111
in Tropical Forest Ecosystems. UNESCO, Paris.

Richards, P. W. 1952. The Tropical Rain Forest: an Ecological Study.
450 pages. Cambridge University Press. Cambridge.

Walter, H. 1973. Vegetation of the Earth in Relation to Climate and
the Eco-physiological Conditions. translated from 2nd German
edition by Joy Wieser. 237 pages. Springer-Verlag. N.Y.

Whitmore, T. C. 1984. Tropical Rain Forests of the Far East. 2nd
edition. Clarendon Press. Oxford.

CHAPTER I

THE HEAD FOREST IN ZAIRE:
EDAPHIC AND SUCCESSIONAL GRADIENTS IN RELATION TO

SINGLE-SPECIES DOMINANCE IN AN AFRICAN TROPICAL FOREST

INTRODUCTION

The latitudinal gradient in species diversity is regarded as
"the most important geographical pattern" regarding the number of
species in communities (Ricklefs 1973). Leigh (1982), Hhitmore (1984),
and Gentry (1982) have recently reviewed this trend as it applies to
the number of tree species in a given area of tropical forest. They
confirm the generalization of earlier authors (Richards 1952) that
tropical forests are considerably more diverse than temperate forests.

The generalization is applied only to mature or "climax"1
tropical forests. There are references in the literature to tropical
secondary forests which are relatively species poor (1-10 woody
:Bpecies. Budowski 1970) or locally dominated by single species

(Iiichards 1952 and Whitmore 1984). The presumed course of tropical

anccession. therefore. is towards increased numbers of tree species and

decreased dominance by any single tree species (Budowski 1970).

Janzen (1974) pointed out that, contrary to expectation.
stable tropical forest communities do exist that are species poor
(1974). He attributed this floristic poverty to limiting edaphic
conditions as exemplified by the Heath Forest growing on bleached sands
or podsols of Bako National Forest, Sarawak. Richards (1941) had
earlier commented on the similarity between the forests on podsols in
southeast Asia and forests on similar soils in British Guiana (now
Guyana) in South America. He inferred that forests on relatively
unfavorable soils show a tendency toward single species dominance
(Richards 1952). A single caesalpiniaceous species. Eperua
falcata, dominates Wallaba Forest on white sands in Guyana (Davis and
Richards 1934). Ashton (1971) suggested that the Heath Forest in
Sarawak demonstrated a general relationship between soil conditions and
tree species diversity in tropical forests: "the ideal soil conditions
for the development of a high tropical rain forest rich in tree species
is therefore where the soil is deep, rich in nutrients. well drained
but with constantly available water. The opposite of these three
conditions is the worst, and leads to poverty in size and number of
species..." According to Brunig (1973) the limiting site conditions
lead to a reduction of the available niche-hyperspace resulting in low
species diversity and dominance by only a few species.

Less easily categorized are the species-poor tropical forests

Iflhich were considered the "climatic climax"2 by botanists and
ecologists working in a particular area. Notable are the tropical

1" orests dominated by single species. There have been a number of

detailed studies of such forests where the field workers failed to
comment on any correlation between single species dominance and a given
soil type and yet the community was considered mature (Beard 1946.
Eggeling 1947, Germain and Evrard 1956, Gerard 1960. Lee 1967).
Particularly in the earlier literature. reference to such tropical
forests was not uncommon (Zon 1915. Laan 1927. Koopman and Verhoff
1938). Two recent studies reported single species dominated forests
occurring on soils similar to those of adjacent mixed forests (Rankin
1978. Swaine and Hall 1981).

In this paper I examine a forest dominated by the single
species Gilbertiodendron dewevrei (Caesalpiniaceae). The study
site was in the Ituri Forest of northeastern Zaire (Figure 1). The
forest type studied. called mbau forest after the local name for the
dominant species. is well represented in much of the Zaire (Congo)
basin. It is considered by some as representative of the climatic
climax for equatorial Africa on well-drained soils (Lebrun and Gilbert
1954. Gerard 1960. Jongen et al.. 1960). Other authors suggest that
this forest type is actually "edaphically determinined" (Richards 1952.
Janzen 1981).

The field study reported here compares mbau forest. dominated
by G. dewevrei, with adjacent mixed forest. The compositions
of the two forests. their edaphic status. and successional states are
compared. In addition to field data. literature concerning mbau forest
was consulted in order to construct a larger scale view of variation
relative to soils. Other tropical single-dominant forest studies were

also reviewed in order to determine the generality of this study's

10

Figure 1. The Ituri Forest. Zaire.

11

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findings and its relevance to other tropical areas.

BACKGROUND
variation of tropical forest composition with

soil factors and successional stages.

Tropical biologists do not agree as to how much of the
observed variation in tropical forest composition is caused by
variation in substrate. There is also no consensus as to the types of
substrate changes most likely to result in changes in community
composition.

Kruckeberg (1969). citing examples from temperate North
America, asserts that "within areas of broad climatic
similarity...geological variability provides the major source of
regional biotic diversity". Goldberg (1985) working in Mexico
demonstrated that species from one forest type were excluded from an
adjacent forest type by soil characteristics originating from different
parent materials. On the other hand. researchers with wide experience
in the tropics have doubted any direct relationship between parent
material and forest composition. Lemée (1961) gave an example from
Ivory Coast of a forest type growing. without detectable difference, on
soils derived from different parent materials. Likewise Wong and
Hhitmore (Pasoh, Malaya, 1970), Hall and Swaine (Ghana 1981) and Leigh
(Barro Colorado Island, Panama, 1982) all reported that different

geological substrates do not give rise to forests of significantly

13

different composition.

Hall and Swaine (1981) suggested that this lack of correlation
may be due to extensive weathering of the tropical substrates, the
parent rock having been buried under great depths of weathered
material. Likewise. Kruckeberg (1969) commented that the influence of
the parent material was most obvious where the processes of soil
formation were impeded. It is, therefore. not unexpected that in
southeast Asia tropical forests growing on rapidly eroding limestone
are frequently characterized by the presence of endemic species and
unusual species distributions (Hhitmore 1984).

Observers have pointed out the unique vegetation growing on
highly leached white sand soils in both the neo- and paleotropics as
evidence for the impact of soil nutrient availability (Richards 1961,
Ashton 1971). But when less extreme soils are looked at the
relationship becomes ambiguous. Ashton (1977) and Brunig (1983)
suggest that the greatest forest diversity is found on soils with
intermediate levels of available nutrients.

Much of the work attempting to correlate soil variables with
vegetation variables has been carried out in Southeast Asia.
Multivariate analyses have. in some cases, shown that tree species
associations were correlated with complex soil factors including
nutrient status (Austin at al. 1972, Ashton 1976. Baillie and Ashton
1983, Newberry and Proctor 1984). The results of such analyses have
not been consistent. A study in Sarawak (Newberry and Proctor 1984)
found significant associations between vegetation "classes" and soil

mineral parameters in Heath Forest and Alluvial Forest but not in

14

Dipterocarp Forest or forest over limestone. Tree species that
appeared to have narrow and different edaphic ranges in Borneo occur
together in a single forest type in Malaya (Austin, et al. 1972). In
some cases plots known to have distinctly different soils failed to
show differences in vegetation (Austin, et a1. 1972). As summarized by
Ihitmore (1984) studies relating soil chemistry to tropical forest
composition have, so far. provided only "cryptic results" and
”enigmatic correlations".

Among the first published, and most cited. examples of change
in tropical forest composition along an edaphic gradient is the study
by Davis and Richards (1933, 1934) at Moraballi Creek in British
Guiana. Five forest types were distinguished within close proximity.
In three of these, the dominant species made up more than 60% of all
large trees (> 41 cm diameter). From their observations they
generalized that the series of forest types was determined by changes
in physical characteristics of the soil. perhaps in combination with
changes in soil depth. They assumed soil chemistry to be similar along
the soil gradient as the parent material and soil pH did not change.

Forest composition changes have been linked to changes in soil
texture because of the influence of soil texture on soil
moisture-holding capacity. Lemée (1961) mentions two floristically
distinct forest types in Ivory Coast that occur on soils with different
water retention capabilities. He also states that near their climatic
distribution limit species may become restricted to moister soils.

Hall and Swaine (1981) report that drier forest types occur on shallow

soils and that species diversity increases with wetter conditions.

15

According to a 1977 Unesco/UNEP/FAO report: "The role of
hydromorphology and texture (as a factor of water retention) needs to
be underlined as regards the distribution of humid tropical forests" (p
261).

In summary there are three substrate factors that have been
cited as being important determinants of forest type. These are:
differences in geology or soil parent material, differences in the
nutrient status of the soil. and differences in soil texture or
water-holding capacity. The importance of these three factors as
regards changes in tree species composition varies from site to site.
In general it appears that the influence of parent material is most
pronounced where soils are young; the chemical composition of soils has
the greatest impact where the contrast in available nutrients is large
with extreme nutrient deficiency in one forest type; finally, the
water—holding capacity of the soil is most influential where local
precipitation is marginal relative to the moisture requirements of the

species in question.

Vegetation discontinuities, that might be attributed to soil
discontinuities, have at times been found to represent different seral
stages on the same substrate. Some tropical forest areas have large
scale natural disturbances such as earthquakes (Garwood et al.. 1979)
and wind storms (Wyatt-Smith 1954. Whitmore 1974) that are common
enough to result in large areas of successional forests. These younger
forests may have abrupt boundaries and, as in the case of the storm

forest in Helantan (Hyatt-Smith 1954). may be dominated by a single

dl

16

tree species.

Without historical records. it is difficult to identify areas
of past disturbance. Confusion between late secondary forest and
primary forest is likely (Davis and Richards 1934. Budowski 1970). A
survey of the abundance of tree species whose juveniles are
shade-tolerant and of the size-class distribution of those species has
been used to compare the successional status of different forest types
(Whitmore 1974). As a forest matures it is likely to be increasingly
dominated by shade—tolerant species which eventually become more
important than light-demanding species in the canopy (Horn 1971).

The maturity of a forest can be assessed by surveying the abundance and
size class distribution of shade-tolerant species. A forest in which
the canopy species are well represented in several levels of the

understory is likely to have a relatively stable species composition.

Single-species dbminant forests in

tropical Africa and other tropical areas.

Upland single-dominant forests cover large areas of tropical
central Africa. They have frequently been considered the climatic
climax by plant ecologists and botanists (Eggeling 1947, Lebrun and
Gilbert 1954, Germain and Evrard 1956, Devred 1958. Gérard 1960). The
dominant species are usually of the Caesalpiniaceae with different
species important in different areas. including : Gilbertiodendron
idewevrei (De Wild.) Léonard, Brachystegia laurentii (De Wild.)

Louis, Cynometra alexandri C.H.Wright, JUIbernardia seretii (De

17

Wild.) Troupin. Afichelsonia microphylla (Troupin) Hauman. Forests
dominated by one or another of these species reach their greatest
extent in Zaire although 0. alexandri forests are found in Uganda
(Eggeling 1947, Hamilton 1981) and G. dewevrei dominated forests
occur in Central African Republic, Cameroon, and Gabon (Letouzey
1970).

In the Congo basin, single-dominant forests are often
evergreen communities occuring on well-drained soils. Such forests
were classified as "les foréts ombrophiles equatoriales" (closed
equatorial forests) and given the rank of order, Gilbertiodendretalia
Dewevrei. by Lebrun and Gilbert (1954). They believed this order to
correspond to the association. Tarrietia-Mapanietum. also apparently
characterized by single dominance. described by Mangenot (1950) for the
Ivory Coast in West Africa. In central Africa, the order is best
represented in a large arc surrounding the Congo basin to the north and
east. The Ituri Forest occurs in this area. Lebrun and Gilbert (1954)
surmised that the poor representation of this forest type in the
low—lying interior of the Congo basin was probably due to the abundance
of marshy and flooded substrates.

Single-dominant evergreen forests on well-drained soils occur
in the American tropics (Beard 1946, Richards 1952), tropical Australia
(Joseph Connell. personal communication), and Southeast Asia (Zon 1915,
Laan 1927, Hoopman and Verhoff 1938. Whitmore 1984). In many of the
mentioned forests the dominant accounts for more than 80% of the
canopy-size trees.

Single-dominant forests are sometimes confined to relatively

18

small areas within a sea of mixed tropical forest, as, for instance.
Talbotiella gentii Hutch. & Greenway (Caesalpiniaceae) forest in
Ghana (Swaine and Hall 1981). Brachystegia laurentii forest in
Zaire (Germain and Evrard 1956) and Lecomptedoxa klaineana (Pierre)
Dubard (Sapotaceae) forest in Cameroon (Duncan Thomas, personal
communication). They are also found covering thousands of hectares, as
with Mbra excelsa Benth. forest in Malaya (Lee 1967. Whitmore
Dryobalanops aromatics Gaertn. forest in Malaya (Lee 1967, Whitmore
1984), and Gilbertiodendron dbwevrei forest in Zaire (Gérard
1960).

Gilbertiodendron dewevrei dominates extensive areas of
upland forest at the center of its range; however. it is also found as
smaller patches or galleries along watercourses in areas where the
principal forest type is mixed (Louis 1947, Gérard 1960. Pecrot and
Leonard 1960, Jamagne 1965). It has been suggested that small islands
of the monodominant forest might be restricted to moister areas beyond

the "real" climatic limit of the forest type (Gerard 1960).

OBJECTIVES

The objective of this study was to investigate the possibility
that monodominance by Gilbertiodendron dewevrei in mbau forest
depends on successional stage or soil conditions. It was assumed that
if either factor was critical, it would be significantly different

between mbau forest and the adjacent mixed forest in which 6.

19

dewevrei is essentially absent. The hypotheses tested were:

1. The mbau forest is a younger successional forest than mixed
forest. This is tested by determining the relative importance of
shade-tolerant species in different size classes.

2. Soil conditions in mbau forest. including soil texture and
chemical composition. are different from in mixed forest. This is
tested by comparing these soil parameters in both forest types.

As suggested in the background section, the transition between
the two forest types in the study area may represent a climatic limit
for either 6. dewevrei or important species of the mixed forest.

If this is the case it may be reflected in the species composition of
the forest islands located beyond the main transition area. The
climatically-stressed species were expected to have a lower
representation and to exhibit poorer regeneration in the forest islands
than in the main forest blocks. Alternatively the soil texture of
outlying "islands" may compensate for the climatic stress in the
surrounding forest resulting in range-extended moisture-limited species
on soils with good water-holding capacity. The hypotheses tested

were:

3. The representation of G. dewevrei in canopy and/or juvenile
size classes is lower in small isolated islands of mbau forest than in
large unbroken blocks of mbau forest. This is tested by comparing the
density of the species in randomly-located plots both in mbau forest
islands and in areas where mbau forest is well established over two or
more contiguous square kilometers.

4. The soil texture is significantly different in small islands of

 

20

one forest type from the soil texture of the surrounding forest type.
This is tested by comparison of the percent sand composition of these
soils.

It was beyond the scope of this study to make field visits to
mbau forests in other parts of the range of G. dewevrei. The
components of forest composition and structure which suggest the
community is successional or mature in the Ituri region may not be
consistent for mbau forest in other parts of its range. Likewise,
interpretation of an association between certain edaphic factors and
mbau forest distribution in the study area would be improved by
information concerning mbau forest soils in other areas.

Comparison of forest composition and structure between the
mbau forest in the study area and another mbau forest is made possible
by the detailed study of mbau forest made by Gerard (1960) in the Uele
region, 400-500 km northwest of the Ituri research site. Gérard
carried out a floristic inventory of mbau forest modelled on the
Braun-Blanquet phytosociological method but with an important
modification. He collected quantitative data on species' presence by
circumference class. This permited a comparison of the relative
importance of dominant species in different size classes for the Uele
and Ituri forests.

There are also published reports which provide evidence of the
various edaphic conditions which have supported mbau forest. In the
1950s and the 19603 several installments of a larger project to map the
soils and vegetation of the then Belgian Congo were published (Frankart

1960. Jamagne 1965. Jongen, et al. 1960. Pecrot and Leonard 1960,

21

Wambeke and Evrard 1954). This project was not finished. The areas
mapped did not include the center of Gilbertiodendron dewevrei's
range but peripheral areas to the northwest and south were included.
These studies along with our own observations and those of Gérard
(1960) and Louis (1947) allowed an assessment of the range of soils.

over a large area, on which mbau forest occurs.

STUDY SITE

The field study was conducted between January 1981 and June
1983 in the central part of the Ituri Forest. Most field work occurred
within a 15 km radius of the town of Epulu (1°25'N, 28°35'E) at a
transition zone between mbau forest, dominated by the single species.
Gilbertiodendron dewevrei, and mixed forest (Figure 2). The Ituri
Forest is bordered to the north and northeast by savanna (Figure 1).
The closest savanna/forest transition is 150 km from Epulu.: To the
east and southeast the Ituri Forest is bordered by mountain forest. To
the south and west there is continuous forest.

The soils in the central Ituri Forest developed from granites,
gneisses. and "very metamorphosed rock" of Precambrian age (Cahen and
Lepersonne 1948). Along with mbau and mixed forest there are areas of
periodically flooded forest along river courses and drier hilltop
forests. The two latter communities showed distinct structural and
compositional characteristics and were not included in this study.

The transition from mbau forest to mixed forest is abrupt and

22

Figure 2. The central Ituri Forest study site. with locations of
forest types and research areas.
Plot locations:
S-A ... Species-area relationships

F-C ... Forest composition

23

 

 

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30.0”. 3031 a
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manna

0.05m

  

OI“.
(In

 

 

 

24

occurs without any altitudinal or other apparent change in topography.
Edaphic differences related to topography were avoided by sampling only
mbau and mixed forest from well-drained upland sites. The two forest
types have extensive common borders; therefore. the same pool of tree
species is available for colonization of both communities along the
transition zone.

There has been no long-term collection of meteorological data
in the Ituri Forest. Bultot (1971) has the most complete compendium of
climatic data for Zaire. He estimates annual rainfall to be between
1700 and 1800 mm for the Ituri Forest based on 30 years of records at
surrounding stations. He further projects that once in forty years an
annual maximum of between 2200 and 2400 mm and an annual minimum of
between 1400 and 1600 mm of rainfall will occur. According to Bultot,
three months. December. January, and February, are likely to receive
less than 100 mm of rain per month. This corresponds to observations
made at Epulu during this study. Of the three "dry seasons" in
1981-1983. two had monthly rainfalls of less than 100 mm for January
and February.

The climatic records most pertinent to this study were
collected. starting in the 19303. at Kisangani and Yangambi, 460 and
520 km west, respectively, from the Epulu study site. Forests similar
to those at Epulu occur in the vicinity of Yangambi and Kisangani.
There are areas of forest dominated by the same species which are
dominant at Epulu. notably B. laurentii and G. dewevrei. The
elevation at Yangambi is 470 m whereas the Epulu study site is at 750

m. The change in elevation is gradual but is likely associated with

25

lower mean annual temperatures at Epulu. Latitudes are similar (0°49'N
at Yangambi and 1°25'N at Epulu) and the mean annual precipitation is
similar. 1700 - 1800 mm rainfall. The annual mean temperature at
Yangambi is 24.5°C (for years 1932-1938) with no monthly means greater
than 25.2°C (Bernard 1945). The mean annual biotemperature is,
therefore, equal to the mean annual recorded temperature (see Holdridge
et a1. 1971).

Using these data it is possible to classify Yangambi according
to the Holdridge Life Zone system (Holdridge et a1. 1971) as
Subtropical Moist Forest, warm transition. Epulu is also in the same
Life Zone although possibly not the warm transition.

This classification, however. seems inappropriate on two
counts. First. the subtropical category is misleading as both sites
are less than 2° from the equator and both span the equator. The
second has to do with the physiognomy and phenology of the forests
themselves. Subtropical moist forests as described by Holdridge et al.
(1971: 703-711) are shorter. more deciduous and drier than the central
African forests. As described by Holdridge et al.. in this Life Zone
trees larger than 25 cm dbh (diameter at 1.5 m from the ground) are
uncommon, lianas are rare and no distinct species-dominants are
present. None of these characteristics fit the forests encircling the
Congo basin. A possible reason for the striking difference in forests
which are purportedly of the same Life Zone is the difference in
seasonality. The Subtropical Moist Forests described by Holdridge et
al. (1971) had longer, more accentuated dry seasons.

The fact that the Holdridge Life Zone system is not easily

26
used for classification of central African vegetation does not mean
that the distribution of dominant species is independent of climatic
factors. Nor does it follow that the physiognomy of the forest is not
correlated with climatic factors. Gerard (1960) has suggested that the
northern limit of forests dominated by G. dewevrei corresponds
roughly with the northern limit of the Am climatic region as defined by
Koppen and mapped by Bultot (1950). However, this has not been
verified throughout the range of this forest type.

White (1983) classifies the vegetation of Africa into
relatively broad categories. The scheme was developed uniquely for
African vegetation. The Ituri Forest and most of the forest in the
Guineo-Congolian region are classified as "rain forest". The forests
in this group are generally greater than 30 m in height, are primarily
evergreen, and contain abundant lianas. Within this broad
classification the Ituri Forest would likely fall into two of White's
subgroups: the mbau forest belonging to ”single dominant moist
evergreen and semi-evergreen rain forest" and mixed forest belonging to
”mixed moist semi-evergreen rain forest". All the dominants in the
Ituri Forest are evergreen but the canopy contains scattered deciduous
elements as well.

White's classification, which is based on physiognomy, has
no pretension of being finely tuned to climatic variation. He does,
however, make the general observation that African rain forests are dry

relative to the so-called rain forests in other tropical regions.

27

METHODS

Species-area curves were generated for both mixed forest and
mbau forest from one series of nested plots in each forest type
(located in Figure 2 as S-A). The smallest plot was a square of 10m on
a side; this was included in a plot of 20 m on a side which was
included in a plot of 40 m on a side and so on. The dimensions of each
plot were twice those of the previous plot with the largest plots being
a square of 160 m on a side (= 2.56 ha). Only stems greater than 2.5
cm dbh were counted. with all new species on any plot being added to
the cumulative total to make the next point on the species-area curve.

Recognizing the possibility for local and regional differences
in forest diversity and structure. forest composition data were
collected from six different sites, three in mixed and three in mbau
forest (located on Figure 2 as F-C). There were eight plots surveyed
per site totaling 24 square plots, of 625 m2 per plot. in each
forest type. All trees > 10 cm dbh and all lianes > 2.5 cm diameter
were identified to species or common name. At each site four of the
eight 25 m x 25 m plots were divided into smaller nested plots. In 15
m x 15 m plots all saplings > 2.5 cm dbh and g 10 cm dbh were
identified. In 5 m x 5 m plots stems > 0.5 m in height but_g 2.5
cm dbh were identified. Finally, seedlings 5 0.5 m in height
were sampled in 2.5 m x 2.5 m plots. The diameter at breast height
(1.5 m) or above buttresses was measured for all individuals > 10 cm

dbh. These larger individuals were also permanently marked with

28

aluminum tags.

Field identifications were made by local field workers using
Kibila. the vernacular, common names. We worked with a group of men
from several local bands of semi-nomadic hunter-gatherers. Although
the composition of the field crew fluctuated over the 30—month study
period all workers assisted in both mbau and mixed forest. Two elder
men who were consistently part of the work crew made identifications
separately.

Our main aim was to differentiate between biological species.
Along with vernacular names. bark, slash, and leaf characteristics were
used. Whenever an identification was suspect (possibly the same or
different from previous identifications) we sent a climber to collect
leaves to be used for later comparisons

In conjunction with the forest composition work, 464 fertile
collections of botanical specimens. primarily trees. were made. These
were identified with the help of H. Breyne at the national herbarium in
Kinshasa. Zaire. L. Liben at the Jardin Botanique at Meise. Belgium,
and Terry Pennington at Kew. Surrey, England. Additional
identifications were made by A.J.M. Leuwenberg (Apocynaceae) and F.
White (Ebenaceae). Sterile specimens were compared to our duplicates
of the fertile material of the same common name. We have confidence in
the integrity of biological species identified at each site. There is
a greater possibility that the same species might have been given more
than one name or that different species might have been given the same
name at different sites. All calculations, therefore. were made on a

site by site basis. Full collections of the fertile specimens are at

29

the national herbarium in Kinshasa, Zaire, and at the Jardin Botanique
National at Meise. Belgium.

Two to four soil samples at a 20 cm depth were taken at each
of the six sites (F-C, fig. 2) for a total of 22 samples.
This depth was chosen to be below the immediate influence of leachates
from the litter yet within the root zone of established seedlings. An
additional 11 soil samples were taken at 150 cm depth. Textural
analysis of the soils was made using a soil hydrometer method (Brower
and Zar 1977). Soil was mixed 1:1 with water for pH readings.
Chemical analyses were made following the recommendations of the North
Dakota Agricultural Experiment Station Bulletin #499 (Dahnke 1980).
Phosphorus was extracted with hydrochloric acid in ammonium fluoride
and the concentration determined with a calorimeter. Exchangeable
cations were extracted with ammonium acetate and their concentration
determined with the atomic absorption spectrophotometer at the Michigan
State University soil laboratory.

A soil sample was taken from the center of each of three small
islands of mbau forest (consisting of approximately 10-20 mature G.
dewevrei). Two samples were also taken from the surrounding mixed
forest on opposite sides of each mbau island. The soils from five
islands of mixed forest isolated within mbau forest were similarly
sampled. The islands of mixed forest were less than 1000 m2 in
size. and were areas conspicuously lacking G. dbwevrei (generally
dominated by B. laurentii). A textural analysis (hydrometer method)
was made of these soils.

The floristic composition of four islands of mbau forest.

 

30

surrounded by mixed forest, was sampled. These islands are too small
to appear on Figure 2. They varied in size from approximately 0.1 ha
to 1.0 ha. All stems > 2.5 cm dbh were identified to species or common
name in two 15 m x 15 m plots in each island. Diameter measurements
were taken on all trees > 10 cm dbh. G. dewevrei seedlings were
recorded in a 5 m x 5 m plot included in each larger plot. Seedlings
were noted as being in one of two size classes: 3 0.5 m in height
or stems > 0.5 m in height but 5 2.5 cm dbh.

Structural and floristic differences among the study sites
were examined by Student's t test or by analysis of variance
(nested design. and single classification with pre-planned
comparisons). Differences in the soil characteristics were examined
separately by Student's t test but, due to the inflated error rates
that result if t-test procedures are applied to more than one
outcome measure (Harris 1975), Hotelling's 12 test is used to
test the overall null hypothesis that soils in the two forests do not

differ in their means for any of the measured parameters.

RESULTS

Forest Description
The striking visual difference between single-dominant mbau
forest and the mixed forest results from their contrasting structures
(Table 1). Both are tall forests with most canopy crowns
attaining between 30 and 40 meters in height. At this height, the mbau

forest crown is homogeneous. formed of the contiguous crowns of 6.

 

 

 

31

dewevrei trees. Crowns of this species are deep and narrow. The
crown frequently accounts for more than half of a tree's total height
with a diameter of no more than 10 or 15 meters (G{rard 1960, pers.
obs.)

The mixed forest canopy, on the other hand. is more
heterogeneous with frequent emergents of 50 or more meters in height.
Canopy level crowns are often not contiguous. The openess this creates
in the upper level of the forest is accentuated by the fact that the
most abundant species have broad crowns with the leaves often
concentrated towards the ends of branches (Germain and Evrard 1956).
Crown diameter of B. laurentii, one of the most frequent canopy
species. averages 20 to 30 meters (pers. obs.).

The understories of both forest types are open. allowing easy
foot passage and good visibility for 10 meters or more. In mixed
forest a subcanopy layer between 10 and 25 meters in height becomes
dense in irregular patches. Although isolated individuals of all
heights are present in mbau forest. an identifiable middle layer above
10 meters is absent.

Standard diversity indices from mixed forest are significantly
higher than those from mbau forest (Table 1). The difference was
significant for both Simpson's and Shannon's diversity indices. both of
which take into account not only the number of species but also the
proportion of the total which occurs in each species.

Three dominance indices were calculated; all show
significantly greater dominance by a single species in mbau forest than

mixed forest (Table 1). In mbau forest 6. dewevrei accounted for

32

Table 1. Structure and composition of mixed forest and mbau forest in

the Ituri Forest of Zaire.

 

 

 

 

mbau forest mixed forest
canopy at closed canopy broken canopy
35-40 meters contiguous crowns frequent emergents
crowns deep crowns shallow
and narrow and wide
subcanopy open open
middle layer absent middle layer. 10-25 m
diversitya
’ b
Ds x 0.37 0.89 P<.01
SD (0.10) (0.05)
H' x 0 45 1.35 P< 001
SD (0.12) (0.11)
c
dominance
% stems x 79.13 28.37 P<.01
SD (6.5) (11.6)
Simpson 1 x 0.63 0.11 P<.01
SD (0.10) (0.05)
IR x 0.68 0.22 P<.001
SD (0.06) (0.06)
a

b

The mean of three site values for each forest type: each site value
was calculated for eight combined 625 m plots at each site.
Calculated only for stems >10 cm dbh.

Enuni-l)
Ds : Simpson diversity index : N(N-1) where ni is the number
of individuals of species 1 and N is the total number of

individuals.
H' : Shannon diversity index : -i(ni/N)log(ni/N)

Analysis by Student's t test; srcsine transformation of
percentages used for calculations.

The mean of three sites. as with the diversity indices.

% stems : percentage of all stems > 10 cm dbh accounted for by the most
abundant species (6. dewevrei in mbau forest; 6. lsurentii in

mixed forest).

inuni-i)
Simpson I : Simpson's dominance index NIH-1)
39 + Rf + RC
IR : Importance Ratio 3 where RD. Rf. and

RC are the density. frequency. and coverage of the most abundant
species in each forest type relative to the density. frequency and
coverage of all other species present.

33

79% of all stems >10 cm dbh. B. laurentii, the most common canopy
species in mixed forest, accounted for only 28% of all stems >10 cm
dbh. Simpson's dominance index, which incorporates densities of all
species present, was significantly higher for mbau forest than for
mixed forest. The importance ratio, also significantly greater for
G. dewevrei in mbau forest than B. laurentii in mixed forest,
included in each case. the relative frequency, density. and coverage
(measured as basal area) of the dominant species in its forest type.

Species-area relationships were compared after censusing 2.56
ha plots in each forest type. The mixed forest area contained 143
woody species > 2.5 cm diameter, 111 of which were trees. The
remainder were lianas. The mbau forest area contained a total of 95
species > 2.5 cm diameter of which 74 were trees (Appendix A). These
values represent 33.6% fewer total species and 33.3% fewer tree
species. respectively, than in mixed forest. The species-area curve
(Figure 3) showed greater leveling off for mbau forest. on the largest
plots. than was shown for mixed forest. There was only a 7.9% increase
in cumulative number of species between the 1.28 ha and 2.56 ha plots
for mbau forest whereas. for the same increase in sample area. there
was a 16.3% increase in cumulative number of species for mixed forest
(Appendix A).

A statistical comparison of species richness for different
size classes was made from the replicated plots. There were
consistently more tree species in mixed forest plots than in mbau
forest plots for all size classes sampled (Table 2). Even the largest

size class (stems > 50 cm dbh). where mixed forest averaged fewer trees

34

Figure 3. Species—area curves generated for stems >2.5 cm dbh
in mixed and mbau forest types of the Ituri Forest.

Zaire.

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37

for a given area, contained more tree species in that area (Table 2).
An average of 18 species (SD=3.6) per 0.5 ha sampled occurred in mbau
forest whereas. there were 65 species (SD=11.8) for the same area
sampled in mixed forest for all trees > 10 cm dbh.

Mixed forest had significantly fewer large trees per hectare
but its sapling (>2.5 cm dbh 510 cm dbh) and pole (>10 cm dbh
525 cm dbh) size classes were significantly denser than in mbau
forest (Table 2). This difference in size class distribution may
correspond to the contrasts in forest structure especially the more
broken upper canopy and denser middle story observed in mixed forest.

Despite different distributions across the size classes, mean
basal area for the two forests was not significantly different (P >

2

.05) for trees > 10 cm dbh. Mbau forest basal area is 34.0 m per

ha and mixed forest basal area is 30.4 a2 per ha.

Major Species

In mbau forest a significantly greater proportion of the basal
area was accounted for by a single species than in mixed forest.
Gilbertiodendron dewevrei accounted for 88% of the mbau forest
basal area whereas the species accounting for the greatest basal area
in mixed forest, Brachystegia laurentii. only made up 32% of the
total basal area (P < .001. Student's t test). Calculated over all
three sites, 6. dewevrei had a mean basal area of 29.9 m2 per
ha; this was almost three times the basal area of B. laurentii in
mixed forest, 10.1 a2 per ha.

Despite the difference in dominance between the two forest

38

types. the species composition of subdominants was remarkably similar.
After Brachystegia laurentii, the species with the greatest basal
area in mixed forest were Cynometra alexandri with a mean basal

area of 4.99 m2 per ha, Cleistanthus michelsonii with 3.27

m2 per ha. and Klainedoxa gabonensis with 0.9 m2 per ha

(Table 3). These three species were also present in mbau forest.
Along with B. laurentii and praca guineensis (Don) Muell. Arg.
(Euphorbiaceae) they made the most significant addition to basal area
after 6. dewevrei. Their contribution, however, was much less in
mbau forest than in mixed forest (Table 3) and their occurrence more
erratic. C. alexandri. for instance, is absent from all eight

plots of two of the mbau forest sites. This pattern is exemplified by
U..guineensis (not in Table 3) whose basal area contribution

averaged over all three sites was 0.54 m2 per ha; however, most of
this was due to a single large tree of over 100 cm dbh occurring in a
single plot.

The dominant species in mbau forest and the most important
species in mixed forest are taxonomically related. Gilbertiodendron
dewevrei and Brachystegia laurentii belong to the same tribe,
Amherstieae, of the Caesalpiniaceae. The Congo basin is also the
center of distribution for both these species although 6. dewevrei
is known from throughout the central Guineen Region including Gabon,
Cameroun, and northern Angola. The second most important species in
mixed forest. cynometra alexandri, (Table 3) is also a member of
the Caesalpiniaceae; however. it belongs to the tribe Cynometreae.

C. alexandri extends farther east than the two former species. into

39

TABLE 3. Base] area of species accounting for >0.5% of basal area in mbau
forest and/or mixed forest.a

 

 

Brachystegia Cleistanthus Cynometra Klainedoxa Gilbertiodendron

 

site laurentii michelsonii alexandri gabonensis dewevrei

MBAU FOREST

Abeto 0.91 0.23 0.00 0.29 26.57

Samba 0.66 0.19 0.00 0.42 29.41

Mangb. 0.00 0:00 0.42 1.20 33.62
x 0.52 0.14 0.14 0.64 29.87

(60) c (0.47) (0.12) (0.24) (0.49) (3.55)

MIXED FOREST

Kapit. 9.75 4.03 3.85 0.55 0.00
Apanz. 8.20 3.99 3.80 0.55 0.00
Epulu 12.38 1.80 7.32 1.59 0.00

x 10.11 3.27 4.99 0.90 0.00
(SD) (2.11) (1.28) (2.02) (0.60) 0.00

 

Basal area is presented as the sum for each species. over the
eight 625 m plots at a given sampling site. reported as m
per hectare.

site abreviations: Wangb. - Mangbara. Kapit. - Kapituri. Apanz. -
Apanzoki.

c SD - standard deviation.

40

the westernmost pockets of forest in Uganda. The next two most
important species belong to different families; Cdeistanthus
michelsonii is of the Euphorbiaceae and Klainedbxa gabonensis is

of the Irvingeaceae (Simaroubaceae).

Distribution of Shade-tolerant Species

All the canopy species with large basal area in either forest
type were present in the shadey understory as well (Table 4).
Gilbertiodendron dewevrei and Brachystegia laurentii had the
greatest representation of shade-suppressed regeneration in the
subcanopy: however. the subdominant species were found in smaller size
classes under undisturbed canopy as well (Table 4). The typical
pattern for shade-tolerant species, of decreasing density from small to
large diameter classes. was shown for C. michelsonii (mixed forest
and mbau forest). C. aiexandri (mixed forest). B. laurentii
(mixed forest), and 6. dewevrei (mbau forest).

Some species occurred as large emergents in both forest types
but were unrepresented in the understory. This group included more
species than the shade-tolerant group but the individual species were
considerably rarer. On the plots sampled. this group of species was
represented by some of the largest individuals. including in mixed
forest : Irvingia gabonensis (Lecomte ex O'Rorke) Baille
(Irvingiaceae), Irvingia robur’Mildbr. (Irvingiaceae), Irvingia
grandifolia (Engl.) Engl. (Irvingiaceae), Kleinedbxa gabonensis
Pierre (Irvingiaceae), Alstonia boonei De Wild. (Apocynaceae).

Celtis adblphi-friderici Engl. (Ulmaceae). Pterocarpus soyauxii

41

TABLE 4. Size class distribution of dominant and sub-dominant canopy
species in the understories of mbau and mixed forests.

 

 

size a Mean number of individuals per hectare
class C.michelsonii C.alexandri K.gabonensis B.laurentii G.dewevrei

 

MBAC FOREST

saplings 7.4 0.0 0.0 18.5 307.0
poles 2.7 0.0 0.0 2.0 138.0
trees 1.3 1.3 0.7 3.3 62.0
large 0.0 0.0 2.0 0.0 66.0
trees

MIXED FOREST

saplings 55.6 18.5 7.4 178.0 0.0
poles 25.3 15.3 0.0 86.0 0.0
trees 10.0 8.0 0.0 39.0 0.0
large 4.7 11.0 2.7 11.0 0.0

trees

 

Size classes: seedlings. >0.5 m height 52.5 cm dbh: saplings.
>2.5 ca dbh 510 cm dbh: poles. >10 ca dbh 525 cm dbh:
trees. >25 cm dbh 550 cm dbh; large trees. >50 cm dbh.

42
(Papilionaceae), Farinari congensis (Rosaceae). Piptadeniastrum
afrcanun (Hook.f.) Brenan (Mimosaceae). In mbau forest. on the plots
sampled. fewer such species occurred, probably because of the rarity of
all species other than 6. dewevrei. Large emergents in the mbau
forest plots included Irvingia gabonensis. Tessmannia africana
Harms (Caesalpiniaceae) and Uhpaca guineensis (Euphorbiaceae).
These species. represented by large individuals, are apparently shade
intolerant as juveniles and may indicate areas of past treefall

disturbance in each forest type.

Soils

The soils under both mixed and mbau forest ranged in color
from reddish brown through ocher to yellowish brown. Soils were
generally deep. uniform in texture, and lacking distinct horizons from
approximately 3 cm to 150 cm depth. Such uniformity is characteristic
of tropical oxisols (Sanchez 1976). In only one of the 12 soil pits
dug to take 1.5 m soil samples was there hard substrate. This was at
135 cm in one of the mbau forest pits. Red clay soils are uncommon in
the central Ituri Forest: however, during the course of the study both
forest types were seen growing on such soils.

There was ho significant difference between mixed forest and
mbau forest for most soil factors tested (Table 5). Although there was
a significant difference in soil pH between the two forest types at 20
cm depth, both forests occurred on very acidic soils (mean pH of 3.9
and 4.2 for mixed and mbau respectively). Furthermore at 150 cm depth

the difference in pH was no longer significant suggesting that the

143

TABLE 5. Soil properties in mixed forest and mbau forest types
of the Ituri Forest. Zaire.

 

 

a. Mean values of the soil parameters analysed. Comparison was
by student's t test. null hypothesis: no difference
between forest types. nd - not detectable.

 

mbau forest mixed forest P
20 cm depth n = 12 n - 10
pH 4.17 3.96 P<.05
% sand 71.7 64.4 NS
K ppm 88.0 77.0 NS
Ca ppm 130.0 150.0 NS
Mg ppm nd nd
P ppm nd nd
150 cm depth n - 7 n - 4
pH 4.24 4.00 NS
% sand 68.4 54.7 NS
K ppm 45.0 107.0 P<.01
Ca ppm 152.0 119.0 NS
I: pp! nd nd
P ppm nd nd

 

h. Hotelling's 72 test for all parameters analysed on
20 cm depth soil samples. The null hypothesis: there is
no significant difference between the soils of mixed forest
and the soils of mbau forest.

Hotellings I'Square 6.7871
F value 1.4423
Degrees of freedom 4.17

P value < 0.2631 NS

 

44

slightly higher pH in mbau forest resulted from some difference in
leachates from the distinctive and relatively thick leaf litter of mbau
forest.

Phosphorus deficiency is common in acid soils (Andrew 1978);
however. the failure to measure any available phosphate may have been a
result of the extraction technique used. Bray-1 extracts calcium- and
aluminum-bonded phosphates but not iron-bonded phosphates (Sanchez
1976). The proportion of total exchangeable phosphorus accounted for
by iron phosphates increases with weathering as well as acidity
(Sanchez 1976); therefore, the failure to detect available phosphorus
using the Bray-1 procedure is indirect evidence of extensive weathering
of the soils under both forest types.

The difference in potassium content of soils at 150 cm depth
is unexplained (Table 5). There were only four sampling points for
mixed forest at this depth and all of them were within a few kilometers
of one another.

There were no significant differences in soil texture between
the two forest types (Table 5). Mbau forest soils ranged from loamy
sand to sandy clay with the majority of samples being either sandy loan
or sandy clay loam. Mixed forest soils ranged from sandy clay loam to
sandy clay with most being the former.

The difference between mean values of all measured soil
variables for the two forest types at a 20 cm depth was tested
simultaneously with Hotellings 12 (Table 5b). It was
concluded that the variation between the soils did not constitute a

significant difference.

45

Forest Islands

The comparison between soil texture from isolated islands of
one forest type and soil texture from the surrounding forest failed to
reveal any significant differences (Appendix B). This was true for
both mbau forest islands in mixed forest and mixed forest islands in
mbau forest.

The floristic composition of mbau forest islands was not
intermediate between mbau forest and mixed forest. The composition
resembled that of the major blocks of unbroken mbau forest in the area.
This similarity was apparent in the pattern of dominance for different
size classes. Relative frequency (RF). relative density (RD) and
relative coverage (RC) of large individuals of G. dewevrei in mbau
islands consistently resembled the values for G. dewevrei in mbau
forest more than the values of B. laurentii in mixed forest (Table
6a). Consequently the Importance Ratio, IR = (RF+RD+RC) - 3, for G.
dewevrei in small islands of mbau forest paralleled the IR of G.
dewevrei in large areas of unbroken mbau forest, for the size classes
measured, more closely than the IR of the mixed forest dominant (Figure
4). The data were not available to calculate these values for smaller
size classes;however. the absolute density and frequency of smaller
stems of the dominant in mbau islands also followed the pattern of G.
dewevrei in mbau forest more closely than the pattern of B.
laurentii in mixed forest (Table 6b).

Correspondence was particularly close between the values for

mbau forest and mbau islands in the largest size classes (>25 cm dbh,

46

Table 6. Average importance values of G. dewevrei in 4 m
islands. compared to the importance of G. dewev
block of unbroken mbau forest and the importanc
dominant (B. laurentii) in a large block of unb

forest.

hau forest

rei in a large

e of the principal
roken mixed

 

 

b

a. Large size classes (> 10 cm dbh).

Size classes in cm dbh

>10 _<_25 >25 _<_50

Rf Rd RC IR Rf Rd RC IR

>50

Rf Rd RC 1R

 

G.dewevrei in

mbau Islands 0.22 0.53 0.38 0.38 0.60 0.78 0.77 0.72

G.dewevrei in

mbau forest 0.29 0.72 0.75 0.59 0.65 0.87 0.86 0.79

B.laurentii in

1.00 1.00 1.00 1.00

0.82 0.93 0.94 0.90

 

mixed forest 0.08 0.25 0.29 0.21 0.21 0.41 0.40 0.34 0.25 0.31 0.27 0.28
b. Small size classes (< 10 cm dbh). b
Size classes
>0.5 m height >2.5 cm dbh
<0.5 m height ‘52.5 cm dbh 510 cm dbh

density frequency density freq.

density freq.

 

6.dewevrei in

mbau islands 3.900 0.87 10.200 1.00
6.dewevrei in
mbau forest 8.000 1.00 11.500 1.00
B.laurentii in
mixed forest 15.467 0.83 1.467 0.75

360 1.00
307 1.00
178 0.92

 

a IR (importance ratio) - (Rf + Rd + Re) 4 3 where:

Rf (relative frequency) - the frequency of the given
proportion of the sum of frequencies of all species:
Rd (relative density) a the density of individuals of
species as a proportion of the summed density of all
Rc (relative coverage) - the basal area for the given
as a proportion of the total basal area for all speci

calculations resulting in a plot size of 450 m in e
the islands for larger size classes. Size classes in
described in the text.

species as a
relative frequency.
the given

species.

species

es.

Plot size: the two plots in each island of mbau were combined for

ach of
mature forest as

Figure 4.

47

Importance ratios of the dominant species for different
size classes in islands of mbau forests. large areas of
mbau forest and mixed forest. (For derivation of importance
ratios. see Table 6).

KEY:

¥-~¥ Gilbertiodendron dewevrei in mbau forest
islands.

D-—(J G. dewevrei in large areas of mbau forest.

o-o Brachystegia laurentji in large areas of

mixed forest.

(In)

RATIO

IMPORTANCE

 

48

 

1 .0 t
W
o
0.8.. D
t
006- U
0.4-
t
O\
/ o
0.21 0
Q0 I I L ”i
>10 >25 >50
5 25 S. 50

DIAMETER cusses (cm)

49
Table 6a) as well as in the large seedling and sapling size classes
(>0.5 m height 510 cm dbh, Table 6b). The small seedling size
class showed the greatest discrepancy between mbau forest and mbau
island plots (Table 6b). The density of small seedlings of G.
dewevrei. although variable, was frequently less in mbau islands than
in unbroken mbau forest. The discrepancy was transitory across size
classes: in the large seedling and sapling size classes. densities of
G. dewevrei were similar in mbau islands and mbau forest. The
reason for the relatively sparse layer of young seedlings in mbau
islands was not determined although increased seed predation may be
important (see chapter 3). In any case, advanced regeneration of G.
dewevrei was abundant in mbau forest islands and. in general,
regeneration of the dominant appeared to follow the same pattern in
islands of mbau forest as in large blocks of mbau forest. In both
cases the greatest density occurred in the size class between 0.5 m in
height and 2.5 cm dbh. This is contrasts with B. laurentii in -ixed
forest, which had a steadily decreasing density with increasing size

classes (Table 6b).

DISCUSSION

The mbau forest in the Ituri study area.

The pronounced dominance by G. dewevrei and low species

richness characterized mbau forest relative to mixed forest. Rherever

50

G. dewevrei occurred in the study area, it was overwhelmingly the
canopy dominant. The species was never found as scattered individuals
in mixed forest but only in apparently self-regenerating stands.

Despite the clear differentiation of the two communities they
had similar basal areas. There did not appear to be any species
restricted to one or the other forest type except 6. dewevrei,
which is restricted to mbau forest. Furthermore, the most abundant
canOpy trees in mixed forest are also the most frequent subdominants in
mbau forest. I

Neither forest type appeared to be successional. All the
important canopy elements occurred in subcanopy size classes,
indicating that the forests were self-replacing without major
disturbance.

Neither mbau nor mixed forest was associated with a particular
substrate in the Ituri area. Texture, color, depth and chemical
composition of the soils were comparable.

Isolated stands of 6. dewevrei occurring in mixed forest
showed no evidence of being moisture-stressed outliers at the climatic
limit of the species. The soil texture in forest islands was not
different from the surrounding forest. The floristic composition of
the islands was also similar to that of unbroken mbau forest as regards
the degree of dominance of G. dewevrei in all size classes.

In summary, the distribution of the single-dominant mbau
forest on the study site was not defined by soil factors. Neither the
mbau forest nor the adjacent mixed forest appeared to be successional.

At least at the scale of the central Ituri transition zone. it is

51
necessary to look for other biotic or historical factors to account for

the differences between the two forest types.

.Mbau forests in other parts of G. dewevrej's range.

Wherever forests containing 6. dewevrei have been
described, the composition suggests that these are mature
self—replacing communities. Vegetation surveys in the north and
northeastern evergreen forests of Zaire have noted the dominance of
G. dewevrei in all size classes whenever the species was
encountered (Louis 1947. Jongen et al 1960; points C and B respectively
in Figure 5). A recent report (Gauthier et al. 1977) described 6.
dewevrei forests in the central basin of the Zaire River in the
Equateur Region. This is outside the area of principal representation
of this forest type as delineated by Lebrun and Gilbert (1954).
Nevertheless. wherever G. dewevrei occurred it was well represented
in all size classes and usually dominant. Letouzey (1970) has reported
"pure" stands of G. dewevrei in Central African Republic, Cameroun,
and Gabon. sometimes covering dozens of hectares.

The most detailed study of an mbau forest outside of the Ituri
region was made by Gérard (1960) in the Uele region (B on Figure 5).
The canopy in nine of Gérard's 12 plots (each 2500 m2) contained
6. dewevrei. These are the plots used for comparison with the Ituri
Forest, the other three plots were dominated by Jalhernardia
seretii.

The Uele plots that contained 6. dewevrei were as clearly

Figure 5.

52

Reported occurrences of mbau forest within the evergreen
forest block of Zaire.

KEY:

boundary of evergreen forest

Central Ituri (Epulu) study area

West Uele (Gérard 1960)

Yangambi (Louis 1947, Wambeke a Evrard 1954)
East Uele (Frankart 1960)

Ubangi (Jongen et al. 1960)

Kivu plateau (Pecrot & Leonard 1960)

= Maniema (Jamagne 1965)

= Equateur (Gauthier et al. 1977)

IQMWUOW>
I

53

 

400 in
J

 

o-

54

dominated by that species as were the mbau forest plots in the Ituri
region even though they were more than 400 km to the southeast (Table
7). The largest two circumference classes had 87% and 90%,
respectively, of all stems accounted for by G. dewevrei (Table 7).

In the Ituri region the percent 6. dewevrei in these size classes

was 92% and 89%. The smallest circumference class, 10-50 cm, showed
the greatest discrepancy with only 19% of stems in the Ituri being
G.dewevrei whereas. in Uele. 34% were 6. dewevrei. The

smallest circumference class was the only class for which it was not
possible to match the Ituri and the Uele size classes due to different
data collection methods between the two sites. The inclusion of
smaller individuals in the Ituri samples (down to 7.8 cm circumference)
may have contributed to the seemingly greater dominance of G.

dewevrei among saplings of the Uele forest.

Gerard did not present the information necessary for
calculation of basal area; however. basal area was estimated from his
data using the mid-point of each circumference class. If a mid-point
of 80 cm dbh is used for the largest size class then the basal area of
G. dewevrei in the Uele mbau forest is approximately 31 m2 per
hectare. This is similar to the 30 m2 basal area of G.
dewevrei for the same size classes in the Ituri mbau forest. There
is evidence that 80 cm dbh is a reasonable mean for the largest size
class from other data Gérard presents from a nearby (Batite) mbau
forest (1960).

The structural similarity between the two forests is

apparent from Gérard's evocative descriptions. He states that the mbau

55

 

mfimum

 

em a" on as so as en «a “so no a
Ax. ommuoon
own man on we we we on «m anon anon»
was: sagas was: "has” has: «cash was: “sass
on-ofi cc“ . on com - cos coax mass»

wousoaob .u
Amocomousmoafio as so. mammo ouqm

 

 

.mmmmmmo :umfiu umomouuau
sou mcommom “use” use man: may no mumoaou scam on» :«
woasmaob mombnmnowuumaawu uo moquumcov o>~ummmnmou .p mam<s

56

forest distinguishes itself from other "monophytique" or
single-dominant forests by the extremely closed nature of its canopy.
The canopy is almost exclusively G. dewevrei crowns that
touch on all sides. There appear to be only two strata, with the space
between shrub and canopy layers lightly filled by pole-size G.
dbwevrei. He further mentions that the herbaceous layer seems to be
absent, "so much is the eye. from the first instant, struck by the
single color and extent of the thick layer of large dead leaves"
(Gérard 1960. p. 63. T. Hart translation). These "leaves" were the
fallen leaflets of G. dewevrei. His descriptions are equally
applicable to the Ituri mbau forest.

Floristic differences are among the most provocative between
the two forests. Julbernardia seretii and Staudtia stipitata
Rarb. (Myristicaceae) were common subdominants in the Uele canopy and
absent in the Ituri canopy. Cleistanthus michelsonii and
Brachystegia laurentii occurred regularly in the Ituri mbau forest
canopy but were absent from the Uele canopy. The distributions of
these four evergreen species are restricted and unique to each
species. The most widespread canopy level or emergent trees appear to
be the rare deciduous ones; these latter species were similar at both
Uele and the Ituri.

In summary, the dominance by G. dewevrei and its
occurrence in all size classes appears to be consistent wherever
the species occurs. There is not, however, a consistent group of tree
species associated with G. dewevrei. The subdominant species vary

and are shared with the mixed forest types in any given area. Tree

57
species are not excluded from mbau forest. The common species of

adjacent mixed forest occur in mbau fores, however. at low density.

Outside of the central Ituri Forest, mbau forest occurs on
soils derived from a diversity of parent materials. In the central and
northern range of G. dewevrei dominated forest (Ituri. Uele. and
Ubangi), the soils are derived from Precambrian eruptive and
metamorphic rocks. At its northern limits, mbau forest occurs on soils
formed from decomposing lateritic shield dating from the end of the
Tertiary (Ubangi and Uele). In the western part of the mbau forest
distribution (Yangambi), the parent material is aeolian sand deposits
of Pleistocene age whereas at the southern limit of its range (Kivu,
Naniema),6. dewevrei occurs on soils from sedimentary rocks of
Carboniferous and Permian age (Cahen and Lepersonne 1948. Heinzelin
1952. Nambeke and Evrard 1954. Gérard 1960, Jongen et a1 1960,
PAO/Unesco 1976).

The soils supporting G. dewevrei-dominated forest are at
least as variable as the parent materials. In Uele. mbau forest is
found on red clay soils and yellow gravelly soils with a sandy-clay
matrix (Frankart 1960). On the Kivu plateau, mbau forest occurs on
soils ranging from heavy yellow clay to yellow sandy alluvial soils
(Pecrot and Leonard 1960). In Ubangi, G. dewevrei-dominated forest
is found on red sandy clay soil as well as soils containing numerous
chips of dismantling lateritic shield (Jongen et al. 1960). At
Yangambi, mbau forest is found on white sands and yellow. ocher to

brown sandy soils with variable clay content up to 30-40% (Louis 1947,

58

Wambeke and Evrard 1954). Locations of these studies are given in
Figure 5.

Gérard's study of mbau forest in the Uele region (1960)
demonstrated the diversity of soils on which this forest type can be
found even in a relatively restricted area. The plots surveyed were
from several topographic positions. Plots taken at the bottom of
slopes had deep sandy soils which were white to ocher. 0n the slopes
the plots were on clay soils, red in color, and apparently underlain by
a broken and weathering hard lateritic layer. Gérard did, however.
report that depth of soil was an important local determinant of forest
type. On shallow soils mbau forest was replaced by forest dominated by
Jaibernardia seretii.

In all the cartographic studies cited above, where both
vegetation type and soil type were mapped. the borders of G.
dewevrei-dominated forest failed to follow the outlines of soil
types. This is in spite of the fact that in all of the mapped areas,
blocks of mbau forest coexisted with blocks of more diverse mixed
forest.

In summary, on the scale of the full range of G. dewevrei
in Zaire there is no evidence that the single dominant mbau forest is
restricted to poor soils or soils of any particular texture or parent
material. In local areas mbau forest is sometimes restricted to
galleries along rivers (Gérard 1960, Pecrot and Leonard 1960. Jamagne
1965). This may indicate that G. dewevrei is moisture limited on
the higher ground. Alternatively, it may be the pattern left after

cutting and cultivation of the upland forests. Although in the Ituri

59
Forest both of the principal forest types have the structure and

composition of mature forests, in more accessible parts of the forest
with longer histories of settlement by agriculturalists. secondary
forest is likely much more widespread. A mosaic of mbau forest and

secondary forest may exist.

A comparison of other single—dominant tropical farests

with the mbau fOrest of central Africa.

There are a number of intriguing similarities between the
single-dominant mbau forest and other single—dominant tropical forests.
Excluding young secondary forests and communities of flooded or swampy
substrates. there still remain reports of numerous such forests in the
literature (Table 8).

The climatic information available indicates that evergreen
forests dominated by a single species occur under a variety of rainfall
regimes in the tropics (Table 8), including perhumid and seasonal
areas. The information is not sufficient to preclude, however. that
particular conditions may be more favorable to such forests than
others.

The published descriptions do not support the view that these
forests are distinct associations with characteristic species not found
in other forest types. As was the case for mbau forest, the species
which co-occur with the canopy dominant are usually also found in more
diverse mixed forests (Table 8). Beard (1946). for instance. found

that in Trinidad the species associated with Mbra excelsa changed

60

 

.emeosuounnmmssu.

 

 

 

«cams—o» sequen- aoooso so a nauseous «amass some». noon ...: con -ommw souauc
cum:- 6 coumaoossm sou "sq—om e—a«mums sumo s: «In m emu-am anon. s-s-o¢~mh use:
as ooo.~«x .sseoschoqmsesu.
ammus~ou aces-o assuou ummqm ago-swooou e—amammm zoom-o can». coma mm~sows
suma- sumscsm s~_mu aces-nos o» umqqmus s—«os ~o sues» sous w 091nm wanna-q ova" mason who! woodman»
mx . .sssomusma.
amass—o» muses sum-us mam-son» « anon usoams> coax assumes chums:-
sumn. meme: .ouam~ 6 s—qos no smash ovum sumo «masses 0 ommnoox mo~miohsm~mah .eemso.
ago-Lucas» omsqos «m3 .smsosaumoousuoqn.
nomms~ou umssou osmooumuoqn mes non-«u tommmoau «can one onNA mouse-ohm muummm.
some. sass a ammo-qua ou smqqmqs s—qos no ewe-u 00‘s a canoe mousse. wean ocean‘s: mmomm~mooaua .samqml
sueseqmoo ope. .sssososmoomsuoqa.
smog—uses «magmas—v usemou mmmoomououa segue mama: so .ooan possum: oonn n~m~usmo
unsung-ass coco vemnmoq on sagas.- susomo -~n moum~ums osmouu com. shamans: unseen sauna:
commas—oh some» nausea-u: ssqosom emu-«oosm< au—o‘uuosom mumaummmm sue-cums: ace-um no swam commom Lax-o asuosom menu-ooa
nnmuaumu accommon
.oummuou gmuqoouu
usqom case‘soo seasons suueqs mo moan-scoucq usgsuqamo no hams-mm .o mun-h

61

 

umeaou usual

.smsom—ono—msemu.

 

 

 

uammoaou ammo-nos aooomo on" naususm moqau<

some. a auqs mesons sqnos moans:- u can a one" summon amen. w~masmuso~ms «acumen
unseen towns on .mmsumqmuonmsssu.

ummmmnou usages-«u ammo-nos ago-muons» sum-«um» aooomo ooo.on ava— sqaoq can usssmmsm moquud

some. coco has: suns seam:- s_qos no omens mugs w cox (cocoa coo" summon umoam cohtesmo~umsa-c Assam-u
.mssosqcuoqmmomo.

acmmsnou ~msuoosqu usssou mamas moan nuos s.nm«am> zoom-o onus unmasu can wwamsh=w~ mouuu<

come. soon :u—I uses:- aqammoum a can a: n~-~ m :«mmueo umoos m~h€~mh£0mh~ .muucou
mews-q Assoc-«:qo—mssso.

was Iowans- sm nausea-«u usouou cow‘s anoomo m: ave” con ummcsws~s soqgu<

ammusaou some. coco guns comm:- ooau ~_os o—nm~ms> a max ooo.-A acqusmum amon- mhusmomhu ummu
soc-usqoh momma "momma-«n sm—osou asumuoosm< auqoquqosom mummy-mam socmcqmoa smcmum no swam common maxmo msaooom acqumooa
..mumqmu uomoumoa
.vsmouueoo. .o snack

62
with location but were always the same as in the adjacent mixed
forest.

From the available information. it is evident that
single-dominant forests are not restricted to poor substrates. Edaphic
factors may limit the distribution of some of these forests (Table 8).
for instance those dominated by S. curtisii and J. seretii.

Others span a diversity of edaphic conditions, for instance. forests
dominated by E. zwageri, Ml excelsa, 12 gentii, and C.

alexandri, as well as G. dewevrei. It is also worth noting that,

in the case of D. aromatica—dominated or kapur forests, the
single-dominant forest was assumed to be restricted to soils derived
from sedimentary rocks (Whitmore 1984). A detailed field study found,
however, that kapur forests "cut across edaphic boundaries in the same
way as other Dipterocarp forests not containing kapur" (Lee 1967). The
view of monodominant tropical forests as "anomalous" and "edaphic
climaxes" is so entrenched in the lore of tropical ecology that such
forests are assumed to be environmentally determined even when evidence
to support this is lacking.

In all cases the dominant species was reported to be shade-
tolerant (Table 8). The understory of these single-species-dominant
forests contained abundant regeneration of the dominant. This is
strong evidence for the maturity of these forests, all of which were
considered self-replacing by the authors of their respective studies.

It is tempting to suggest that all these tropical
single-dominant forests of well-drained upland sites constitute a

cohesive forest type. This would suggest that similar mechanisms led

63

to the relative poverty in species and strong dominance by a single
species in all cases. The studies needed to substantiate this have not
yet been done; neverthless, two characteristics shared by most. if not
all, of the dominant species in these single dominant forests indicate
that similar mechanisms may be involved in the maintenance of single
species dominance. All species for which information was found had
large poorly dispersed seeds which produced an abundance of shade
tolerant juveniles (Table 8). Dispersal was generally ballistic
expulsion of heavy propagules. There may or may not be other traits,
shared by the forest dominants. affecting their competitive ability or
stress tolerance.

A number of the studies reported that the boundaries of the
single-dominant forest were not stable and that they appeared to be
steadily encroaching on adjacent mixed forest (Beard 1946, Eggeling
1947, Louis 1947). In some areas. the current boundaries of the
single-dominant forest may only reflect a slow rate of dispersal of the
dominant species after ancient large-scale disturbance or climatic

change.

In summary. there are mature "climax" tropical forests which
are species poor and dominated by single tree species. Such
communities do not exist solely because the dominant tree is the only
available species that can tolerate severe edaphic conditions.
Single-dominant forests and more diverse forests occur on the same
substrates. Many of these monodominant forests span a variety of soil

types and topographic positions.

64

The results of this study do not demonstrate that soil
characteristics are unrelated to the floristic composition of mature
tropical forests. They do, however, demonstrate that in the case of
the single-dominant mbau forest. the mechanisms leading to
monodominance by G. dewevrei are not closely linked to edaphic
factors. As suggested in the literature. this may be the case for

other tropical single-dominant forests as well.

1

65

FOOTNOTES

The term "climax" is here given the meaning ascribed to it by
H. S. Horn (1974), the stage when "changes in the specific
composition of the community become undetectably slow or cease

altogether".

The term "climatic climax" is used to refer to the expected
mature community in a given climatic zone wherever conditions

(soils. topography. etc.) are not severely limiting.

66

APPENDIX A. Number of species > 2.5 cm dbh as a function of area in mixed and
mbau forest.

 

 

 

area trees number of % trees number of %
m2 and species increase only species increase
lianes added added
NBAU FOREST
100 14 —- -- 8 -- --
200 16 2 14.3 10 2 25.0
400 26 10 62.5 20 10 100.0
800 34 8 30.8 28 8 40.0
1600 44 10 29.4 37 9 32.1
3200 56 12 27.3 47 10 27.0
6400 67 11 19.6 56 9 19.1
12800 88 21 31.3 70 14 25.0
25600 95 7 7.9 74 4 5.7
mean % increase 27.9 34.2
(SD) (16.4) (28.4)

 

MIXED FOREST

100 19 -- -- 15 -- --
200 26 7 36.8 20 5 33.3
400 37 11 42.3 30 10 50.0
800 54 17 45.9 42 8 26.7
1600 68 14 25.9 52 10 23.8
3200 85 17 25.0 66 14 26.9
6400 107 22 25.9 83 17 25.8
12800 123 16 14.9 95 12 14.5
25600 143 20 16.3 111 16 . 16.8
mean % increase 29.1 27.2

(SD) (11.4) (11.0)

 

67

APPENDIX 8. Soil texture. measured as percent sand. of soils from
forestaislands and of soils from the surrounding forest
type.

 

 

a. Soils from islands of mbau forest and surrounding mixed gorest.

 

mbau forest islands adjacent mixed forest P
46.72 46.20
54.03
56.79 47.98
54.33
42.71 41.55
43.85
mean c 48.74 47.99 NS
(SD) (7.25) (9.05)

 

b. Soils from islands of mixed forest and surrounding mbau gorest.

 

mixed forest islands adjacent mbau forest P

54.57 50.13
49.40
48.68 65.65
54.09
53.07 55.33
57.10
57.67 63.79
52.80
58.24 52.54
66.37

mean 54.45 56.72 NS
(59) c (3.87) (6.33)

 

Composition reported as the arcsine transformation of percent
sand.

Student's t test was used to examine the null hypothesis that
there is no significant difference in composition between soils
inside and outside the island. NS - P>.05.

SD - standard deviation.

68

LIST OF REFERENCES

Andrew, C. S. 1978. Legumes and acid soils. pages 135-160 in
J. Dobereiner, R. Burris, and A. Hollaender. eds. Limitations
and Potentials for Biological Nitrogen Fixation in the
Tropics.

Ashton, P. S. 1971. The plants and vegetation of Bako National Park.
Malayan Nature Journal 24: 151-162.

Ashton, P. S. 1976. Mixed dipterocarp forest and its variation with
habitat in the Malayan Lowlands: a re—evaluation at Pasoh.
Malayan Forester 39 (2): 56-72.

Ashton, P. S. 1977. A contribution of rain forest research to
evolutionary theory. Annals of the Missouri Botanical Garden
64: 694-705.

Austin. M. P., P. S. Ashton, and P. Graig—Smith. 1972. The
application of quantitative methods to vegetation survey.
III. A re-examination of rain forest data from Brunei.
Journal of Ecology 60: 305-324.

Baillie, I. C. and P. S. Ashton. 1983. Some soil aspects of the
nutrient cycle in the mixed Dipterocarp forests of Sarawak.
East Malaysia. pages 347-356 in S. L. Sutton. T. C. Whitmore.
and A. C. Chadwick. eds. Tropical Forest Ecology and
Management. Blackwell Scientific Publ.. Oxford.

Beard. J. S. 1946. The more forest of Trinidad, British West Indies.
Journal of Ecology 33 (2): 173-192.

Bernard. E. 1945. Le climat Ecologique de la Cuvette Centrale
Congolaise. Publications de l'Institut National pour l'Etude
Agronomique du Congo Belge (INEAC). Hors série. 240 pages.
Brussels.

Brower. J. E. and J. H. Zar. 1984. Field and Laboratory Methods for
General Ecology. 2nd edition. 226pp. W. C. Brown. Publishers,
Dubuque.

Brunig. E. F. 1973. Species richness and stand diversity in relation
to site and succession of forests in Sarawak and Brunei
(Borneo). Amazonia 4 (3): 293-320.

Brunig. E. F. 1983. Vegetation structure and growth. pages 49-75 in
Ecosystems of the World. vol.14 A: Tropical Rain Forest
Ecosystems, Structure and Function. F. B. Golley, ed.

381 pp. Elsevier Scientific Publishing Co.. N.Y.

69

Budowski, G. 1970. The distinction between old secondary and climax
species in tropical Central American lowland forests.
Tropical Ecology 11 (1): 44-48.

Bultot, F. 1950. Carte des régions climatiques du Congo Belge établie
d'aprés les critéres de depen. Publications of INEAC.
Bureau climatologique. communication no.2.

Bultot, F. 1971. Atlas climatique du bassin congolais, deuxieme
partie. publication of the Institut National pour l'Etude
Agronomique du Congo (INEAC) Hors série. Brussels, Belgium.

Burgess, P. F. 1969. Preliminary observations on the autecology of
Shorea curtisii Dyer ex King in the Malay Peninsula.
Malayan Forester 32(4): 438.

Cahen, L. and J. Lepersonne. 1948. Atlas général du Congo. #31:
notice de la carte géologique du Congo Belge et du
Ruanda—Urundi. Institut Royal Colonial Belge. Brussels.
Belgium.

Dahnke, w. C., ed. 1980. Recommended Chemical Soil Test Procedures
for the North Central Region. Bulletin #499. North Dakota
Agricultural Experiment Station. North Dakota University,
Fargo.

Davis. T. A. M. and P. W. Richards. 1933. The vegetation of Moraballi
Creek, British Guiana: an ecological study of a limited area
of tropical rain forest. Part 1. Journal of Ecology 21:
350-384.

Davis, T. A. N. and P. W. Richards. 1934. The vegetation of Moraballi
Creek, British Guiana: an ecological study of a limited area
of tropical rain forest. Part 2. Journal of Ecology 22:
106—133.

Devred, R. 1958. La végétation forestiére du Congo Belge et du
Ruanda-Urundi. Bulletin de la Société Royale Forestiere de
Belgique. #6: 408-468.

Eggeling, W. J. 1947. Observations on the ecology of Budongo rain
forest, Uganda. Journal of Ecology 34: 20-87.

FAO/Unesco. 1976. Carte mondiale des sols. Tome 6: Afrique. Paris.

Frankart. R. 1960. Carte des sols et de la vegetation du Congo Belge
et du Ruanda—Urundi. Vol.14: Uele. INEAC. Brussels,
Belgium.

Garwood. N. C., D. P. Janos. and N. Brokaw. 1979. Earthquake-caused
landslides : a major disturbance to tropical forests. Science
205: 997-999.

7O

Gauthier. Poulin. Thériault, Ltd. 1977. Manuel de dendrologie.
Prepared for the government of the Republic of Zaire in accord
with the program of cooperation of the Canadian Agency for
International Development. Quebec.

Gentry. A. H. 1982. Patterns of neotropical plant species diversity.
Evolutionary Biology 15: 1-84.

Gérard. Ph. 1960. Etude écologique de la forét dense a
Gilbertiodendron dewevrei dans la région de l'Uele.
INEAC. série scientifique #87. 159pp. Brussels, Belgium.

Germain. R. and C. Evrard. 1956. Etude écologique et
phytosociologique de la forét a Brachystegia laurentii.
INEAC. série scientifique #67. 105pp. Brussels, Belgium.

Goldberg, D. E. 1985. Effects of soil pH. competition, and seed
predation on the distributions of two tree species. Ecology.
66: 503—511.

Hall. J. B. and M. D. Swaine. 1981. Distribution and Ecology of
Vascular Plants in a Tropical Rain Forest: Forest Vegetation
in Ghana. 383 pages. Dr. M. Junk Publishers. Boston.

Hamilton, A. C. 1981. A field guide to Uganda Forest Trees. 279pp.
Makerere University, Uganda.

Harris. R. J. 1975. A Primer of Multivariate Statistics. 332pp.
Academic Press. N.Y.

Heinzelin. J. de 1952. $013, paléosols et désertifications anciennes
dans le secteur nord-oriental du bassin du Congo. INEAC.
Brussels. Belgium.

Holdridge, L. R., W. C. Grenke, M. M. Matheway, T. Liang, and J. A.
Tosi, Jr. 1971. Forest Environments in Tropical Life Zones.
a Pilot Study. 747 pages. Pergamon Press, N.Y.

Horn, H. S. 1971. The Adaptive Geometry of Trees. Monographs in
Population Biology #3. Princeton University Press, Princeton.

Horn, H. S. 1974. The ecology of secondary succession. Annual Review
of Ecology and Systematics 5: 25-37.

Jamagne, M. 1965. Carte des sols et de la végétation du Congo Belge
et du Ruanda-Urundi vol.19: Maniema. INEAC Brussels,
Belgium.

Janzen. D. M. 1974. Tropical blackwater rivers, animals and mast
fruiting by the Dipterocarpaceae. Biotropica 6: 69-103.

71

Janzen, D. H. 1981. The defenses of legumes against herbivores.
pages in R. M. Polhill and P. H. Raven, eds. Advances in
Legume Systematics, part two. Royal Botanic Gardens, Kew.

Jongen,P., M. van Oosten, C. Evard. and J-M. Berce. 1960. Carte des
sols et de la végétation du Congo Belge et du Ruanda—Urundi.
vol.11: Ubangi. INEAC Brussels, Belgium.

Koopman, M. J. F. and L. Verhoff. 1938. Eusideraxylon zwageri T.
a B., het ijzerhout van Borneo en Sumatra. Tectona 31:
381—399.

Kruckeberg, A. R. 1969. Soil diversity and the distribution of plants
with examples from western North America. Madrono 20:
129-154.

Laan, E. van der. 1927. De analyse der bosschen van de eilanden
poeloe laoet en seboekoe der residentie zuideren
oosterafdeeling van Borneo. Tectona 20: 19-36.

Lebrun, J. and G. Gilbert. 1954. Une classification écologique des
foréts du Congo. INEAC série scientifique #63. Brussels,
Belgium.

Lee, P. C. 1967. Ecological studies on Dryobalanaps aromatics
Gaertn. Unpublished PhD dissertation submitted to the Faculty
of Science, University of Malaya.

Leigh, E. 6., Jr. 1982. Introduction: Why are there so many kinds of
tropical trees? pages 63-66 in E. G. Leigh, Jr., A. S. Rand,
& D. M. Windsor, eds. The Ecology of a Tropical Forest.
Seasonal Rhythms and Long-term Changes. Smithsonian
Institution Press, Washington, D.C.

Lemée, G. 1961. Effets des caractéres du sol sur la localisation de
la végétation en zones équatoriale et tropicale humide.
Proceedings of the Symposium on Tropical Soils and Vegetation,
Abidjan. pages 25-39. UNESCO, Paris.

Letouzey, R. 1970. Manuel de botanique forestiére: Afrique
tropicale. Tome 2A. 210pp. Centre Technique Forestier
Tropical. Nogent s/Marne, France.

Louis, J. 1947. Contribution a l'étude des foréts équatoriales
congolaises. pages 902-915 in Comptes rendus de la semaine
agricole de Yangambi. Communication #100. INEAC. Brussels,
Belgium.

Mangenot, G. 1950. Essai sur les foréts denses de la C6te
d'Ivoire. Bulletin de la Société Botanique de France. 97
(7-9): 159-162.

72

Newberry, D. McC. and J. Proctor. 1984. Ecological studies in four
contrasting lowland rain forests in Gunung Mulu National Park,
Sarawak. IV. Associations between tree distribution and soil
factors. Journal of Ecology 72: 475-493.

Pecrot, A. and A. Leonard. 1960. Carte des sols et de la végétation
du Congo Belge et du Ruanda-Urundi. vol.16: Dorsale du Kivu.
INEAC. Brussels, Belgium.

Rankin, J. M. 1978. The influence of seed predation and plant
competition on tree species abundances in two adjacent
tropical rain forests. Unpublished Ph.D. dissertation. The
University of Michigan, Ann Arbor.

Richards, P. W. 1941. Lowland tropical podosols and their vegetation.
Nature 148: 129-131.

Richards, P. W. 1952. The tropical rain forest, an ecological study.
450pp. Cambridge University Press, N.Y.

Richards, P. W. 1961. The types of vegetation of the humid tropics in
relation to the soil. Proceedings of the Symposium on
Tropical Soils and Vegetation, Abidjan. pages 15-23. UNESCO,
Paris.

Ricklefs, R. E. 1973. Ecology. 861pp. Chiron Press, Inc.,
Portland.

Sanchez, P. A. 1976. Properties and Management of Soils in the
Tropics. 618pp. John Wiley and Sons, N.Y.

Swaine, M. D. and J. B. Hall. 1981. The monospecific tropical forest
of the Ghanaian endemic tree, Talbotiella gentii. in:
Proceedings of the International Conference on Biological
Aspects of Rare Plan Conservation. H. Synge, ed. Wiley,
London.

Unesco/UNEP/FAO 1977 Tropical Forest Ecosystems: A state-of-knowledge
report. 683 pages.

Wambeke, A. van and C. Evrard. 1954. Carte des sols et de la
végétation du Congo Belge et du Ruanda-Urundi. vol.6:
Yangambi. INEAC Brussels, Belgium.

White, F. 1983. Vegetation Map of Africa South of the Sahara. 2nd
edition. text: 356pp. Unesco/AETFAT/UNSO, Paris.

Whitmore, T. C. 1974. Change with Time and the Role of Cyclones in
Tropical Rain Forest on Rolombangara, Solomon Islands.
Commonwealth Forestry Institute Paper #46. 92 pages.
Oxford.

73

Whitmore, T. C. 1984. Tropical Rain Forests of the Far East. 2nd edition.
352pp. Clarendon Press, Oxford, U.K.

Wong, W. Y. and T. C. Whitmore. 1970. On the influence of soil
properties on species distribution in a Malayan lowland
Dipterocarp rain forest. Malayan Forester 33: 42-54.

Wyatt-Smith, J. 1954. Storm forest in Kelantan. Malaysian Forester
17: 5-11.

Zon, P. van. 1915. Mededeelingen omtont den kamferboom
(Dryobalanops aromatica). Tectona 8: 220-224.

CHAPTER II

A COMPARATIVE STUDY OF THE IMPACT OF NATURAL DISTURBANCE

ON FOREST COMPOSITION IN NORTHEASTERN ZAIRE.

INTRODUCTION

It has recently been suggested that the composition of
tropical forests is strongly influenced by the pattern of natural
disturbance sustained by these forests (Connell 1978, Hartshorn 1978.
Oldeman 1978, Whitmore 1978, 1982, Denslow 1980, Florence 1981, Leigh
1982, Orians 1982, Pickett 1983). The rain forests1 of
northeastern Zaire provide a case by which this relationship can be
examined. There are two forest types in the Ituri Forest (Figure 1).
both of which are apparently maturez, but each having different
dominant tree species and different species diversities. The mbau
forest is dominated by a single species, Gilbertiodendron dewevrei,
(Caesalpiniaceae) which makes up 80% or more of the stems reaching
canopy level. As a result, mbau forest is less diverse than the mixed
forest. Brachystegia laurentii (Caesalpiniaceae), cynametra

alexandri (Caesalpiniaceae), and Cdeistanthus michelsonii

(Euphorbiaceae), are dominant in the latter forest type, but no species

74

75

Figure 1. The Ituri Forest, Zaire.

76

M.

 

 

   

.\

r
00080.3.

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....l’g‘ '
I <
I?
‘ <
t hi
2.
l ‘(
P
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\ z
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\\
Q
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V ‘ __
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77
accounts for more than 30% of total tree density (>10 cm dbh).

Both forest types cover thousands of square kilometres over a
wide range of soils and are without intervening topographic
discontinuities. Over most of their range, soil differences do not
appear to have been important in determining forest type as both
forests occur on soils derived from the same parent material and with
similar chemical and textural qualities (see chapter 1: also, for
forest dominated by 6. dewevrei, see Louis 1947, Gérard 1960, and
Jongen et al 1960; for forest dominated by B. laurentii see Germain
and Evrard, 1956).

In this paper I investigate the relationship between natural
disturbance and the two forests' floristic composition by comparing
natural disturbance regimes and the process of regrowth after
treefall. The resilience of the forest communities, and of the
dominant species in particular, are assessed by comparing secondary

forests with the primary forests.

BACKGROUND AND LITERATURE REVIEW

Disturbance can affect community composition in a number of
ways. As defined by Grime (1979: 39) and used here, disturbance
”consists of the mechanisms which limit the plant biomass by causing
its partial or total destruction”. Disturbance may interfere with
species interactions such that species already present in the
environment can continue to coexist, or it may create open patches,

allowing disturbance-adapted species to invade. These possibilities

78
are briefly described below.

Periodic destruction of biomass may interfere with the
assertion of dominance by one or a few species. In the absence of
disturbance, in some communities resource monopoly by a single species
is likely to result either from that species' superior competitive
ability or from its greater resistence to stress and predation (Paine
1984, referring to marine sessile organisms). Both Connell (1978) and
Bubbell (1980) have hypothesized that the non-equilibrium conditions
resulting from repeated disturbance promote species coexistence in
tropical forests by preventing dominance by single species of trees.

Treefall disturbances in tropical forests have been
interpreted as providing a resource dimension along which tree species
have specialized. Denslow (1980) and Pickett (1983) suggested that
tree species are capable of reaching maturity within only a limited
range of gap sizes. These species are categorized as small and large
gap specialists. It has also been suggested that different species may
be specialized to exploit particular microsites within a gap (Orians
1982). Thus, mechanisms maintaining tree species diversity in tropical
forests are envisioned as analagous to those hypothesized for animal
species such that "diversity of species is proportional to the
diversity of resources" (MacArthur, 1972, page 177). In the case of
tropical forests the resources include establishment sites in treefall
gaps.

Apart from its influence on species richness, the disturbance
regime will determine the relative proportions of shade tolerant and

shade intolerant species in the forest. With increasing size and

79

frequency of treefalls, species adapted to germinate and grow under the
environmental conditions provided by gaps will be favored (Hartshorn
1978, 1980; Whitmore 1974, 1982).

Typical character syndromes have been suggested for gap
species (Whitmore 1978, Hartshorn 1980) and field data have shown that
certain tree species which are regular components of mature tropical
forest benefit from gaps. Stores of quiescent seeds which germinate
after exposure to light have been found in the soils of numerous humid
tropical forests (Guevara and Gomez-Pompa, 1972, Cheke et al. 1979,
Mall and Swaine 1981, Putz 1983, Uhl and Clark 1983). The survival of
all nine species of wind-dispersed tree seedlings tested by Augspurger
(1984) in Panama was greatly enhanced by transplantation of the
seedlings into light gaps. In a five year study, Brokaw (1985, Barro
Colorado Island) found that "pioneer" species grew poorly or not at all
in small gaps and the fastest growing "pioneers" were in large gaps.
The same conclusion, i.e. that certain tree species important in the
forest canopy are unable to persist under the shade of the canopy, has
been reached by studying the distribution of seedlings and saplings at
a given point in time (Hubbell 1979, Veblen et al. 1979). Juveniles of
some species are found only in gaps.

Most disturbance studies in tropical forests have focused on
the effects of disturbances which can be witnessed and measured in
human lifetimes (some exceptions to this include extrapolations made
from studies of major windstorm damage (Wyatt-Smith 1954, Webb 1958,
Whitmore 1974). This is not the case in temperate latitudes where the

impact of past glaciations (Davis 1976) and prehistoric fires (Walker

80
1982) on present forest composition has been studied with the help of
pollen profiles. Comparable data are not available for such studies in
tropical ecosystems, but buried charcoal horizons indicate that a
number of presumably primary humid tropical forests have burned during
the Holocene (Sanford et al. 1985 in Venezuela, and Hart. this study,
in Zaire). Studies of modern lightning damage suggest the same for
some areas of forest in Sarawak (Anderson 1964).
Apparent differences in forest composition seen today are
possibly a reflection of large-scale disturbances several centuries or
even millenia past. This interpretation seems tenable given the slow,
growth and poor dispersal of many of the dominant trees in mature
tropical rain forest and the growing evidence for climatic shifts in
tropical regions during the Holocene (Flenley 1979, Livingstone 1980a,
1980b, Lewin 1984, Talbot et al. 1984, Leyden 1985).
From the above discussion several hypotheses can be developed
regarding the two forest types in the Ituri region of Zaire:
Hypotheses concerning species diversity
1. The mixed forest has had more frequent and larger disturbances than
the mbau forest.
Rationale: The single species dominance of the mbau forest may
represent a resource monopoly established in the absence of
significant disturbance.

2. The mixed forest has more varied treefall gaps than mbau forest,
providing a greater diversity of microsites for seedling
establishment.

Rationale: If tree species have specialized relative to different

81

within-gap establishment sites, then the more diverse forest may
provide a greater variety of such sites.

Hypotheses concerning species composition

3. Gap species account for a greater proportion of the tree species in
mixed forest than in mbau forest.
Rationale: The greater diversity of mixed forest may result from
the abundance of gap-dependent species.

4. One of the two forest types is composed of species more resilient
to major disturbance.
Rationale: The pattern of forest type distribution may be a
reflection of major past disturbance. The spread of the original
forest into the destroyed area may be very slow.

Not all of the above hypotheses are easily tested, nor do they
cover all of the possible relationships between species diversity and
disturbance in these forests. Nevertheless, they provide a framework
in which to investigate the possibility that differences in species
dominance and species diversity between mixed and mbau forest are due

to differences in disturbance regime.

METHODS

Gap size, frequency, and distribution were measured in both
forest types. A survey was made of four 2.5 ha plots (50 m x 500 m) at
each of three sites in both forest types such that a total of 30 he was
surveyed for both mixed forest and mbau forest (G-D in Figure 2). A

lap was made of all recent treefall gaps showing size, shape, and

82

Figure 2. The central Ituri Forest study site. with locations of
forest types and research areas.
Plot locations:
G-D ... Gap dynamics
8 ..... 15 year-old secondary forest

40 year-old secondary forest was 20 km west of
Epulu.

83

 

 

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84

orientation. A treefall gap was considered recent enough to include if
the height of the new growth was less than 3 m and the fallen tree
trunk was intact. If there were signs of advanced decay, such as moist
and crumbly wood, other evidence for the recent nature of the gap was
sought (small pioneer seedlings, freshly broken understory

species...). Only treefall disturbances large enough to have caused
canopy gaps were censused.

Two area measurements were made of each gap. The ground-level
disturbance was determined by judging the approximate shape of the gap
and then taking the measurements necessary to calculate the area. In
this case the edge of the gap was defined by the stems of unaffected
vegetation. The second area determined was the canopy gap or the
actual area of open sky exposed by the treefall. In this case the edge
of the gap was defined by the bordering crowns of adjacent standing
trees. The necessary measurements were made by sighting upward or,
where the ground gap was smaller than the canopy opening, by
estimation.

Old treefall disturbances and mature light-dependent trees
were enumerated on each plot. The disturbances were identified as
rotted logs on the forest floor with canopy gaps above. The trees were
species known to germinate and grow in large treefall gaps. The
frequency of old gaps and mature pioneer species served as estimations
of past treefall disturbance. Analysis was by 1-way ANOVA with
preplanned comparisons (Sokal and Rohlf, 1969, pages 226-235).

The process of regrowth in treefall gaps was studied in

relatively recent gaps within a six kilometer radius of the base camp

85

at Epulu. A total of 41 gaps, in which the new growth did not exceed 3
m in height were surveyed. Gaps were included as they were encountered
except that small branchfalls were usually passed up in favor of larger
treefall openings. Rather than follow paths, a given direction was
chosen and then traversed with forest guides. Additionally, two sample
surveys were made in a 70-100 ha blowdown in mixed forest.

Gap age was approximated by comparing the size of the largest
pioneer tree seedling in these gaps with the size of the largest
pioneer seedling of the same species growing on a favorable site in a
gap of known age. It was estimated that all but six of the treefall
gaps were less than one year in age when first visited.

The gaps were measured by the same method used on the 2.5 ha
plots. Mature trees adjacent to the gap were identified. The entire
gap was systematically searched and all newly-germinated seedlings were
identified. An individual seedling was determined to have germinated
since gap formation by a combination of characteristics: 1. condition
of the leaves (not coriaceous, without epiphylls); 2. number of leaf
scars (few): 3. lack of woodiness in stem; and 4. absence of the
species as a seedling under the closed canopy of the mature forest. The
last characteristic was not absolute as shade tolerant species could
germinate in gaps as well. The largest of the newly germinated
seedlings were measured and tagged. Samples of light-released
seedlings or saplings of the dominant forest species were also measured
and tagged. In the later gaps surveyed (13), released sapling and
.Dole-size stems were enumerated throughout the gap, recorded and

identified.

86

Percent canopy cover was measured with a concave spherical
densiometer; readings were taken at 5 m intervals along the major axis
of each gap. Readings were taken while standing on fallen trunks or
branches at about 3 m height, and thus above the dense regrowth and
fallen debris. Notes were taken on litter cover, and browse damage to
seedlings and resprouts. Two of the largest and two of the smallest
gaps were resurveyed after two years. Differences between gaps in
mixed forest and mbau forest were tested by Students' t-test.

Two sampling techniques were used to determine the density and
composition of soil seed banks:
1. Plots were searched for large seeds (3 5 mm, longest
dimension). Leaf litter, humus, and superficial soil was sifted on a
total of 99 one meter square plots in mixed and mbau forest. Seeds
were placed in flats in the sun and were watered for six months.
2. For smaller seeds, a volume of soil (300 cm2 x 7 cm) was
spread in the sun on sterilized sand to form germination beds. These
beds were on a platform to discourage predators and covered with fine
mesh mosquito netting to avoid contamination. A trellis of palm fronds
provided light shade. Twenty samples each were taken from mixed
forest, mbau forest, and secondary forest. Half the samples were taken
at the wettest time of year (November) and half at the driest time
(February). Germinations were monitored for four months in each case.

Another pair of seed beds was maintained, one in the open and
one under the shade of the forest canopy. As seeds of gap-colonizing
Species became available they were set into small cleared plots so that

germination and growth could be observed. The group of plots in the

87
large clearing of the base camp received partial shading from a trellis
of palm fronds. These plots and those in the forest shade were
unmanipulated except for occasional weeding.

The composition of secondary forest of two different ages and
histories was studied on sites previously used for slash and burn
agriculture (S in Figure 2). The younger secondary forest had
developed on sites abandoned 15 years earlier and subjected to only one
planting and harvest cycle after the mature forest was cleared.
Original cover had been mixed forest with several islands of mbau
forest. In the older, 40 year-old, secondary forest, woody vegetation
had become re-established after the village and gardens of the town of
Biane were abandoned. The original vegetation was mixed forest and it
is likely that, after clearing, most of the Biane area sampled had been
subjected to two or more planting cycles.

Twelve plots, 25 m x 25 I each, were located at both sites.
All stems >10 cm dbh were identified (or a specimen collected) and the
diameter measured. All stems > 2.5 cm dbh and 5_10 cm dbh were
recorded in 15 m x 15 m subplots, one in each of the larger plots. The
plot sizes were the same as those used for composition studies of both
mixed and mbau forest (described in chapter 1). This permited direct
comparisons between secondary and primary forest sites. Analysis was

by 1-way ANOVA with preplanned comparisons.

88

RESULTS

There were significantly (P < .01) more gaps
in mixed forest than in mbau forest (Table 1). Mean size of individual
gaps, whether measured at ground or canopy level, was not significantly
different at a probablility of 0.05. Site means for canopy gap
size were consistently larger in mixed forest but due to large
variances, the two forest types only differed at a probability of 0.1.

Given that there were more gaps in mixed forest and that there
was no significant difference in gap size, the expectation is that for
any given area of forest, a larger proportion would have been disturbed
by treefalls in mixed forest than in mbau forest. There was, in fact,
a significant difference (P < .05) in total gap area per plot when
open canopy area was compared between the two forest types but when
ground disturbance areas were compared the difference was only
significant at a probability of P < 0.1 (Table 1).

Variances for gap size and disturbance area measurements were
very high at all sites in both forest types, (see standard deviations,
SD, Table 1). This indicates that treefall disturbance was highly
irregular relative to the sample size (plot size = 2.5 ha). There was
indication that even at a much larger scale, gap occurrence would have
remained irregular. Nomadic hunters reported a large blowdown in mixed
forest which, upon inspection, was estimated to have leveled from 70 to
100 ha of forest. Even the older hunters had never seen a blowdown of

this scale. The periodicity with which such blowdowns occur is

89

Table 1. Size and frequency of treefall gaps. on 2.5 ha plots. in mixed
and mbau forest types of the Ituri Forest. Zaire.

 

 

 

 

Mbau forest sitesb Mixed forest sites CoIparisonsc
sites within forest among
N E S 2 N I when mixed forests
IIP -
frequency2 x 4.0 2.8 2.3 6.3 8.5 2.8 NS P<.05 P<.01
8/25000 I 80 1.41 0.98 0.96 0.98 3.70 0.98
ground p x 124.8 99.3 241.0 203.8 216.8 166.5 . NS NS NS
8186 I 50 93.31 81.88 273.81 148.27 140.90 87.28
CInopy 58p 8 58.5 88.8 108.0 111.0 147.3 133.8 as MS (P<.1)
8128 I 80 50.69 53.80 113.12 65.58 85.30 51.71
ground _
plot area a . 496.5 210.8 440.8 965.3 1083.3 416.8 85 NS (P<.1)
opened a 80 536.25 161.50 573.11 773.99 850.01 199.5
canopy _ .
plot area a 202.5 104.3 184.3 569.3 618.8 349.3 NS NS P<.05
opened a 60 265.48 67.09 250.53 532.30 858.3 171.5
. m - 12 plots in each forest type (three sites with four plots each).
A total of 30 he was surveyed in each forest type.
b Mbau forest sites : I - langbars. E - Eboyo. 8 - 8ambo.
lined forest sites : 2 - Apanzoki. N - ldski. R - Nadiketu.
c

Analysis by 1-may ANOVA with preplanned comparisons: probabilities
of < 0.1 and > 0.05 are shown in parentheses; probabilities > 0.1
are not significant (NS). '

90

unknown.

The range of gap size and disturbance area did not differ
significantly among the three sites in either forest type (Table 1).
Gap frequency, on the other hand, did vary significantly within mixed
forest sites (P < .05). The four plots at the Kadiketu site had
relatively few gaps as compared to plots at the other mixed forest
sites.

Notes were made on some variables likely to affect the
diversity of microsites available for plant germination and growth in
all gaps encountered in the plots (Table 2). There were no significant
differences between the two forest types in the percent of gaps
originating from branchfalls, single treefalls, or multiple treefalls.
In both mixed and mbau forest approximately half of all disturbances
were from single treefalls. Nor was there a significant difference
between forest types in the percent of treefall gaps with at least one
upturned rootmass. In both cases slightly more than one fourth of all
gaps had rootmasses with exposed mineral soil.

Further observations on differences between gaps in mixed
forest and mbau forest were made in the 41 gaps studied more
intensively. Spherical densiometer readings of percent open sky did
not differ significantly for the two forest types (mbau forest mean =
15.2%, SD = 8.46; mixed forest mean = 18.8%, SD = 7.57). Two similar
samples were taken in the large blowdown (> 70 ha). Both had much
higher mean readings ( > 50% open sky) than any of the other treefall
gaps.

Certain species occurred regularly as newly germinated

91

Table 2. Percent of gaps with specific characteristics relevant to seedling

 

 

 

microsites.
Forest Type

gap t b
characteristic Mbau Mixed value significance
branch-fall x 37.2 24.9 1.456 NS

50 3.91 8.79

single x 51.8 54.0 0.619 NS
tree-fall SD 3.69 0.23
multiple x 11.0 20.9 1.346 NS
tree-fall SD 1.58 9.25
upturned x 25.7 31.9 0.430 NS
rootmass SD 23.08 19.41

 

Analyses. using mean values from each site (four plots per site.
three sites per forest type). were by Students' t test using

arcsine transformed values. Standard deviations (SD) were calculated
from arcsine transformed values.

b NS - not significant. P > 0.1.

92
seedlings in treefall gaps. The 18 most common species were found in
from five to 32 of the 41 gaps surveyed (Figure 3, Table 3). Of these
18, four species germinated in at least 29 of the gaps (Table 3). In
most cases there were no mature individuals of the same species
adjacent to the gap (exceptions: six gaps with MUsanga cecropioides
adjacent and one gap with Ricenodendron heudelotii adjacent).
These 18 species accounted for 94% of all tree seed germinations in
treefall gaps, even after excluding from the calculation all seedlings
with a mature individual of the same species on the perimeter of the
treefall.

The 18 common gap species were poorly represented in the
canopy of the mature forest. Of stems greater than 10 cm dbh, they
composed 2.8% in mixed forest and only 0.6% in mbau forest. They were
an even smaller component of the understory of mature forest.

Along with the 18 shade-intolerant gap species, 38 other tree
species occurred as new seedlings in gaps (Figure 3). Some of these
appeared to be shade- intolerant species as are the 18 gap species.
Mature individuals were rare or absent from undisturbed forest but were
common in the canopy of secondary forest less than 50 years old
(Erythina sp., Barteria nigritans, Dacryodes sp.). Also found as
seedlings in gaps were some understory species (Garcinia smeathmanii,
Hunteria cangolana, Pancovia harmsiana, Trichilia rubescens) and some
canopy species of the mature forest (Mbnopetalanthus microphyllus,
Irvingia gabonensis, Donella prunifbrmis, Dialium corbisieri). The
seedlings and saplings of these latter two groups could be found in

undisturbed forest as well.

93

Figure 3. The frequency with which individual species occur

as seedlings in treefall gaps.

94

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95

Table 3. Occurrence of common gap-regenerating tree species in the
treefall gaps surveyed. with their principal mode of seed

dispersal. in the Ituri Forest of Zaire.

 

 

 

number of dispersal

species family gaps (n-41) agentsa
Mbsanga cecropioides Moraceae 32 b. p, m
Macaranga monandra Euphorbiaceae 32 b?
Ricinodendron heudelotii Euphorbiaceae 30 m
Macaranga spinosa Euphorbiaceae 29 b?
Alstonia boanei Apocynaceae 18 w
Tress orientalis Ulmaceae 18 b
Albizia gummifera Mimosaceae 13 ?
Pagara macrophylla ~Rutaceae 13 b
Canarium schweinfurthii Burseraceae 12 b, h
Bridelia sp. Euphorbiaceae 8 b?
cola lateritia Sterculiaceae 7 p?
Ficus capensis Moraceae 7 p
praca guineensis Euphorbiaceae 7 p?
Crotch mubango Euphorbiaceae 7 m
Harungana madagascariensis Guttiferae 7 b?
Erythrqphleum suaveolens Caesalpiniaceae 6 7
Phyllanthus sp. Euphorbiaceae 6 m
Anthocleista schweinfhrthii Loganiaceae 5 p?

 

bird
arboreal primate

wind
humans

580617
a

terrestial mammal (duiker. elephant)

96

Except for the 18 gap species, all other species were rare as
germinating seedlings in treefall gaps. Four of the 38 occurred in
three gaps, ten in two gaps, and 24 in one gap (Figure 3). Not
included here are Brachystegia laurentii and Gilbertiodendron
dewevrei. These were found in gaps but always within approximately
10 meters of the crown of a mature individual of the same species.
These two species are found abundantly in all size classes under
undisturbed canopy of mixed forest (3. laurentii) or mbau forest
(6.dewevrei).

Only the 18 gap species were common enough as seedlings to be
used to contrast treefall gaps in mixed and mbau forest with regard to
species composition of germinating seeds. Of the 41 gaps surveyed,
four were in transition forest. Only those clearly in mixed or mbau
forest were appraised (Table 4).

All 18 gap species were found as seedlings in both mixed and
mbau forest gaps. No species was restricted by conditions peculiar to
gaps of only one of the forest types.

The two smallest gaps surveyed (< 50 m2) had no
germinations (gap # 33) or only one germination (gap # 35). There was
a bias towards sampling larger gaps as the aim of the survey was to
identify tree species germinating in gaps. The 37 fully-analyzed gaps
were grouped into three size classes. All but two of the 18 gap
species were found as seedlings in at least one gap of each size class
(Table 4). The two exceptions were among the least common of the 18
gap species; Crotch mubango was found in only six gaps and

Alstonia boonei was found in only five. Most of these species were

97

Table 4. Pioneer species germinations in gaps of different size in mixed and
mbau forest types of the Ituri Forest, Zaire. a

 

 

2 b
Gap size (a ) and forest type

 

pioneer (250 3250 <500 3500
species mbau mixed mbau mixed mbau mixed
Musanga
cecropioides 4 2 6 6 5 6
Macaranga
monandra 3 1 6 7 5 6
Ricinodendron
heudeiotii 3 2 4 7 5 7
Nacaranga
spinosa 4 2 5 6 4 6
Alstania
boonei 1 O 3 2 5 5
Trema
orientaiis 2 0 1 3 4 5
Albizia
gummifera 1 1 1 2 3 3
Fagara
macrophylla 0 1 2 2 2 3
Canarium
schweinfurthii 1 0 2 3 2 1
Bridelia sp. 1 0 3 2 O 2
Cola
lateritic 1 0 0 2 1 3
Ficus
capensis 1 1 1 0 1 3
Uhpaca
guineensis 0 1 0 2 1 2
Crotch
mubango 0 0 0 1 1 4
Harungana
madagascariensis 2 0 1 1 1 1
Erythrophleum
suaveolens 2 0 0 1 2 0
Phyiianthus sp. 1 0 2 0 1 2
Anthocieista
schweinfurthii 0 0 1 O 3 1
number of gaps n-7 n-3 n-6 n-9 n-5 n-7

 

A total of 37 gaps were included in the analysis. 18 from when forest
and 19 from mixed forest. Gaps from transition forest were excluded.

Ground measurement of gap area.

98
found in the smaller gaps (< 250 me) as well as the larger ones.
This is remarkable considering that the smaller gaps provided much less

total surface area for colonization.

The occurrence of mature individuals of the five gap species
found most commonly as seedlings in gaps, Musanga cecropioides,
Macaranga monarda, Macaranga spinosa, Ricinodendron heudelotii, and
Alsonia boonei, was considered an indication of past treefall
disturbance in primary forest. All canopy-level individuals of these
gap species were recorded for the 2.5 ha plots (Table 5). These
species have different growth rates but, judging from disturbances of
known age where the species are found, these mature individuals of
pioneer species represent disturbances of from 10 years (M.
cecropioides, Macaranga spp.) to probably more than 30 years of age
(A. boonei, R. heudelotii).

The number of mature light-dependent trees did not differ
significantly between the two forest types at a probablility of .05;
however, a trend toward more such trees in mbau forest was apparent at
a probability of 0.1 (Table 5). When sites within a single forest type
were compared there was a significant difference in mbau forest between
the Eboyo and Sambo sites (P < .05). (These data were not taken at the
Mangbara site).

The five pioneer species were not equally represented as
mature individuals in the two forest types. The fastest growing ones

(Musanga cecropioides, Macaranga spp.) accounted for most of the

99

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100

mature pioneer individuals recorded in mbau forest (94% or 79 of 84
individuals). In mixed forest, the slower—growing pioneer species
(Ricinodendron heudelotii, Alstonia boonei) were a larger

proportion of the mature pioneer species in the canopy (53% or 36 of 68
individuals).

The number of old gaps was significantly greater in mixed
forest than in mbau forest (Table 5, P < .01). When the sites within a
single forest were compared, no significant difference was found (P >
0.1). The old gaps, recognized as decaying logs under residual canopy
gaps, were used as an approximation of the frequency of
intermediate-aged disturbances (5-15 years of age).

The difference in density of surviving sapling and pole-size
individuals in mixed and mbau forest treefalls was only significant at
a probability of < 0.1 (Table 6; mbau forest mean = 2.70, SD = 1.15;
mixed forest mean = 1.52, SD = 0.53). If the only species considered
are those reaching maturity at canopy height, then the density of
surviving juveniles > 2.5 cm diameter was significantly greater in mbau
forest gaps than in mixed forest gaps (Table 6: mbau forest mean =
2.52, SD = 0.98: mixed forest mean = 1.19, SD = 0.51). Gaps in
transition forest and the smallest treefall gaps were omitted from the
calculations. The highest densities of remaining saplings and poles
was found in the two smallest gaps ( < 50 m2), both in mbau
forest, (means = 11.11 and 12.24 surviving individuals per 100 m2)
presumably because less damage is caused by a falling branch than by an
entire living tree.

The two-year growth data for seedlings of gap-species (i.e.

101

2
Table 6. Density per 100 m of surviving saplings and poles in treefall
a

 

 

 

gaps.
Mbau forest Mixed forest t b
(n a 8 gaps) (n - 5 gaps) value significance
all x 2.70 1.52 2.134 (P<0 1)
species SD 1.15 0.53
potential x 2.52 1.19 2.782 P<.05
canopy SD 0.98 0.51

species

 

All stems > 2.5 cm dbh and g 20 cm dbh included in survey.

Probability > .05 in parentheses.

102

pioneers) and released shade-tolerant saplings in gaps were difficult
to summarize because of the great variability between species and among
individuals within species. The cause of variability in growth rate
within individuals of the same species arises, no doubt, from the many
uncontrolled factors, including size at first measurement, browse
damage, shading from adjacent vegetation, position within gap, genetic
variability, etc.

Four gaps were revisisted after four years, two medium—sized

2

gaps in transition forest (500 m and 290 m2) and two large

gaps (2600 m2 in mixed forest and 2250 m2 in mbau forest).
The large gap in mbau forest received frequent okapi (Okapia
johnstoni) damage and none of the marked pioneer seedlings, primarily
of the 18 gap species, were present after two years. Some new ones had
apparently seeded in and three of these had basal diameters > 3 cm.
Height had been stunted by repeated browsing. Released seedlings and
saplings of caesalpiniaceous dominants were free from browse damage.
Recorded diameter increments on light-released saplings were 15 mm
(Gilbertiodendron dewevrei, from 22.6 to 24.1 cm dbh) and 7 mm
(Brachystegia laurentii, from 6.2 to 6.9 cm dbh). Released
seedling of G. dewevrei (< 1 m height when first measured) grew a
mean of 31.5 cm in height (h = 4, SD = 13.63).

The large gap in mixed forest was not frequented by okapi.
Individuals of some pioneer species were very prominent after two
years. The greatest diameter increment was in Mbsanga cecrqpiaides

(+86 mm, +100 mm, and +92 mm, measured above the incipient aerial

roots; original basal diameter measurements had been 20 mm, 50 mm, and

103

81 mm respectively). The fastest growing pioneers were those receiving
maximum sunlight. They were in the center part of the gap and had
germinated on upturned rootmasses above the surrounding vegetation and
debris. Other measured pioneer species that were located after 2 years
(n = 8) varied in basal diameter increment from 5.2 mm (canarium
schweinfurthii) to 31.4 mm (Crotch mubango).

-No pioneer species was refound in one of the two medium sized
gaps. In the other, of three pioneer seedlings found in 1981, two had
died after two years. The remaining one, Macaranga spinosa. had
only increased 4 mm in basal diameter. Two released seedlings of
dominant species showed growth equal to or better than the pioneer
species. A Gilbertiodendron dewevrei seedling had a basal diameter
increment of 4.5 mm (from 17.1 to 21.6 mm) and a Brachystegia
laurentii seedling had a basal diameter increment of 3.8 mm (from
11.6 to 15.4 mm).

Eight of the 18 common gap species have seeds large enough to
have been picked out from soil samples searched for large (> 0.5 cm
length) seeds (Ricinodendron heudeiotii, Alhizia gummifera, canarium
schwienfurthii, Cola lateritia, Dapaca guineensis, croton mubango.
Erythrqphieum suaveolens, and Phylianthus sp.). One viable seed
of Ricinodendron heudelotii and one of C. schweinfurthii were
found and subsequently germinated. Two seeds of E. suaveolens were
found which failed to germinate in five months but which appeared to be
'viable when cracked open. Seven other viable seeds, of six species,
were found as well (Table 7). Not included in the survey results were

‘the numerous seeds of B. laurentii which were just ripe and falling

104

Table 7. Large viable seeds (> 5 cm length) found in the litter and uppermost
soil layer of mbau forest and mixed forest.

 

 

 

Mbau forest Mixed forest
2 2
area sampled 61 m 38 m
species found Ricinodendron Klainedoxa
heudeiotii gabonensis
Canarium Tabernaemontana sp.
schweinfurthii
Erythrophleum Strombosiopsis
suaveoiens tetrandra

two unknowns one unknown

 

105

to the ground during one sample period.

The total area searched for large seeds was 99 m2 (Table
7), about half the size of an average gap. Although not very many
seeds of large-seeded light-dependent trees were found, this density
corresponds with the findings in actual treefall gaps. Most gaps
contained only one to two seedlings of Ricinodendron heudelotii
whereas many seedlings of a small-seeded species such as.Musanga
cecropioides or Macaranga spp. are likely to be present.

Relative to large-seeded species, during both wet and dry
seasons, woody species with small seeds (generally < 3 mm length) were
well represented in the soil seed banks of all three forest types
(Appendix A). Four of the eighteen most common gap species were found
in these samples (Masanga cecropioides, Trema orientalis, Macaranga
spp. Phyllanthus sp.). Of these, the two most abundant,.M.
cecropiaides and It orientalis were found in soil collected both
during the wet and the dry season and in soil from both mixed and mbau
forest (Table 8). Small-seeded woody species maintained a mean density
of 50 seeds per square meter for both collecting periods in all three
forest types (Figure 4). In the two primary forests Ml
cecropioidbs was the most abundant species in the seed bank with a
mean density of 82 seeds per square meter (averaged over collection
periods and the two forest types). Seedlings of this species and the
other small-seeded species are generally restricted to exposed mineral
soil in treefall gaps. This microsite, including upturned rootmasses,
accounts for only a small proportion of the area affected by treefall

disturbance.

106

Table 8. Number of seed germinations in soil samples from three forest
types during a wet and dry season. 1982-1983.

 

 

a
Number of germinations

 

Mbau forest Mixed forest Secondary forest
wet dry wet dry wet dry
lusanga
cecropioides 15 23 7 54
frame
arientalis 4 11 5 17 44 37
Ficus
exasperata 2
Ficus sp. 1 1
Ahcaranga sp. 1
Phyiianthus sp. 1 1
unknown ‘ 7 1 1
unknown 1
total 22 30 15 72 44 39

 

For both seasons. 10 soil samples were taken from each forest type.
Each sample was a volume of soil. 300 cm x 7 cm.

107

Figure 4. Abundance of viable seeds of small-seeded woody species
in the soils of three forest types during the wet and

dry season (1982-1983).

germinations
per
m2

7+ISE

300

100

 

108

 

wet season

dry season

 

 

 

mixed secondary

forest type

109

Seeds of three of the gap species were available in large
enough quantities to allow preliminary observations on germination
response under different conditions. Seeds of Phyllanthus sp. and
Ricinodendran heudelotii, both large-seeded, and those of the
small-seeded.Mhsanga cecropioides were planted in sub-canopy and
open germination beds. Phyllanthus seeds and Ricinodendron are
antelope dispersed. Seeds regurgitated during rumination were
collected from captive antelope pens. M. cecropioides seeds are
much smaller and are commonly dispersed by primates after passage
through the digestive track. The whole fruit was mashed into a slurry
with water and spread into plots.

After eight months, 18 of 118 Phyllanthus seeds planted in
the open produced seedlings while none of the 59 planted in the shade
germinated. The first seeds in the open plots germinated after 1 1/2
months and seeds were continuing to germinate after seven months. Many
of the seeds had "disappeared", however, possibly due to predation.
Eight months after planting, all but eight seeds had disappeared from
the shade plots and these were found to be rotten when broken open.

None of the 143 Ricinodendron heudelotii seeds placed in
shade beds germinated during 1 1/2 years of observation. Thirty of the
ungerminated seeds appeared to be viable when broken open a year after
planting (the embryo was firm and white). 0f approximately 500 seeds
placed in the Open germination beds, 38 had germinated after a year and
a half. As with Phyllanthus, germinations were not synchronous but
occurred irregularly throughout the observation period with the first

germinating two months after planting and others germinating during the

110
last months of observation. Of the ungerminated seeds remaining in the
plots, more than 90% appeared to be viable when hammered open.

The slurry of Musanga cecropioides seeds was spread over
two plots each in the open and shaded germination beds. In each
location, one of the plots had been cleared and scraped to mineral soil
and the other plot was covered with dead fallen leaflets of G.
dewevrei. The total number of seeds planted was not counted but
numbered in the 1003 for each plot. After six months in the shaded
beds, no germinations had occurred on the litter-covered plots. During
the sixth month of observation,though, three seedlings germinated on
the bare mineral soil. In the open beds, one germination occurred
after six months in the litter-covered plot; many (>50) germinations
occurred in the bare mineral soil plot.

Using standard diversity indices to compare secondary forest
with the two types of primary forest, it is apparent that, for stems >
10 cm dbh, both 15 year-old and 40 year-old forests are more diverse
than, or at least comparable in diversity to, mixed forest. The two
secondary forests are considerably more diverse than mbau forest. The
Simpson's diversity indices (03 = [ 1- (Sini(ni-1) / N(N-1))] for 15
year-old and 40 year-old forests are 0.92 and 0.95 respectively. The
Ds values for mixed forest and mbau forest are 0.89 and 0.37
respectively. In the case of Simpson's diversity indes, greater
diversity causes the value to approach unity. The value of the Shannon
diversity index (H' - -EZpilogpi where pi - ni/N) is also higher for
more diverse communities. The H' values for the 15 year-old and 40

year-old forests are 1.37 and 1.68 respectively. The H' values for

111

mixed and mbau forest are only 1.35 and 0.45 respectively.

A statistical comparison of the diversities of secondary and
primary forest was made by comparing species richness (number of
species per plot) and stem density (number of stems per plot) for all
forest types (Table 9). Four different diameter classes are considered
independently. The 15 year-old secondary forest was significantly less
species rich than the 40 year-old secondary forest for two of the
diameter classes, the sapling class (P < .01, all stem > 2.5 cm dbh
5 10 cm dbh) and the tree class (P < .05, all stems > 25 cm dbh
.3 50 cm dbh). The species richness of the pole-size class (> 10
cm dbh 5 25 cm dbh) and large tree size class (> 50 cm dbh) were
not significantly different between the two forests. Tree species in
the largest size class included those which were not cut when the
forest was originally cleared (two species in two plots of the 15-year
forest, three species in one plot of the 40-year forest).

The mixed forest was significantly richer in species than 40
year-old secondary forest for the pole-size class (P < .05) but for
other size classes there is no significant difference. The 40-year
forest is significantly richer than mbau forest (Table 9, P < .01 or
.001) for all size classes except the large tree class (> 50 cm dbh).

There is no significant difference in stem densities between
15 year-old and 40 year-old forests (Table 10) except for the pole size
class which was denser in 40 year-old forest (P < .05). Four of the 15
year-old forest plots had suffered extensive elephant damage in the
previous two years. It appeared that most of the pioneer species

broken had resprouted, often with several stems.

112

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oncomqamowoo Homo moo mowooom uo monsoz
.mumouou some one
woman ommuom can .amomou amoucooom uaolmooa co .uoomou anopcoooa
vnoumcoa ma cu mommo~o mousse—c unomouuuv uo euocsoqu eo—ooom .a smash

113

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mo.va mz mz ~v.m o~.~ m~.~ pc.a x
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NH": «an: «nu: «an: enema
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.m> amoauov .m> noo>uov .w> noo>unfi :mnm coxwm nmozuov unmanna uouo mouommnc
omcomqnmomoo pogo coo macaw uo monmsz
.muuomou some one conga
enzyme was .umonou ammvmoooo vnonmooa ow .umomou amoucooom
ufiounooa on em wowaoao couomoqu ucoaouuqc uo moququcou scum .og canoe

114

Both mixed forest and mbau forest had a greater density of
sapling size stems in the understory (P < .001 and P < .05,
respectively) than did 40 year-old forest. Mixed forest also had a
denser pole size class (P < .001) than did the 40 year-old forest.
Mbau forest was significantly sparser in the tree size class (P < .05)
but significantly denser in the largest size class (P < .05) than the
40 year-old forest.

The basal area of all species > 10 cm dbh did not differ
significantly between the 40 year-old secondary forest ( mean = 29.6

m2 ha-l, SD = 7.62) and the two mature forests (mixed forest

mean = 30.4 m2 ha-l, SD = 8.016; mbau forest mean = 34.08

m2 ha-l, SD = 11.2).

There was very little overlap between the secondary and mature
forests in terms of which species account for the basal area. Shade-
intolerant species dominated in the secondary forests, although there
remained the few remnant mature forest trees, mentioned earlier, which
were not cut when the forest was cleared. Many of the gap species
were important in the canopy of secondary forest, in particular,
.Musanga cecropioides, Macaranga spinosa and Phyllanthus sp..

The 18 gap species alone were responsible for 77% (SD = 19.6) of the
basal area in 40 year-old forest where they were 54% of all stems > 10
cm dbh. In the 15 year-old forest they comprised 76% of stems > 10 cm
dbh.

The important species contributing to basal area in mature

forest were shade-tolerant species whose seedlings and saplings were

represented in all size classes of the understory. G. dewevrei

115

accounts for 88.5% (SD = 15.05) of the basal area in mbau forest.
B. laurentii, C. alexandri, and C. michelsonii combined account
for 60.7% (SD = 20.31) of the basal area in mixed forest.

The dominant species of the mature forest were strikingly
rare, even as juveniles, in the secondary forest. They were absent
from the sapling and pole size classes (Table 11). The combined
density of G. dewevrei, B. laurentii, C. alexandri and C.
michelsonii was significantly lower for these size classes in 40 year
old forest than in either of the mature forest types (P < .01 and P <
.001). Nor were these species any more frequent as juveniles in the 40
year-old forest than in the 15 year-old forest (Table 11). In fact,
although there were no significant differences, the mean density of
these species was higher in the younger forest where many of them may
have been sprouts from undamaged root stock. (The younger forest had
only been burned once).

Smaller seedlings were not systematically censused in the
secondary forest but special note was taken of seedlings of G.
dewevrei and B. laurentii. Where these were seen, they were
always closely associated with a parent tree which had not been cut
during cultivation. The seedlings formed a narrow seedling shadow
reflecting the limited range of the characteristic ballistic
dispersal. The mature forest species appearing in the understory of
secondary forest and not associated with remnant parent trees were
animal dispersed. These included species such as Dacryodes sp.,
Anonidium manii, Celtis mildbraedii. Dialium sp., Chlorophora

excelsa, and Farinari exceisa. All of these species are

116

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«mu: emu: «an: «an: muono
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sons nexus penance umomou umomou umomou umomou Aumvomum mmm~o
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nmcowummomou uoao moo mmoum no moamsz
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uo m~o=c«>~uca ommmnoaoo can ucfiaoma uo >u~ucov osquonoomoo .nfi agony

117

infrequent in the mature forest relative to the shade-tolerant

dominants.

DISCSUSSION

Species diversity relative to size and frequency of treefall gaps

The first hypothesis proposed in this study was that the more
diverse mixed forest has more frequent and larger disturbances than
mbau forest. The results were somewhat equivocal. There are likely to
be more treefall disturbances for any given area of several hectares in
mixed forest than for a similar sized area in mbau forest. The
disturbed proportion of the total area, however, was not predictably
greater in mixed forest than mbau forest due to gap size variability
and the irregularity of gap occurence in both forests.

If individual sample plots were larger, for instance 1-3
km2 per plot, this would reduce the inter-plot variability in
total area disturbed, at least if gaps of only up to approximately 1000
m2 were encountered. These larger plots, however, would still not
allow adequate sampling for the blow down scale disturbances. In fact.
it is unlikely that any size plot would be adequate because of the time
factor. Large blowdowns are not only rare in space but also in time.
This does not preclude the possibility that they have had an influence
on the distribution of forest types.

It is possible that an area with very few recent treefalls may

118
have had many in the past. The fact that old gaps with decaying logs
were more numerous in mixed than in mbau forest supports the hypothesis
of greater overall disturbance in mixed forest. It is particularly
interesting that the mixed forest site with the fewest recent
treefalls, Kadiketu, had the most old gaps. This suggests a possible
cyclical occurrence of gaps at a time interval of > 15 years. Such
patterns were not seen, or looked for, elsewhere but they merit further
investigation.

The five most common pioneer species were more frequent as
mature individuals in mbau forest than in mixed forest (although only.
at P < 0.1). This result appears to be in conflict with the presence
of more old gaps in mixed forest. It is curious that only the fastest
growing pioneer species, in particular Mbsanga cecropioides, were
represented in the mbau forest canopy, whereas the slower growing
pioneers were more common in mixed forest. A possible explanation for
this is a difference in the nature of canopy closure of gaps in the two
forest types. The dominant and emergent trees in mixed forest have
broad shallow crowns which often are not contiguous, allowing light to
reach subcanopy layers. Subcanopy size classes are denser in mixed
forest than mbau forest (Table 10, see also chapter 1). It may be that
shade-intolerant gap-species are able to maintain themselves as
pole-size individuals in mixed forest but not mbau forest. In mbau
forest the dominant, G. dewevrei, has deep narrow crowns which are
generally contiguous. The subcanopy layers are relatively sparse and
composed mainly of shade-tolerant species.

This interpretation points to the importance of canopy

119
structure to the maintenance of species diversity. The perpetuation of
species richness in the upper canopy depends on the species richness of
shade suppressed understory layers because the understory is the major
source of future canopy level crowns. In the Ituri Forest the
difference in diversity between mixed and mbau forest understories may
be more closely tied to differences in canopy structure than to

differences in gap dynamics.

Species diversity relative to the variety of gap microsites

The second hypothesis proposed was that treefalls in the mixed
forest provide a greater diversity of microsites for seedling
establishment and growth than mbau forest. None of the measured
variables thought to affect microsite differed significantly between
the two forest types (number of gaps with upturned rootmasses, overhead
cover, and number of gap-forming trees).

The litter was different in the two forest types as a result
of differences in species composition. Mbau forest gap litter was
composed primarily of G. dewevrei leaves and branches whereas
litter from this species was essentially absent from mixed forest.
These differences did not have a measurable influence on germination of
pioneer species. Similar species colonized gaps in both forest types.
Although gap size and shape undoubtedly determined whether or not
individual seedlings would be likely to reach maturity, above a certain
minimum area (approximately 100 m2), gap size did not influence
which species germinated.

There was no evidence that tree species had specialized in any

120
more than a general way to specific sites within gaps or to specific
"kinds" of gap. For instance, small-seeded species did not root
through thick litter but they were found germinating not only on root
masses but also spots of bare soil and rotting wood. Also, released
dominants grew better than shade-intolerant pioneers in small gaps,
but, except for young seedlings, they were also able to grow in the
full sunlight conditions of large gaps.

In terms of affecting forest composition, the important
conditions in treefall gaps may not be those at ground level, which are
pertinent primarily to germinating pioneers, but rather those at
mid-level which are pertinent to released canopy species. Overall,
pioneer species make a very small contribution to canopy diversity.
Released saplings and poles are probably less microsite sensitive and
may be able to benefit from a range of increased availability of
light. Although the density of potential canopy species was greater in
the understory of mbau forest, the species richness of this layer was’
greater in mixed forest (see chapter one). The factors affecting the
diversity of the suppressed subcanopy layers may be more immediately
relevant to the maintenance of canopy diversity than variations in
seedling microsites provided by treefall gaps of different sizes or
shapes.

In terms of autecological studies pertinent to forest
diversity, it is likely to be more productive to investigate tolerance
ranges for different species rather than microsite specializations.
Particularly interesting are ranges of tolerance to shade and sunlight

for different sizes or ages of any given species as these factors

121

affect the relative abundance of canopy species as suppressed

individuals in the understory.

Contribution of gap-dependent species to overall forest diversity

The third hypothesis proposed was that gap-dependent species
account for a greater proportion of all tree species present in mixed
forest than in mbau forest. The 18 species which regenerate in and
commonly restricted to gaps occur in both forests but are relatively
unimportant in both. Both forest types are dominated by shade-tolerant
species, C. dewevrei in mbau forest and B. laurentii, C.
alexandri, and C. michelsonii in mixed forest: however, the
relative abundance of the shade-tolerant dominants is less in mixed
forest, both in terms of density and basal area, than in mbau forest.

The decreased importance of shade-tolerant dominants in mixed
forest was not matched by an increased importance of the common
gap-dependent species. Instead, a group of species of uncertain shade
tolerance was more prominent in mixed than in mbau forest. These
species were not common in the understory of mature forest but this
fact is not an adequate indication of their shade intolerance as they
were also rare in the canopy. The conditions under which these tree
species usually germinate and establish remain obscure, except that
they do not behave like pioneer species as they were not common in
early secondary forests. It is not even clear that these species will
show similar physiological responses to a given set of environmental
conditions.

The scattered individuals of mature forest species found as

122

juveniles under the canopy of 40 year-old forest belonged to this
group. All the species found had animal-dispersed seeds whereas the
seeds of the shade-tolerant dominants in mature forest were heavy and
normally received no further dispersal than the forceful expulsion from
their pods.

This difficult-to—classify group of species may correspond to
Whitmore's (1982) "broad class of species of intermediate tolerance",
or late secondary species. The fact that these species are more
abundant and diverse in mixed forest than in mbau forest may be related
not only to the frequency of gaps in mixed forest but also to the
forest structure itself. The upper canOpy (35-45 m) is more open and
heterogeneous in mixed forest than mbau forest. It may be that B.
laurentii, due in part to the geometry of its crown, is less likely
to exclude species of intermediate tolerance which can not survive

under a closed canopy of G. dewevrei.

Distribution of forest types relative to major past disturbances.

The fourth hypothesis proposed was that one of the two forest
types is composed of species more resilient to large scale disturbance
than the other forest type. Presumably the species association of one
forest type can invade and establish more rapidly than the species
association found in the other.

If we consider a major disturbance to be one that kills all
living trees over an area of several hectares or more, then tree
species that disperse diaspores over large distances will have the

best chances for establishment. Mixed forest contains a greater

123

proportion of animal and wind-dispersed tree species than mbau forest.
Thus, the forest that would eventually replace early secondary species
after a major disturbance would more closely resemble mixed forest.
Because of their poor dispersal capabilities, however, mixed forest
dominants, including Brachystegia laurentii, Cynometra alexandri,

and Cleistanthus michelsonii would be conspicuously absent.

None of the shade-tolerant dominants from either forest type
are adapted to colonize large disturbances. These species have
primarily ballistically dispersed diaspores. In a 40 year period,
seedlings of the shade-tolerant dominants from mature forest had not
invaded the secondary growth on abandoned garden sites more than
several meters beyond the crown edge of remnant mother trees.
Nevertheless, the three dominant canopy species in mixed forest have
larger crowns and smaller seeds than the mbau forest dominant and they
would, therefore, be likely to move into a disturbance from its border
more quickly than Gilbertiodendron dewevrei.

It is tempting to hypothesize that prehistoric disturbance
is responsible for the current distribution of the two forest types in
the Ituri region, or at least, for the distributions of the forest
dominants. Gilbertiodendron dewevrei, Brachystegia laurentii,
cynometra alexandri, and Cleistanthus michelsonii may be slowly
spreading from isolated forest pockets left in the wake of large scale
major disturbance. In the case of mixed forest, in the central Ituri
Forest, the three latter shade-tolerant species are now co-dominant.
On the other hand, in some areas a single dominant species may act as a

slowly-moving invasive front (see Louis 1947 for G. dewevrei and

124
Eggeling 1947 for C. alexandri). The transition zone where
species' fronts meet today may be dynamic and subject to change
according to local disturbance patterns.

An extensive burned charcoal layer, at 20 cm depth, was found
in the study area and was dated at 2,290 390 years B.P. (Beta
Analytic Inc., Coral Gables, FL). This is evidence for past
disturbance. There is, as yet, however, no palynological data to
support a "refugium-expansion" explanation for forest type
distributions in the Ituri watershed. A field study that might reveal
a relationship between species distributions and pre-historical fire
would involve mapping the extent of the burned charcoal layer in
conjunction with maps of dominant forest species.

In summary, some support was found for three of the four
hypotheses proposed in this paper. Their ability to adequately explain
the difference in species diversity between the two forest types,
however, is uncertain. The more diverse mixed forest had more frequent
though not consistently larger treefall disturbances than the mbau
forest. No difference in microsite availability within treefall gaps
was found between the two forest types. The five most common tree
species found as seedlings in treefall gaps were not more frequent as
mature individuals in mixed forest than mbau forest and they accounted
for only a small proportion of the trees present in either forest. The
mixed forest contained a greater proportion of well-dispersed tree
species indicating that it may be more resilient to major disturbance
than mbau forest. Well-dispersed species would be relatively rapid

colonizers, but the majority of canopy-level individuals in both forest

125

types is accounted for by only a few poorly—dispersed species which are
not good colonizers.

Although the less complete dominance by a single
shade—tolerant species in mixed forest may be due, in part, to the more
frequent treefall disturbance in this forest type as compared to mbau
forest, this study suggests that other factors are also important.
Differences in density and regularity of the upper canopy affect the
species richness of suppressed subcanopy layers which, in turn,
determine the diversity of species able to be released by small canopy
gaps.

If the less frequent treefall disturbance in mbau forest is
due to the forest structure itself, then normal disturbance rates may
be important to the maintenance of diversity within each forest type
but not to major changes in forest composition. This is because the
characteristic structure of mbau forest is due to the established
single species dominance by Gilbertiodendron dewevrei. That 6.
dewevrei stand structure might engender low disturbance rates is
suggested by its aerodynamically smooth canopy surface and the species'
tap root (Putz 1984). A variable disturbance rate at the transition
zone between mixed and mbau forest might affect the rate of advance or
retreat of 6. dewevrei but only the rare large-scale disturbance
would make major changes in species diversity and then only by changing
dominance patterns and restructuring the forest.

Normal disturbance rates, as measured in this study, may be
relatively trivial patterns, as far as forest composition and diversity

are concerned, imposed on a more fundamental pattern of recovery from

126
ancient disturbance. Although there is ample evidence for Holocene
changes in the extent of African rain forest (Hamilton 1982,
Livingstone 1980a, 1980b), how these climatically—mediated shifts are
reflected in modern forest composition at any given point has not been
clarified. But, to the extent that interpretations can be drawn from a
larger time scale, our understanding of dominance and diversity in

African equatorial forests would be greatly enhanced.

127

FOOTNOTES

The Ituri Forest is generally included in tropical rain

forest maps as the northeastern edge of the Guineo—congolese forest
block (Richards 1952, Walter 1973, White 1983). It fits the
general structural and climatic definition of rain forest as used
by Richards (1952) and Whitmore (1984). Although very few climatic
data have actually been collected in the Ituri region, Bultot
(1971) inferred, from patterns at surrounding stations
(observations 1930-1959), that mean annual precipitation was
between 1700 and 1800 mm with a rainless period of no more than 40
days. The driest period is from mid-December to the end of
February, during which time the monthly precipitation may fall

below 100 mm.

"Mature", here, means "climax" as used by Lorimer (1980) to
describe an all-aged forest of Southern Appalachia, "capable of
self perpetuation in the absence of severe disturbance". The
dominant canopy trees of both Ituri forest types occur as
seedlings, saplings and poles under the forest canopy (see chapter

one).

128

LIST OF REFERENCES

Anderson, J. A. R. 1964. Observations on climatic damage in peat
swamp forest in Sarawak. Emp. For. Rev. 43: 145-58.

Augspurger, C. K. 1984. Seedling survival of tropical tree species:
interactions of dispersal distance, light-gaps, and pathogens.
Ecology 65: 1705-1712.

Brokaw, N. V. L. 1985. Gap-phase regeneration in a tropical forest.
Ecology 66: 682-687.

Bultot, F. 1971. Atlas Climatique du Bassin Congolais, deuxieme
partie. Publication of the Institut National pour l'Etude
Agronomique du Congo (INEAC). Hors série. Brussels.
Belgium.

Cheke, A. S., W. Nankorn, C. Yankoses. 1979. Dormancy and dispersal
of seeds of secondary forest species under the canopy of a
primary tropical rain forest in northern Thailand. Biotropica
11: 88-95.

Connell, J. H. 1978. Diversity in tropical rain forests and coral
reefs. Science 199: 1302-1309.

Davis, M. B. 1976. Pleistocene biogeography of temperate deciduous
forests. Geoscience and Man. Volume 13: Ecology of the
Pleistocene. Baton Rouge.

Denslow, J. S. 1980. Gap partitioning among tropical rain forest
trees. Biotropica 12 (supplement): 47-55.

Eggeling, W. J. 1947. Observations on the ecology of Budongo rain
forest, Uganda. Journal of Ecology 34: 20-87.

Flenley, J.R. 1979. The Equatorial Rain Forest: a Geological History.
162 pages. Butterworths, Boston.

Florence, J. 1981. Chablis et sylvigenése dans une forét dense
humide sempervirente du Gabon. Thesis presented at the Louis
Pasteur University of Strasbourg in order to obtain the
doctorat with specialy in sciences.

Gérard, P. 1960. Etude écologique de la forét dense a
Gilbertiodendron dewevrei dans la région de l'Uele.
Publication of the Institut National pour l'Etude Agronomique
du Congo (INEAC). série scientifique # 87, Brussels.

Germain, R. and C. Evrard. 1956. Etude écologique et
phytosociologique de la forét a Brachystegia laurentii.
INEAC, série scientifique # 67, Brussels.

129

Grime, J. P. 1979. Plant Strategies and Vegetation Processes.
222 pp. John Wiley and Sons, New York.

Guevara, S. and A. Gomez-Pompa. 1972. Seeds from surface soils in a
tropical region of Vera Cruz, Mexico. Journal of the Arnold
Arboretum. 53: 312-335.

Hall, J. B. and M. D. Swaine. 1981. Distribution and Ecology of
Vascular Plants in a Tropical Rain Forest: Forest Vegetation
of Ghana. Dr. W. Junk, Boston.

Hamilton, A. 1982. Environmental History of East Africa: A Study of
the Quaternary. Academic Press, N.Y.

Hartshorn, G. S. 1978. Treefalls and tropical forest dynamics. pages
617-638 in P.B. Tomlinson and M.H. Zimmerman, eds. Tropical
Trees as Living Systems. Cambridge University Press,
Cambridge.

Hartshorn, G. S. 1980. Neotropical forest dynamics. Biotropica 12
(supplement): 23-30.

Hubbell, S. P. 1979. Tree dispersion, abundance, and diversity in a
tropical dry forest. Science 203: 1299—1309.

Hubbell, S. P. 1980. Seed predation and the coexistence of tree
species in tropical forests. Oikos 35:214-229.

Jongen, P., M. van Oosten, C. Evrard, and J-M. Berce. 1960. Carte des
sols et de la végétation du Congo Belge et du Ruanda-Urundi.
Vol. II: Ubangi. INEAC, Brussels.

Leigh, E. G., Jr. 1982. Why are there so many kinds of tropical
trees? pages 63-66 in E.G. Leigh, A.S. Rand, and D.M.
Windsor, eds. Ecology of a Tropical Forest: Seasonal Rhythms
and Long-term Changes. Smithsonian Institution Press,
Washington, D.C.

Leyden, B. W. 1985. Late Quaternary aridity and Holocene moisture
fluctuations in the Lake Valencia basin, Venezuela. Ecology
66: 1279—1295.

Lewin, R. 1984. Fragile forest implied by Pleistocene pollen.
Science 226: 36-37.

Livingstone, D. A. 1980a. Environmental changes in the Nile
headwaters. pages 339-359 in M. Williams and H. Faure, eds.
The Sahara and the Nile: Quaternary Environments and
Prehistoric Occupation in Northern Africa. A. A. Balkema,
Rotterdam.

Livingstone, D. A. 1980b. History of the tropical rain forest.

130

Paleobiology 6: 243-244.

Lorimer, C. 1980. Age structure and disturbance history of a southern
Appalachian virgin forest. Ecology 61(5): 1169-1184.

Louis, J. 1947. Contributions 3 l'étude des foréts équatoriales

congolaises. in Comptes rendus de la semaine agricole de
Yangambi (February 26- March 5, 1947). INEAC (hors série),
Brussels.

MacArthur, R. H. 1972. Geographical Ecology: Patterns in the
Distribution of Species. Harper and Row, New York.

Oldeman, R. A. 1978. Architecture and energy exchange of
dicotyledonous trees in the forest. pages 535-560 in
P.B. Tomlinson and H. Zimmerman, eds. Tropical Trees as
Living Systems. Cambridge University Press, Cambridge.

Orians, G. 1982. The influence of tree-falls in tropical forests
on species richness. Tropical Ecology 23: 255-279.

Paine. R. T. 1984. Ecological determinism in the competition for
space. Ecology 65: 1339-1348.

Pickett, S. T. A. 1983. Differential adaptation of tropical tree
species to canopy gaps and its role in community dynamics.
Tropical Ecology 24: 68-84.

Putz, F. E. 1983. Treefall pits and mounds, buried seeds and the
importance of soil disturbance to pioneer trees on Barro
Colorado Island, Panama. Ecology 64: 1069-1074.

Putz, F. B., P. D. Coley, K. Lu, A. Montalvo, and A. Aiello. 1983.
Uprooting and snapping of trees: structural determinants and
ecological consequences. Canadian Journal of Forest Research
13: 1011-1020.

Richards, P. W. 1952. The Tropical Rain Forest, an Ecological Study.
450 pages. Cambridge University Press, N.Y.

Sanford, R. L.,Jr., J. Saldarriaga, K. E. Clark, C. Uhl, and R.
Herrera. 1985. Amazon rain forest fires. Science 227:
53-55.

Sokal, R. R. and F. J. Rohlf. 1969. Biometry. The Principles
and Practice of Statistics in Biological Research.
776 pp. W. H. Freeman 8 co., San Francisco.

Talbot, M. R., D. A. Livingstone, P. G. Palmer, J. Maley, J. M. Melack.
G. Delibrias, S. Gulliksen. 1984. Preliminary results from
sediment cores from Lake Bosumtwi, Ghana. Palaeoecology of
Africa and the Surrounding Islands 16: 173-192.

131

Uhl, C. and K. Clark. 1983. Seed ecology of selected Amazon basin
successional species. Bot. Gaz. 144 (3): 419-425.

Veblen, T. T., D. H. Ashton, F. M. Schlegel. 1979. Tree regeneration
strategies in a lowland Nothofagus-dominated forest in
south-central Chile. Journal of Biogeography 6: 329-340.

Walker, D. 1982. The development of resilience in burned vegetation.
pages 27-43 in E.I. Newman, ed. The Plant Community as a
Working Mechanism. Blackwell Scientific Publishers. U.K.

Walter, H. 1973. Vegetation of the Earth in Relation to Climate and
the Eco-physiological Conditions. Translated from the 2nd
German edition by Joy Weiser. 237 pp. Springer-Verlag, N.Y.

Webb, L. J. 1958. Cyclones as an ecological factor in tropical
lowland rain forest, No. Queensland. Australian Journal of
Botany 6: 220-228.

White, F. 1983. Vegetation Map of Africa South of the Sahara. 2nd
edition. text: 356 pages. Unesco/AETFAT/UNSO. Paris.

Whitmore, T. C. 1974. Change with Time and the Role of Cyclones in
Tropical Rain Forest on Kolombangara, Solomon Islands.
78 pp. Commonwealth Forestry Institute Paper # 46.

Whitmore, T. C. 1978. Gaps in the forest canopy. in P.B. Tomlinson
and M.H. Zimmerman, eds. Tropical Trees as Living Systems.
Cambridge University Press, Cambridge.

Whitmore. T. C. 1982. On pattern and process in forests. pages
45-59 in E.I. Newman, ed. The Plant Community as a Working
Mechanism. British Ecological Society. Blackwell. Oxford.

Wyatt-Smith, J. 1954. Storm forest in Helantan. Malaysian Forester
13: 40-45.

CHAPTER III

REGENERATION PATTERNS OF DOMINANT TREES IN LOW AND

HIGH DIVERSITY TROPICAL FORESTS

INTRODUCTION

Humid evergreen and semi-evergreen forests throughout the
tropical zone are noted for high tree species diversity relative to
temperate forests (reviews in Unesco/UNEP/FAO 1977, Hall 6 Swaine 1981.
Leigh 1982, and Whitmore 1984). Large numbers of tree species are
found to coexist in even relatively small forest sample areas. The
co-occurrence of many tree species is remarkable in view of the fact
that most mature trees, regardless of species, have similar resource
requirements (Hubbell 1980, Whitmore 1982). As pointed out by Connell
(1978) and Hubbell (1980), this homogeneity of resource base makes it
unlikely that tropical forest diversity can be explained by niche
differences among different species of mature tree. The ecology of
juvenile stages has, therefore, been invoked as being critical to an
understanding of species richness. Two general hypotheses have been
proposed: 1. The regeneration niche hypothesis (Grubb 1977) and 2. The
seed and seedling predation hypothesis (Janzen 1970, Connell 1971).

In this paper predictions generated from these hypotheses are
examined in a comparative manner, using experiments and observations in

132

133

both a species-rich and a species-poor tropical forest. Field work was
conducted between January 1980 and June 1983 in the Ituri Forest of
northeastern Zaire (Figure 1). The base of operations was at Epulu in
a transition zone between single-species dominant mbau forest and mixed
forest (Figure 2). The rationale and assumptions of the comparative
approach are explained after discussion of both hypotheses and
presentation of predictions derived from them.

Regeneration Niche Hypothesis. Grubb (1977) suggests that
plant species diversity is tied to differences in species' requirements
for regeneration. He considers all stages of the regeneration cycle to
be potentially important including flowering, pollination, seed-set,
dispersal, germination, establishment and the further development of
the immature plant. Grubb predicts that in species-rich tropical
communities available regeneration niches have been partitioned such
that species have narrowly defined regeneration niches. Recently these
ideas have been applied specifically to tropical forests through the
concept of "gap-partitioning" or the partitioning of establishment

sites by tropical tree seedlings (Hartshorn 1978, 1980: Denslow 1980;

Orians 1982, Pickett 1983).

There have been numerous studies of germination requirements
and seedling morphology of tropical tree species (Guevara 8 Gomez-Pompa
1972. Ng 1978, Hall 8 Swaine 1981, Putz 1983, Uhl 8 Clark 1983) and the
phenology of flowering and pollination syndromes (Janzen 1967, Heithaus
et al 1974, Stiles 1975, 1978, Frankie 1975, 1976). These studies have
added greatly to our knowledge of regeneration of tropical trees, but

they do not directly test the hypothesis that tree species richness in

134

Figure 1. The Ituri Forest, Zaire.

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forest types and research areas.
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138

tropical forests is maintained by partitioning of the regeneration
niche.

Using a comparative approach, I predict that in mature
species-rich tropical forest coexisting species will have discrete
and narrow regeneration capabilities. These syndromes are
expected to contrast with a relatively wider, less-specialized
regeneration niche for the dominant species in mature species-poor
tropical forest.

Seed/seedling'predation hypothesis. According to this
hypothesis, as stated by Janzen (1970) and Connell (1971), diversity is
promoted by the fact that seeds and juveniles suffer particularly high
mortality near the parent tree. This hypothesis, dubbed the "escape
hypothesis" by Howe and Smallwood (1982), allows that species specific
predation may increase either because of the greater concentration of
seeds under the parent or because of the nearness of a conspecific
adult. In both cases the expected result is elimination of all
juveniles under the parent and increasing probability for survival and
establishment at greater distances from conspecific adults. This
process leads to the coexistence species. Numerous field studies
conducted during the 19708 gave conflicting results (reviewed in Howe
and Smallwood 1982, Connell et al. 1984. Clark 8 Clark 1984). Two of
the recent studies demonstrated that the process of greater mortality
near the parent or adult conspecifics does indeed frequently occur
(Augspurger 1983, Clark 8 Clark 1984).

It has been pointed out that the expected pattern of predation

may occur during juvenile stages but, nevertheless, not make a major

139

contribution to the species richness of mature trees (Hubbell 1980).
This would be the case in a non-equilibrium community where the
presence of many species results from disturbance (past or ongoing) or
slow climatic change (Connell 1978).

Our comparative approach simultaneously tests the
seed-predation hypothesis and its importance to the maintenance of
species richness. It is predicted that in species-rich tropical
forests seed and seedling mortality will be very high close to the
parents and less severe distant from adult conspecifics. If this
process is important to the maintenance of species diversity, a
contrasting pattern will occur in species-poor forests. Juvenile
mortality near parents will be less devastating and may not differ

significantly from mortality distant from parents.

If the comparative approach is going to be informative it is
essential that there be no other overriding causes determining the
differences in species richness between the two contrasted forests.
Neither forest should be successional and both forests should occur on
equivalent sites without marked differences in topography, soils, or
water regime. In northeastern Zaire these conditions hold for the
single species dominant mbau forest and the species-rich mixed forest.

In their ecological classification of the forests of central
Africa, Lebrun and Gilbert (1954) identified an order of forests which
was evergreen, dense and equatorial (Gilbertiodendretalia Dewevrei).
These forests are widespread on deeply weathered, well-drained

latosols. Two of the characteristic species are Gilbertiodendron

140

dewevrei (DeWild.) Leonard and Brachystegia laurentii (DeWild.)

Louis ex Hoyle. The former is the dominant of the monodominant mbau
forest, accounting for more than 90% of the canopy-level stems and is
well represented in all the juvenile size classes (Louis 1947, Gerard
1960, chapter one, this study). According to Gerard mbau forest is
found on a wide variety of soils in the Uele region (3°N,

240E). Vegetation and soil maps drawn for northeastern and

eastern parts of the evergreen forest zone confirm that mbau forest is
not linked to any outstanding site characteristic and co-occurs with
mixed forests on many soil types (Pecrot 8 Leonard 1960; Evrard et al.
1960; see also chapter one, this study).

The second characteristic species, B. laurentii, is the
most important of several co-dominants in the mixed forest, but never
accounts for more than 40% of the canopy-level stems in our study area
(chapter one. this study). It too is shade tolerant with juveniles in
all size classes (Germain 8 Evrard, 1956). Two other co-dominant
species in mixed forest also have shade tolerant seedlings and
saplings, Cynometra alexandri (Eggeling 1947) and Cleistanthus
michelsonii (pers.obs.). All three mixed forest species are
important elements in forests on a variety of soils.

Our study area contains large blocks of both mixed and mbau
forests (Figure 2). They form a ragged mutual border with island
inclusions of several hectares to several km2 of one forest type
within the other. Soil samples from both forest types were analyzed
for texture and macronutrient availablility but failed to reveal any

significant differences in substrate between mbau and mixed forests

141

(chapter one, this study). Both forests occur on gently rolling
topography. The prevalence of canopy species regeneration in the
understory suggests that both forest types are mature with a basically
self-replacing species composition.

The mixed and mbau forests in northeastern Zaire meet the
conditions of being neither successional nor edaphic formations;
however, before we can test the two diversity hypotheses comparatively
we must establish that opposing predictions would necessarily be made
in each forest type. Diversity differences between the two forest
types are striking (Table 1). Simpson's diversity indices (Ds), which
measure both richness and equitability. are significantly different
(P<.01) when calculated for stems >10 cm dbh in both forest types.
Mixed forest has significantly more tree species per half hectare than
mbau forest. Gilbertiodendron dewevrei accounts for a
significantly greater percentage of the stems in mbau forest than B.
laurentii does in mixed forest. These differences in diversity give
strong reason to infer that if any single process is operating to
maintain species richness in mixed forest, it would be inoperative in
mbau forest.

Comparisons between the two forests are rendered more
meaningful by the fact that species with similar morphological and
ecological attributes exist in each forest type and can be compared.
Gilbertiodendron dewevrei, the dominant in mbau forest, which is
essentially absent from mixed forest except for rare stands. is of the
same tribe, Amherstiae (Caesalpiniaceae), as Brachystegia

laurentii, the most abundant canopy tree in mixed forest. The next

142

Table 1. Species diversity of mixed and mbau forest types of the
Ituri Forest. Zaire, calculated for stems > 10 cm dbh.

 

 

 

 

Mixed forest Mbau forest Probability
b

D3 .89 .37 P<.01
species richness 65 18 P<.01

in 0.5 ha

dominancec 28 79 P<.01

(% stems)

a

Data collected from 24 625m2 plots in each forest type.

b Analysis by Student's t test.

Simpson diversity index: greatest possible value (species richness
and equitability) = 1.

Percent of all stems accounted for by the dominant species in

each forest type.

143
most common species in mixed forest, cynometra alexandri (Table 2),
although of another tribe, is also caesalpiniaceous and has a flower
and a fruit morphology similar to that of G. dewevrei and B.
laurentii. The comparisons presented here consist of contrasting
observations or experimental results obtained of the two mixed forest
species with those obtained of G. dewevrei in the mbau forest. A
third mixed forest co-dominant Cleistanthus michelsonii was
excluded from the study although it also is well represented in all
size classes (Table 2). It belongs to a different family,
Euphorbiaceae, and has very different reproductive characteristics.
Presumably, if single-dominance arises from specific characteristics of
the dominant canopy species. this will be more apparent when this
species is contrasted with canopy species which do not attain
comparable dominance but which, nevertheless, resemble the

single-dominant speices in reproductive ecology and morphology.

The outstanding diversity differences between the two forests
and the morphological similarity of some of the component species in
each community allow a comparative examination of the two diversity

hypotheses. Predictions for each forest type are:

PREDICTIONS
HYPOTHESES MIXED FOREST MBAU FOREST
1. regeneration narrow regeneration broad regeneration
niche niche, (evidence of niche
specialization)
2/ seed/seedling high mortality near good survival near

predation parents parents

144

Table 2. Size class distribution of three co-dominant canopy species
in mixed forest.

 

 

Average number of individuals per hectare

 

 

b
size class Cleistanthus cynometra Brachystegia
michelsonii alexandri laurentii
saplings 55.6 18.5 178.0
poles 25.3 15.3 86.0
trees 10.0 8.0 39.0
large trees 4.7 11.0 11.0
a

2
Data collected from 24 625m plots in each forest type.

size classes:

saplings. stems > 2.5cm dbh g 10 cm dbh:
poles. stems > 10 cm dbh 5 25 cm dbh:
trees. stems > 25 cm dbh 5,50 cm dbh:
large trees. stems > 50 cm dbh.

145

in mortality distant
from parents

The work of Rankin (1978) set a precedent for studying
the "escape hypothesis" in single-species-dominant tropical forest. In
the mora forests of Trinidad she substantiated prediction 2 for the
dominant Abra excelsa. There was low predation on seeds and a high
level of seedling establishment under parents in the single species
dominant forest. Due to the high density of Mhexcelsa adults it
was impossible to experimentally remove seeds to greater and greater
distances from the parent in mora forest and simultaneously be moving
them farther from adult conspecifics. For this reason experimental
seed-predation plots were either located under adult conspecifics or
removed to an alternate forest type. The same experimental procedure
was used in the Ituri Forest study because of the high density of G.
dewevrei in mbau forest.

There is an additional reason for this design in the Ituri
Forest. All three caesalpiniaceous species produce mast seed crops.
That is, they fruit synchronously, flooding the environment temporarily
with a single species' seeds. The seeding periods of the three species
themselves do not overlap. It was possible, therefore, to test
predation on seeds at low overall seed density in the environment and
distant from adult conspecifics by removing the seeds to the alternate
forest type: C. alexandri and B. laurentii seeds were removed
to the mbau forest and G. dewevrei seeds were removed to mixed
forest.

The mast fruiting pattern itself suggests a third hypothesis

146

related to the "escape hypothesis". It has been suggested that where
there is a high density of a given tree species, and relatively low
populations of potential seed predators, the tree species can escape
decimation of its seed crop by mast fruiting (Janzen 1974, 1976:
Boucher 1981). Predator satiation can occur in such a situation long
before the seed resource has been destroyed. Such community-level
predator satiation requires that the density of seeds be high over a
large area. Seeds removed from the high density area would,
presumably. be destroyed. Patterns of predation revealed by
seed-transplants allow an evaluation of this mechanism for juvenile
survival under adult 6. dewevrei. A third prediction generated

from this hypothesis is outlined as follows:

PREDICTIONS
HYPOTHESIS MIXED FOREST MBAU FOREST
3. predator heavy predation on low percentage of
satiation G. dewevrei seeds 6. dewevrei seeds
when artificially destroyed by
introduced into predation in mast
environment devoid fruiting area

G.dewevrei seeds

METHODS

The predictions from the regeneration-niche hypothesis are
less specific than predictions from the second and third hypotheses and

are not amenable to direct experimental testing. Instead, systematic

147
observations were made on the following aspects of the regeneration
niche: flowering and fruiting phenology, pollination and seed
dispersal. The species observed were Gilbertiodendron dewevrei
(mbau forest). Brachystegia laurentii (mixed forest), and
cynometra alexandri (mixed forest). Predictions from the predation
and predator-satiation hypotheses were tested with a series of
seed-transplant experiments carried out over two years. Seed-predators
were identified and populations of one important predator group
(rodents) were assessed. Survivorship of newly germinated seedlings

was monitored.

Flowering and fruiting phenology

Canopy level trees of G. dewevrei and B. laurentii
were monitored. The nearest canopy tree of a given species at every 10
m interval along a transect was permanently marked for a total of 65
B. laurentii in mixed forest and 62 G. dewevrei in mbau forest
(P in Figure 2), although one marked 6. dewevrei was not refound in
1982 and 1983.

The method used for assessing flowering level was similar to
that used by Gerard (1960). Ground counts of floral bracts reflect
flower density because floral bracts fall regardless of whether or not
pollination occurs and, being very coriaceous, they persist on the
forest floor for more than a month. At the end of the flowering period
all fallen floral bracts were counted within a 1 m2 plot two paces

from the base of each tree in an easterly direction. The direction was

adjusted to be under the tree crown in the case of B. laurentii

148

which frequently had asymmetrical and noncontiguous crowns.

At the end of the fruiting period, an estimate of fruits
matured was made by counting all seeds and new seedlings within a
radius of 2 1/2 meters of each marked tree. The number of propagules
present may have been greatly reduced through predation: therefore. a
count was also made of the empty pods on the ground. Pods fall soon
after dehiscence and the size and depression marks indicate whether or

not seeds matured. All evidence of seed predation was noted.

Pollination studies.

Pollination experiments were aimed at determining whether or
not xenogamy (out-crossing) was essential or if geitonogamous
pollinations (between flowers on a single tree) could result in
successful fertilization. These manipulations were accomplished only
on one species, 6. dewevrei. This species was the easiest to work
with because. being the most abundant. it had the greatest number of
accessible crowns. It also had the largest flowers of all three
caesalpiniaceous species. A technique that yielded satisfactory
results involved bagging all experimental flowers prior to anthesis.
Fine cotton weave facing-material was used for the bags. Tanglefoot
was generously applied to the stem to discourage ants from making
holes in the bags. Stamens of all flowers to be out-crossed were
clipped, but only after anthesis. It was clear, by inspection, that a
single flower, at least when bagged, did not deposit pollen on its own
stigma. All manipulations were made soon after dawn, the apparent time

of anthesis. Ten infloresences were bagged on three trees.

149

Observations were made of flower visitors at G. dewevrei crowns

convenient for observation.

Seed Dispersal.

The three main caesalpiniaceous species have ballistic seed
dispersal with no special adaptations for dispersal by animals.
Dispersal distance is largely determined by the force of propulsion
from the dehiscing pod. the mass of the seed, and interference in the
canopy. The distribution of seedlings around isolated mature
individuals is a good reflection of seed-dispersal distance. By using
isolated trees, interference from other canopy-level trees was
avoided. Four B. laurentii trees and four 6. dewevrei trees
were located which had been left standing when garden plots were
cleared around them. At the time of the study they had been isolated
in forest regrowth vegetation for 16 to 18 years. The radius of each
crown was measured as was the distance of all seedlings in a 4 m wide

unidirectional belt transect from the base of each trunk.

Seed-transplants.

Each of the caesalpiniaceous species has a separate fruiting
season and, therefore, predation experiments were necessarily done with
one seed species at a time: in 1981, C. alexandri followed by G.
dewevrei and in 1982, G. dewevrei followed by B. laurentii.

The methods used were modified as additional information was acquired
and, in consequence. the experimental designs were varied for each of

the four seed transplant periods (Table 3). In each case the design

150

 

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151
was factorial and the experimental units were 1 m2 plots. Seeds
were placed in them and subjected to various treatment modifications.
Seed disappearance. evidence of seed-predation, and germination were
recorded in each plot at one to two week intervals until at least two
weeks after full expansion of the eophylls of surviving seedlings.

The treatment which most directly applies to prediction 2
(treatment column A. Table 3) had two components: 1. natural seed
density on the forest floor and 2. distance from adult conspecifics.
at the location where an experimental plot was placed. In 1981, for
C. alexandri, these two components varied together: plots were
either in a mast-fruiting area where there were both C. alexandri
adults and seed-rain or they were in the other forest type (mbau) where
neither was present. That same year during 6. dewevrei seed fall.

a stand of mbau forest was found that was not in fruit and did not have
fruiting G. dewevrei near-by. This permitted partial testing of

the two components separately. Plots with G. dewevrei seeds could

be located under adult conspecifics where there was no background seed
fall.

In 1982, the two components were not tested separately.
but "intermediate sites" were added. The intermediate site for
G. dewevrei seeds was mixed forest where it bordered on
mast-fruiting mbau forest. In most areas these borders were quite
abrupt. For B. laurentii, the intermediate site was an island of
mbau forest (less than 1 kmz) which was surrounded by mixed forest
with mast-fruiting B. laurentii trees. Thus. in both cases, plots

in the intermediate site were in a no-seed area where. nevertheless,

152

adult conspecifics and seeds were present in large numbers at less than
a 200 meter distance. The site with high conspecific seed density and
proximity to parents was, for G. dewevrei, mbau forest where G.
dewevrei was mast-fruiting and, for B. laurentii, mixed forest

where B. laurentii was mast-fruiting. The opposite conditions for

each were in the alternate forest type.

As an attempt to identify the effect of seed-predators, plots
were placed in exclosures (treatment column B, Table 3). In 1981 the
only prior information on predators came from an analysis of forest
antelopes' rumens (J. Hart, 1985). The antelope ate seeds of all
three caesalpiniaceous species. Meter-high wattle fences were erected
around those plots which were to have antelope excluded. The 1981
observations revealed that rodents were significant predators as well.
Enough 5 mm wire mesh was acquired to make 10 all-mammal exclosures for
the 1982 seed-transplant plots.

Although soils were similar in mixed and mbau forests there
remained a possibility that other site factors, rather than or in
addition to differential seed predation. could affect seed and seedling
survival in mast and no-mast sites. Most obvious were differences in
leaf litter. When seeds of mixed forest species were removed to mbau
forest in order to remove them from conspecific seeds and adults, an
additional treatment effect was a change in litter type. In mbau forest
the litter is composed of large coriaceous G. dewevrei leaflets.
Leaf-litter in mixed forest is more heterogeneous and generally
composed of smaller leaves and leaf-parts. In 1981 an added factor in

the design of C. alexandri seed-transplants was litter removal

153

(treatment column C, Table 3). By the fortuitous finding of a
non-fruiting mbau stand during 6. dewevrei seed fall in 1981, all
site factors, not just litter, could be controlled for G. dewevrei
seed-transplants by having two no-mast sites, one under non-fruiting
conspecific adults and one in mixed forest. A site factor was not
included in the 1982 designs.

Seed plots were set out one to two weeks before peak seed fall
for each species. The number of seeds placed in each plot varied with
the species and from year to year (last column, Table 3).

Brachystegia laurentii and C. alexandri have smaller seeds than

6. dewevrei (Table 4) and, therefore, more of them were required

per plot to approximate a comparable "reward" for a seed predator. It
is estimated that the 1982 seed plots represent. over the 1 m2
area, a seed density two to three times greater than would be expected
under the canopy of a heavily fruiting tree at peak seed fall.

The actual field design varied with each seed-transplant
experiment (Table 3). In 1981, the C. alexandri seed plots were
set up as two grids of 28 plots each, one grid in mixed forest (mast)
and one grid in mbau forest (no-mast). Plots were 3 m apart. Within
each grid the four possible combinations of treatments were randomly
assigned.

A short-coming of the grid design was that all plots were
concentrated in a single area of each forest type. Predators could be
concentrated in a given area due to some factor other than seed fall.
This problem was alleviated for G. dewevrei seed-transplants in

1981 by locating paired seed-plots along transects, each plot-pair 15 m

154

Table 4. Seed characteristics of the three dominant caesalpiniaceous
tree species of the Ituri Forest. Zaire.

 

 

seed

wet dry

 

a b
Species diameter weight weight
Cilbertiodendron dewevrei 5.5 cm 30.4 gm 18.2 gm
(SD=4.11) (SD=2.15)
Brachystegia laurentii 2.5 cm 3.5 gm 2.8 gm
(SD=0.13) (SD=0.13)
cynometra alexandri 2.5 cm 2.0 gm not
($080.08) recorded

 

The approximate shape of all three species is a flattened disc:
the measurement was of the longest dimension.

Both wet and dry wieghts were calculated as the means from five
lots of ten seeds each for 6. dewevrei and C. alexandri.

and from three lots of 50 seeds for B. laurentii.

155

apart last, for a total of ten pairs in each of three environments.

The three environments were mast-fruiting mbau forest (heavy
seed-fall), no-mast mbau forest (no seed fall), and mixed forest (no
seed-fall). Within each environment the paired treatments were antelope
exclosure versus no exclosure.

Plots were spread out over an even larger area in each forest
type in 1982. For 6. dewevrei seed-transplants there were five
transects, with five unenclosed plots 15 m apart per transect in the
mast environment (mbau forest). There were two transects each in the
no-mast and intermediate environments (mixed forest), with five plots
per transect. The mast and no-mast environments both had five
additional all-mammal exclosure plots. Plots were laid out in a
similar manner along transects for B. laurentii seed-transplants.

There were 25 plots in three transects in the no-mast environment (mbau
forest) and an additional two all-mammal exclosure plots. There were
ten plots in two transects, for both the intermediate environment (mbau
forest island) and the mast environment (mixed forest). An additional
three plots in the intermediate site and five plots in the mast site
were covered by all-mammal exclosures.

The number of G. dewevrei seeds falling to the mbau forest
floor near plots was monitored in 1981 and 1982. In 1981 all naturally
fallen seeds were counted in a third 1 m2 plot between each set of
paired plots. Additional seeds falling into the plot were recorded.

In 1982, before seeds were placed into the test plots, the natural
background seedfall was estimated from five 1 m2 seed counts near

each plot location.

156

Seed-predators.

For trapping purposes, in 1982 one hundred piles of G.
dewevrei seeds and 43 piles of B. laurentii seeds were set out in
a variety of habitats. As soon as seeds disappeared from a pile or
other evidence of predation was seen. a snap trap baited with the test
seed species was set by the pile. More seeds were added to the piles
as seeds disappeared.h Traps were checked daily for approximately three
weeks.

Four species of forest antelope were in captivity at the Epulu
base camp, Cephalophus dorsalis, C. monticola, C. leucogaster, and
C. nigrifrons. All four species were offered B. laurentii and
G. dewevrei seeds so that their handling of the seeds could be
observed.

Small rodent populations in mixed and mbau forest were sampled
with peanut-baited snap traps in order to determine if rodent
communities in the two forest types had similar of species composition
and density and if there was an increase in rodent density in either
forest type during the fruiting season of the dominant trees. This was
done by means of two replicate grids of snap traps (36 traps, 5 paces
apart, 6 rows of 6 traps each) checked daily. The environments thus
sampled were:

A. mbau forest just after G.dewevrei seed fall Nov.3-15, 1982
B. mbau forest when there are no G.dewevrei March 19-30, 1983
seeds falling or on ground
. mixed forest at end of B.laurentii seed fall Jan.18-27, 1983

. mixed forest when there are no B.laurentii Apr.6-15, 1983
seeds falling or on ground

DO

157

Seedling'survivorship.

Seedling survivorship of G. dewevrei and B. laurentii
was studied in three ways: 1. estimation of the density of surviving
seedlings from the 1982 seed crops, 2. calculation of the total
understory seedling density, and 3. measurement over two years of
survivorship and growth of suppressed seedlings of unknown age.
Methods were as follows.

1. In January 1983. about three months after the end of
seed-fall, all newly germinated G. dewevrei seedlings were counted
in six 50 m x 6 m plots. The plots were in areas of mbau forest where
no rodent trapping had been undertaken. No census of B. laurentii
survival from the 1982 seed crop was made; however, a sample was made
of B. laurentii survival from the 1980 seed crop. All new
seedlings were counted in eight 3m x 2m mixed forest plots. These
plots included those set up to study suppressed seedlings (described
below under 3.).

2. The density of all seedlings of G. dewevrei, B.
laurentii and C. alexandri less than 0.5 m in height was recorded
by complete seedling counts in 24 randomly located 6.25 m2 plots
in mixed and mbau forest (12 plots in each forest type). Seedlings
>0.5 m in height but <2.5cm dbh were similarly measured in 25 m2
plots (12 in each forest type). Larger size classes were measured in
225 m2 plots (stems < 10 cm dbh) or in 625 m2 plots (stems >

10 cm dbh). There were 24 plots of the two larger plot sizes in each

forest type (see chapter one).

158

3. In order to monitor growth and mortality of shade tolerant
seedlings on the forest floor, all seedlings of G. dewevrei and
B. laurentii in seven 3 m x 2 m plots were marked with aluminum
tags in 1981: all leaves and leaf scars were counted. The plots were
at 10 m intervals along a transect which ran from mbau forest into
mixed forest. The seedlings were checked at least twice each year.
Height increment and new leaves were recorded for surviving seedlings.
New seedlings were marked, their height measured, and leaf number

recorded.

RESULTS

Phenology.

Flowering of G. dewevrei and B. laurentii is irregular
from year to year. Also, trees may flower but fail to produce mature
fruit (Table 5). With all mbau forest sites considered together, 1981
and 1982 were mediocre flowering and fruiting years for 6. dewevrei
relative to 1983 when all marked trees produced a dense carpet of
floral bracts. The two years during which data were collected for B.
laurentii were markedly different. The first. 1981, was low for both
flowers and fruits, whereas 1982 was an improved flowering year and a
very successful fruiting year.

The censusing technique did not permit comparisons of

reproductive effort between G. dewevrei and B. laurentii

159

Table 5. Percent of marked Brachystegia laurentii and Cilbertiodendron
dewevrei producing flowers and fruits. 1981 - 1983.

 

 

 

 

b b
flowering level fruiting level
a
species year none low high none low high
Brachystegia 1981 47 31 22 89 11 O
laurentii
1982 18 25 57 1 14 85c
1981 21 31 49 41 48 ll
Gilbertiodendron
dewevrei 1982 5 48 47 36 39 25
1983 O 0 100
a

n = 65 B. laurentii trees and n - 62 G. dewevrei trees (1982
and 1983. only 61 G. dewevrei trees).

flowering level:

none - no floral bracts in sample:
low 2 >0 <50 floral bracts per m2:
high . 250 floral bracts per m2.

fruiting level:

none - no seeds or mature pods under crown:

low - 1-15 mature pod valves and/or 1-15 seeds under crown:
high . >15 seeds under crown.

This high percentage is probably an artifact of seed dispersal from
adjacent trees.

160

because species differences in crown structure affect the density of
fallen floral bracts and dispersal differences affect the density of
fallen seeds. Nevertheless, the data do allow within-species
comparisons. Trees in any given area tend to be synchronous with
respect to their reproductive state. Defining a stand as synchronous
where 3/4 or more of the marked trees were either reproductive (>50
flowers per m2) or non-reproductive (including low reproductive
effort, <50 flowers per m2), it was found that collectively, over
three years, there were 24 synchronous and five asynchronous stands
(Table 6). The synchrony was most pronounced for 6. dewevrei.
Individuals that flowered out of synchrony with the rest of
the stand had low reproductive success. Flowering trees were
considered to be isolated (asynchronous) when 3/4 or more of the other
marked trees in the stand did not flower. In all there were nine
asynchronous B. laurentii trees (out of 65 trees observed over two
years) and two asynchronous 6. dewevrei trees (out of 62 trees
observed over three years). Four of these individuals showed no signs
of successful pollination (one 6. dewevrei and three B.
laurentii). Aborted pods were found under eight others (two 6.
dewevrei and six B. laurentii) and only three had fallen pods
with the marks of mature seeds (one 6.dewevrei and two B.
laurentii). Of these latter only one still had a surviving seed
under it (6. dewevrei). This low reproductive success may have
been due to reduced pollination in asynchronous trees and/or to
increased pre- and post-dispersal predation.

Supra-annual flowering schedules may indicate that an

161

 

 

 

 

Table 6. Synchrony of flowering between trees within stands.
number of number of
a a
Species stands years synchronous asynchronous

Brachystegia

laurentii 4 2 5 3
Gilbertiodendron

dewevrei 7 3 19 2

a

Synchronous stands were sampling sites in which 75% or more of
the marked trees were either reproductive or non-reproductive.

If less than 75% were of the same reproductive state the stand
asynchronous.

162

individual tree lacks the energetic resources for two consecutive years
of reproductive effort. A chi-square test for two independent samples
was used to test the null hypothesis that the flowering status of a
tree in a given year is independent of its previous year's flowering
record. The null hypothesis cannot be rejected for B. laurentii
(Table 7a). The second year, 1982, was an overall "good" flowering
year. Even trees that flowered in 1981 apparently were not
significantly less likely to flower in 1982 than those which did not
flower in 1981.

In the case of G. dewevrei the null hypothesis is rejected
(Table 7b). If a tree does not flower in year one it is more likely to
flower in year two than an individual that flowered in year one. It
is noteworthy, however, that 1983 was a uniformly high flowering year
and all trees observed had a dense carpet of flowers and bracts beneath
the canopy no matter what the previous year's flowering record had
been. Conceivably there are very poor years for reproduction as well.

when no trees flower regardless of the previous year's record.

Pollination experiments.

The only experimental flowers whose ovaries developed were
those that had had xenogamous pollen transfers (Table 8). Considering
that fresh pollen was always abundant and close at hand for
geitonogamous transfers but scarce for out-crossing, these results are
strong evidence that xenogamy is essential to fertilization in G.
dewevrei.

The most common morning flower-visitors in G. dewevrei

163

Table 7. Reproductive status of individual trees on consecutive
a
years.

 

 

a. Brachystegia laurentii

 

b
flowering level. flowering level. year 1
year 2
O-low high
O-low 20 8
high 31 6

2
X = 1.49, NS

 

b. Gilbertiodendron dewevrei

 

flowering level, flowering level, year 1
year 2
O-low high
O-low 10 22
high 51 39
2

X = 6.1. P<.05

 

Analysis was by a chi square test for two independent samples.
P>.05 is not significant (NS).

Flowering level was high at 350 pairs of fallen floral
bracts per m , and 0-low at <50 pairs of a fallen floral
bracts per m .

 

164

Table 8. Record of ovary maturation subsequent to hand
pollination of Gilbertiodendron dewevrei, 1982

 

 

 

ovaries ovaries
pollinated matured
cross pollinations 35 12

geitonagamous crosses 20 0

 

165

crowns were sunbirds. The olive sunbird, Cyanomitra olivacea. and
the violet-tailed sunbird, Anthreptes aurantium, frequented the
trees observed. The honeybee, Apis mellifera, was not attracted to
G. dewevrei flowers, the only showy part being a single deep red
standard petal which often dropped coincident with sunbird visitation.
The relatively large space (1-2 cm) between anthers and stigma makes it
unlikely that honeybees or other small insects could effect
pollination.

Pollination experiments were not possible for the other two
caesalpiniaceous species but both B. laurentii and C. alexandri
infloresences were intensely visited by honeybees. The flowers are

smaller and more compact, making pollination by insects likely.

Seed Dispersal.

Considering that both B. laurentii and G. dewevrei are
self-dispersed by the explosive force of the dehiscing legume, it is
not surprising that the lighter seeds (Table 4) of B. laurentii
generally land farther from the parent tree. .Of the four
reproductively mature and isolated G. dewevrei individuals
examined. the farthest dispersed propagules, as evidenced by surviving
seedlings, were six meters beyond the edge of the crown. The mean
maximum dispersal beyond crown edge for the four trees was 3.25 m
(SD=2.5). Of the four B. laurentii individuals whose seedling
shadows were measured, the greatest dispersal distance beyond the edge
of the crown was 39 m and the mean maximum distance was 33.25 m

(SD=6.898). The dispersal distance of B. laurentii propagules was

166

significantly greater than that of G. dewevrei (Student's t
test, P<.001). It appears that cypometra alexandri seeds disperse
even farther. Despite efforts to find adequately isolated C.
alexandri trees in secondary forest, the seedling shadow of any one
tree overlapped with the seedling shadow of another. This was in spite
of the fact that the trees were 100 m or more distant from each
other.
Seed-Transplants.

Mortality due to predation was greatest prior to and just
subsequent to germination. Seeds that germinated and successfully
reached the stage of having at least one normally-expanded seedling
leaflet were counted as having survived the seed stage. All three
caesalpiniaceous species have epigeal seedlings with exposed spreading
storage cotyledons. Freshly fallen seeds sown in plots begin to
germinate in four days or less. At this point the radicle has emerged
from the seed coat. One to two weeks after the emergence of the
radicle. the hypocotyl lengthens in undamaged seeds and the cotyledons
are lifted off the ground. During the elongation of the hypocotyl, the
seeds appear to have the same range of predators as prior to
germination. Destructive predation can still be heavy at this time and
continue right up to the extension and expansion of the eophylls. The
cotyledons are not caducous and remain attached to seedlings after
expansion of seedling leaves unless removed by predators or knocked
off. Presumably loss of cotyledons is less disastrous at this point.
After expansion of eophylls, which occurs several days after the

extension of the hypocotyl, seedlings become considerably less

167

vulnerable to predators although new seedling leaves of all three
species were nipped to some extent.

There were three visible types of predator damage on all three
species at seed-transplant piles. These were identified with rodents,
ungulates (duikers), and insects.

1. Rodent damage. Tooth marks were visible on cotyledons.
Fine shavings from the gnawing of cotyledons were evident. In the case
of G. dewevrei, parts of seeds rather than whole seeds were missing
and only one to several seeds were gnawed overnight.

2. Duiker damage. Several to many seeds were missing during a
24 hour period, and usually only seed coats and radicles were left. If
cotyledon parts were left. they had broken edges but no tooth marks. In
the case of B. laurentii and C. alexandri many entire seeds
completely disappeared overnight. Furthermore, duiker tracks were
often found in conjunction with this type of damage. These criteria
are consistent with the remains found in the captive-duiker pens after
feeding trials.

Rodent and duiker damage were readily distinguished in the
field in the case of G. dewevrei seeds; however, their damage to
the smaller seeds of B. laurentii and C. alexandri was more
confusing as even rodents may have carried whole seeds away. Where
seeds were entirely missing from plots duiker and rodent damage could
be confounded. Shavings and partly eaten seeds were nevertheless often
left as evidence of rodent culpability. The reliability with which the
signs of these two groups of mammalian predators could be distinguished

at G. dewevrei piles is demonstrated by trapping results (Table

168

9). More rodents were caught at piles which had previously been
identified as showing "rodent-type" damage than at piles identified as
showing "large-mammal-type" damage (P<.001, chi square test for two
independent samples). This is in spite of the fact that damage to seed
piles would continue after the traps were in place.

3. Insect damage. This was best observed in the field in the
case of G. dewevrei seeds. Initially beetle damage appeared as
oviposition holes through the seed coat but as the infestation
progressed, piles of frass appeared on the outside of the seed. Heavily
infested seeds either did not germinate or there was no further growth
after the radicle protruded. Neither lifting of the hypocotyl nor leaf
expansion occurred. Less heavily infested seeds where only the
cotyledons were damaged but the rest of the embryo left unharmed could
successfully germinate but the resulting seedling was smaller with the
cotyledons shrunken, blotchy, and riddled. Gilbertiodendron
dewevrei and B. laurentii seeds showing oviposition holes were
kept in ventilated jars until beetles began to emerge. Two curculionid
species emerged from the G. dewevrei seeds. These were the same
beetles which were found to be active around seeds on the forest
floor. One bruchid species emerged from the B. laurentii seeds.

A number of other insects were found in or on seeds. Among
the largest were lepidopteran larvae and orthopterans. These insects
were relatively rare, and solitary. In the case of G. dewevrei
their damage was generally small relative to the size of the seed;
however, these external feeders could, conceivably, have entirely

consumed the smaller seeds of the mixed forest species.

169

Table 9. Type of seed damage and rodent-catch at piles of
Gilbertiodendron dewevrei seeds where associated
traps were baited with G.dewevrei seeds.

 

 

 

type of total piles where piles where total number

damage number no rodent rodent(s) of rodents

recorded of piles was caught were caught caught
rodent 20 6 14 26
large mammal 13 12 1 3
unknown 10 9 1 1
rodent and 6 3 3 3

large mammal

 

170

Mortality due to fungal attack was rare, but was likely the
cause of some seed loss in one C. alexandri seed plot and two B.
laurentii seed plots. No mortality having fungal pathogens as a
primary cause was noted for G. dewevrei in either 1981 or 1982.
Gerard (1960), on the other hand, reported thick mycelial proliferation
over some 6. dewevrei seeds in mbau forest 400 km northwest of

Epulu.

Seed-transplant experiments.

cynometra alexandri (1981). After ten days 50% or more of
the total mortality recorded at seven weeks had already occurred. The
early mortality occurred during the seed stage or after the emergence
of the radicle and appeared to have been caused mainly by rodents and
ungulates.

Survivorship to the seedling stage, seven weeks after the
seeds were sown into the plots, was analyzed with a three-way factorial
analysis of variance (Table 10 a 8 b). Clearly the most important main
effect was forest type, with more than 40 percentage points difference
in seed survival between the two environments (Table 10a). There was
much higher survival for the seeds in mixed forest where there was
already a background of C. alexandri seed-fall than for seeds
placed in mbau forest where C. alexandri seeds and adults were
absent.

Greater survival occurred inside the exclosures where duikers
were excluded. There also was a significant interaction between forest

type and litter (i.e. A x C, Table 10b). This results from the

171

Table 10. Survival of cynometra alexandri seeds and seedlings in
seed-transplant plots. seven weeks after seeds were
set out (1981).

 

 

a. Percent survival of C. alexandri seeds and seedlings. Each value
is the mean from seven replicate plots. the standard deviation
is in parentheses.

 

 

 

 

Treatment : A C B
enclosed open
mixed forest litter 54.3 (13.0) 45.7 (9.6)
(mast) no litter 56.1 (11.1) 53.1 (7.8)
mbau forest litter 8.6 (10.2) 1.9 (2.1)
(no mast) no litter 3.7 (2.8) 2.1 (2.7)
b. Three-way ANOVA table. P<.05 is not significant (NS).
source of variation df SS F
A. forest type 1 32.593 3227 P<.001
B. antelope exclosure 1 345 34 P<.001
C. litter 1 19 1.8 NS
A x B 1 9 <1 NS
A x C 1 168 16.6 P<.01
B x C 1 101 10 P<.05
A x B x C 1 3409 337.6 P<.001

Error within subgroups 48 487

 

172

increased survivorship in mbau forest but decreased survivorship in
mixed forest under the conditions of litter being present. One
possibility is that the large dark mbau leaflets tended to camouflage
or actually cover the seeds. The significance of the two-way
interaction (A x B x C, Table 10b) might be related to the fact that
the effect of the mbau forest litter varied according to the predator.
Inside exclosures, where the main predators were rodents, litter was
associated with lower seed mortality; however, outside exclosures where
the duikers, as well as rodents, were predators, the litter effect was
absent. Relative to the main effects, litter had a minor impact on
predation levels.

Brachystegia laurentii (1982). Considering only the open
plots, mortality of B. laurentii seeds was found to be
significantly different in the three environments tested (P<.001,
Kruskal Wallis test, Table 11). The highest survival occurred in the
intermediate site where 64.2% of the seeds produced viable seedlings.
Rodent activity was lower in the intermediate site than in the mast
site as evidenced by lower rodent catches from the seed-piles where
traps were put out. In 97 trap days in mixed forest (mast area) during
B. laurentii seed-fall, four rodents were caught in snap traps
baited with B. laurentii seeds. Despite more than twice as many
trap days (226) in the small island of mbau forest, still only four
rodents were caught.

Omitting the intermediate site. a chi-square test for two
independent samples showed that there was significantly greater

survival of B. laurentii seeds in the mast area than in the no-mast

173

Table 11. Survival of Brachystegia laurentii seeds and seedlings
in seed-transplant plots, seven weeks after seeds

were set out (1982).

 

 

a. Mean number of B.laurentii seeds surviving to seven-week seedling

stage. Standard deviation in parentheses.

The number of

seed-transplant plots is reported as n - x and the original number

of seeds per plot was fifty.

 

Treatment : A
enclosed open
mean mean %
mixed forest 29.6 23.6 47.2
(mast) (15.1) (10.0)
n = 5 2 sites. n = 10
mbau forest 41.3 32.1 64.2
near mast area (4.0) (11.2)
(intermediate site) n = 3 2 sites. n - 10
mbau forest 37.5 3.1 6.2
distant from (10.6) (5.8)
mast area n = 2 3 sites. n = 25

 

b. Differences in seed and seedling survival according to treatment.
The null hypothesis is that there is no difference.

Treatment Significance level

Statistical test

 

A forest type P<.001
(open plots only)

A forest type P<.001
(intermediate site excluded)
(open plots only)

A x B exclosures in P<.01
both forest types
(intermediate site excluded)

Kruskal-Wallis

chi square test for
two independent
samples

chi square test for
two independent
samples

 

174

area (P<.001) with 47.2% survival in the former and only 6.2% survival
in the latter. As in the C. alexandri seed-transplants. the
exclosures had a positive impact on survival in all environments (Table
11). With B. laurentii, however, the impact of the exclosures was
much greater. All mammals were excluded from the screen exclosures
whereas the 1981 C; alexandri exclosures only excluded antelope.

Insects were the principal predators able to penetrate the
all-mammal exclosures. Mortality within these exclosures was.
therefore, a measure of the impact of insects. Comparison between mast
and no-mast areas shows significantly greater mortality due to insects
in the mast area with 40.8% mortality in the former and 25% in the
latter (P<.01, chi-square test for two independent samples).

In the absence of a direct measure, mortality due to mammals
can be estimated by subtracting the percent mortality under the
exclosure cages from the percent mortality in the open seed piles.

This gives 68.8% mortality due to mammals in the no-mast area as
opposed to only 12% in the mast area.

Gilbertiodendron dewevrei (1981). In 1981, seeds were
transplanted into mixed forest, no-mast mbau forest (non-fruiting), and
mast mbau forest. In the mast mbau forest, the natural density of seeds
on the ground was 11.2 seeds per m2 (s x=3.1) when seeds were
originally sown into plots. Accumulation of seeds in empty plots over
the next two weeks averaged one seed per m2 per week and dropped
to half that rate over the subsequent three weeks.

Seed predation was markedly different in the two mbau forest

175

sites. Very few seeds showed evidence of mammal damage in the mast
site. Of the original 30 seeds per plot, a mean of 28 (SD=1.97)
remained on the enclosed plots and 29 (SD=0.97) on the open plots. In
the no-mast mbau forest, on the other hand, ten days after the seeds
were placed, all but three of the 600 seeds had disappeared. In most
cases there were bits of seed coat and cotyledons with rodent
toothmarks left at the sites. Evidence of predation in the mixed
forest (no-mast) was similar to that in the non-fruiting mbau forest.
Ten days after sowing in mixed forest plots, the seeds at 11 of the
plots had disappeared and only scraps of seed remained.

The seed disappearance patterns were even more pronounced
after three and a half weeks (Table 12). No viable seeds or seedlings
remained in either of the no-mast environments. The majority of the
original seeds were still present on the plots in the mast environment
and there was no significant difference between the number left in the
enclosed as opposed to the open plots (Student's t test).

This apparent difference between mast and no-mast environments
was, however, spurious as regards actual seed survival. All C.
dewevrei seeds remaining in the mast forest were rotten and riddled
with beetle emergence holes. Any viable seeds would have long since
germinated. In fact none of the 1,800 seeds used in the 1981 G.
dewevrei seed transplant experiments produced a surviving seedling.

Gilbertiodendron dewevrei (1982). On open plots of the
1982 G. dewevrei seed transplants, mortality was very high in both
the mast (mbau forest) and the no-mast (mixed forest) areas. As with

B. laurentii seed-transplants, greatest survival occurred at an

176

Table 12. Survival of Gilbertiodendron dewevrei seeds and seedlings
in seed-transplant plots. three and a half weeks after
seeds were set out (1981).

 

 

a. Mean number of C.dewevrei seeds or seedlings remaining in plots.
For all values n - 10 plots and originally there were thirty
seeds sown into each plot. Standard deviation in parentheses.

 

Treatment : A B
enclosed open
total viable total viable
seeds seeds seeds seeds
mbau forest 26.6 0 27.9 0
(mast area) (3.0) (3.4)
mixed forest 0 0 0 0

(no-mast area)

mbau forest 0 0 O O
(no-mast area)

 

b. Differences in seed and seedling survival according to treatment.
The null hypothesis is that there is no difference.

 

treatment significance level statistical test
A. forest type not significant by inspection
B. antelope exclosure not significant by inspection
A x B exclosures in not significant by inspection

both forest types

Differences in actural number of seeds remaining in plots.
(i.e. not completely eaten or removed).

A. forest type highly significant by inspection

8. antelope exclosure not significant Student’s t test
(mast area only)

 

177
intermediate site where there was no seed-fall but where a
concentration of conspecific seeds and adults was nearby.

Due to variability in density of seed-fall in mbau forest, two
environments were recognized as separate treatments: 1. heavy
seed-fall (all plots in areas averaging > 1 seed per m2) and 2.
light seed-fall (many plots in areas averaging < 1 seed per m2).

The two treatments from the no-mast (mixed) forest were: 1. near 6.
dewevrei seed-fall (intermediate site) and 2. distant from
seed-fall. The null hypothesis that there is no difference in the
average number of seeds which survive the seed-stage in the four
environments is rejected (Table 13. P<.01, Kruskal Wallis test). As
with the B. laurentii seed-transplants, the treatment result that
deviated the most from the others is the intermediate site having the
highest survival rate of 33%.

When the intermediate site was removed from analysis and
survival was contrasted at the mast (light seed-fall) and no-mast
(distant) areas, no significant difference was found (Table 13,
Mann-Whitney U test). Despite the similarly severe seed/seedling
mortality, the causal agents were different in the two environments.
This was clear from the difference in survival under all-mammal
exclosures (Table 13). In the mixed forest (no-mast) where all mammals
were prevented access to the G. dewevrei seeds, there was high
survival (93%). There continued to be high mortality (13% survival),
in the mbau forest, even in the exclosures, due to insect predation.
Thus the null hypothesis of similar mortality under mammal-proof

exclosures in the two environments is rejected (P<.004, Mann-Whitney U

178

Table 13. Survival of Gilbertiodendron dewevrei seeds and seedlings
in seed-transplant plots. five weeks after seeds were
set out (1982).

 

 

a. Mean number of G.dewevrei seeds surviving to the five-week
seedling stage. Standard deviation in parentheses. The number
of seed-transplant plots is reported as n = x. and the original
number of seeds per plot was 30.

 

Treatment : A B
enclosed open
number % number %
heavy seed fall 0.2 1.3
(0.4)
mbau forest 1 site. n = 5
(mast area)
light seed fall 2.0 13 1.65 11
(2.3) (2.8)
n - 5 4 sites, n s 20
distant from mast 14.0 93 1.0 6.7
(1.7) (1.6)
mixed forest n . 5 2 sites. n = 10
adjacent to mast 5.0 33
(intermediate site) (3.5)

2 sites. n . 10

 

b. Differences in seed and seedling survival according to treatment.
The null hypothesis is that there is no difference.

Treatment Significance level Statistical test

 

A forest type P<.01 Kruskal-Wallis
(open plots only)

A forest type NS Mann-Whitney U-test
(intermediate site excluded)
(open plots only)

A x B exclosures in P<.01 chi square test for
both forest types two independent samples
(intermediate site excluded)

 

179

Test).

The large size of G. dewevrei seeds made it possible to
visually determine the cause of seed damage. For this reason data in
addition to the mammal exclosure results can be used in comparing
causes of mortality between the two principal environments. There was
a much larger sample size when observations made at the open seed piles
were included. The results were consistent with the exclosure results
(Table 14). The following hypotheses are rejected: 1. mortality due
to insect damage and 2. mortality due to mammal damage were the same
for seeds set out in the two environments, mbau forest with seed-fall.
and mixed forest without seed-fall (chi—square test for two independent
samples, P<.001 in both cases). Insect predation was intense in the
mast area whereas a much greater percentage of G. dewevrei seeds
succumbed to mammal predators when the seeds were placed far from mast

areas .

Trap-grids

The trap-grid data must be interpreted cautiously for a number
of reasons. One reason has to do with the experimental design itself.
Each day of an assessment period was meant to represent the same
trapping effort: 36 traps per grid with two grids in a single habitat
type. In actuality rain or falling twigs and seeds would often spring
traps during the 24 hours between checking periods. For graphing
purposes, trap nights were defined as the number of traps found still
set or with a caught rodent after a 24 hour period. When sprung traps

resulted in a trapping effort for a single night of less than 20 traps.

180

Table 14. Percent total seed mortality due to insects or mammals
at seed-transplant plots (Gilbertiodendron dewevrei, 1982).
Original seed number was 300 seeds in each forest type.

 

 

 

unaccounted
mammal insect for
mbau forest 3.4 95.0 1.6
(mast area)
mixed forest 97.0 0.7 2.3

(no-mast area)

 

181

that night's catch was combined with the subsequent night's results,
until twenty trap nights or more effort were achieved. This avoided
artificially low data points. Unfortunately there was no way to be
certain whether or not a trap was sprung immediately after being set or
just before being checked. This makes data from rainy periods, such as
the first days of trapping in no-mast mixed forest, difficult to
interpret.

Another reason for caution in interpretation of the data is
that the rodents may not have responded to the peanut bait in the same
way at different periods. When traps were put out during a mast period
they were presumably being put into a background of food abundance,
whereas during a no-mast period the peanuts may have been appearing in
an environment where there was a shortage of rodent food.

The two primary rodent species caught with peanuts on the trap
grids, Hylomyscus stella and Hybomys univittatus (Table 15).
were also the primary species caught at seed-piles using 6.
dewevrei and B. laurentii seeds as bait. They accounted for 28
out of 33 rodents caught in traps baited with G. dewevrei seeds and
six out of nine rodents caught in traps baited with B. laurentii
seeds. In fact all species caught in traps baited with
Caesalpiniaceous seeds were also caught with peanut bait. Therefore.
the relative rodent densities estimated by the trap grids are relevant
to seed predation of these two caesalpiniaceous tree species.

There were fewer species of rodents caught in mbau forest
during both mast and no-mast periods (three species and two species

respectively) than were caught in mixed forest (six species during both

182

Table 15. Rodents caught on trap grids during mast and no-mast

seasons in mbau and mixed forest. Peanuts used as
bait (1982 8 1983).

 

 

a. Rodent species caught in each forest type.
number of number of
environment trap nights species individuals

per species total

 

MBAU FOREST

 

 

Hylomyscus stella 23
mast period 605 Praomys jacksoni 3
Hybomys univittatus 1 27
no-mast period 640 H. stella 12
H. univittatus 2 14
MIXED FOREST
H. stella 15
H. univittatus 8
mast period 644 Deomys ferrugineus 5
P. jacksoni 3
Laphuromys luteogaster 1
Grammomys rutilans 1 33
H. stella 9
H. univittatus 8
no-mast period 411 P. jacksoni 6
D ferrugineus 4
Malacomys longipes 2
Malacomys verschureni 1 30
b. Number of rodents caught over first ten days of trapping
in each forest type. Standard deviation in parentheses.
fruiting ' forest type
condition mbau mixed
14 11
mast 11 (2.12) 22 (7.78)
5 16

no-mast 9 (2.83) 14 (1.40)

 

183

mast and no-mast. Table 15). This is consistent with expectations due
to the higher shrub and tree diversity and greater microhabitat
diversity of the mixed forest.

In order to compare rodent densities it was assumed that a
greater number of rodents caught on trap grids reflected a greater
density of rodents. The experimental design suggested use of a two-way
ANOVA to test the hypothesis that there was no differences in numbers
of rodents caught over ten days and nights in the four environments
(mixed forest vs. mbau forest and peak fruiting season vs. post
fruiting season, Table 15b). In actuality, due to the low replication
and the high variance for mixed forest during the peak fruiting season
(SD=7.78), a non-parametric test was considered more appropriate. A
chi-square test, however. failed to reveal any significant differences
between the environments with respect to the number of rodents caught.

If the mast periods are eliminated from consideration, a
comparison of the "normal" or no-mast rodent population in the two
forest types can be made. A Student's t test was used to test the
hypothesis that rodent catches were the same both in mixed forest and
mbau forest during the non-fruiting seasons of B. laurentii and
G. dewevrei. In this case the null hypothesis can be rejected, but
only if we accept a probability level of P<0.1. Rodents occur at lower
density in mbau forest.

Since snap traps were used. all rodents caught were killed.
It was expected that. without significant immigration, all the rodents
in the immediate area of a grid would be "trapped out". For this

reason it is interesting to examine a plot of rodents caught over time

184

(cumulative trap nights. Figure 3 ). The two curves which conform most
closely to the expected "trap out" pattern are those for the no-mast
periods in both mbau and mixed forest (Figure 3). In both cases there
was an initial decline in the number of rodents caught followed by a
low-level catch which never reached the original capture rate. By the
end of the trapping period, in both forest types (all four trap grids),
the catch was down to zero rodents per day.

In mbau forest. during the seed-fall of G. dewevrei, and
in mixed forest, during the seed-fall of B. laurentii, the pattern
was more erratic (Figure 3). In the mixed forest. the curve shows an
initial decline but there continue to be surprisingly high catches on
trap nights 5,6,7 and 10. In the mbau forest, even the initial decline
in rodent catch is absent. One grid had the highest catch on trap
night 5 and the other on trap night 8. In neither of the forest types,
and on only one grid in mixed forest, was the rodent catch on the final
trapping night zero. These patterns suggest that immigration of

rodents into the trapping areas did occur during mast periods.

Seedling'survival.
The understory surveys, made in mbau forest several months
after seed-fall, showed high overall seedling mortality for G.
dewevrei in 1982. The average density of surviving seedlings in
March 1983 was 0.02 seedlings per m2 (Table 16). This was only
1/40th the mean number of all small size G.dewevrei seedlings in
the understory (0.8 seedlings per m2 <0.5m in height). Slightly

larger seedlings were even denser (1.07 seedlings per m2, >0.5m in

185

Figure 3. Rodents caught on successive nights in snap traps in
mixed and mbau forests. Mean and range are from two

trap grids.

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Table 16. Density of seedlings in the forest understory.

 

 

 

Gilbertiodendron dewevrei Brachystegia laurentii
-2 , -2
density (m ) in mbau forest density (m ) in mixed forest
2nd year 2nd year
lst to <0.5m 30.5m lst to <0.5m 20.5m
year high <2.5m high year high <2.5m high
0.022 0.8 1.067 13.74 1.55 0.147
a
(0.022) (0.43) (0.86) (11.03) (1.2) (0.23)

 

Standard deviation in parentheses.

188

height <2.50m dbh. Table 16).

An estimate of B. laurentii seedling survival from a
single year's seed-fall shows an overall higher density than was
measured for G. dewevrei with 13.7 seedlings per m2 (Table
16). This was more than eight times the density of small size B.
laurentii seedlings in the understory when first year seedlings were
not included (1.55 seedlings per m2 < 0.5m in height). Slightly
larger seedlings were even sparser (0.147 seedlings per m2 > 0.5m
in height and < 2.5 cm dbh). Thus, 6. dewevrei and B.
laurentii exhibited opposite trends in density with increasing
seedling size (Table 16). Larger seedlings of G. dewevrei were the
densest seedling size class whereas larger seedlings of B.
laurentii were the sparsest seedling size class.

When progressively larger size classes were surveyed similar
trends were found (Figure 4). In mixed forest B. laurentii showed
a greater reduction in number of stems in the larger size classes than
did 6. dewevrei in mbau forest. Whereas B. laurentii
diminishes in importance in the largest size class (>50 cm dbh),
accounting for a smaller proportion of all species present, 6.
dewevrei accounts for a consistently larger and larger percent of all

stems in the increasingly larger size classes.

The two-year monitoring of seedlings was more productive for
G. dewevrei than for B. laurentii. By counting leaves and
leaf-scars, life-time leaf production could be reliably determined for

small seedlings of G. dewevrei which are stouter and more woody

189

Figure 4. The importance of Brachystegia laurentii in
mixed forest and of Gilbertiodendron dewevrei
in mbau forest for different size classes,
expressed as mean stem density and as mean

percent of all species.

(+35)

PER HECTARE

STEMS

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STEMS

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191

than B. laurentii. Brachystegia laurentii seedlings frequently

lost whole segments of stem, thus reducing the size of the living plant
being maintained in the understory and also erasing the record of leaf
emergence. G. dewevrei seedlings also maintain active meristems

low on the stem and frequently began a second axis of growth but
terminal portions were not lost.

A total of 124 G. dewevrei seedlings less than one meter
in height were monitored. Considering that G. dewevrei seedlings
are 0.3 to 0.35 m in height (to first node) immediately after
germination and full expansion, the observed seedlings had not, for the
most part, doubled their germination size (mean height at end of
observation = 54.7 cm; SD = 13.76). The marked seedlings were
considered to be the suppressed seedling bank which had survived
without any canopy opening.

Periodicity of leaf production was estimated so that
seedling's leaf + leaf scar number (= leaf index) could be converted
into an age estimate. These estimated indicated how long each seedling
had survived in the shaded understory. Although it would have been
preferable to have started with first year seedlings, observations of
new seedlings in the shaded understory (made in conjunction with seed
predation studies) revealed that leaf production during the first two
years of seedling life was no greater than during subsequent years.
During the first year, with few exceptions. two opposite eophylls were
produced; the vast majority of unreleased seedlings produced a single
additional leaf or no new leaves during the second year.

In two years 16% of the marked 6. dewevrei seedlings

192

died. Of the remaining seedlings, 10% produced no leaves, 45% produced
only one leaf and 22% produced two leaves. Only 6% produced more

than two leaves. The mean annual leaf production by the marked
understory seedlings was 0.63 leaves (SD=0.612, Table 17). The average
periodicity of leaf production. therefore, was 1.58 years between
leaves. There was no single season which corresponded to a leaf flush
in the understory.

The mean leaf index figure for all marked seedlings was 7.2
(SD=3.04). Multiplied by the periodicity of leaf production, this
converted to a mean age of 11.4 years for small, unreleased seedlings
of G. dewevrei in the mbau forest understory. Inspection of the
distribution of seedlings along a gradient of increasing leaf index
indicated a range in ages (Figure 5). There appeared to be three
peaks, possibly caused by the intermittent, supra-annual, nature of
mast seed production. When the plots were last monitored (April 1983)
the ground was covered by a thick fall of G. dewevrei flowers. If,
as the flower density suggests, 1983 was a successful year for seedling
production, the mean age of unreleased seedlings will have shifted

downwards in all plots.

DISCUSSION

Re-examination of the three hypotheses
1. The "regeneration niche" hypothesis was invoked to
predict that the dominant species, Gilbertiodendron dewevrei,

occurring at high density in the low-diversity forest, would have a

193

Table 17. Growth and survival of small Gilbertiodendron dewevrei
seedlings in the shaded forest understory. Originally
124 seedlings were marked and observed.

 

 

 

no new one new two new

leaves leaf leaves dead
Year 1 31 68 12 13
Year 2 64 37 3 7

mean annual leaf production per seedling = 0.63 leaves year
SD . 0.612

 

194

Figure 5. Leaf index (leaves and leaf scars) of Gilbertiodendron
dewevrei seedlings <1 m in height in the shaded forest

understory.

195

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broader regeneration niche than the related species, Brachystegia
laurentii and cynometra alexandri, which are found only at lower
densities in a species-rich tropical forest.

A number of previous studies have suggested that the
coexistence of tropical tree species may be possible through the
partitioning of establishment sites in gaps (Orians 1982) or between
gaps (Hartshorn 1980, Denslow 1980). As was clear from the seed
predation experiments and forest survey plots, all three
caesalpiniaceous species of the Ituri germinate and persist for several
years beneath unbroken forest canopy. They were found as advanced
regeneration in the vicinity of conspecific mature individuals. None
of the three caesalpiniaceous species has specialized to particular
sites for germination and early establishment but, rather, all utilize
the universally available shaded forest floor.

Other aspects of the "regeneration niche" were examined for
evidence of greater specialization by the mixed forest species.
Observations of reproductive phenology showed a tendency toward
synchrony in stands of both C. dewevrei and B. laurentii:
however, fewer G. dewevrei trees flowered asynchronously. C.
dewevrei was also more predictable in that if a tree failed to flower
one year it was more likely to be reproductive the next.

Comparative data for pollination systems are lacking: however,
it is doubtful that B: laurentii or Ch alexandri would have
more specialized syndromes than that of 6. dewevrei which is
obligately out-crossed and sunbird pollinated. and whose flowers last

only a single day. This is an interesting contrast to the expectation

197

Janzen had for mast-fruiting tropical tree species on poor soils
(1974). He predicted that the flowers should last more than one day
and be available to a wide variety of pollinator life forms.

All three caesalpiniaceous species have the same general
self-dispersal system. It is, however, most restricted in the case of
G. dewevrei. both in terms of the average distance from the parent
that a seed falls and, because of the greater weight of the seeds, the
likelihood for accidental dispersal by mammals.

In summary, for all aspects of regeneration considered, from
flowering to establishment, we failed to find any evidence suggesting
that G. dewevrei has a broader regeneration niche than related
species in species-rich tropical forest. On the contrary, G.
dewevrei has a more clearly defined and predictable flowering
pattern, a specialized pollination system, and relatively less flexible
seed dispersal possibilities.

2. The seed and seedling predation hypothesis can only be
evaluated from the data presented if the disappearance of seeds from
plots can be reliably interpreted. For statistical analysis
disappearance was treated as mortality. If a fraction of these missing
seeds had been removed and left to germinate the implications for the
parent tree would be very different. Large rodents are known to be
both seed predators and seed dispersers in South American tropical
forest (Smythe, 1978). Scatter-hoarding behavior is apparently common
among South American pacas and agoutis and often results in seed
dispersal.

The litter found at seed-transplant plots of all three

198

caesalpiniaceous species of this study suggested that rodents often ate
right at the site. For 6. dewevrei this was almost always the case
or else the seed was gnawed into smaller pieces to be carried away.
Probably only the largest rodent in the Ituri Forest, cricetomys
emini, could carry whole 6. dewevrei seeds in its mouth. We have

no direct observations of its eating 6. dewevrei seeds but it seems
likely that it would considering the diversity of other rodents using
6. dewevrei seeds as food. C. emini is not known to

scatter-hoard; however. it does carry seeds into its burrow to eat.
The chamber of these burrows is generally greater than a half meter
underground (pers. obs.). A G. dewevrei seed left uneaten in such

a chamber would dry out or rot.

The thin papery seed coat and rapid germination of all three
caesalpiniaceous species make them unsuitable for hoarding. None of
them have arils or edible fruit parts to entice removal of the seed
without damage to the embryo but, due to the smaller size of B.
laurentii and C. alexandri seeds, accidental dispersal by mammals
is more likely than with G. dewevrei. Occasionally a rodent may
transport a seed to a safer environment in which to eat but then, for
some reason, abandon the seed.

Larger mammals do not appear to be better seed dispersers than
rodents. The litter left by duikers feeding on the caesalpiniaceous
seeds indicated that the seeds were slightly chewed and then swallowed
into the rumen. This was, indeed, the behavior observed in the captive
duiker pens when seeds were provided. As in the case of rodent

predation, the seeds are destroyed. Dispersal is a very unlikely

199

outcome, especially dispersal more than a meter or two from where the
seed landed when catapaulted from the tree crown by the splitting pod.

In the case of G. dewevrei, the only likely agents of
accidental dispersal are the largest mammals. Humans eat and transport
G. dewevrei seeds. Hunter-gatherers and agriculturalists, however,
have probably only immigrated into the dense evergreen forest during
the past few centuries (Hart 8 Hart, in press). Their contribution to
dispersal is recent. Elephants also eat 6. dewevrei seeds. It may
be that they toss them or occasionally carry them significant
distances. Such dispersal events must be very rare and difficult to
quantify.

The interpretation of seed disappearance as seed mortality
seems justified. Any visitation of seed plots by elephants would have
left ample evidence. Removal of seeds by smaller mammals likely
entailed seed destruction.

The seed and seedling predation hypothesis suggests that
juveniles of G. dewevrei in the low-diversity forest would escape
heavy predation in the vicinity of the parent tree. whereas juveniles
of mixed forest species in the high-diversity forest would suffer
greater predation near parents than distant from parents. Seed
transplant experiments did not substantiate this pattern.

Mortality was similar for both mixed forest species, B.
laurentii and C; alexandri (summarized in Figure 6). On open
plots (no exclosure) the greatest mortality occurred in the no-mast
area distant from conspecific seeds and seedlings. Survival was

significantly improved near a concentration of conspecific seeds and

200

Figure 6. Percent survival of mixed and mbau forest species

as seeds or seedlings in mast and no-mast areas.

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201
adults. Gilbertiodendron dewevrei, the dominant species in the
single-dominant forest, sustained high levels of seed predation both
near and distant from fruiting conspecifics (Figure 6). Contrary to
expectations of the seed/seedling predation hypothesis, 6. dewevrei
suffered more, not less, seed-predation under parent trees whereas the
mixed forest species experienced less seed predation in the vicinity of
parent trees.

It was possible to determine that the main environmental
factor influencing predation on any single group of seeds set out was
the presence or absence of a mast seed crop in the area. Litter had a
negligible impact on seed predation in C. alexandri seed-
transplants. The type and severity of damage suffered by G.
dewevrei was similar in non-reproductive mbau forest with typical
mbau forest litter (1981) and in mixed forest with typical mixed forest
litter. The results from the no-mast mbau forest further indicate that
the presence of adult conspecifics was less critical than the overall
density of conspecific seeds in the environment. This is further
supported by the fact that asynchronously reproductive trees had poor
reproductive success.

During seed-fall in mbau forest the density of G. dewevrei
seeds is much greater and more even than the density of B.
laurentii or C. alexandri seeds in mixed forest during their
respective seasons of seed-fall. This is due to the greater synchrony
and dominance of G. dewevrei trees. It is surprising, in light of
the predation hypothesis, that seed-fall in mixed forest should have a

greater positive impact on survival of B. laurentii and C.

 

202

alexandri juveniles than the impact of mast seed-fall in mbau forest
on G. dewevrei juveniles.

3. The predator satiation hypothesis suggests that seeds
removed from an area of mast-fruiting conspecifics will suffer
increased predation. Community-level predator satiation would only be
expected for mast-fruiting species. But, as stated above. the predator
satiation prediction was not fulfilled for G. dewevrei, the species
with the most pronounced mast-fruiting syndrome. Seed-predation was
equally severe both within and distant from mast-areas. Predator
satiation was more effective in the case of B. laurentii and C.
alexandri. both of which occur at lower densities than 6.
dewevrei.

Seed survival in mammal exclosures and intermediate
seed-transplant plots offered some insight into the mechanisms
resulting in these predation patterns (Figure 7). In both cases the
exclosures produced the most dramatic increase in seed survival in the
no-mast areas. An additional 69% of B. laurentii seeds and 82% of
G. dewevrei seeds survived under exclosures in no-mast areas as
opposed to only an additional 12% and 4%. respectively. in mast areas.
This suggests that mammalian predators were responsible for a greater
proportion of the mortality occurring in no-mast areas than in mast
areas.

This corroborates observations that beetle seed predators were
most abundant in mast areas, and particularly in mbau forest. The
curculionid species which specialize on G. dewevrei seeds were,

alone, able to demolish most of the seeds in mast areas. It may be

203

Figure 7. Percent seed survival with and without mammal exclosures

in mast and no-mast areas.

204

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205

that if the experimental design had included a plot in mast areas which
excluded insects but not mammals, there would have been high seed
survival.

Mammalian predators may be satiated in the mast areas of all
three caesalpiniaceous species, leaving the vast majority of seeds
untouched. The survival of the remaining seeds, then, depends on the
density of insect predators or fungal pathogens. In our study fungal

pathogens were relatively unimportant and insect predators were
unevenly distributed. Species-specific insect predators were
concentrated in mast areas and, in both 1981 and 1982, those
specializing on G. dewevrei in mbau forest had, by far, the most
devastating effect on seed survival.

Results at intermediate area seed-transplant plots indicate
that mammals may have been migrating into mast areas even though their
proportionate impact on seed survival was much less in mast areas.
Intermediate seed-transplant plots were located in no-mast areas but
within 50-100 meters of a seed-fall area. Of all plots without
exclosures, the greatest seed survival occurred in intermediate areas
for both 6. dewevrei and B. laurentii. For B. laurentii
seeds, 17% more seeds survived in intermediate area plots than in mast
area plots and 58% more than in no-mast plots. For 6. dewevrei
seeds, 24% more survived in intermediate area plots than in mast area
plots and 22% more than in no-mast plots.

Both mammalian and insect predators were less common at the
intermediate plots. In the case of the species-specific insect

predators. the small anomalous piles of seeds may have been too distant

206

from the main concentration of seeds to be found. As for the scarcity
of mammals, the trap-grid results support the interpretation of their
absence as emigration from these areas into the adjacent mast areas.

Visual interpretation of the graphed results from the trap
grids (rodent catch over time) suggests that there was greater movement
of rodents during mast periods than no-mast periods. Although there
was a lower population of rodents in mbau forest than in mixed forest
during no-mast seasons, this was not the case during their respective
mast seasons. At the time of mast seed-fall, the numbers of rodents
caught showed no significant difference between mbau and mixed forest.

In summary. if the only predators threatening the seeds had
been mammals, there would have been dramatically improved survival of
seeds placed in mast areas due to predator satiation. Even though
mammalian seed predators migrated into seed-fall areas they had only a
small impact on the total crop of casealpiniaceous seeds. This
translated into greater seed survival for B. laurentii and C.
alexandri in mixed forest but not for G. dewevrei in mbau forest.

In the latter, the reduced predation pressure from mammals was more
than compensated for by concentrated populations of stenophagous beetle
seed predators.

Several paradoxes emerge from this discussion of the three
hypotheses. The mechanisms proposed to enhance either species
diversity or single species dominance were indeed discovered to be
operative in the Ituri Forest. but the diversity-promoting processes
were found in the least diverse community and the dominance-promoting

process was found in the community with the least dominance (Table 18).

207

Table 18. The predicted and actual Ituri Forest communities where effects
of three processes pertinent to species diversity were recorded.

 

 

 

a
Process Predicted effect Community with effect
predicted actual
specific seed-predators promote species mixed single-
cause massive mortality coexistence forest dominant

under parent trees

non-specific seed-
predators "switch" to
abundant species

community-level
predator satiation

(Janzen 1970.
Connell et al. 1984)

promote species
coexistence
(Connell et al. 1984)

maintain dominance
(Janzen 1974. 1976.
Boucher 1981)

mbau forest

mixed single-
forest dominant
mbau forest

single- mixed
dominant forest
mbau forest

 

Citations are to articles stating or supporting the prediction.

208

Specific seed predators cause massive seed mortality to G. dewevrei
seeds under 6. dewevrei adults. It has been suggested that such a
predation pattern would promote species co-existence (Janzen 1970,
Connell et a1. 1984); however, 6. dewevrei is strongly dominant in
mbau forest. Nonspecialized feeders feed heavily on the seeds of G.
dewevrei as the seeds become abundant. It appears. for instance,

that rodents migrate into mbau forest during the mast-fruiting season.
It has been proposed that prey "switching", by concentrating predation
on the most abundant species, would lead to species co-existence
(Connell et al. 1984). G. dewevrei, however. continues to

monopolize the canopy, co-existing only with species which are at very
low density. There is decreased predator-caused mortality on B.
laurentii and C. alexandri seeds in areas of mast seed-fall. It

has been suggested that such community-level predator satiation would
lead to dominance by the mast-fruiting species (Janzen 1974, 1976,
Boucher 1981). The mixed forest where predator-satiation apparently
occurs, however, is more species-rich than mbau forest where
predator-caused mortality to the seeds of the dominant is equally high
in mast and no-mast areas.

Although the hypothesized processes are real and occurring in
the Ituri Forest communities, they have not had a controlling influence
on the species diversity of adult trees. Based on the mortality
patterns during the early juvenile stages, a very different community
composition for mature individuals is predicted than actually occurs.
How is it that C. dewevrei can suffer such devastating seed

mortality and still make up 90% or more of the stems in the canopy

209

level size class? One possibility is that the mortality results from
the seed transplants under-represented overall 6. dewevrei seed and
seedling survival. Post-germination surveys, however. confirmed that
there was indeed extremely high mortality to seeds in the G.

dewevrei mast areas. Another possibility is that 1981 and 1982 were
anomalous or, at least, that there are occasionally years with
considerably higher survival of G. dewevrei seedlings. This

remains a possibility, but it is interesting that the apparent age
distribution of small seedlings in the understory ranges from first
year seedlings to seedlings of over 15 years in age. 6. dewevrei
seedlings, relative to B. laurentii seedlings are very persistent

in the shaded understory. appearing to accumulate from year to year.

The presence of G. dewevrei in all subcanopy size classes
suggests that it is able to take advantage of small canopy openings and
to withstand repeated canopy closure. Although B. laurentii is
present in all size classes in mixed forest, it does not have the
pattern of progressively greater importance, measured as percent of all
stems, which 6. dewevrei exhibits for increasingly large size
classes in mbau forest. This pattern in G. dewevrei may be
indicitive of slower growth and an ability to withstand protracted
shading in all sub-canopy size classes.

Gilbertiodendron dewevrei exhibits many characteristics of
the stress-tolerator syndrome as described by Grime (1979) and, when
contrasted with B. laurentii, it shows relatively more of these
characteristics in a more pronounced manner. Observations on small

suppressed seedlings in the understory showed longer leaf life and

210

slower growth for G. dewevrei as compared to B. laurentii. The
reason for such low confidence in determining the age of B.
laurentii seedlings was their more rapid leaf production and shedding
at several nodes simultaneously. According to Grime's schema,
morphogenetic responses to stress which are slow and small in magnitude
are typical of the "stress-tolerator" whereas the more rapid changes
(leaf-area, root-shoot ratio, etc.) are typical of the "competitor".
The stress which apparently gives 6. dewevrei its understory
advantage relative to other species, is inflicted by parent
individuals. the deep even canopy of contiguous G. dewevrei crowns
typical of mbau forest.

If this interpretation of G. dewevrei dominance is
correct, then this is a life history pattern which would not be
expected to be successful in chronically disturbed tropical forests
(cyclone belt, steep slopes). It would also be expected that after
major disturbance or climatic amelioration establishment of such a
single-dominant forest would be slow relative to a more diverse mixed
forest. The encroachment of this single-dominant forest is necessarily
slow due to the feeble dispersal of propagules and the lengthy
seed-to-canopy generation time. The mixed forest, on the other hand,
contains numerous animal dispersed species and even the
caesalpiniaceous species which dominate the canopy disperse farther
than 6: dewevrei. Many canopy- level species in mixed forest are
shade-tolerant as juveniles. suggesting that the species composition of
the mixed forest may be self-replacing over many generations. However.

transition zones between mixed forest and when forest may be dynamic,

211

with progressive shifts in species composition as 6. dewevrei
invades the mixed forest understory or disturbances make major changes
in the light environment of advanced regeneration.

The "regeneration niche" hypothesis was earlier rejected as a
useful paradigm in understanding diversity differences between mixed
and mbau forest. It was pointed out that related species in both
forest types have similar establishment requirements despite their
marked differences in dominance. This is true in that all three
caesalpiniaceous species germinate and persist for some time in the
shaded understory beneath parent trees. However, if a long term
perspective is taken, what may be a key difference between the mixed
and mbau forest species is quite consistent with the "regeneration
niche" hypothesis. Preliminary data suggests that G. dewevrei may
be able to tolerate shady subcanopy conditions considerably longer
than B. laurentii or C. alexandri. The mbau forest dominant
may be buffered against high seed mortality by the fact that any
seedling which survives the early predation threats has a substantially
better chance of persisting until a canopy gap provides light for
growth. The distinctive dimension of G. dewevrei's "regeneration
niche" is seen in the accumulation of aging seedlings and saplings in

a basically undisturbed forest understory.

212

LIST OF REFERENCES

Augspurger, C. K. 1983. Offspring recruitment around tropical trees
changes in cohort distance with time. Oikos 40:189-196.

Boucher, D. H. 1981. Seed predation by mammals and forest dominance
by Quercus oleoides. a tropical lowland oak.
Oecologia 49:409-414.

Clark, D. A., and D. B. Clark. 1984. Spacing dynamics of a tropical
rain forest tree: evaluation of the Janzen-Connell model. The
American Naturalist 124:769-788.

Connell, J. H. 1971. On the role of natural enemies in preventing
competitive exclusion in some marine animals and in rain
forest trees. Pages 298-312 in P. J. den Boer and G. R.
Gradwell, editors. Dynamics of Populations. Center for
Agricultural Publishing and Documentation. Wageningen, The
Netherlands.

Connell, J. H. 1978. Diversity in tropical rain forests and coral
reefs. Science 199:1302-1310.

Connell, J. H., J. G. Tracey, and L. J. Webb. 1984. Compensatory
recruitment, growth, and mortality as factors maintaining rain
forest tree diversity. Ecological Monographs 54:141-164.

Denslow, J. S. 1980. Gap partitioning among tropical rainforest
trees. Biotropica 12 supplement:47-55.

Eggeling, W. J. 1947. Observations on the ecology of the Budongo Rain
Forest, Uganda. Journal of Ecology 34:20-87.

Evrard. C., J. Berce. P. Jongen, and M. Van Oosten. 1960. Carte des
sols et de la végétation du Congo Belge et du Ruanda-Urundi:
Ubangi. Publication de l'Institut National pour l'Etude
Agronomique du Congo Belge (I.N.E.A.C). volume XI. Brussels.
Belgium.

Frankie, G. W. 1975. Tropical forest phenology and pollinator plant
co-evolution. in L. E. Gilbert and P. H. Raven, editors.
Coevolution of animals and plants. University of Texas Press.
Austin, Texas.

Frankie, G. W. 1976. Pollination of widely dispersed tropical trees
by animals in Central America, with an emphasis on bee
pollination. in Burley and Styles, editors. Varieties,
breeding and conservation of tropical forest trees. Academic
Press.

213

Gérard, P. 1960. Etude écologique de la forét dense
8 Gilbertiodendron dewevrei dans la région de
l'Uele. Publication I.N.E.A.C., série scientifique 87.
Brussels, Belgium.

Germain, R. and Evrard, C. 1956. Etude écologique

et phytosociologique
de la forét d Brachystegia laurentii. Publication
I.N.E.A.C., série scientifique 67. Brussels, Belgium.

Grubb, P. J. 1977. The maintenance of species richness in plant
communities importance of the regeneration niche. Biological
Review 52:107-145.

Guevara, S. S. and A. Gomez-Pompa. 1972. Seeds from surface soils in
a tropical region of Veracruz, Mexico. Journal of the Arnold
Arboretum. 53:312-335.

Hall. J. B. and M. D. Swaine. 1981. Distribution and ecology of
vascular plants in a tropical rain forest: forest vegetation
in Ghana. Dr W. Junk. Boston.

Hart, J. A. 1985. Comparative dietary ecology in a community of
African forest ungulates. Unpublished PhD dissertation
submitted to the department of Fisheries and Wildlife at
Michigan State University, East Lansing.

Hart, T. B. and J. A. Hart. in press. The ecological basis of hunter
gatherer subsistence in the African rain forest : the Mbuti of
eastern Zaire. Human Ecology.

Hartshorn, G. S. 1978. Treefalls and tropical forest dynamics. Pages
617-638 in P. B. Tomlinson and M. H. Zimmerman, editors.
Tropical trees as living systems. Cambridge University Press,
Cambridge.

Hartshorn, G. S. 1980. Neotropical forest dynamics. Biotropica 12
(supplement): 22-30.

Heithaus, B. R., P. A. Opler, and H. G. Baker. 1974. Bat activity and
pollination of Bauhinia pauletia: plant pollinator
co-evolution. Ecology 55:412-419.

Howe, H. F. and J. Smallwood. 1982. Ecology of seed dispersal. Annual
Review of Ecology and Systematics 13:201-228.

Hubbell, S. P. 1980. Seed predation and the coexistence of tree species
in tropical forests. Oikos 35:214-229.

Janzen, D. H. 1967. Synchronization of sexual reproduction of trees with
the dry season in Central America. Evolution 21: 620-637.

214

Janzen, D. H. 1970. Herbivores and the number of tree species in tropical
forests. American Naturalist 104:501-528.

Janzen, D. H. 1974. Tropical blackwater rivers, animals and mast fruiting
by the Dipterocarpaceae. Biotropica 6: 69-103.

Janzen. D. H. 1976. Why bamboos wait so long to flower. Annual Reviews
of Ecology and Systematics 7:347-391.

Janzen, D. H. 1980. Specificity of seed-attacking beetles in a Costa
Rican deciduous forest. Journal of Ecology. 68: 929-952.

Lebrun. J. and G. Gilbert. 1954. Une classification écologique des
foréts du Congo. Publication I.N.E.A.C., série scientifique
63. Brussels, Belgium.

Leigh, E. G. Jr. 1982. Why are there so many kinds of tropical trees?
in E. G. Leigh, A. S. Rand, and D. M. Windsor. editors.
Ecology of a tropical forest: seasonal rhythms and long-tern
changes. Smithsonian Institution Press, Washington D. C.

Louis, J. 1947. Contribution 8 l'étude des foréts équatoriales
congolaises. Comptes rendus de la semaine agricole de
Yangambi (February 26 - March 5, 1947). Publication
I.N.E.A.C. (hors série). Brussels, Belgium.

Hg, P. S. P. 1978. Strategies of establishment in Malayan forest
trees. in P. B. Tomlinson and M. H. Zimmerman, editors.
Tropical trees as living systems. Cambridge University Press.
Cambridge.

Orians, G. H. 192. The influence of tree-falls in tropical forests
on tree species richness. Tropical Ecology 23:255-279.

Pécrot,A. and IL Léonard. 1960. Carte de sols et de la végétation du
Congo Belge et du Ruanda-Urundi: dorsale du Kivu. Publication
I.N.E.A.C. volume Brussels, Belgium.

Pickett, S. T. A. 1983. Differential adaptation of tropical species
to canopy gaps and its role in community dynamics. Tropical
Ecology 24: 68-84.

Putz, F. E. 1983. Treefall pits and mounds, buried seeds and the
importance of soil disturbance to pioneer trees on Barro
Colorado Island, Panama. Ecology 64: 1069-1074.

Rankin, J. M. 1978. The influence of seed predation and plant
competition on tree species abundances in two adjacent
tropical rain forests. Dissertation. University of Michigan.
Ann Arbor.

Smythe, N. 1978. The natural history of the Central American agouti

215

(Dasyprocta punctata). Smithsonian Institution Press,
Washington D. C.

Stiles. F. G. 1975. Ecology, flowering phenology and hummingbird
pollination of some Costa Rican Heliconia species.
Ecology 56: 285-301.

Stiles. F. G. 1978. Temporal organization of flowering among
hummingbird food plants of a tropical wet forest. Biotropica
10:194-210.

Uhl. C. and K. Clark. 1983. Seed ecology of selected Amazon basin
successional species. Botannical Gazette 144:419-425.

Unesco/UNEP/FAO 1977. Tropical forest ecosystems: a state-of—knowledge
report.

Whitmore, T. C. 1982. On pattern and process in forests. in E. I.
Newman. ed. The Plant Community as a Working Mechanism.
British Ecological Society.

Whitmore, T. C. 1984. Tropical Rain Forests of the Far East. 2nd
edition. 352 pages. Clarendon Press, Oxford, 0.x.