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This is to certify that the

dissertation entitled

SOURCES, COMPONENTS, AND INHERITANCE OF RESISTANCE
TO COCCOMYCES HIEMALIS IN _P____RUNUS SPECIES

presented by
Thomas Martin Sjuiin
has been accepted towards fulfillment

of the requirements for

Ph.D. degree in HorticuIture

7.42%....

Major rrofessor

 

 

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SOURCES, COMPONENTS, AND INHERITANCE OF RESISTANCE

TO COCCOMYCES HIEMALIS IN PRUNUS SPECIES

By

Thomas Martin Sjulin

A DISSERTATION

Submitted to
Michigan State University
in partia1 fu1fi11ment of the requirements
for the degree of

DOCTOR OF PHILOSOPHY
Department of Horticulture

1981

l.
. I
,

// /..4—

/

4 V‘
‘1'
L7

ABSTRACT

SOURCES, COMPONENTS, AND INHERITANCE OF RESISTANCE
TO COCCOMYCES HIEMALIS IN PRUNUS SPECIES

By

Thomas Martin Sjulin

Resistance to Coccomyces hiemalis, the cause of fungal leaf
spot of cherry, was evaluated in field and greenhouse studies with
several Prunus species. In a field planting of a total of 25 culti-

vars of E. aviumz E. cerasus, E. gondouinii, and E. fruticosa, culti-

 

vars differed in rate and severity of both infection and defoliation,
but none was completely resistant. E. _a_vi_um_ cultivars were more
resistant to defoliation than_E. cerasus and E, gondouinii cultivars.
Field resistance to defoliation was negatively correlated with lesion
development and sporulation in the greenhouse.

In greenhouse studies, cultivars of E, axing, g. cerasus,

and £,ggndouinii differed in components of resistance, including

 

numbers of lesions, time, and rate of lesion appearance, and lesion
size and sporulation. Lesions on E, avigm appeared later, were
smaller, and produced fewer spores than lesions on E. cerasus and
.3. gondouinii. Numbers of spores per lesion varied with lesion
size, time of lesion appearance, leaf age, and numbers of lesions

per unit area of inoculated leaf. Cultivar x isolate interactions

Thomas Martin Sjulin

were not significant for cultivars of these three species and six
fungal isolates. These isolates differed in all components except
time and rate of lesion appearance.

Inheritance of components of resistance was evaluated in
families of juvenile seedlings from an incomplete diallel of four
.E- cerasus and one_fi. gondouinii cultivars. No discrete classes of
resistance were observed and broad-sense heritabilities of all com-
ponents except lesion size were less than 0.5 on an individual plant
basis. Thus, resistance did not appear to be simply inherited.
General combining ability differed among cultivars at two of three
dates of inoculation, but family x date of inoculation interactions
were detected for all components except numbers of spores per lesion.

Seedlings and clones representing 15 33233; species and inter-
specific hybrids were inoculated with an isolate from E. cerasus.

Members of the Padus subgenus, the Pseudocerasus and Mahaleb sections

 

of Prunus, and interspecific hybrids between these sections and the

Eucerasus section of Prunus exhibited complete resistance.

To

Kay and Scott Michael

ii

ACKNOWLEDGMENTS

My special thanks to my major professor, Dr. R. L. Andersen,
who helped me become a horticulturist and plant breeder as well as a
close friend of his family. I also deeply appreciate the special
part Dr. A. L. Jones played by allowing me full access to his labora-
tory and greenhouse facilities; without his generosity, this research
would not have been possible.

I would also like to thank the other guidance committee mem-
bers: Dr. A. H. Ellingboe for valuable advice early in this research;
Drs. M. J. Bukovac, J. F. Fobes, and R. P. Scheffer for their critique
and suggestions; and Dr. J. A. Flore for helping on such short notice.

Many others must also be thanked: my fellow graduate students
in Horticulture and Botany Plant Pathology, especially Scott Eisen-
smith and Mike Dessert; Mr. Gail Ehret and Mr. Fred Richey for valu-
able assistance; and Mrs. Nancy Heath for her excellent preparation
of the manuscript.

Finally, warmest thanks of all to my wife Kay, who spent many
long hours at my side in the field, laboratory, and greenhouse during

this research. Her assistance, advice, and support had no equal.

iii

TABLE OF CONTENTS

LIST OF TABLES .
LIST OF FIGURES

INTRODUCTION AND LITERATURE REVIEW

Chapter
I.

II.

III.

Resistance in Cherry to Coccomyces Hiemalis
Variation in Coccomyces Hiemalis .

Research Objectives

Literature Cited

 

FIELD RESISTANCE OF CHERRY CULTIVARS AND SELECTIONS TO
COCCOMYCES HIEMALIS .

Abstract .
Introduction .
Materials and Methods
Results . .
Discussion .
Literature Cited

 

COMPONENTS OF PARTIAL RESISTANCE TO COCCOMYCES
HIEMALIS IN PRUNUS SPECIES . .

Abstract.

Introduction
Materials and Methods

Results

Discussion .
Literature Cited

INHERITANCE OF RESISTANCE TO COCCOMYCES HIEMALIS in
JUVENILE SEEDLINGS OF CHERRY . . .

Abstract . . . . .
Introduction .

Materials and Methods
Results . .

iv

Page

vi

viii

u—l

$000010.)

35

36
38
38
45
67
7O

Chapter

Discussion . . . .
Literature Cited . . .

IV. VARIABILITY OF COCCOMYCES HIEMALIS TO COMPONENTS OF
RESISTANCE IN PRUNUS SPECIES. .

Abstract. .
Introduction . .
Materials and Methods
Results

Discussion . .
Literature Cited

 

V. POSSIBLE SOURCES OF COMPLETE RESISTANCE TO COCCOMYCES

HIEMALIS IN PRUNUS SPECIES

Abstract.

Introduction . .
Materials and Methods
Results and Discussion
Literature Cited

SUMMARY AND CONCLUSIONS .
Summary of Results

Suggestions for Future Research
Literature Cited . .

Page

88
92

108

109
110
111
113
119

121
122

124
133

Table

LIST OF TABLES

Resistance of cherry cultivars and selections to infec-
tion by Coccomyces hiemalis . . . . . . . . .

 

Resistance of Prunus species to infection by Coccomyces

 

hiemalis . . . . . . . . . . . . . . . .

Resistance of cherry cultivars and selections to defo-
liation by Coccomyces hiemalis . . . . .

 

Resistance of Prunus species to defoliation by Cocco-
myces hiemalis . . . . . . . . . . .

 

Components of resistance to Coccomyces hiemalis in
cultivars of Prunus cerasus and E, gondouinii

 

Infection efficiency and lesion development in culti-
vars of Prunus species inoculated with Coccomyces

 

hiemalis . . . . . . . . . . .

Spore production and reproductive efficiency in culti-
vars of Prunus species inoculated with Coccomyces

 

hiemalis . . . . . . . .

Correlations of components of resistance with the
reported field resistance of l9 cherry cultivars

Components of resistance to Coccomyces hiemalis in
parent cultivars of each experiment . . . . . .

Components of resistance to Coccomyces hiemalis in
progeny of experiment l . . .

Components of resistance to Coccomyces hiemalis in
progeny of experiment 2 . . . . . . .

Components of resistance to Coccomyces hiemalis in
progeny of experiment 3 . . . . . . . . .

Mean squares for components of resistance to Coccomyces

hiemalis in progeny of experiment l . . . . .

vi

Page

22

24

25

46

48

50

66

79

81

82

83

84

Table Page

6. Mean squares for components of resistance to Coccomyces
hiemalis in progeny of experiment 2 . . . . . . . 85

 

7. Mean squares for components of resistance to Coccomyces
hiemalis in progeny of experiment 3 . . . . . . . 86

 

8. General combining ability estimates for components of
resistance to Coccomyces hiemalis in each experiment . 87

 

9. Parent and progeny broad-sense heritability estimates
for components of resistance to Coccomyces hiemalis . 89

 

1. Mean squares for components of resistance to six iso-
lates of Coccomyces hiemalis in eight cherry culti-
vars . . . . . . . . . . . . . . . . . 101

 

2. Response of six Coccomyces hiemalis isolates to com-
ponents of resistance in cultivars of Prunus species . 102

 

3. Components of resistance to Coccomyces hiemalis in
cultivars of three Prunus species . . . . . . . 103

1. Resistance of cherry species to Coccomyces hiemalis . 114

vii

LIST OF FIGURES

Figure Page

1. Mean percent infection curves for cultivars of four
cherry species inoculated with Coccomyces hiemalis
on day 189 . . . . . . . . . . . . . . . 20

 

2. Mean percent defoliation curves for cultivars of four
cherry species inoculated with Coccomyces hiemalis on
day 189 . . . . . . . . . . . . . . . . 28

 

1. Relationship of infection efficiency to leaf age in
cultivars of three Prunus species inoculated with
Coccomyces hiemalis . . . . . . . . . . . . 52

 

2. Relationship of time of lesion appearance to leaf age
in cultivars of three Prunus species inoculated with
Coccomyces hiemalis . . . . . . . . . . . . 55

 

3. Relationship of spores per lesion averaged over three
sampling times to leaf age in cultivars of three
Prunus species inoculated with Coccomyces hiemalis . . 58

4. Relationship of spores per lesion to days after inocula-
tion for three leaf ages in cultivars of three Prunus
species inoculated with Coccomyces hiemalis . . . . 61

5. Relationship of reproductive efficiency to leaf age in

cultivars of three Prunus species inoculated with
Coccomyces hiemalis . . . . . . . . . . . . 64

viii

INTRODUCTION AND LITERATURE REVIEW

Cherry leaf spot is a serious fungal disease of cultivated
cherries in most cherry producing regions of the world (2). The
disease was first described in New York in 1878 on native black cherry

(Prunus serotina Ehrh.), although the pathogen was incorrectly named

 

Septoria cerasina (28). The disease was reported in Europe on

 

European bird cherry (Prunus padus L.) in 1884 and the pathogen was

 

named Cylindrosporium_padi (17). American workers subsequently

reported Cylindrosporium species on several cherry and plum species.

 

Finally, Higgins in 1914 divided the Cylindrosporium species occurring

 

on Prunus species into three separate species of the Ascomycete genus

Coccomyces (11). The fungi occurring on sour cherry (E. cerasus L.),

 

sweet cherry (E. avium L.) and pin cherry (E, pennsylvanica L.) were

named Coccomyces hiemalis; those found on plum species were named

 

§,prunophorae; and those found on black cherry, choke cherry

 

(_P_. vifliniana L.) and 3. mahaleb L. were named g. lutescens.

 

Higgin's classification continues to be accepted by most
American workers. However, European workers in recent years have
accepted von Arx's reclassification of the three Coccomyces species
into a single species named Blumeriella jaapii (4). Higgin's classi-

fication will be used for the remainder of this dissertation.

The disease on cultivated cherries (E. avigm, P. cerasus and
_E. gondouinii Rehd.) is characterized by small necrotic lesions on
leaves, petioles and occasionally on fruit pedicels (34). Primary
infection of expanding leaves in the spring is from ascospores dis-
charged from apothecia produced over winter in fallen leaves.
Ascospores are discharged during rainy periods from the time of first
leaf emergence until about 6 to 7 weeks after petal fall (1). Secon-
dary infections are from conidia splashed from acervuli produced on
the primary infections and subsequent secondary infections. Secon-
dary infections can occur throughout the growing season as long as
susceptible host tissue is present and conditions are favorable for
infection. Conditions favorable for both primary and secondary
infection are determined mainly by temperature and leaf wetness (8).
Thus, the increase of disease during the growing season is not con-
tinuous, but instead, occurs in discrete stages called infection
periods (19).

Severely infected leaves usually become chlorotic and subse-
quently abscise. If defoliation is severe before harvest, fruit
may fail to ripen properly (10). More commonly, premature defoliation
reduces both the vigor and hardiness of the tree in subsequent seasons.
Reduction in vigor in sour cherry is in turn related to reduction in
yield and fruit quality (20). Dutton and Wells (7) observed reduced
bud survival, fruit set and fruit size the year following severe
defoliation from leaf spot. In addition, fruiting spur development,
flower bud survival and fruit set were reduced the second year follow-

ing defoliation. Howell and Stackhouse (12) also observed reduced

bud survival and fruit set for two seasons following premature defolia-
tion by Q. hiemalis. Furthermore, they observed delayed acclimation

in the fall and more rapid deacclimation in the spring of both vege-
tative and flower buds of prematurely defoliated trees.

Fungicidal sprays are currently the principal means for pre-
venting leaf spot infection and subsequent defoliation. In Michigan,
the initial fungicide application is made at petal fall, followed by
four additional sprays at 10 to 14-day intervals until harvest. A
final application is made soon after harvest (13).

Cherry cultivars with increased resistance to Q, hiemalis
would be useful in several ways. First, use of a cultivar immune to
g, hiemalis could eliminate several costly fungicide sprays. Second,
an increased (but not complete) level of resistance could reduce the
number of fungicide sprays. Finally, an increased level of resistance
could allow use of less effective fungicides if the preferred fungi-
cides became unavailable due to resistant pathogen strains or loss of
their use for economic or environmental reasons. Strains of
g, hiemalis resistant to benzimidazole fungicides have been found in

Michigan (15).

Resistance in Cherry to Coccomyces Hiemalis

Little is known about the relative resistance of either sour
cherry or sweet cherry cultivars to Q. hiemalis. Sweet cherry culti-
vars are, in general, more resistant than sour cherry cultivars (32),
but little within species variation in resistance was thought to

exist (1).

Recent reports from Eastern Europe indicate that within
species variability for resistance does exist (3,6,16,21,22,29,31,
35.36.40). Although few, if any, cultivars in these studies were
found to be completely resistant to Q, hiemalis, there does appear
to be potential for selecting for increased resistance in both
.3. avigm_and E. cerasus. Enikeyev (9) found that certain cultivars
of both E. cerasus and E. avium_produced a higher percentage of
resistant seedlings in their progenies than did other cultivars.
Also, crosses involving the European ground cherry (P. fruticosa
Pall.) were generally much more susceptible than crosses not involv-
ing this species. .3. cerasus is thought to have arisen as an
allotetraploid of P. fruticosa and P, avium_(25).

Several species of cherry in the Pseudocerasus, Lobopetalum
and Mahaleb sections of the subgenus Cerasus, and in the subgenus
Padus (30) appear to have much greater resistance to g, hiemalis
than cultivated cherries. The Pseudocerasus and Lobopetalum sections
contain the Japanese flowering cherries. Many of these species appear
to remain free of cherry leaf spot infection in ornamental plantings.
In addition, a number of these species have been reported to form
hybrids with E. avium_(5). However, no systematic evaluation of the
resistance of these species to C, hiemalis has been made to date.

3, mahaleb has been observed to be more resistant to C.
hiemalis than either 3. avium or E. cerasus (37). A number of
.E.Ia!ium.x.fi. mahaleb clones selected as potential cherry rootstocks
(38) may be possible sources of increased resistance to C, hiemalis

in P. avium.

Three cherry species in the subgenus Padus (P. padus,

.E. serotina and P. virginiana) were completely resistant to infection

 

by isolates of Q. hiemalis from P. avium or_fl. cerasus (11,18). How-

ever, all three species are susceptible to strains of Coccomyces

 

that Higgins considered to be a separate species, C. lutescens (11).
The use of any of these cherry species as a source of complete
resistance to Q. hiemalis would have to be done guarding against intro-
duction of susceptibility to Q. lutescens. Furthermore, no reports
have been found to date of interspecific hybrids between these
species and the cultivated cherries. A fourth member of this sub-
genus, E. maackii Rupr., has been successfully crossed with culti-
vated cherries (24). It is not yet known if this species is resistant
to Q. hiemalis.

There appear to be two basic approaches to breeding cherries

resistant to Coccomyces leaf spot. One is to select for increased

 

levels of resistance within the cultivated species (B. aVium,

 

.3. cerasus and E. gondouinii). Most studies indicate that cultivars
differ quantitatively in terms of the incidence or severity of
disease in the field. This type of resistance, called partial
resistance, is a type of incomplete resistance that reduces the rate
of pathogen mutiplication even though the host is susceptible to
infection (26,33). Breeding for partial resistance is sometimes
enhanced or simplified by selecting for one or more component of
resistance contributing to partial resistance (26).

The alternate approach is to identify sources of complete

resistance in other cherry species, and incorporate the resistance

into cultivated cherries, if complete resistance is not found within
cultivated cherries to begin with. This approach has been used
successfully in Mglu§_to breed scab resistant apple cultivars (39).
Which approach is chosen depends upon several factors,

including (1) the level of resistance needed; (2) the horticultural
characteristics of the resistance sources; (3) the number and nature
of the genes controlling resistance; and (4) the genetic variability
of the pathogen to the resistance. At present our understanding of

these factors is too poor to wisely choose the best approach.

Variation in Coccomyces Hiemalis
Higgins (11) first examined pathogenic variation among

Coccomyces strains isolated from Prunus species. The results of cross-

 

inoculation studies indicated pathogenic specialization by Coccomyces

 

among several species of Prunus, Isolates from hosts in the subgenus,
Padus would not infect hosts in the subgenera, Cerasus and Prunophora,
with the exception of E, mahaleb in Cerasus. Isolates from hosts in
the subgenera Cerasus and Prunophora would not infect hosts outside
of their respective subgenus. Higgins assigned these three groupings
of isolates to separate species of Coccomyces, because there were
morphological differences between the groups of isolates when grown
in culture.

Keitt (18) examined in greater detail the ability of

Coccomyces isolates to cross-infect other Prunus species. His results

 

generally supported Higgins' conclusions. However, the grouping of

isolates was not as distinct as that found by Higgins. Isolates from

all seven hosts tested in three subgenera of Prunus (Prunophora,

 

Cerasus and Padus) readily infected P. mahaleb. .3. munsoniana

 

Night & Hedr. (subgenus Prunophora) was readily infected by isolates

 

from E. cerasus (subgenus Cerasus), but not by isolates from

.2. domestica L. (subgenus Prunophora). Isolates from_E. virginiana

 

 

(subgenus Padus) readily infected members of both Padus and Bruno:
.phgrg, as well as E. mahaleb. Isolates from E. serotina (subgenus
Padus) did not infect other members of Padus. Keitt's work does not
support Higgin's decision to assign three species designations within

Coccomyces. The use of formae speciales designations for isolates

 

 

from different hosts would also be confusing, as several hosts are
readily infected by more than one group of isolates. It is probably
best to designate these groups of isolates as different pathogenic
races until the genetic relationships among groups can be determined.
Magie (23) studied the variability of Q. hiemalis isolates
collected from a single host species, B. cerasus. Isolates differed
considerably in growth habit, growth rate and spore production on
artificial media. Isolates also differed in the type and number of
infections produced on leaves of both sweet cherry and sour cherry.
No evidence of pathogenic races was found. However, only one sweet
cherry cultivar and one sour cherry cultivar were used, and the condi-
tions of the experiments varied considerably. Parlevliet and Zadoks
(27) have demonstrated that biologically significant cultivar by
isolate interactions may contribute only a small part to the total
experimental variance. It is important that experiments of this kind

be well controlled to minimize residual error variance.

The demonstrated variability in Coccomyces at the species

 

level of the host is of immediate concern if attempts are to be made
to introduce complete resistance into cultivated cherries by inter-
specific hybridization. Care must be taken that incorporation of

resistance to one group of Coccomyces isolates does not introduce

 

susceptibility to another. In addition, utilizing sources of partial
resistance apparently existing within cultivated cherries does not
preclude consideration of the variability of the pathogen to this
type of resistance. Partial resistance in several host-pathogen

systems have been found to be race-specific in nature (14).

Research Objectives

 

This research presents the first attempts to systematically
identify, characterize and utilize resistance in Prunus species to

Coccomyces hiemalis. The specific objectives were (1) identify

 

sources of complete or partial resistance in cultivated cherries;

(2) identify components of resistance contributing to the resistance
identified in the first objective; (3) obtain preliminary estimates
of the heritable components of resistance; (4) evaluate the varia-
bility of the pathogen population to the resistance identified in the
first objective; and (5) identify sources of complete resistance to

g, hiemalis in related cherry species.

10.

11.

LITERATURE CITED

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Anonymous. 1976. Distribution maps of plant diseases, no. 58,
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Higgin, B. B. 1914. Contribution to the life history and
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10

Howell, G. S. and S. S. Stackhouse. 1973. The effect of
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11

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Rehder, A. 1940. Manual of Cultivated Trees and Shrubs, 2nd ed.
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Robinson, R. A. 1969. Disease resistance terminology. Rev.
Appl. Mycol. 48: 593-606. .

Stewart, F. C. and H. J. Eustace. 1901. Notes from the
botanical dept. N. Y. (Geneva) Agric. Expt. Sta. Bull. 200:
81-101.

Suta, V., G. Moruju, I. Morea, S. Nica, C. Radulescu, and N.
Mateescu. 1961. Susceptibility of some apple, pear and cherry
varieties to attack by the main diseases in the first nine
years after planting at the Voinesti Station, 1951-1959 (in
Russian). Lucr. Stiint Inst. Cerc. Horti-Vitic. 4: 865-876.
Abstracted in Rev. Appl. Mycol. 43: 1064 (1964).

Timoshenko, S. E. 1977. The resistance of different sweet
cherry cultivars and hybrids to cherry leaf spot (in Russian).
Trudy Stavropol'sk NII s.-Kh. 48: 76-82. Abstracted in Hort.
Abstr. 49: 420 (1979).

Tukey, H. B. 1929. Seedling fruit stocks. N. Y. (Geneva)
Agric. Expt. Sta. Bull. 569. 34 pp.

38.

39.

40.

12

Westwood, M. N., A. N. Roberts and H. 0. Bjornstad. 1976.
Comparison of mazzard, mahaleb and hybrid rootstocks for

Montmorency cherry (Prunus cerasus L.). J. Amer. Soc. Hort.
Sci. 101: 268-269.

 

Williams, E. B. and J. Kuc. 1969. Resistance in Malus to
Venturia inaegualis. Ann. Rev. Phytopath. 7: 223-246.

Zekovic, P. and D. Vuletic. 1975. A contribution to the
knowledge of susceptibility of different sorts of cherries and
sour cherries to Coccomyces hiemalis Higg. in Metohiza (in
Hungarian with English summary). Zastita Bilja 26: 79-83.

CHAPTER I

FIELD RESISTANCE OF CHERRY CULTIVARS AND
SELECTIONS TO COCCOMYCES HIEMALIS

 

13

CHAPTER I

FIELD RESISTANCE 0F CHERRY CULTIVARS AND
SELECTIONS T0 COCCOMYCES HIEMALIS

 

Abstract

Resistance to infection and defoliation by Coccomyces

 

hiemalis Higg. was measured in a field planting of 25
cultivars and selections representing four Prunus species
(3. avium L., P. cerasus~ L., g. fruticosa Pall. and 3.
gondouinii Rehd.). No cultivar was completely resistant
to either infection or defoliation. The rates and sever-
ity of infection and defoliation, and the estimated

dates of 50% infection and defoliation by g, hiemalis
differed among cultivars. Correlations between defolia-
tion severity and measures ofinfection were poor. Rates
of defoliation and dates of 50% defoliation were highly
correlated with defoliation severity. Comparisons
between species indicated that P. _ay_iu_m cultivars were
more resistant than B. cerasus or E. gondouinii culti-
vars in terms of infection rate, defoliation rate, date
of 50% defoliation and defoliation severity. Defolia-
tion severity was less in P, avium cultivars than in

P, fruticosa cultivars. P, fruticosa cultivars were

14

15

more resistant than B. cerasus cultivars in terms of
infection severity, defoliation rate, date of 50% defolia-

tion, and defoliation severity.

Introduction

 

Cherry leaf spot, caused by Coccomyces hiemalis, is a serious

 

disease of cultivated cherries throughout the world (2). At present,
little information exists on the genetic variation for resistance

within sour cherry (Prunus cerasus) or other cultivated cherry spe-

 

cies. An evaluation of the relative resistance of available culti-
vars would aid selection of parent material for use in a cherry
breeding program.

Sweet cherries (E. avium) are considered more resistant to
leaf spot than sour cherries (15). The relative resistance of duke
cherries (P. gondouinii), which are hybrids between sweet and sour
cherries, is uncertain. The European ground cherry (P. fruticosa)
was reported to be less resistant than either B. avium or _P_. cerasus
(8).

Reports from Eastern Europe indicate that genetic variation
for resistance also exists within sweet, sour, and duke cherries
(3,6,13,19,21). The purpose of this research was to evaluate the
relative resistance to infection and defoliation by Q. hiemalis of
cultivars and selections within these four species of cherry. In
addition, planned statistical comparisons were made between these
species on the assumption that the cultivars and selections evaluated

were representative of their respective species.

16

Materials and Methods

Plant material. Twenty-five cultivars and selections repre-

 

senting four species of cultivated cherries (E. m, P. cerasus,
.3. gondouinii and_E. fruticosa) were chip budded in September, 1979,
onto seedling rootstocks of P. mahaleb L. All budwood except that of
3. 2M 'Governor Wood', _P. m 'Yellow Glass', 3. cerasus 'SHT-2'
and E. gondouinii 'SHT-3' was obtained as virus-free budwood from the
U.S.D.A. Interregional Project No. 2 repository in Prosser, WA 99350.
Budwood of 'Governor Wood' and 'Yellow Glass' was obtained from
Interstate Nurseries, Inc., Hamburg, IA 51640. Budwood of 'SHT-3' and
'SHT-Z' was obtained from the original seedling trees at the South
Haven Experiment Station, South Haven, MI. 'SHT-Z' is an open-
pollinated seedling of an unknown morello sour cherry. 'SHT-3' is an
apparent interspecific hybrid between E. cerasus 'North Star' and
an unknown culitvar of E, axiom. Both 'SHT-2' and 'SHT-3' were pre-
viously selected at the South Haven Experiment Station for their
resistance to Q. hiemalis (R. L. Andersen, unpublished). The remain-
ing cultivars were selected to represent a genetically diverse samp-
ling of cultivars within each species.

The budded trees were dug in November, 1979, and stored at
1-4 C until planting in April, 1980. Trees were planted at 1.5 m by
1.8 m spacing in Locke sandy loam in a randomized complete block with
five replications. Trees were irrigated daily throughout the growing
season with a biwall drip irrigation system buried 2- to 5-cm deep

adjacent to each tree. Seedling tops were removed from each tree

17

within 10 days after planting to force growth from the propagated

bud. A single vegetative shoot was forced from each tree and main-
tained as a single shoot until terminal bud formation. Each tree
received approximately 3090f 12% N-12% P205-12% K20 fertilizer in a
single application 2 weeks after budbreak and a supplementary appli-
cation of 33 g of urea one month later. Trees were sprayed as needed
throughout the growing season to control insects and mites. Pyrazophos

(Afugan 30 EC, 0.5%, v/v) was applied twice within 4 weeks after

inoculation to control powdery mildew (14).

Inoculation with Coccomyces hiemalis. Each tree in the experi-

 

ment was inoculated with C. hiemalis on July 7, 1980. Conidia for
inoculation were washed from naturally infected leaves of P. cerasus
'Montmorency' from trees adjacent to the experimental plot. A 2 cm2
area on the lower surface of the second unfolded leaf below the shoot
apex was inoculated by spraying a suspension of 105 conidia per ml
with a mist bottle. The inoculated leaf was enclosed over night in a
polyethylene bag containing a wet paper napkin for approximately 12

hours. Subsequent spread of inoculum and infection occurred through-

out the growing season during periods of natural leaf wetness.

Evaluation of resistance. Trees were evaluated starting

 

Ju1y 7, 1980, and at 1- to 2-week intervals through October 2, 1980.
Percent of total leaves that were infected or defoliated were déter-
mined at each evaluation. The total number of leaves for an indi-

vidual tree was the number of unfolded leaves present on August 6,

18

1980, when the terminal leaf had unfolded on the first trees to
cease terminal growth.

Preliminary analysis of angular-transformed data as a split-
plot in time (18) indicated that there was a highly significant
cultivar by time of evaluation interaction for both percent infection
and percent defoliation. In addition, the angular transformation did
not adequately linearize the data, as a highly significant non-linear
residual term remained after fitting the linear term.

Gompertz and logistic equations were fit to the sigmoidal
percent infection and percent defoliation curves to determine if at
least part of the interaction was due to differences in slope and/or
position of the curves. Examination of the residuals and correlation
coefficients for individual trees indicated a better fit with the
Gompertz transformation (-1n(-1n(y))). Linear regression of Gompertz-
transformed values against time of rating was used to estimate rates
(k) of infection and defoliation for each tree (4). In addition, the
time in days of the year to 50% infection and 50% defoliation were
estimated from the regression equations.

Estimates of disease severity were made by calculating the
areas under the percent infection and percent defoliation curves.

Areas for each tree were calculated by the following equation:

n
Area = 1.:]((R1. f Rifl)/2)(ti+l - ti)

19

where ti = day of the year at evaluation "i," Ri = percent infection

or percent defoliation at evaluation "i," and i = 1 to 9.

Results

Inoculation of a single leaf per tree resulted in the nearly
uniform establishment of infection throughout the experimental
plot. At the time of inoculation, 57% of the trees showed no visible
symptoms of infection on any leaves. All but one of the 125 trees
showed visible symptoms of infection on the inoculated leaf 14 days
later.

The level of infection increased rapidly in the plot. The
mean percent of leaves infected was less than 5% on the day of
inoculation (Figure l). The mean percent of leaves infected reached
70% at 4 weeks after inoculation (day 219), and increased to greater
than 98% at eight weeks after inoculation (day 248).

Variation in infection and defoliation existed within and
between the four species of cherry (Tables 1-4). No cultivar was
free of infection or defoliation, and significant quantitative dif-
ferences in infection and defoliation between cultivars were detected.

Rates of infection varied over a 2-fold range among the 25
cultivars from a low of 0.062 for E, ayium_'Hedelfingen' to a high
of 0.126 for_E. cerasus 'North Star' (Table 1). Estimated date of
50% infection varied by less than 10 days among the 25 cultivars.
Infection severity (area under infection curve) ranged from a low of
5754 for g. _av_i_u_m 'Yellow Glass' to a high of 6679 for _P. 211%“.

'Schmidt'.

20

Figure 1. Mean percent infection curves for cultivars of four
cherry species inoculated with Coccomyces hiemalis
on day 189 (inoc). Curves are the mean of 9,16: 6,
and 4 cultivars for Prunus avium, E, cerasus,
E, gondouinii and E, fruticosa, respectively.

 

 

INFECTION

PERCENT

21

 

 

 

 

‘00 "' I .. u: -----

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— E. gerasus ,f

- -- 1’. mm o a ,,’
“'1’. gondouinii //
I.
so - I:
I.’
1.:
/.~'
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I:

60 '-
40 '-

inoc
20 1-

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.; ,J
[I
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180 200 220 240 260

DAY OF THE YEAR

280

223

TABLE l.--Resistance of cherry cultivars and selections to infection by
Coccomyces hiemalisV

 

 

_ . Date of Infection
CUIthBV I":§§:&°“ 50% infection severity
(day of the (area under
year)x inf curve)-y
Prunus avium
Black Tartarian .086 cdefgz 211.9 bcdefgh 6251 abcdef
Emporer Francis .089 bcdefg 212.2 bcdefgh 6191 bcdef
Governor Wood .085 cdefg 214.8 defgh 5981 defg
Hedelfingen .062 9 210.7 abcde 6451 abc
Lambert .071 fg 212.5 bcdefgh 6202 bcdef
Napoleon .073 efg 211.5 abcdefg 6269 abcde
Schmidt .079 cdefg 208.9 abc 6679 a
Windsor .075 defg 213.9 cdefgh 6038 cdefg
Yellow Glass .083 cdefg 216.6 h 5754 g
.E. cerasus
Early Richmond .085 cdefg 210.3 abcd 6424 abc
English Morello .078 cdefg 210.2 abcd 6312 abcd
Meteor .108 abcd 210.5 abcde 6327 abcd
Montmérency .107 abcde 208.6 ab 6560 ab
North Star .126 a 215.0 defgh 6011 cdefg
SHT-Z .112 abc 215.4 efgh 5924 defg
.E. gondouinii
Brassington Duke .082 cdefg 216.2 gh 5848 efg
Kansas Sweet .091 bcdefg 216.0 fgh 5905 defg
Krassa Severa .104 abcdef 206.9 a 6655 ab
May Duke .082 cedfg 208.9 abc 6421 abc
SHT-3 .085 cdefg 216.2 gh 5818 fg
Wczesna Z Prin .100 abcdef 212.0 bcdefgh 6219 bcdef
.E. fruticosa
Dwarf Rich .109 abcd 213.2 bcdefgh 6095 cdefg
IR 323-2 .105 abcdef 215.4 efgh 5926 defg
IR 586-3 .121 ab 211.1 abcdef 6315 abcd
IR 587-1 .086 cdefg 214.4 defgh 5958 defg

 

vMean of 5 single-tree replications.
wSlope of linear regression of Gompertz-transformed percent infection data.

xEstimated from the linear regression of Gompertz-transformed percent
infection data.

1
tion 1 and Ri - percent of leaves infected at evaluation i (i a 1-9).

yArea - 2((Ri + R1+1)/2)(t.+1 - ti)’ where ti = day of the year at evalua-

zMean separation by Duncan's multiple range test (p_= 0.05).

23

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TABLE 3.--Resistance of cherry cultivars and selections to defoliation by
Coccomyces hiemalis.V

 

 

D f 11 Date of Defoliation
. e o ation 50% defoliation severity
Cu1t1var ratew (day of the (area under
year) def curve)Y
Prunus avium
Black Tartarian .064 abcdefgz 234.2 abcd 4045 cdef
Emporer Francis .052 efgh 246.5 defg 2828 h
Governor Wood .057 defgh 236.7 bcde 3724 def
Hedelfingen .038 ghi 246.8 defg 2874 gh
Lambert .088 ab 238.9 cdefg 3471 fg
Napoleon .064 abcdefg 234.4 abcd 3755 def
Schmidt .034 hi 247.4 efg 2803 h
Windsor .055 defgh 246.6 defg 2879 gh
Yellow Glass .049 fghi 249.3 fg 2716 h
3, cerasus
Early Richmond .064 abcdefg 228.0 abc 4551 abc
English Morello .077 abcde 227.4 abc 4644 abc
Meteor .060 cdefgh 228.7 abc 4377 abcd
Montmorency .090 a 224.5 ab 4936 ab
North Star .044 fghi 237.5 cdef 3736 def
SHT-Z .055 defgh 235.2 abcde 3623 ef
2, gondouinii
Brassington Duke .063 abcdefg 237.9 cdefg 3686 ef
Kansas Sweet .067 abcdef 238.0 cdefg 3542 f
Krassa Severa .085 abc 222.8 a 4994 a
May Duke .065 abcdefg 230.1 abc 4378 abcd
SHT-3 .062 bcdefg 231.3 abc 4219 cde
Wczesna Z Prin .082 abcd 227.5 abc 4594 abc
E, fruticosa
Dwarf Rich .058 cdefgh 240.0 cdefg 3555 f
IR 323-2 .066 abcdef 229.4 abc 4342 bcd
IR 586-3 .062 bcdefg 234.5 abcd 3996 cdef
IR 587-1 .025 1 250.3 g 2934 gh

 

vMean of 5 single-tree replications.

wSlope of linear regression of Gompertz-transformed percent defoliation data.

xEstimated from linear regression of Gompertz-transformed percent defolia-

tion data.

yArea under defoliation curve a 2((Di + Di+l)/2)(ti+l - ti)’ where ti =

day of year at evaluation i and D

i (i - 1-9).

zMean separation by Duncan's multiple range test (p,= 0.05).

.i

= percent of leaves defoliated at evaluation

25

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26

Higher rates of infection were not always associated with
earlier dates of 50% infection. For example, 'Yellow Glass' had a
slightly higher infection rate than 'Schmidt', but the estimated date
of 50% infection was more than 7 days earlier for 'Schmidt' than for
'Yellow Glass.’ Similarly, the infection rate for 'North Star' was
considerably higher than B. cerasus 'Montmorency', but the estimated
date of 50% infection was more than 6 days earlier for 'Montmorency'
than for 'North Star.’

The average infection rate for E. ayium cultivars was signifi-
cantly lower than that of the other three species (Table 2). However,
date of 50% infection and infection severity did not differ signifi-
cantly between E. avium and the other species. These results reflect
the higher average percent infection in E, gyium cultivars early in the
season, compared with a lower percent infection for _P_. 3311111 later
in the season (Figure 1).

Rates of defoliation differed more than 3-fold among these
cultivars, from a low of 0.025 for P. fruticosa 'IR 587-1' to 0.090
for 'Montmorency' (Table 3). Dates of 50% defoliation range from
earlier than day 223 for the duke cherry 'Krassa Severa' to later than
day 250 for 'IR 587-1'. Defoliation severity (area under defoliation
curve) was highest for 'Krassa Severa' (4994) and lowest for 'Yellow
Glass' (2716). In general, cultivars with low defoliation severity
values had lower defoliation rates and later dates of 50% defoliation.
Simple correlations calculated on a cultivar mean basis between
defoliation severity and either defoliation rate (r = 0.743) or date

of of 50% defoliation (r = -0.986) were highly significant (p'< 0.01).

27

However, E:.é!i!fl 'Lambert' had a relatively high defoliation rate
(0.088) but a moderately low defoliation severity value (3471). The
defoliation curve for this cultivar was characterized by a delay in
the onset of defoliation, followed by a relatively rapid increase in
defoliation later in the season.

Parameters that estimated resistance to infection were poorly
correlated with defoliation severity. Only the date of 50% infection
was significantly correlated with defoliation severity (r = -0.426,
.p = 0.05). In addition, some cultivars estimated to be least resis-
tant to infection were among the most resistant to defoliation, and
vice-versa (Tables 1 and 2). For example, 'Schmidt' had the highest
infection severity of all 25 cultivars, and one of the lowest defolia-
tion severity values.

Differences between species in resistance to defoliation
were greater than differences in resistance to infection (compare
Figures 1 and 2). _P. 211.9111 was significantly more resistant than

either 3. cerasus or P. gondouinii in all three defoliation parameters,

 

and more resistant than B. fruticosa in terms of defoliation severity
(Table 4). .3. cerasus was significantly less resistant than B.

fruticosa in all three parameters.

Discussion
The results of this study provide valuable information on
selection of parents for breeding cherries with increased resistance

to C, hiemalis. How resistant cultivars can be developed depends not

28

Figure 2. Mean percent defoliation curves for cultivars of four
cherry species inoculated with Coccomyces hiemalis on
day 189 (inoc). Curves are the mean of 9, 6, 6, and
4 cultivars for Prunus avium, E, cerasus, E, gondouinii
and E. fruticosa, respectively.

 

PERCENT DEFOlIATION

29

 

100 -

.0 -

60 b

 

....... [- aVium
— _lf. cerasus
-- E. fruticosa

“" E. gondouinii

 

 

 

200 220 240

DAY OF THE YEAR

260

280

30

only upon identification of a source of resistance, but also on the
number and nature of genes controlling resistance. Preliminary
studies indicate that cultivars of sweet, sour and duke cherry differ
in breeding value for resistance to C. hiemalis (8,17).

Evaluation of resistance to Q, hiemalis should accurately
assess resistance to defoliation. Severe defoliation by C. hiemalis
reduces the yield, growth and hardiness of cherry trees up to two
seasons following defoliation (7,9). Reduction in growth can, in
turn, reduce the development of fruiting spurs important to future
productivity (12). 0f the three defoliation parameters evaluated in
this study, defoliation severity probably best measures the impact
of defoliation on the tree. Defoliation severity, calculated as the
area under the defoliation curve, assesses not only the extent of
defoliation, but also when during the season that defoliation occurs.
Defoliation early in the season would be more detrimental to the
tree than defoliation later, even if the total severity of defolia-
tion was the same. Unfortunately, accurate determination of defolia-
tion severity requires that several evaluations be made for each tree
throughout the season. Measurements of defoliation severity, date
of 50% defoliation, or defoliation rate probably are not practical
for use in a breeding program except for advanced selection evaluation
in replicated trials. Evaluation of components of resistance in
young seedlings under controlled conditions has been proposed as an
alternate method of resistance screening (16), but initial results

indicate that heritabilities of individual components are too low to

31

apply this method to initial single-plant selection (17). Initial
screening of individual seedlings can probably be done most effi-
ciently by a single evaluation per season in the field when the mean
level of defoliation appears to be 50%, which should allow for great-
est dispersion of the genotypes around the mean. Establishment of a
uniform point source of inoculum in each tree should provide suffi-
cient disease pressure in most seasons.

Although no cultivar in this study was completely resistant,
genetic variation in the level of resistance to C. hiemalis was

present within all four cherry species. In addition, the differences

between cultivars in this study probably underestimate the magnitude
of differences between the same cultivars in orchard plantings.
Conidia are likely to splash from heavily infected trees to adjacent
trees during wind-driven rain in this closely spaced planting (5).
This type of plot-to-plot interference can diminish true differences
in resistance between cultivars (20).

The need for increased resistance to C, hiemalis is espe-
cially critical in sour cherry. The sour cherry industry in Michigan
and the rest of the United States is based almost entirely on the
cultivar 'Montmorency' and strains derived from it (I). 'Montmorency'
was very susceptible to defoliation in this study (Table 3). The
sour cherry cultivar 'North Star', in contrast, showed much greater
resistance to defoliation. In addition, initial studies on the
inheritance of resistance in sour cherry indicate that 'North Star'
is a good parent for obtaining progeny with resistance to Q, hiemalis

(17). The introduction of commercially acceptable cultivars with a

32

level of resistance comparable to 'North Star' should reduce the
number of fungicide sprays needed each season to control leaf spot.
Currently, about six fungicide applications per season are recom-
mended to Michigan sour cherry growers to control this disease (10).

An alternate approach to increasing resistance in sour cherry
is interspecific hybridization with the more resistant sweet cherries.
There is indication, however, that this approach may be complicated
by non-additive gene action. The mean resistance to defoliation of
the duke cherries in this study was very similar to that of the sour
cherries (Table 4). If these duke cherry cultivars are representa-
tive of hybrids between sweet and sour cherry, then the genes for
resistance in sweet cherry may be recessive to genes in sour cherry.
This hypothesis should be tested by creating hybrids between sweet
and sour cherries. Levels of resistance in hybrid progenies should
be compared to within-species progenies as well as clonal parent

material.

10.

LITERATURE CITED

Andersen, R. L. 1981. Cherry cultivar situation. Fruit Var. J.
35: 83-92.

Anonymous. 1976. Distribution maps of plant diseases, no. 58,
ed. 4. Commonwealth Mycological Institute, Kew, England. 2 pp.

Anonymous. 1976. Field resistance of sour cherry and cherry
varieties to coccomycosis under the conditions of the Crimea
(in Russian). Sadovodstvo 24: 51-61. Abstracted in Rev. Plant
Path. 56: 3634 (1977).

Berger, R. D. 1981. Comparison of the Gompertz and logistic
equations to describe plant disease progress. Phytopathology
71: 716-719.

Corke, A. T. K. 1966. The role of rainwater in the movement
of Gloeosporium spores in apple trees. Pages 143-149 in:

M. F. Madelin, ed. The Fungus Spore. Proc. 18th Symp. Colston
Research Soc., Univ. Bristol, 1966. Butterworths, London.

Daugis, M. 1962. Some data on varietal resistance in cherry
to_coccomycosis in the conditions of the Latvian S.S.R. (in
Russian). Pages 148-149 in: Brief Summaries of Research Work
on Plant Protection in the Baltic Zone of the U.S.S.R., vol. 4
(1961). Abstracted in Rev. Plant Path. 45: 940x (1966).

Dutton, W. C. and H. M. Wells. 1925. Cherry leaf spot residual
effects and control. Mich. Agric. Expt. Sta. Spec. Bull. 147.

15 pp.

Enikeyev, K. K. 1974. Resistance of cherry hybrid seedlings
to the leaf-spot disease (Coccom ces hiemalis). Proc. 19th
Int. Hogt. Cong., Warsaw, Poland, Sept., 1974, vol. IA: 327
Abstr. .

Howell, G. S. and S. S. Stackhouse. 1973. The effect of defolia-
tion time on acclimation and dehardening in tart cherry (Prunus

cerasus L,). 'J. Amer. Soc. Hort. Sci. 98: 132-136.

Howitt, A. J., J. Hull and A. L. Jones (eds.). 1981. Fruit
Pesticide Handbook. Mich. St. Univ. Extn. Bull. E-154.
96 pp.

33

11.

12.

13.

14.

15.

16.

17.

18.

19.

20.

21.

34

Keitt, G. W. 1918. Inoculation experiments with species of
Coccomyces from stone fruits. J. Agric. Res. 13: 539-569.

 

Kenworthy, A. L. 1974. Sour cherry-tree vigor as related to
higher yields and better fruit quality. Mich. St. Univ. Agric.
Expt. Sta. Res. Rpt. 223. 4 pp.

Khokhryakova, T. M., I. I. Minkevich, and A. N. Rakhmanova.
1971. The field resistance of cherry to coccomycosis (in
Russian). Trudy Prikl. Genet. Selek. 43: 237-240. Abstracted
in Rev. Plant Path. 51: 1658 (1972).

Klos, E. J., D. Ritchie and K. Keever. 1975. Page 41 in:
C. W. Averre, ed. Fungicide and Nematicide Tests, Results of
1974, vol. 30. The American Phytopathological Society, St. Paul.

Roberts, J. W. and L. Pierce. 1919. Control of cherry leaf
spot. United States Dept. Agric. Farmers Bull. 1053. 8 pp.

Sjulin, T. M. 1981. Components of resistance to Coccomyces

hiemalis in Prunus species. Chapter II of this dissertation.

Sjulin, T. M. 1981. Inheritance of resistance to Coccomyces
hiemalis in juvenile seedlings of cherry. Chapter III of this

 

dissertation.

Steel, R. G. D. and J. H. Torrie. 1960. Principles and Pro-
cedures of Statistics. McGraw-Hill, New York. 481 pp.

Timoshenko, S. E. 1977. The resistance of different sweet
cherry cultivars and hybrids to cherry leaf spot (in Russian).
Trudy Stavropol'sk NII S.-Kh. 48: 76-82. Abstracted in Hort.
Abstr. 49: 420 (1979).

Van der Plank, J. E. 1963. Plant Diseases: Epidemics and
Control. Academic Press, New York. 349 pp.

Zekovic, P. and D. Vuletic. 1975. A contribution to the knowl-
edge of susceptibility of different sorts of cherries and sour
cherries to Coccomyces hiemalis Higg. in Metohiza (in Hungarian
with English summary). Zastita Bilja 26: 79-83.

CHAPTER II

COMPONENTS OF PARTIAL RESISTANCE TO COCCOMYCES

 

HIEMALIS IN PRUNUS SPECIES

35

CHAPTER II

COMPONENTS OF PARTIAL RESISTANCE T0 COCCOMYCES

 

HIEMALIS IN PRUNUS SPECIES
Abstract

Cultivars of Prunus avium, P. cerasus and P, gondouinii

 

differing in levels of partial resistance to Coccomyces

 

hiemalis were evaluated for components of resistance in
the greenhouse in two separate experiments. In the first
experiment, components were evaluated over four leaf

ages (6.5, 10.5, 14.5 and 18.5 days old) in six 2, cerasus

cultivars and two P. gondouinii cultivars. ‘Numbers of

 

lesions per cm2 of inoculated leaf (infection frequency)
at 6 (but not 16) days after inoculation and proportion
of lesions present at 6 days differed among cultivars.
Lesion areas and spores per lesion, both measured 20
days after inoculation, differed over leaf ages and

2 of inoculated leaf,

among cultivars. Spores per cm
the combined effect of infection frequency and spores
per lesion, differed nearly 5-fold among cultivars.
Cultivar x leaf age interactions were present for
lesion area, spores per lesion and spores per cm2 of

inoculated leaf area. Measurement of spores per lesion

36

37

were predicted from measurements of lesion areas, pro-
portion of lesions present and leaf age (R2 = 0.68).

In the second experiment, components of resistance were
evaluated over three leaf ages (7.5, 19.5, and 31.5 days
old) in ten P, ayium_cultivars, five E. cerasus culti-
vars and five 3. gondouinii cultivars. Infection effi-
ciency (ratio of lesions produced to inoculum applied),
days to 50% of lesions present, rate of lesion appear-
ance, lesion area, spores per lesion at 9, 18 and 36
days after inoculation, and reproductive efficiency
(ratio of spores produced to inoculum applied) differed
among cultivars and over leaf ages. Cultivar by leaf
age interactions were present for infection efficiency,
days to 50% of lesions present, spores per lesion at

all three dates, and reproductive efficiency. Much.of
the interaction for each component was attributed to
differences between the three species. Measurements

of lesion area, lesions per leaf, days to 50% of

lesions present and leaf age predicted spores per

lesion at 9 days (R2 = 0.33), 18 days (R2 = 0.70) and

36 days (R2 = 0.86) after inoculation. Field resistance
to defoliation in these cultivars was highly correlated
with the components days to 50% of lesions present

(r = -0.70), rate of lesion appearance (r = 0.79),
lesion area (r = 0.81), spores per lesion (r = 0.78) and

reproductive efficiency (r = 0.82).

38

Introduction

 

Cherry leaf spot, caused by Coccomyces hiemalis Higg.,
is a widespread fungal disease of cultivated cherries. Resistance
to Q. hiemalis has been reported in cultivars of sweet cherry

(Prunus avium L.). sour cherry (E, cerasus L.) and duke cherry

 

(P. gondouinii Rehd.) (1,2,7,12,14,16). P, avigm_cultivars are
generally more resistant to defoliation by Q, hiemalis than either
.3. gondouinii or g. cerasus cultivars (12). Most cultivars in

these studies were susceptible to infection by g, hiemalis, but
differed quantitatively in percent of leaves infected and/or defoli-
ated. This type of resistance has been termed partial resistance
(10).

Factors that directly or indirectly measure the ability of the
pathogen to reproduce on the host are called components of resistance,
and are often strongly correlated with differences in partial resis-
tance in the field (9). The purpose of this study was to identify
components of resistance in cultivars of E, avium, P. cerasus and P.
gondouinii. In addition, the relationship of these components to
previously reported disease severity of the same cultivars (12) was

examined.

Materials and Methods

 

Plant material. Cultivars and selections of P. avium,

 

P, cerasus and E. gondouinii were chip budded onto seedling root-
stocks of P. mahaleb L. Budwood of all cultivars was obtained as

previously described (12).

39

Trees for each experiment were grown in 3.7-L containers in
a greenhouse at 15-30 C. Trees for experiment one were grown in a
mixture of soil and perlite (2:1, v/v), and fertilized biweekly with
a 5.3 g/L solution of 20% N-20% P203-20% K20 fertilizer (Robert B.
Peters Co., Inc., Allentown, PA 18104). Trees for experiment two
were grown in a mixture of sand, peat moss, and perlite (1:1:1, v/v)
and fertilized once with 5.25 g of 19% N-6% P205-12% K20 controlled
release fertilizer (Osmocote, Sierra Chemical Co., Milpitas, CA 95035)
per container plus 0.75 g of sustained released micronutrient mixture
(Esmigran, Mallinckrodt Inc., St. Louis, MO 63147) per container.

All trees were grown as a single vegetative shoot by cutting
back to a single vegetative bud and removing lateral shoots at weekly
intervals. Because there is a relationship of leaf age to infection
frequency by Q. hiemalis in P. cerasus (5), the age of each leaf was
calculated from the date of unfolding, i.e., when the laminar blades
were separated by an angle greater than 90°. All leaves unfolding
within a 4-day period were assigned to the same age group. The age
of a leaf was the average number of days from unfolding to inocula-
tion. Thus, each tree had a range of leaf ages present at the time

of inoculation.

Inoculum. A single-conidium isolate of_Q. hiemalis (isolate
B) from naturally infected P. cerasus 'Montmorency' leaves in a
commercial orchard near Decatur, Michigan, was used in both experi-
ments. The isolate was maintained by periodically inoculating young

leaves of 'Montmorency' trees grown in the greenhouse, or by freezing

40

leaves bearing sporulating lesions at -20 C for a maximum of 6 months.
Inoculum used for each experiment was washed from 2- to 3-week old

lesions on leaves that had not been frozen.

Experiment 1. Components of resistance to C, hiemalis were

 

determined for six cultivars of P. cerasus and two of E. gondouinii

 

in a split-plot design. Cultivars were the whole units, blocked by
time of inoculation into three single-tree replications, and leaf ages
were subunits. A single leaf in each of four age groups,6.5,10.5,14.5,
and 18.5 days, was inoculated on each tree. The area of each leaf
was measured with an area meter (Model LI-3000, Lambda Instrument
Corp., Lincoln, NE 68504) on the day of inoculation.

Leaves were inoculated with a conidial suspension of Q.
hiemalis in distilled-deionized water. The suspension was adjusted
to 105 conidia per ml with a hemacytometer. The conidial suspension
was sprayed uniformly onto the undersurface of each leaf with an
atomizer (The DeVilbis Co., Somerset, PA 15501) Operated at 0.7 bar.
Within 5 min after inoculation, trees were placed in a mist chamber
at 19 to 21 C for 48 hr. Trees were then incubated in a cheesecloth
tent on a greenhouse bench covered with 6 cm of sand. The cheese-
cloth and sand were wetted daily to maintain a high relative humidity
around the plants. The mean temperature during incubation was 23 C
(range 17-30 C).

Lesions per leaf were counted at 6 and 16 days after inocula-
tion. Infection frequency was expressed as the number of lesions per

cm2 of leaf area at inoculation. The proportion of lesions on day 6

41

was the number of lesions on day 6 divided by the number of lesions
on day 16. The leaves were removed 20 days after inoculation and
frozen at -20 C for further analysis.

Sizes of lesions were measured at 20 days with a binocular
dissecting microscope fitted with a calibrated ocular micrometer.
Length by width measurements were made on five randomly chosen lesions
per leaf, and the lesion area was calculated as a rectangle, square
or right triangle.

Spore production was measured at 20 days by washing conidia
from each leaf into 40 ml water. Six samples from each spore wash
were counted with a hemacytometer and spore production was expressed
as spores per lesion basis and as spores per cm2 of leaf area at
inoculation.

Log]0 transformations were made on lesion areas, spores per

2 data prior to analysis of variance to elim-

lesion and spores per cm
inate proportionality between means and their standard deviations (8).
The relationship of spores per lesion to other variables was examined

by stepwise multiple regression analysis (3).

Experiment 2. Components of resistance to C, hiemalis were

 

determined for ten cultivars of P. avium, five of P. cerasus and five
of E. gondouinii in a split-plot design. Cultivars were the whole
units, blocked by time of inoculation with Q. hiemalis into four single
tree replicates, and three leaf age groups, 7.5, 19.5 and 31.5 days,

were subunits.

42

A single leaf in each age group on each tree was inoculated
with a Schein quantitative inoculator (11) modified by addition of
an electronic timer to operate the solenoid valve. Two circular

2 were inoculated on each leaf. A DeVilbiss atomizer

areas 2.1 cm
containing a 105 conidia/ml suspension of Q, hiemalis was positioned
43 cm from the leaf undersurface and operated for 1 sec at 1.4 bar
(1.4 atm). The number of conidia deposited on each leaf was estimated
by periodically inoculating sections (1.5 by 1.5 cm) of membrane fil-
ters (0.45 u pore size) placed on 2% water agar. Four sections were
inoculated per replication and incubated in glass petri dishes in the
mist chamber containing the inoculated trees for 48 hr. Germinating
and total numbers of spores were counted in five random light micro-
scope fields at 200x (0.88 mm diameter) for each section. Average
number of conidia deposited on filter sections varied from 9600 to
11300 for the four replications. Germination of conidia on filter
sections exceeded 90% for all replications.

Immediately after inoculation the trees were placed into a
mist chamber for 48 hr at 18 to 21 C. Trees were then incubated as
described for experiment 1 at 17 C (range 7-24 C).

Lesions per leaf were counted 3 days after inoculation and
at l to 3 day intervals for 20 days. Total lesions per leaf were
determined 36 days after inoculation. Infection efficiency was cal-
culated as the number of lesions per leaf divided by the number of
spores applied to each leaf (11). Rate and time of lesion appearance
were estimated from lesion count data by an asymptotic curve,

-(bX +

Y = l-e a)’ using the equivalent form, ln(T}V) = bX f a, to

43

fit a linear regression line where x = number of days after inocula-
tion, Y = lesions present at day X as a proportion of the total,

b = slope of the regression line, and a = intercept of the regression
line. Estimates of days to 50% of lesions present and rate of lesion
appearance (slope of the regression line) were made for each leaf
and subjected to analysis of variance, using loge transformed values
for date of 50% lesions.

Lesion areas were determined 36 days after inoculation as
described for experiment 1, and the data were log10 transformed prior
to analysis of variance.

Spore production was measured at 9, 18 and 36 days after
inoculation. At 9 and 18 days, conidia were washed from each inocu-
lated leaf into 9 ml distilled deionized water with a DeVilbiss
atomizer operated at 0.7 bar. One ml of 2% (w/v) formaldehyde plus
1% (v/v) polyoxyethylene sorbitan monolaurate (Tween 20, Sigma Chem.
Co., St. Louis, MO 63178) in distilled deionized water was added to
each spore suspension to preserve the spores and minimize adherence
of spores to glass surfaces. At 36 days, conidia were removed by
immersing the inoculated area of each leaf into 5 m1 of 2% (w/v)
formaldehyde plus 0.1% (v/v) Tween 20 in distilled deionized water.
Samples were stored at 2 C until counted.

Numbers of conidia in each sample were estimated by measuring
absorbance of the spore suspensions at 700 nm with a dual beam spec-
trophotometer (model DB-G, Beckman Instruments, Inc., Fullerton,

CA 92634). A standard curve relating absorbance to hemacytometer

44

counts was developed for each set of samples measured on a given
day. Hemacytometer counts were estimated from absorbance by a power
curve, Y = bAm, using the equivalent form, log10 Y = log1o b + m

absorbance at

(log10 A), to fit a linear regression line where A
700nm and Y = hemacytometer count, b = intercept and m = slope of
linear regression line.

Spore production was expressed as spores per lesion and as
reproductive efficiency (defined as the number of spores produced
divided by the number of spores applied as inoculum). Both measure-
ments were log10 transformed prior to analysis of variance. In addi-
tion, the relationship of spores per lesion to other variables was
examined by stepwise multiple regression analysis.

Cultivar and cultivar x leaf age interactions in experiment 2
were partitioned into planned orthogonal comparisons (8) of _P_. m
cultivars versus the combination of_P. cerasus and P. gondouinii

cultivars and_fi. cerasus cultivars versus 3, gondouinii cultivars.

 

The basis for these comparisons was the reported higher level of
resistance among P. avium cultivars relative to P. cerasus and E,

gondouinii cultivars (12).

 

Correlations between these components of resistance and
evaluations of field resistance were determined for 19 of the 20 cul-
tivars in experiment 2 (field resistance evaluations were not avail-
able for P. aligm 'Angela'). Simple correlations were made between
each component of resistance and both the infection severity and the

defoliation severity reported for these cultivars (12).

45

Results

Experiment 1. Infection frequency at 6 (but not 16) days

 

after inoculation, size of lesions, numbers of spores per lesion and
per cm2 of inoculated leaf differed significantly among the eight
cultivars (Table l). The proportion of lesions present 6 days after
inoculation was significantly lower for P. cerasus 'SHT-Z' than for
the other P. cerasus cultivars.

Size of lesions showed a highly significant quadratic trend
with increasing leaf age. Lesions were largest in 14.5-day-old leaves;
however, a significant cultivar x leaf age interaction indicated that
not all cultivars showed the same trend.

Numbers of spores per lesion decreased linearly with increas-
ing leaf age; however, cultivar x leaf age interactions were present.
Much of this interaction was due to the significantly lower number
of spores per lesion in the 6.5-day-old leaves of North Star (2.63 x
104) and Kansas Sweet (2.40 x 104) compared to 10.5-day-old leaves

4 4

(3.39 x 10 and 3.20 x 10 for North Star and Kansas Sweet, respec-

tively). In contrast, numbers of spores were highest for lesions
in 6.5-day-old leaves of all other cultivars (average of 6.74 x 104),
and lower in 10.5-day-old leaves (5.20 x 104).

2

Numbers of spores per cm of inoculated leaf varied 5-fold

from 4.79 x 104 for Kansas Sweet to 2.57 x 105 for Meteor (Table l).
Cultivar x leaf age interactions were also present, mainly due to the
low number of spores per lesion in 6.5-day-old leaves of North Star

2

and Kansas Sweet. Number of spores per cm decreased linearly with

increasing leaf age in inoculated leaves of all other cultivars.

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47

Sporulation was related to the proportion of lesions present
6 days after inoculation and size of lesions. Simple correlations
of log spores per lesion with log lesion area (r = 0.76) and pro-
portion of lesions present (r = 0.55) were highly significant. A
multiple regression equation including lesion area, proportion of
lesions present 6 days after inoculation, and leaf age accounted for

67.9% of the total variation in spores per lesion.

Experiment 2. Highly significant differences existed among

 

the cultivars for each component of resistance (Tables 2 and 3).
Leaf age effects were also significant or highly significant for each
component. Cultivar x leaf age interactions were detected for time
of 50% lesion appearance, numbers of spores per lesion on each date
of sampling, infection efficiency, and reproductive efficiency.

The average infection efficiency for the 20 cultivars was

0.91% with a range from 0.48% (E, gondouinii 'Brassington Duke') to

 

1.51% (E. avium 'Governor Wood'). Planned comparisons between species
averaged over all leaf ages did not differ significantly. HOwever,

a significant portion of the cultivar x leaf age interaction could be
attributed to comparisons between species (Figure 1). .3..avium_culti-
vars showed a generally linear trend of decreasing infection effi-
ciency with increasing leaf age, while the trends with P. gondouinii
and_P. cerasus cultivars were strongly nonlinear. Infection effi-
ciencies were highest in 19.5-day-old leaves of E. cerasus cultivars,

but were slightly higher in 7.5- than in 19.5-day-old leaves of

48

 

 

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.mo.o u m..nmeu emcee ewewuwes w.eeo:=n an mcsepeo cwnuwz cewueeeeem nee—e:fl

.eewweee seweoeee en newueweoeew eeewe whee mm weep ewe :eeeoeeeee weeem Peeee we ewuemx

.ceweeweoenw eeuwe exec;

.wwme weep ween» ew>e eemeee>e mceweeowweee weeu1wpmcwm eeew we neez>

 

eme weep x ee>wep=o

 

 

 

a; ecw .3. .1
«a. as... t... «a. mom wew.—
.I. «a. «a. Ne}. 93> .5 :6
wonewee> we wwwapece Eeew emee-e we woneowwwnmwm
xfimewv mxee on when mp sweee m
xocewowwwe ee>wupeo mewowem
w>eeoeeeeewm Amewv cewmep ewe meeeem

 

.emscwucou11.m mnm<h

52

Figure 1. Relationship of infection efficiency to leaf age in
cultivars of three Prunus species inoculated with
Coccomyces hiemalis.

 

53

 

 

 

 

 

 

 

 

"m 1
m 8 o
u a d
.I f n
v o o
l C C-
w" on. e”.
n u
u _ _
u _ I
_ p _
o s o. s. 6.
9m 1. 1 O 0
ahzmocmn: >Ozm_0.n_u_w 20....0mn—z_

31.5

19.5

7.5

(DAYS)

LEAF AGE

54

.P. gondouinii cultivars. All cultivars showed a large reduction in
infection efficiency in 31.5-day-old leaves.

Differences among cultivars in number of days to 50% of
lesions present were highly significant. Comparisons between species
were significant at each leaf age, and were greatest in 3.15-day-old
leaves (Figure 2). The cultivar x leaf age interaction was largely
due to differences among species, rather than differences within
species.

Rate of lesion appearance was significantly slower (p = 0.01)
for E, gyium_cultivars (0.44) than for P. cerasus (0.75) and E.
gondouinii (0.65) cultivars. Differences between P. cerasus and
.3. gondouinii cultivars were not significant. The rate of lesion
appearance decreased linearly with increasing leaf age when averaged
over all cultivars.

Average lesion areas 36 days after inoculation were signifi-
cantly smaller (2 = 0.01) for P, gyigm cultivars (0.22 mmz) compared

to_£. cerasus (1.24 mm2) and E, gondouinii (0.88 mmz) cultivars.

 

Differences between E. cerasus and P. gondouinii cultivars were also

 

highly significant. Averaged over all cultivars, log lesion area
increased linearly with increasing leaf age.

Large differences were observed among cultivars in spore
production per lesion at all three dates of sampling (Table 3). The
significantly lower (9 = 0.01) spore production in lesions of P. avigm

cultivars compared to E. cerasus and E, gondouinii cultivars accounted

 

for much of the difference among cultivars. In addition, spore

55

Figure 2. Relationship of time of lesion appearance to leaf age in
cultivars of three Prunus species inoculated with
Coccomyces hiemalis.

 

DAYS TO 50 % OF LESIONS

 

 

 

..... .. _. Ivlum .0.
0..
E. cerasus
___ g. ondoulnn

\\“.’

 

7'5 19.5 31.5

 

57

production in E. cerasus cultivars was significantly greater than that

in _P. @ndouinii cultivars.

 

Combined analysis of spores per lesion data over all three
dates of sampling indicated that there were highly significant culti-
var x leaf age and cultivar x date of sampling interactions. In addi-
tion, significant leaf age x date of sampling interactions were
present.

A large portion of the cultivar x leaf age interaction could
again be attributed to significant differences in the linear and non-
linear trends 0f.E:.E!i!fl cultivars compared to P. cerasus and E.
gondouinii cultivars (Figure 3). In addition, comparisons between
.3. cerasus and P. gondouinii indicate that P. gondouinii cultivars
show a linear trend of increasing spores per lesion with increasing
leaf age, whereas 3. cerasus cultivars show little indication of a
linear trend.

0n the basis of the results of experiment 1, numbers of
spores per lesion as a function of leaf age for_P. cerasus 'North
Star' were compared to the mean of the other_P. cerasus cultivars.
Numbers of spores in leaves of North Star were significantly less
than those of the other cultivars at each leaf age. In North Star,
numbers of spores per lesion increased logarithmically with increas-
ing leaf age (4.57 x 102, 1.20 x 103, and 2.09 x 103 for 7.5-, 19.5-
and 31.5-day-old leaves, respectively). However, numbers of spores
were higher in 7.5-day-old leaves (8.91 x 103) than in 19.5-day-old
(4.79 x 103) or 31.5-day-old leaves (7.08 x 103) of the other culti-

VdY‘S .

Figure 3.

58

Relationship of spores per lesion averaged over three
sampling times (9, 18 and 36 days after inoculation)
to leaf age in cultivars of three Prunus species
inoculated with Coccomyces hiemalis.

 

(LOG)

SPORES PER LESION

59

 

-

 

u IIIII £- I'lum
— _P_. cerasus

-—- _P_. mdoulnll

 

7.5 10.5 31.5
LEAF AGE (DAYS)

 

60

The triple order interaction of cultivar x leaf age x date of
sampling for spores per lesions was attributed in large part to
between-species comparisons. The general trend was for sporulation
to increase logarithmically between dates of sampling. However,
numbers of spores per lesion were lowest for youngest age leaves
(7.5-day-old) in all three species at 9 days after inoculation while
they were lowest for intermediate age leaves (19.5-day-old) at 18 and
36 days after inoculation. Much of this interaction is explained by
differences in the slopes of the linear regression of log spores per
lesion against log days after inoculation for each species at each
leaf age (Figure 4). Overall, the rate (slope of regression line) of
increase in spores per lesion as a function of days after inoculation

was significantly less (p_= 0.01) for P. avium cultivars than for

 

.P. cerasus and E. gondouinii cultivars.

Reproductive efficiency (ratio of spores produced to inoculum
applied) differed greatly among the three species at 36 days after
inoculation. The average reproductive efficiency of E. gyium culti-
vars (5.84) was significantly less (0 = 0.01) than that of P. cerasus
and P. gondouinii cultivars. The average reproductive efficiency of
.E- cerasus cultivars (285.23) was significantly greater (9 = 0.01)
than that of P. gondouinii cultivars (142.25). Log reproductive
efficiency averaged over all cultivars decreased linearly (p_= 0.01)
with increasing leaf age; however, the slope of this linear trend
differed among the three species (Figure 5). .P.‘gvigm;cultivars

showed a much greater rate of decrease than B. cerasus and

61

Figure 4. Relationship of spores per lesion to days after
inoculation for three leaf ages in cultivars of three
Prunus species inoculated with Coccomyces hiemalis.

 

(LOG)

62

 

A 7.5 day O|d Ie°ves

     

- .ooi..‘..6‘
5”::...... “
- 6”"

 

B 19.5 day old leaves

 

 

 

 
 
 

IOOCDIOIUIIOIOUOD

III-ICCCCOQUCOODII.

 

coo-or.
' /
5”,
l O
1 use... 2. w
.. — g. car—me
-_- 2' Miami—i
J J l
9 ll 36

DAYS AFTER INOCULATION

 

63

,E-,ggflgggigii cultivars. The trend with P. cerasus and P, gondouinii

 

cultivars appeared to be nonlinear.

Numbers of spores per lesion were correlated with several
other variables in experiment 2. Highly significant negative corre-
lations were observed between either log time of 50% lesion appear-
ance or log lesions per leaf, and log spores per lesion at 9, 18 and
36 days after inoculation. Highly significant positive correlations
were observed between log lesion area, and log spores per lesion at
each time of evaluation. Multiple regression equations that included
the lesion area, lesions per leaf, time of 50% lesion appearance and
leaf age as independent variables accounted for 33%, 70%, and 86% of
the total variation hispores per lesion at 9, 18, and 36 days after
inoculation, respectively.

Simple correlations with the reported defoliation severity
of 19 of the 20 cultivars in experiment 2 (field resistance ratings
not available for P. avium 'Angela') were highly significant for
each component of resistance except infection efficiency (Table 4).
Correlations with infection severity were not significant for all

components of resistance.

Discussion

 

Diseases caused by pathogens such as C, hiemalis with more
than one reproductive cycle per season are called Pcompound interest
diseasesf (15). The severity of a compound interest disease is the
cumulative effect of environmental factors, the level of initial

inoculum, genetic factors affecting reproduction of the pathogen

64

Figure 5. Relationship of reproductive efficiency (ratio of spore
production to inoculum applied) to leaf age in cultivars
of three Prunus species inoculated with Coccomyces
hiemalis.

(LOG)

REPRODUCTIVE EFFICIENCY

65

 

 

 

 

 

 

O.
O
O
Q
Q
Q
Q
Q
Q
Q
Q
Q
Q
Q
9
C
O
Q
O
O
O
O
O.
..
O...
O.
O.
Q.
0..
O...
.....
a I 5 I 9 I 5

LEAF AGE (DAYS)

 

66

TABLE 4.--Correlations of components of resistance with the reported
field resistance of 19 cherry cultivars."

 

Field resistance parameterw

 

Component of

 

resistanceV infection defoliation
severity severity

Infection efficiency .099 n.s.z .313 n.s.

Days to 50% of lesions -.091 n.s. -.704**

Rate of lesion appearance .261 n.s. .789**

Log (lesion area) .359 n.s. .808**

Log (spores per lesion)x .231 n.s. .782**

Log (reproductive efficiency)y .191 n.s. .815**

 

uCorrelations included each cultivar in experiment 2, except
P, avium 'Angela'.

vMean of four replications over three leaf ages for each cul-
tivar.

wMean of five replications for each cultivar.
xTotal spores per lesion 36 days after inoculation.
y36 days after inoculation.

zn.s., ** = correlation coefficient (r) not significant at
.p = 0.05 or significant at.p = 0.01, respectively.

67

on its host (components of resistance and pathogenicity), and the
ability of the host to endure the presence of the pathogen (tolerance).
Prediction of disease severity for a compound interest disease
requires an understanding of each of these factors and their inter-
relationships.

A model has been developed which predicts infection of
Montmorency sour cherry from measurements of leaf wetness duration and
air temperature (4). The components of resistance measured in this
study should allow incorporation of a host resistance factor into the
model. The model would then predict not only infection, but also the
relative amount of inoculum present at the next infection period. The
effect of changes in host resistance components on disease severity
could be predicted in different simulated environments. These pre-
dictions could then be used to establish the level of resistance (or
component of resistance) needed in a breeding program.

Prediction of leaf spot severity must also account for
changes in resistance due to leaf age (6). The highly significant
cultivar x leaf age interactions in the present study indicate that
the effect of leaf age is.not uniform over all genotypes. Most of
this interaction could be attributed to differences between species
(Figures 1 to 5), but some important differences within species
remained. For example, sporulation in lesions on young leaves of
North Star sour cherry was considerably lower than that in older
leaves, but sporulation was generally highest in youngest leaves of

other sour cherry cultivars. Thus, prediction of relative leaf spot

68

severity among cultivars or species requires that adjustment be made
for changes in relative proportions of leaf age classes during the
growing season (5). Also, the level of resistance of a cultivar
under conditions of vigorous vegetative growth (where leaf emergence
would cease later in the season) may be quite different from that
under a less vigorous condition due to differences in the relative
proportion of leaf age classes.

Identification of components of resistance contributing to
observed differences in field resistance provides a systematic
approach to breeding for partial resistance. The components can be
selected in a breeding program following artificial inoculation under
controlled conditions. However, associations between components must
be considered. For example, a negative correlation was observed
between spore production per lesion and lesion number per inoculated
area in these studies. Selection based solely on fewer spores per
lesion (or smaller lesion size) could lead to indirect selection for
increased infection efficiency. A better selection criterion is
reproductive efficiency, which is the combined effect of the com-
ponents of infection efficiency and spores per lesion. Reduced
reproductive efficiency could be due to reduced infection efficiency
or reduced spore production or both. In addition, reproductive
efficiency in these studies was measured more rapidly than any other
component when a quantitative inoculator (11) was used and spore
production was estimated by absorbance measurements of spore washes.

Improvement in the level of partial resistance in these

cherry species should be possible by selection for components of

69

resistance. Genetic variation was large for each component in
experiment 2, except infection efficiency. Reproductive efficiency
differed 500-fold among the cultivars at 36 days after inoculation
(Table 3). However, the rate of improvement in resistance will be
affected by the number and nature of the genes controlling expression
of the component selected. Initial studies of the inheritance of
components of resistance in juvenile seedlings of P. cerasus and

£5 gondouinii indicate that heritabilities calculated on an indi-

 

vidual plant basis are quite low (13), suggesting that the rate of
improvement will be slow. This study should be considered only pre-
liminary, though, because there were large differences from experi-
ment to experiment in expression of resistance among progenies. More
work is needed to determine the applicability of this approach to

breeding leaf spot resistant cherries.

10.

11.

LITERATURE CITED

Anonymous. 1976. Field resistance of sour cherry and cherry
varieties to coccomycosis under the conditions of the Crimea
(in Russian). Sadovodstvo 24: 51-61. Abstracted in Rev. Plant
Path. 56: 3634 (1977).

Daugis, M. 1962. Some data on varietal resistance in cherry
to coccomycosis in the conditions of the Latvian S.S.R. (in
Russian). Pages 148-149 in: Brief Summaries of Research Work
on Plant Protection in the Baltic Zone of the U.S.S.R., vol. 4
(1961). Abstracted in Rev. Appl. Mycol. 45: 940x (1966).

Draper, N. R. and H. Smith. 1966. Applied Regression Analysis.
John Wiley & Sons, New York. 407 pp.

Eisensmith, S. P. and A. L. Jones. 1981. A model for detecting
infection periods of Coccomyces hiemalis on sour cherry.
Phytopathology 71: 728-732.

 

Eisensmith, S. P., A. L. Jones and J. A. Flore. 1980. Predict-
ing leaf emergence of 'Montmorency' sour cherry form degree-day
accumulations. J. Amer. Soc. Hort. Sci. 105: 75-78.

Eisensmith, S. P., T. M. Sjulin, A. L. Jones and C. E. Cress.
1981. Effects of leaf age and inoculum concentration on infec-
tion of Sour cherry by Coccomyces hiemalis. Phytopathology 71;
(in press).

 

Kan'shina, M. V. and A. I. Astakhov. 1979. The resistance of
sour cherries to cherry leaf spot (in Russian). Zaschita
Rastenii 6: 29. Abstracted in Hort. Abstr. 49: 711 (1979).

Little, T. M. and F. J. Hills. 1978. Agricultural Experimenta-
tion. John Wiley & Sons, New York. 350 pp.

Parlevliet, J. E. 1979. Components of resistance that reduce
the rate of epidemic development. Ann. Rev. Phytopathol. 17:
203-222.

Robinson, R. A. 1969. Disease resistance terminology. Rev.
Appl. Mycol. 48: 593-606.

Schein, R. D. 1964. Design, performance and use of a quantita-
tive inoculator. Phytopathology 54: 509-513.

70

12.

13.

14.

15.

16.

71

Sjulin, T. M. 1981. Field resistance of cherry cultivars and
selections to Coccomyces hiemalis. Chapter I of this disserta-
tion.

 

Sjulin, T. M. 1981. Inheritance of resistance to Coccomyces

hiemalis in juvenile seedlings of cherry. Chapter II o t is

dissertation.

Timoshenko, S. E. 1977. The resistance of different sweet cherry
cultivars and hybrids to cherry leaf spot (in Russian). Trudy
Stavropol'sk NII S.-Kh. 48: 76-82. Abstracted in Hort. Abstr.

49: 420 (1979).

Van der Plank, J. E. 1963. Plant Diseases: Epidemics and
Control. Academic Press, New York. 349 pp.

Zekovic, P. and D. Vuletic. 1975. A contribution to the knowl-
edge of susceptibility of different sorts of cherries and sour
cherries to Coccomyces hiemalis Higg. in Metohiza (in Hungarian
with English summary): Zastita Bilja 26: 79-83.

 

CHAPTER III

INHERITANCE OF RESISTANCE TO COCCOMYCES HIEMALIS
IN JUVENILE SEEDLINGS OF CHERRY

72

CHAPTER III

INHERITANCE OF RESISTANCE TO COCCOMYCES HIEMALIS
IN JUVENILE SEEDLINGS OF CHERRY

Abstract

Components of resistance to Coccomyces hiemalis Higg.
of infection efficiency, lesion area, spores per lesion
and reproductive efficiency were studied in an incomplete

diallel of four Prunus cerasus L. cultivars and one P.

 

(gondouinii Rehd. cultivar. A total of 342 progeny from 14

 

families plus clonal parent material were inoculated in
a series of three experiments that differed in average
age of plants. All components of resistance differed
among both parents and families. Mean values for each
component differed from experiment to experiment in
both parents and progenies. Experiment by family inter-
actions were present in all components except spores
per lesion. No genetic variation between families was
detected in the first experiment involving the young-
est seedlings. General and specific combining ability
effects were present among families in the second
experiment. Only general combining ability effects

were detected in the third experiment. P, cerasus

73

74

'North Star' had the highest breeding value for reducing
spores per lesion and reproductive efficiency. Overall
broad-sense heritabilities calculated on a single-plant
basis were less than 0.5 for all components except lesion

area in progeny.

Introduction
Cherry leaf spot, caused by Coccomyces hiemalis, is a serious

fungal disease of sour cherry (Prunus cerasus) throughout the world

 

(3). Yield, vegetative growth, and wood and bud hardiness of sour
cherry are measurably reduced for up to two seasons following severe
defoliation by Q. hiemalis (5,8). 'Montmorency' sour cherry, the
predominant cultivar in the Michigan sour cherry industry (2), is
very susceptible to defoliation by Q. hiemalis (14). Increased resis-
tance to Q. hiemalis is an important objective of the sour cherry
breeding program at Michigan State University.

Previous work (4,9,13,14,17) has demonstrated that variation
for resistance to Q. hiemalis occurs within and among several species
of cultivated cherries. Complete resistance was not observed in most
of these studies. Instead, cultivars of sour cherry, sweet cherry
(E. ayium L.) and duke cherry (P, gondouinii) differed quantitatively
in the levels of partial resistance to Q. hiemalis, In addition,
factors associated with disease development, called components of
resistance, differed among cultivars of these species. Components
of resistance that measured lesion development and sporulation in

infected leaves were the best predictors of resistance in the field

(15).

75

Little information exists on the inheritance of resistance to
.9. hiemalis in cultivated cherries. Enikeyev (6) reported that cer-
tain cultivars of sweet and sour cherry were better parents than others
in breeding cherries resistant to C, hiemalis. Crosses involving
cultivars of the European ground cherry (P. fruticosa Pall.) gave
higher percentages of susceptible seedlings than crosses of E. cerasus
or P. am cultivars.

This research was undertaken to determine the inheritance of
components of resistance to C. hiemalis in progenies of cultivars of

_P. cerasus and P.gondouinii.

 

Materials and Methods

 

Plant material. An incomplete diallel of unequal progeny

 

numbers per cross was constructed in 1980 with 4 cultivars of P.
cerasus ('English Morello', 'Meteor', 'North Star' and 'HTO 405')

and 1 cultivar of P. gondouinii ('Kansas Sweet'). A total of 342

 

progeny from 14 crosses were used, with each parent represented in 4
to 6 crosses. Seeds from each cross were stratified at 1-4 C for

4-6 months until germination occurred. Germinated seeds were planted
in peat pellets (Jiffy-7, Jiffy Products Ltd., Norway) covered with
perlite in presterilized flats in a greenhouse at 181:6 C. Seedlings
were transplanted at the 1- to 3-1eaf stage in January, 1981, into
sand:peat:per1ite (1:1:1, v/v) in lO-cm diameter clay pots, and
fertilized with 5 g/L solution of 20% N-20% P205-20% K20 fertilizer
(Robert B. Peters, Co., Inc., Allentown, PA 18104) plus 1.3 g per pot
of 19% N-6% P205-12% K20 controlled release fertilizer (Osmocote,

76

Sierra Chemical Co., Milpitas, CA 95035). All seedlings were sprayed
prior to emergence of the inoculated leaf with four weekly applications
of 500 ppm gibberellic acid (Pro-Gibb, Abbott Laboratories, North
Chicago, IL 60064).

Single-shoot trees of each parent cultivar except 'HTO 405'
were grown as previously described (experiment 2 in (15)) hithe same
greenhouse as the seedlings. Parent performance of 'HTO 405',a bud
mutation of E. cerasus 'Montmorency' from Hilltop Orchards and
Nurseries, Inc., Hartford, MI 49057, was estimated with single-shoot
trees of 'Montmorency'. Three trees of each cultivar were included

as controls at each date of inoculation.

Inoculation. Seedlings were inoculated when 2- to 3-months

 

old in three separate experiments. Progeny from each cross were
divided into three approximately equal-number groups. Group one from
each cross was inoculated on March 11, 1981; group two was inoculated
on March 19, 1981; and group three was inoculated on March 27, 1981.
Previous studies have demonstrated that components of resis-
tance to g, hiemalis in Prunus species are affected by leaf age (15).
Therefore, a single leaf, 7- to l4-days old at the time of inocula-
tion, was inoculated with a modified Schein quantitative inoculator
as previously described (15). All plants were randomized prior to
inoculation. An average of 6360, 2150 and 2870 conidia per leaf were
applied in the March 11, March 19 and March 27 experiment, respec-
tively. Plants were placed into a mist chamber at 18-21 C for 48 hr
after inoculation, and then incubated in a cheesecloth tent in the

greenhouse (15) at 20 i 6 C.

77

Components of resistance. Infection efficiency, lesion area,

 

spores per lesion and reproductive efficiency were determined 20 days
after inoculation as previously described (15). Spore production

was estimated from the absorbance at 700 nm of spore suspensions (10).
A standard curve of hemacytometer counts of conidia to absorbance

was established for each experiment. Examination of residual pat-
terns and correlation coefficients indicated that spore counts in all
three experiments were best estimated by the linear and cubic terms

of absorbance measurements.

Data analysis. Analysis of variance for each component of

 

resistance were performed on parent and progeny data from each experi-
ment as well as the combined data for all experiments. Equal numbers
of progeny per experiment was assumed for a given cross in the analy-
sis of the combined progeny data (16, p. 477). Estimates of general
combining ability (GCA) and specific combining ability (SCA) were
made for each component of resistance in individual experiments by
Gilbert's procedure (7) for incomplete diallels with unequal numbers
of progeny per cross.

Broad-sense heritability estimates for each component of
resistance were calculated on an individual-plant basis from the
analysis of variance for parents and progenies in each experiment.
Parent estimates were calculated as follows:

2

_ x2 2 2
BS - Obc/(abc I awc)

h

78

2
be

between-clone component of variance and 63c is the within-clone

where hgs is the broad-sense heritability estimate, 6 is the

component of variance.

Progeny broad-sense heritabilities were calculated using 65c

as an estimate of environmental variance by the following equations:

2_2 2 2 2 2
“as ’ (a p l 6wp)/(6bp + 6up 1 wc)

2
hi)

the within-progeny component of variance. Coefficients of average

where 6 is the between-progeny component of variance and 65p is
progeny number in the expected mean squares were calculated assuming
random effects for samples of unequal sizes (16, p. 289).

Broad-sense heritabilities of the combined data from all
three experiments were corrected for clone by experiment and cross
by experiment interactions. The component of variance due to the
interaction of experiments with clones and experiments with crosses
was included in the denominator of the equations for broad-sense

heritabilities of parents and progenies, respectively.

Results
Cultivars differed significantly in all 4 components of
resistance (Table l). Cultivar by experiment interactions were not
significant, but significant (p = 0.01) experiment to experiment
variation was detected for each component. Although the relative
ranking of cultivars differed from experiment to experiment, the
components of infection efficiency, lesion area and reproductive

efficiency were lowest overall in 'Kansas Sweet'. 'North Star' had

79

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80

the highest average infection efficiency but the lowest value for
spores per lesion. The components of lesion area, spores per lesion
and reproductive efficiency were highest overall in 'Meteor'.

Families also differed significantly (p_= 0.01) for each
component of resistance. Highly significant family by experiment
interactions were present in each component of resistance except
spores per lesion. Variation from experiment to experiment averaged
over all families was highly significant for each component.

Analysis of progeny data from each experiment indicated that
the amount of genetic variation between families differed from
experiment to experiment. In experiment 1, mean values for each
component of resistance differed little among families (Table 2), and
estimates of total between-family variation, GCA and SCA were not
significant (Table 5). Differences among families were much greater
in experiments 2 and 3 for all components (Tables 3 & 4). Estimates
of total between-family variation, GCA and SCA were significant for
each component in experiment 2 (Table 6). Total between-family
variation, GCA but not SCA, were significant in experiment 3 (Table 7).

Parent GCA estimates for each component showed little con-
sistency from experiment to experiment (Table 8), but some trends
were apparent. 'North Star' progenies had fewer spores per lesion
in all experiments and lower reproductive efficiencies in experi-
ments 2 and 3. Lesion areas and spores per lesion were highest in
'Meteor' progenies in experiments 2 and 3, while infection efficiencies

were lowest for 'Meteor' in these same experiments.

81

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82

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83

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bility (GCA) estimates for components of resistance to

Coccomyces hiemalis in each experiment.

1n1ng a

TABLE 8.-General comb

 

 

Component of resistance GCA estimate (i standard error)

 

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yNumber of lesions/number of inoculum x 100.

2Number of spores/number of inoculum.

88

Broad-sense heritability estimates for both parents and
progenies varied considerably from experiment to experiment (Table 9).
Overall estimates on a single-plant basis are less than 0.5 for all
components except lesion areas in progenies (h:S = 0.68). Most of
the genetic variance for lesion areas in all three experiments was
attributed to the within-family rather than between-family variance

component.

Discussion

 

Selection for components of resistance has been suggested as
a means of increasing the level of partial resistance in cultivated
cherries to C. hiemalis (15). Reproductive efficiency, which is the
combined effect of the components of infection efficiency and spore
production, is highly correlated with measurements of field resistance
to defoliation in cherry. Reproductive efficiency can be measured
rapidly by inoculation of individual plants with a quantitative
inoculator and measurement of spore production from absorbance of
spore suspensions. It is estimated that the total time required to
measure leaf age, inoculate, and measure spore production is less than
ten minutes for each plant. Susceptible genotypes, if identified by
such a procedure, could be eliminated early in the breeding cycle,
thus increasing efficiency of land utilization in the breeding pro-
gram.

The adoption of this procedure to screen for partial resis-
tance to Q. hiemalis in cherry depends not only on deve10pment of

methods that rapidly eStimate components of resistance that contribute

89

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90

significantly to resistance in the field. The genetics of components
of resistance and factors affecting expression of that resistance

are also very important. The large experiment by family interactions
and the low heritabilities observed in this study question the suita-
bility of this approach to breeding cherries resistant to leaf spot.
Further work is needed to explain the nature of this interaction.

The low heritability estimates for components in experiment 1
relative to experiments 2 and 3 (Table 9) appear to be due to a lack
of expression of resistance in that experiment rather than increased
error. Although numbers of conidia inoculated and incubation condi-
tions varied from experiment to experiments, differences among
clonal parent cultivars were detected for most components of
resistance in each experiment (Table l). Coefficients of variation
within families were similar for all three experiments (Tables 5 to 7),
but the progeny means for families in experiment 1 differed little
for any component of resistance (Table 2). This lack of expression
of resistance could be related to age of the seedlings, which were
youngest, on average, in experiment 1. There may be a minimum plant
age for expression of resistance.

The mid-parent value for infection efficiency in each experi-
ment (based on clonal performance) was considerably less than the
overall progeny mean (Tables 2 to 4). This deviation could not be
consistently attributed to specific families, and may be an effect
of juvenility on expression of resistance. Increased susceptibility
of juvenile tissue to infection has been reported for other host-

pathogen combinations (12).

91

Progeny means for all components of resistance appear to be
continuous in nature. No evidence of discrete classes were observed
in any family. This would suggest that the genetic control of each
component is polygenic. The low heritabilities support this con-
clusion. It appears unlikely that an individual component of
resistance gene can be rapidly fixed in the breeding population.
However, the significant GCA effects observed in experiments 2 and 3 ‘
indicate that selection of parents will be effective in increasing the
level of partial resistance.

Of the five cultivars evaluated in this study, 'North Star'
appears to have the best breeding value for increasing partial resis-
tance to C. hiemalis. GCA estimates for spores per lesion and repro-
ductive efficiency were lowest for this cultivar in experiments 2
and 3. These components, in turn, are good indicators of field
resistance to defoliation (15). Crosses should be made involving
this cultivar to increase the level of resistance in the breeding
p0pulation. The method of identification of resistant genotypes
resulting from such crosses remains to be determined. Precise field
evaluation of partial resistance can be time consuming (14). The low
heritabilities observed in this study indicate that individual plant
selection by component of resistance evaluation will be ineffective.
Selection for traits with low heritabiities can be improved by
progeny tests or clonal family evaluations (1). It may be possible
to adapt these improved selection methods to greenhouse component of
resistance evaluations without greatly increasing the length of the

breeding cycle.

10.

11.

LITERATURE CITED

Andersen, R. L. 1971. Some quantitative genetic considerations
pertinent to breeding asexually propagated crops. Ph.D. thesis,
Univ. Minnesota, St. Paul. 147 pp.

Andersen, R. L. 1981. Cherry cultivar situation. Fruit Var.
J. 35: 83-92.

Anonymous. 1976. Distribution maps of plant diseases, no. 58,
ed. 4. Commonwealth Mycological Institute, Kew, England. 2 pp.

Anonymous. 1976. Field resistance of sour cherry and cherry
varieties to coccomycosis under the conditions of the Crimea
(in Russian). Sadovodstvo 24: 51-61. Abstracted in Rev. Plant
Path. 56: 3634 (1977).

Dutton, W. C. and H. M. Wells. 1925. Cherry leaf spot residual
effects and control. Mich. Agric. Expt. Sta. Special Bull.
147. 15 pp. ‘

Enikeyev, K. K. 1974. Resistance of cherry hybrid seedlings to
the leaf-spot disease (Coccomyces hiemalis). Proc. 19th Int.
Hort. Cong., Warsaw, Poland,Sept., 1974, vol. IA: 327 (Abstr.).

Gilbert, N. 1967. Additive combining abilities fitted to plant
breeding data. Biometrics 23: 45-49.

 

Howell, G. S., and S. S. Stackhouse. 1973. The effect of defolia-
tion time on acclimation and dehardening in tart cherry (Prunus

cerasus L.). J. Amer. Soc. Hort. Sci. 98: 132-136.

Kan'shina, M. V. and A. I. Astakhov. 1979. The resistance of
sour cherries to cherry leaf spot (in Russian). Zaschita
Rastenii 6: 29. Abstracted in Hort. Abstr. 49: 711 (1979).

Morris, S. C. and P. J. Nicholls. 1978. An evaluation of optical
density to estimate fungal spore concentrations in water suspen-
sions. Phytopathology 68: 1240-1242.

Parlevliet, J. E. 1979. Components of resistance that reduce

the rate of epidemic development. Ann. Rev. Phyt0pathol. 17:
203-222.

92

12.

13.

14.

15.

16.

17.

93

Populer, C. 1978. Changes in host susceptibility with time.
Pages 239-262 in: Horsfall, J. G. and E. B. Cowling, eds. Plant
Disease, an Advanced Treatise, vol. II. Academic Press, New York.

Reznikova, L. M. 1976. Resistance of cherry varieties to
coccomycosis (in Russian). Zaschita Rastenii 1: 56. Abstracted
in Rev. Plant Path. 55: 3660 (1976).

Sjulin, T. M. 1981. Field resistance of cherry cultivars and
selections to Coccomyces hiemalis. Chapter I of this disserta-
tion.

 

Sjulin, T. M. 1981. Components of partial resistance to
Coccomyces hiemalis in Prunus species. Chapter II of this dis-

 

sertation.

Snedecor, G. W. and W. G. Cochran. 1967. Statistical Methods,
6th ed. Iowa State Univ. Press, Ames. 593 pp.

Zekovic, P. and D. Vuletic. 1975. A contribution to the knowl-
edge of susceptibilty of different sorts of cherries and sour
cherries to Coccomyces hiemalis Higg. in Metohiza (in Hungarian
with English summary). liastita Bilja 26: 79-83.

 

CHAPTER IV

VARIABILITY OF COCCOMYCES HIEMALIS TO COMPONENTS

 

OF RESISTANCE IN PRUNUS SPECIES

94

CHAPTER IV

VARIABILITY OF COCCOMYCES HIEMALIS T0 COMPONENTS
OF RESISTANCE IN PRUNUS SPECIES

Abstract

Components of resistance to six isolates of Coccomyces

 

hiemalis were evaluated in eight cherry cultivars repre-
senting three Prunus species. Eight-fold differences in
infection efficiency were observed among 9. hiemalis
isolates averaged over all cultivars. Isolates also
differed in size of lesions produced, numbers of spores
per lesion and reproductive efficiency (ratio of spores
produced to inoculum applied) on hosts 20 days after
inoculation. Numbers of spores per lesion, averaged
over all isolates, varied 20-fold among the cultivars.
Infection efficiency, time of lesion appearance, lesion
size and reproductive efficiency also differed among
cultivars. Lesions on P, avium cultivars were smaller
with fewer spores per lesion than lesions on other cul-
tivars. Cultivar x isolate interactions were not sig-
nificant for all components of resistance. No evidence
of specific interaction of host resistance genes with

pathogen virulence genes was observed.

95

96

Introduction
Coccomyces hiemalis Higg. causes a serious leaf spot disease

of sour cherry (Prunus cerasus L.) and related cherry species in

 

Michigan and other cherry production regions in the world (1). Severe
infection by Q. hiemalis results in premature defoliation of trees.
This defoliation can measurably reduce yield, vegetative growth and
wood and bud hardiness of sour cherry (2,5).

Genetic differences exist among cultivars of sour cherry,
sweet cherry (E:.é!i!fl.L-) and duke cherry (P, gondouinii Rehd.)
in resistance to infection and defoliation by Q. hiemalis (15).
Greenhouse studies indicated that these differences were due in part
to components of resistance that affected lesion development and
sporulation in infected leaves (16).

Specialization by Q. hiemalis is known to occur at the
species level of the host (4,8). However, little information exists
on the relative ability of Q. hiemalis isolates to infect cultivated
cherries. Magie (12) observed large differences in the average abil-
ity of an isolate to infect and sporulate on cherry hosts, but no
consistent differences were found in relative virulence on a limited
number of hosts. The purpose of this research was to examine the
variability of Q. hiemalis isolates to previously identified differ-
ences in components of resistance in cultivars of three Prunus

species.

97

Materials and Methods

Plant material. Cultivars used in this study were selected
to represent a range in previously identified components of resistance
(16). Trees of four cultivars of E. cerasus (Montmorency, North
Star, Meteor and English Morello), one cultivar of P. gondouinii
(Kansas Sweet), and three cultivars of P, gyjum_(Governor Wood,
Napoleon and Yellow Glass) were grown on P. mahaleb L. rootstocks in
the greenhouse at 19 1 6 C as previously described (experiment 2 in

(16)), except that each tree was trained to have six lateral shoots.

Isolates of Coccomyces hiemalis. Six monoconidial isolates
collected from a range of cherry hosts and geographic areas were
used in this study. Each isolate came from sporulating lesions on
naturally infected hosts. Isolates were grown on an agar media con-
taining (per liter): KH2P04, 1.9 g; MgSO4 - 7H50,1.0 g, CaClz,

0.1 9; K HPO4, 0.1 9; 00504 9 5 H20, 1.0 mg; MnSO4 0 H20, 0.06 mg;

2
ZnClZ, 0.04 mg; Naz M004 - 2H20, 0.05 mg; H3B03, 0.06 mg; FeSO4 -

7 H20, 1.0 mg; NazEDTA, 1.2 mg; Thiamine HCl, 0.5 mg; Difco yeast
extract, 4.0 g; and sucrose, 20 g. Isolates were grown in culture
until sporulation occurred, and then maintained by periodically
inoculating young leaves of the same hosts from which they were iso-

lated. Leaves with sporulating lesions were frozen at -20 C up to

6 months between inoculations.

Inoculation. The experiment was conducted in a split-plot

 

design replicated five times with cultivars as the main plot blocked

98

by the time of inoculation. Isolates were the subplot with a single
leaf on each lateral shoot inoculated with one isolate. Only 11- to
l4-day-old leaves were inoculated.

Conidia of each isolate were washed from 2- to 3-week-old
sporulating lesions on infected leaves into distilled deionized water.
Concentration of each isolate was adjusted to approximately 105
conidia per ml by measuring absorbance of conidial suspensions at
700 nm (16). A single 2.1 cm2 area on each leaf was inoculated using
a modified Schein quantitative inoculator (14). Numbers of conidia
deposited per leaf for each isolate were estimated by counting conidia
deposited on a single membrane filter section (16) for each repli-
cation. Average number of conidia deposited on filter sections were
1400, 2500, 2000, 1800, 2300 and 1800 for isolates A, B, C. D, E and
F, respectively. Germination of all isolates on filter sections
exceeded 90%.

Trees were placed into a mist chamber immediately after

inoculation for 48 hr at 15 to 18 C. Trees were then incubated in a

cheesecloth tent on a greenhouse bench (16) at 18 C (range 13 to 23 C).

Components of resistance. Infection efficiency, lesion area,

 

and reproductive efficiency were determined 20 days after inoculation
as previously destribed (l6). Spores per lesion were determined by
hemacytometer counts of spores washed from leaves 20 days after
inoculation into 5 ml of 2% (w/v) formaldehyde plus 0.1% (v/v) poly-
oxyethylene sorbitan monolaurate (Tween 20, Sigma Chemical Co., St.

Louis, MO 63178) in distilled deionized water. Lesion areas, spores

99

per lesion and reproductive efficiency measurements were log.I0
transformed prior to analysis of variance to eliminate proportionality
between the means and their standard deviations (11).

Previous work indicated that theproportion of visible lesions
approaches the total number of lesions asymptotically with time after
inoculation (9,16). However, fitting an asymptotic curve to this
data was unsatisfactory due to the large number of leaves with 10 or
fewer total lesions. Therefore, the estimated time to 50% of lesions
present was calculated by an adaptation of the Spearman-Karber

method (3) for estimating LD50 for quantal response data:

Tl
LPSO = 12 (pi+] ' p1)((t1+] + t1)/2)

where LP50 is the natural log of the estimated number of days to 50%
of lesions present; ti is the natural log of days after inoculation

at evaluation 1; pi is the proportion of lesions present at evaluation
i; and i is l to 10. Lesions were counted at l to 2-day intervals

from 4 to 20 days after inoculation.

Data analysis. Data for each component of resistance were

 

subjected to analysis of variance. Evidence for the presence or
absence of specific interactions between isolates and hosts for each
component of resistance was determined by the significance of the

interaction term in the analysis of variance (l7).

100

Resu1ts

Significant interactions between isolates and hosts were not
detected in this experiment for any of the components of resistance
(Table 1). However, cultivars differed significantly for each com-
ponent of resistance. In addition, significant differences were
observed among isolates for infection efficiency, size of lesions,
numbers of spores per lesion and reproductive efficiency.

Isolates differed more than 8-fold in average infection effi-
ciency (Table 2). This large difference in infection efficiency
accounted for most of the difference in reproductive efficiency, as
isolates with high infection efficiencies (isolates B, C and 0) also
had high reproductive efficiencies. However, no consistent
relationship was observed between the average infection efficiency
and the size of lesions or numbers of spores per lesion, or between
size of lesions and numbers of spores per lesion (Table 2). For
example, average lesion area was largest for isolate A and smallest
for isolate F, but these isolates did not differ significantly in
infection efficiency. Furthermore, average lesion area did not
differ significantly between isolates D and E, but numbers of spores
per lesions did differ between these isolates.

Average infection efficiency varied 4-fold among the eight
cultivars, from 0.30% for_P. gondouinii 'Kansas Sweet' to 1.14% for
_P. alum 'Governor Wood' (Table 3). Numbers of spores per lesion

3

varied nearly 20-f01d among these cultivars, from 5.37 x 10 for

.E. avium 'Yellow Glass' to 1.02 x 105 for P. cerasus 'Meteor'. In

101

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104

general, large numbers of spores per lesion were associated with a
shorter time to lesion appearance, larger lesion areas and higher

reproductive efficiency (Table 3).

Discussion

 

The relative differences in components of resistance among
these cultivars averaged over all six isolates are reasonably consis-
tent with the differences previously reported using one of these
isolates (isolate 8) (l6). For example, the small lesions with
fewer spores per lesion found in leaves of E, angm_cultivars are
typical for this species. In addition, the reduced sporulation and
reproductive efficiency in leaves of 'Kansas Sweet' and 'North Star'
compared to 'Montmorency', 'Meteor' and 'English Morello' confirm
earlier observations made in young leaves of these cultivars. How-
ever, differences between E, axium_cultivars and the other cultivars
in days to 50% lesion appearance (Table 3) are less than that pre-
viously reported. This discrepancy may be due to differences in the
methods used to calculate time of lesion appearance, or it may reflect
experiment to experiment variation. In general, though, Components
of resistance in these Eguggg species were accurately estimated by
individual isolates of Q. hiemalis. Identification of resistant
cultivars by components of resistance analysis (16) would be greatly
simplified by the use of single isolates.

The absence of significant cultivar x isolate interactions,
plus large differences among both cultivars and isolates in components
of resistance, suggest that resistance in these cherry species is

race-nonspecific in nature (17). However, major limitations to this

105

work must be resolved before it can be concluded that partial resis-
tance in cherry is stable against all genotypes of Q, hiemalis.

First, this study tested only a small sample of Q. hiemalis genotypes.
A larger number of isolates from a wider range of hosts and geographic
locations should be tested. Second, the statistical test for inter-
actions used in this study is an average test (ll). Biologically
significant cultivar x isolate interactions may be masked by a greater
number of insignificant interactions. Prior knowledge about these
isolates could have led to logical single degree of freedom com-
parisons within the 35 degrees of freedom for interaction variance in
this study. Planned comparisons of this type have demonstrated sig-
nificant cultivar x isolate interactions when none were detected by

an average test over all interactions (ID).

A more serious objection to the interaction test was raised by
Parlevliet and Zadoks (13). A model in which genes for partial resis-
tance interacted in a gene-for-gene manner with genes for virulence
in the pathogen indicated that only a small portion of non-environmental
variance would be attributed to the interaction variance. Most of the
variance was present as main effects. They concluded that the absence
of significant interactions is more an indication of polygenic resis-
tance than evidence of race-nonspecific resistance.

The best test of the stability of a resistance source is its
widespread use over a long period of time (6). Detection of erosion
in partial resistance can be enhanced by continual monitoring of the
pathogen population with a sensitive method of components of resis-

tance evaluation (7).

10.

11.

LITERATURE CITED

Anonymous. 1976. Distribution maps of plant diseases no. 58,
ed. 4. Commonwealth Mycological Institute, Kew, England. 2 pp.

Dutton, w. C. and H. M. Wells. 1925. Cherry leaf spot residual
effects and control. Mich. Agric. Expt. Sta. Special Bull. 147.

15 pp.

Finney, D. J. 1978. Statistical Methods in Biological Assay,
3rd ed. Charles Griffin & Co., London. 508 pp.

Higgins, B. B. l914. Contribution to the life history and
physiology of Cylindrosporium on stone fruits. Amer. J. Bot. l:
45- 73.

 

Howell, G. S. and S. S. Stackhouse. l973. The effect of defolia-
tion time on acclimation and dehardening in tart cherry (Prunus

cerasus L.). J. Amer. Soc. Hort. Sci. 98: 132-136.

Johnson, R. l981. Durable resistance: definition of, genetic
control, and attainment in plant breeding. Phytopathology 71:
567-568.

Johnson, R. and A. J. Taylor. 1976. Spore yields of pathogens
in investigations of the race-specificity of host resistance.
Ann. Rev. Phytopathol. 14: 97-119.

Keitt, G. w. 1918. Inoculation experiments with species of
Coccomyces from stone fruits. J. Agric. Res. 13: 539-569.

 

Keitt, G. M., E. C. Blodgett, E. E. Wilson and R. 0. Magie.
1937. The epidemiology and control of cherry leaf spot.
Univ. Misc. Agric. Expt. Sta. Res. Bull. 132. 117 pp.

Latin, R. X., D. R. MacKenzie and H. Cole, Jr. l98l. The
influence of host pathogen genotypes on the apparent infection
rates of potato late blight epidemics. PhytOpathology 7T: 82-
85.

Little, T. M. and F. J. Hills. 1978. Agricultural Experimenta-
tion. John Wiley & Sons, New York. 350 pp.

106

12.

13.

14.

15.

16.

17.

107

Magie, R. 0. 1935. Variability of monosporic cultures of
Coccomyces hiemalis. Phytopathology 25: 131-159.

 

Parlevliet, J. E. and J. C. Zadoks. 1977. The integrated con-
cept of disease resistance; a new view including horizontal and
vertical resistance in plants. Euphytica 26: 5-21.

Schein, R. D. 1964. Design, performance and use of a quanti-
tative inoculator. Phytopathology 54: 509-513.

Sjulin, T. M. 1981. Field resistance of cherry cultivars and
selection to Coccomyces hiemalis. Chapter I of this disser—
tation.

 

Sjulin, T. M. 1981. Components of partial resistance to
Coccomyces hiemalis in Prunus species. Chapter II of this dis-

 

sertation.

Van der Plank, J. E. 1968. Disease Resistance in Plants.
Academic Press, New York. 206 pp.

CHAPTER V

POSSIBLE SOURCES OF COMPLETE RESISTANCE TO
COCCOMYCES HIEMALIS IN PRUNUS SPECIES

 

108

CHAPTER V

POSSIBLE SOURCES OF COMPLETE RESISTANCE TO
COCCOMYCES HIEMALIS IN PRUNUS SPECIES

 

Abstract
Seedlings and clones representing 15 Prung§_species
were inoculated with a strain of Coccomyces hiemalis Higg.
isolated from P. cerasus L. Complete resistance to this

isolate was found in the Padus subgenus, the Pseudocerasus

 

and Mahaleb sections of the Cerasus subgenus, and inter-
specific hybrids between these sections and the Eucerasus
section of Cerasus. Lesions were absent or nonsporulat-
ing on inoculated leaves of P. maackii Rupr., P. serotina

Ehrh., P. virginiana L., P. sargenti Rehd., P. serrula

 

Franch., P. serrulata Lindl., P. subhirtella pendula
Tanaka,_P. yedoensis Mats., P. hillieri (P. japonica
Thunb. x P. sargenti Rehd.), _P. m L. x _P. 1532512—
cerasus Lindl. ('Colt'), P. pennsylvanica L., and P.

dropmoreana (P. cerasus X.E- pennsylvanica). Sporulating

 

lesions were present on inoculated leaves of P. cerasus
'Montmorencyf, P. avium 'Angela?, and two clones of_P.
mahaleb L. Spores per lesion were greatest on 'Mont-

morency', intermediate on 'Angela' and P, mahaleb

109

110

'IR 758-1', and lowest on P. mahaleb 'IR 759-2'. Infec-
tion efficiency on 'IR 758-1' was reduced relative to

'Montmorency', Angela' and 'IR 759-2'.

Introduction

 

The Michigan sour cherry (Prunus cerasus 1) industry is

 

based almost entirely on one cultivar, 'Montmorency', and strains
derived from it (2). 'Montmorency' is very susceptible to infection

and defoliation by the cherry leaf spot fungus, Coccomyces hiemalis

 

(l5). Severe defoliation of sour cherry by g, hiemalis reduces
yield, vegetative growth, and wood and bud hardiness for up to two
seasons (4,6). Currently, about five fungicide applications per
season are recommended to Michigan sour cherry growers to control this
disease (7). An alternative to chemical control is the development
of cultivars with resistance to Q. hiemalis.

Sources of partial resistance are present in sour cherry,
sweet cherry (P. avium) and duke cherry (E. gondouinii) (15). Com-
ponents of resistance that affect lesion development and sporulation
in infected leaves were strongly correlated with the level of
resistance to defoliation in the field (16). However, expression of
components of resistance in families of juvenile seedlings from
.3. cerasus and-E. gondouinii cultivars was variable, and heritabili-
ties of the components were low (17).

An alternate approach to breeding leaf-spot-resistant sour
cherries would be to identify sources of complete resistance in

related cherry species, and introduce this resistance into cultivated

111

cherries by interspecific hybridization. Keitt (9) identified
several cherry species that remained free of leaf spot following
inoculation with strains of g, hiemalis isolated from E, cerasus or
.E-.9!i£fl: The purpose of this research was to evaluate additional

cherry species as possible sources of resistance to C, hiemalis.

Materials and Methods

 

Plant material. Clones and seedlings representing a total
of 15 species and interspecific hybrids from the Cerasus and Padus
subgenera of Prunus (11) were used. Trees of all species except

3, pennsylvanica, P. serotina and P, virginiana were propagated by

 

 

chip-budding onto 3. avium or P. mahaleb rootstacks. Trees of

 

.P. pennsylvanica were transplanted from a single clump of native trees

 

growing in Van Buren County, MI. .3. serotina and P. virginiana were

 

grown from seed obtained from native trees in Ingham County and

Ogemaw County, MI, respectively. Budwood of P, drgpmoreana, a

 

selection ”from the FZ-generation of E. cerasus 'Kozlov' x P. pennsyl-
yanjgg,(8), was obtained from Interstate Nurseries, Inc., Hamburg,
IA 51640. Budwood of P. cerasus 'Montmorency' clone 'IR 309-2',

E, avium 'Angela', and P, mahaleb clones 'IR 758-l' and 'IR 759-2'
were obtained from the U.S.D.A. Interregional Project No. 2 reposi-
tory in Prosser, WA 99350. Budwood of E:.E§£Eiiy.E- sargenti, P.

serrula, P. serrulata 'Kwanzan', P. subhirtella pendula, P. yedoensis,

 

.E. japonica x.P. sargenti (P. hillieri 'Hillier Spire') and P, avium x

P. pseudocerasus ('Colt') were obtained from trees on the campus of

 

Michigan State University, East Lansing, MI.

112

All trees were grown in sand:peat:per1ite (1:1:1, v/v) in
3.7-liter containers in the greenhouse at 13-30 C. Trees were fertil-
ized at bud break with 5.25 g of 19% N-6% P205-12% K20 controlled
release fertilizer (Osmocote, Sierra Chemical Co., Milpitas, Ca 95035)
plus 0.75 g of sustained-release trace elements (Esmigran, Mallinckrodt
Inc., St. Louis, MO 63147) per container. A second application of
Esmigran (0.75 g) was made 1 month later. Trees were trained to a

single shoot by removing lateral shoots weekly.

Inoculation with C. hiemalis. Four trees of each species

 

were inoculated with a strain of Q. hiemalis (isolate PB?) isolated
from a naturally-infected P. cerasus 'Montmorency' tree. Leaves in
three leaf age classes (5- to 8-day-old, 17- to 20-day-old and 29- to
32-day-old) were inoculated on each tree with a modified Schein
quantitative inoculator (16). About 800 conidia were applied to a

2 area on each leaf. Trees were placed in a mist chamber

2.1 cm
immediately after inoculation for 48 hr at 18-21 C. Trees were then
incubated in a greenhouse in a cheesecloth tent (16) at 13-27 C.
Eight days after inoculation, the inoculated leaves were removed from
each tree and placed into plastic boxes lined with moist paper towels
for an additional 8 days at 22-30 C. Leaves were then frozen at -20 C
until analysis.

The experiment was repeated on the same trees using about

2900 conidia per leaf. Trees were held in the mist chamber 48 hr at

21-24 C and then incubated for 20 days in the cheesecloth tent in the

113

the greenhouse at 16-30 C. Leaves were then removed from each tree

and frozen at -20 C until analysis.

 

Evaluation of resistance. Number of lesions per leaf were
counted and divided by the total number of conidia inoculated to A
determine infection efficiency (12). Spores were washed from leaves
with visible lesions into 5 ml water containing 2% (w/v) formal-
dehyde plus 0.1% (v/v) polyoxyethylene sorbitan monolaurate (Tween
20). Number of conidia in 8 samples from each leaf wash were
counted with a hemacytometer. Lesions were classified as non-
sporulating if spore-bearing acervuli were not observed under a
dissecting microscope at 40x and if the number of conidia washed from
each leaf was less than the number applied as inoculum. Percent
infection efficiency values were square root-transformed and spores
per lesion counts were log transformed prior to analysis of

variance (10).

Results and Discussion

 

A number of the species were inlnune to the isolate of C.
hiemalis used in this study (Table l). All members of the Padus

subgenus and most members of the Pseudocerasus section of the

 

Cerasus subgenus showed no visible lesions on any leaves following
inoculation in both studies. Lesions produced on E, yedoensis and
on a.P. avium x.P. pseudocerasus interspecific hybrid ('Colt') were

non-sporulating. .P.pennsylvanica of the Mahaleb section of Cerasus

 

subgenus was also immune, and lesions produced on the P. Cerasus x

-P.pennsylvanica hybrid (P. dropmoreana) were non-sporulating.

 

114

 

 

 

 

 

 

 

 

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115

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116

However, at least three of these species are not immune to all
strains of Q. hiemalis. Keitt (9) observed that P. serotina, E,

virginiana and P. pennsylvanica were resistant to isolates of g.

 

hiemalis from P. cerasus or P. avium, but susceptible to strains iso-
lated from naturally-infected members of their own species. Thus,
introduction of resistance to strains from P. cerasus by inter-
specific hybridization could simultaneously introduce susceptibility
to other strains of Q. hiemalis. Species and hybrids immune to the
isolate in this study should be tested against a wide range of iso-
lates, and planted in several locations where environmental conditions
are favorable for natural infection by C, hiemalis.

The average infection efficiency and relative spore produc-
tion of this C, hiemalis isolate on_P. cerasus 'Montmorency' and P.
iavium,'Angela' are consistent with that previously reported for these
cultivars (16). Spore production differed significantly (p = 0.01)
from experiment to experiment in those species with sporulating
lesions, but species by experiment interactions were not significant,
indicating that the relative sporulation between clones was uniform
from experiment to experiment. The two P, mahaleb clones, which were
reported resistant to Q. hiemalis (5), were not completely resistant.
However, infection efficiency in one clone (IR 758-1) was signifi-
cantly lower than B. avium 'Angela' and P. cerasus 'Montmorency',
and sporulation was significantly lower in the other clone (IR 759-2)
(Table l). Interspecific hybrids between_P. avium_and P. mahaleb
that were developed as cherry rootstocks (18) may be potential sources

of increased partial resistance to C, hiemalis.

117

Scab-immune apple cultivars have been successfully developed
by crossing completely resistant crab apple species (Malus floribunda)
with susceptible apple cultivars (M. pumila), followed by back-
crosses to susceptible cultivars. Resistance, controlled by a single
dominant gene, was selected in segregating progenies after each back-
cross (14). Application of a similar approach to the development of
leaf spot-resistant cherry cultivars depends not only on the ability
to create fertile interspecific hybrids and subsequent backcross
progenies, but also upon the number and nature of the genes control-
ling resistance. If several genes control complete resistance, or if
resistance is recessive to susceptibility, intercrossing and selection
after each backcross generation may be necessary (1). This inter-
crossing and selection step after each backcross would greatly
lengthen the time required to develop leaf spot-resistant cultivars
with desirable horticultural characteristics.

A substantial number of interspecific hybrids between culti-
vated cherries and potentially leaf spot-immune species have been
reported (3,13). Infertility in the F1 generation of at least one of

these hybrids, P. dropmoreana, has been overcome by colchicine treat-

 

ment of flowers (8). The clone used in this study from the resulting
F2 appears to be immune to Q. hiemalis (Table l), and is fertile

(T. M. Sjulin, unpublished). The number or nature of genes con-
trolling resistance in this clone, and the feasibility of back-
crosses to cultivated cherry is not known. It is hoped that inter-

specific hybridization in cherries appears to be promising and should

118

be pursued for development of leaf spot-immune cultivars, and also for

hybrids to test as potential cherry rootstocks (3).

10.

11.

12.

LITERATURE CITED

Allard, R. W. l960. Principles of Plant Breeding. John Wiley
and Sons, New York. 485 pp.

Andersen, R. L. 1981. Cherry cultivar situation. Fruit Var.
J. 35: 83-92.

Cummins, J. N. 1979. Interspecific hybrids as rootstocks for
cherries. Fruit Var. J. 33: 85-89.

Dutton, W. C. and H. M. Wells. 1925. Cherry leaf spot residual
effects and control. Mich. Agric. Expt. Sta. Special Bull. 147.

15 pp.

Fridlund, P. R. 1979. Fruit tree scions available from the IR-Z
Repository, fall 1979 through spring, 1980. Prosser, WA.
8 p. mimeo.

Howell, G. S. and S. S. Stackhouse. 1973. The effect of defolia-
tion time on acclimation and dehardening in tart cherry (Prunus

cerasus L.). J. Amer. Soc. Hort. Sci. 98: 132-136.

Howitt, A. J., J. Hull and A. L. Jones (eds.). 1981. Fruit
Pesticide Handbook. Mich. St. Univ. Extn. Bull. E-154. 96 pp.

Hutchinson, A. and W. H. Upshall. 1964. Short-term trials of
root and body stocks for dwarfing cherry. Ontario Hort. Expt.
Sta. Rpt. for 1963. pp. 8-16.

Keitt, G. W. 1918. Inoculation experiments with species of
Coccomyces from stone fruits. J. Agric. Res. 13: 539-569.

 

Little, T. M. and F. J. Hills. 1978. Agricultural Experimenta-
tion. John Wiley and Sons, New York. 350 pp.

Rehder, A. 1940. Manual-of Cultivated Trees and Shrubs, 2nd
ed. MacMillan, New York. 996 pp.

Schein, R. D. 1964. Design, performance and use of a quanti-
tative inoculator. Phytopathology 54: 509-513.

119

13.

14.

15.

16.

17.

18.

120

Schmidt, H. 1976. On the inheritance of the length of the
juvenile period in interspecific Prunus hybrids. Pages 229-234
in R. H. Zimmerman, ed. Symposium on Juvenility in Woody
Perennials. Acta. Horticulturae No. 56. 317 pp.

Shay, J. R., L. F. Hough, E. B. Williams, D. F. Dayton,

C. H. Bailey, J. B. Mowry, J. Janick and F. H. Emerson.
l973. Apples. Pages 362-374 in R. R. Nelson, ed. Breeding
Plants for Disease Resistance. Penn. St. Univ. Press, State
College.

Sjulin, T. M. 1981. Field resistance of cherry cultivars and
selections to Coccomyces hiemalis. Chapter I of this disser-
tation.

 

Sjulin, T. M. 1981. Components of partial resistance to
Coccomyces hiemalis in Prunus species. Chapter II of this
dissertation.

Sjulin, T. M. 1981. Inheritance of resistance to Coccomyces
hiemalis in juvenile seedlings of cherry. Chapter III of this

 

dissertation.

Westwood, M. N., A. N. Roberts and H. 0. Bjornstad. 1976.
Comparison of mazzard, mahaleb and hybrid rootstocks for

'Montmorency' cherry (Prunus cerasus L.). J. Amer. Soc. Hort.
Sci. 101: 268-269.

 

SUMMARY AND CONCLUSIONS

121

SUMMARY AND CONCLUSIONS

An important objective of the sour cherry (Prunus cerasus L.)

 

breeding program at Michigan State University is the deve10pment of
cultivars with increased resistance to Coccomyces hiemalis Higg.

The results of this research provide valuable information contributing
to that objective. The purpose of this section is to summarize the
significant points of the research, and to suggest further work indi-

cated by the results.

Summary of Results

 

Genetic variation for resistance was clearly demonstrated
within and among several species of cultivated cherry in field evalua-
tions. Cultivars of sour cherry, sweet cherry (P. avium L.), duke

cherry (P. ggndouinii Rehd.) and ground cherry (P, fruticosa Pall.)

 

differed quantitatively in levels of partial resistance to both
infection and defoliation (10). Sweet cherries, as a species, were
considerably more resistant to defoliation than either sour cherries
or duke cherries. Ground cherries were intermediate in resistance.
Greenhouse evaluations of components of resistance confirmed
the increased resistance of sweet cherry observed in the field.
Although numbers of lesions were similar for all three species, lesions
on sweet cherry appeared later, were smaller and produced fewer spores

than those on sour cherry or duke cherry (11). Measurements of lesion

122

123

deve10pment or sporulation were strongly correlated with resistance
to defoliation, while numbers of lesions were not. This implies that
resistance is expressed after lesion establishment by restricting the
growth and reproduction of the pathogen in the host tissue. Since
leaf spot is a disease with multiple cycles of infection per season,
a reduction in spore production after each cycle of infection would
significantly reduce the secondary spread of the disease.

The relative resistance within and among sweet, sour and duke
cherries was uniform over a range of Q. hiemalis isolates (13).

There was no indication that host or geographic source of an isolate
was related to its relative ability to infect or reproduce on the
cultivars tested. It appeared that evaluations of resistance based
on a single isolate were representative of most, if not all, isolates
attacking sour cherry. However, variation in the pathogen population
should be continuously monitored in a breeding program to detect
shifts in the population since increased use of resistant sorts for
sour cherry may lead to selection within the pathogen population for
strains that are able to overcome the resistance.

Inheritance studies indicated that genetic control of resis-
tance in sour cherry and duke cherry is polygenic at the level of
individual components (12). Heritabilities of all components of
resistance were low (most less than 0.5 on an individual plant basis),
and there was no indication of discrete classes of resistance in the
progenies. Cultivars did differ in the average resistance of their
progeny, indicating that resistance was at least partially controlled

by additive gene action. However, selection for components of

124

resistance in juvenile seedlings did not appear promising. The low
heritabilities indicate that progress would be slow if individual
plants were selected, and significant genotype by experiment inter-
actions were not completely resolved.

A number of cherry species and interspecific hybrids were com-
pletely resistant to an isolate of C, hiemalis attacking sour cherry
(14). These species were outside of the Eucerasus section of Prunus
that include the cultivated cherries. The resistant species were in

the Pseudocerasus section of Prunus (Japanese flowering cherries), the

 

Mahaleb section (B, pennsylvanica L.) and the Padus subgenus. In

 

addition, complete resistance was present in interspecific hybrids

between the Eucerasus section and both the Pseudocerasus and Mahaleb

 

sections. Selections of P. mahaleb L. were not completely resistant,
but showed higher levels of partial resistance than sweet cherry or

sour cherry cultivars.

Suggestions for Future Research

 

There are several approaches to breeding for leaf spot resis-
tance in cherry. Probably no one approach is the best, and the most
effective approach may be a combination of two or more separate
schemes.

One approach is to select for increased partial resistance
within sour cherry. The cultivars 'North Star' and 'SHT-2' appear to
be valuable sources of resistance within sour cherry. These two
cultivars were more resistant to leaf spot than other cultivars in

both field (10) and greenhouse (11) studies. Furthermore, 'North

125

Star' was the best parent for obtaining progeny with increased resis-
tance (12). However, the resistance genes in 'SHT-2' could be iden-
tical to those in ‘North Star' since the pedigree of 'SHT-2' is
unknown (10). A wider range of sour cherry germplasm should be
evaluated to identify additional sources of partial resistance.

Since inheritance of resistance in sour cherry appears to be
polygenic with at least some additive gene action, a recurrent
selection scheme should be effective in increasing the average level
of resistance in the breeding population (2). Intermating of the
best parents or their progenies after each generation of selection
will increase the frequency of resistance alleles in the population.
As allele frequency increases, the chance of obtaining resistant
individuals also increases.

The simplest recurrent selection scheme is mass selection in
which individual plants are the selection unit (2). The selected
individuals are intermated to produce the next generation of progeny.
A recurrent mass selection scheme could be readily adapted to com-
ponent of resistance evaluations of juvenile seedlings. Individual
seedlings would be screened at an early age, preferably before
transplanting to the field. The most resistant seedlings represent-
ing a predetermined portion of the total population would be saved
and the remaining individuals discarded. The resistant seedlings
would be evaluated for other characteristics and the best individuals
intermated. This method of independent culling is not as efficient

as the selection index approach for improving more than one

126

character (3), but the savings in time and space by early culling
probably outweigh the lower efficiency.

Unfortunately, the low individual plant heritabilites for
components of resistance (12) indicate that progress will be slow
in a recurrent mass selection scheme. Recurrent selection based on
clonal family performance can be more effective than mass selection
when heritabilities are low (2). However, use of n propagules per
genotype in the field reduces to l/n the number of genotypes evalua-
ted per unit of land, and increases the time and work required to
complete each generation. These disadvantages would nullify the
advantages of clonal family selection.

If clonal families could be rapidly pr0pagated and evaluated
in the greenhouse, then most of the disadvantages of clonal family
selection would be avoided. This may be feasible with sour cherries.
Propagules, ideally rooted cuttings, could be taken from individuals
in the top 5 to 10% of the population, based on field resistance
evaluations and total score from evaluation of other characters.
Propagules would be forced in the greenhouse and artificially inocu-
lated for component of resistance evaluations in the winter. These
resistance evaluations can then be included in a selection index of
total horticultural value weighted for each character on the basis
of its economic importance and heritability (3). The best individuals
would then be intermated the following spring to produce the next
generation. This method of clonal family evaluation would improve
estimates of phenotypic variance without lengthening the generation

time or reducing field space available for seedling evaluation.

127

Another scheme is recurrent selection based on full-sib,
half-sib or self-family performance. Of these three, half-sib
families can be most easily obtained in sour cherries. The evalua-
tion scheme would be similar to clonal family evaluation except that
seed collected from the most promising (e.g., the top 5 to 10%)
individuals would be the evaluation unit,instead of clonal families.
For this evaluation, performance of open-pollinated half-sib seed-
ling families, grown and evaluated in the greenhouse during the
winter, would be included in the selection index. A major disadvantage
of selection based on half-sib family performance is that only 1/2 of
the total additive genetic variance is utilized for selection (2).
However, if the open-pollinated families are actually highly self-
pollinated, then the evaluation scheme should compete favorably with
evaluation based on clonal family performance, since most of the
additive genetic variance would be utilized (2).

Another approach to breeding sour cherries resistant to leaf
spot is interspecific hybridization with sweet cherries. Sweet
cherries are a source of increased partial resistance to g, hiemalis
(10). In addition, sweet cherries may be an important source of
genetic diversity for other characters, since sour cherry is believed
to be an allotetraploid of sweet cherry and ground cherry (8).

Interspecific hybrids are readily produced between sweet and
sour cherry. The resulting hybrids are either highly sterile
triploids or tetraploid with partial fertility. Fertility in the

tetraploids (the duke cherries), which are thought to arise from the

128

union of an unreduced sweet cherry gamete with a reduced sour cherry
gamete (4) is related to the level of quadrivalent formation at
meiosis (9). The higher the percentage of quadrivalents, the lower
the fertility, probably due to nondisjunction. Quadrivalent formation
may be due to differentiation in sour cherry of the chromosomes origi-
nally derived from sweet cherry ancestors. This differentiation

could reduce homology with chromosomes of contemporary sweet cherry
cultivars, making possible competitive pairing of both sets in sour
cherry with those of sweet cherry. How seriously quadrivalent forma-
tion will impede introduction of specific characters such as disease
resistance from sweet cherry into sour cherry is not known.

The relative advantage of sweet cherry x sour cherry hybridi-
zation versus selection with sour cherry for resistance depends also
on the number and nature of genes controlling resistance. If few
loci with fairly large individual effects control the difference in
spore production between these two species, interspecific hybridiza-
tion followed by backcrosses to sour cherry could be used. If
resistance is polygenic or recessive, then the backcross method will
not be very effective (1).

Another difficulty with interspecific hybridization is the
difference in ploidy level between these two species. Sweet cherry
is diploid (2n = 16) while sour cherry is tetraploid (2n = 32). A
large number of hybrids will be highly sterile triploids (4). Unless
fertile tetraploids can be differentiated from triploids at an early
age, much time and space will be inefficiently used. Gamete selec-

tion in sweet cherry pollen to increase the frequency of unreduced

129

gametes would increase the number of tetraploids in hybrid progenies.
Production of tetraploid sweet cherry parents by colchicine treatment
(8) or selection for haploid sour cherry parents would eliminate
differences in ploidy between the two species.

Before greenhouse component of resistance evaluations can be
applied to a recurrent selection scheme, the nature of genotype by
time of inoculation interactions observed in juvenile seedlings
should be explained. One hypothesis previously suggested is an
effect of plant age on expression of resistance (12). This hypothe-
sis could be tested by inoculating the same group of seedlings at
intervals after germination. The seedlings should represent several
families of crosses among parents differing in levels of resistance.
Clonal parent material should also be included to estimate environ-
mental error.

Breeding objectives in addition to leaf spot resistance
should be considered in the selection of sweet cherry parents for
interspecific hybridization. Resistance to X-disease, a serious
mycoplasma-induced disease of cherry, has been reported for P, avium
'Angela' (16). This cultivar showed moderately high resistance to
C, hiemalis in component of resistance evaluations (11), and thus
would appear to be a good parent for interspecific hybridization.
The self-fertile sweet cherries recently developed from mutation
work (7) are other potential parents. Use of self-fertile sweet
cherries would prevent introduction 0f.E-.E!iEfl self-incompatibility

genes into E. cerasus germplasm. Self-incompatibility could later

130

impede intercrosses or self-fertilization, or reduce the usefulness
of potential selections by requiring a pollinizing cultivar.

_P. mahaleb clones are another source of partial resistance
(14). Incorporation of resistance from this species into sour cherry
may be even more difficult than using_E..avigm, due to the greater
genetic distance between P. mahaleb and P. cerasus as well as the
poor fruit quality of P. mahaleb. However, 3. mahaleb represents a
different source of resistance alleles which may be valuable if
changes in the pathogen population through mutation or selection
erode other sources of resistance.

Breeding for complete resistance is yet another approach to
the development of leaf spot resistant cherries. An advantage of
complete resistance is the ease by which resistance can be detected
in segregating progenies. If natural levels of infection are not
sufficient for accurate evaluation of complete resistance, trees can
be artificially inoculated. Inoculation of a single leaf per tree
should be sufficient to detect most susceptible progeny (10). Any
tree showing secondary spread of infection beyond the inoculated leaf
would be considered susceptible.

Complete resistance in other host-pathogen systems is often
controlled by a single gene which can be introduced from a donor
parent into improved material by backcross procedures (1). With
heterozygous material of long generation times such as sour cherries,
the recurrent parent often differs from generation to generation,

resulting in a modified backcross approach. Intercrossing and

131

selection among recurrent parents can lead to fixation of resistance
genes in the breeding population.
Sources of complete resistance are not available at present

3, gondouinii). Complete resistance in some of these species has been

 

reported in field resistance evaluations by Eastern European workers
(6,15), but retesting by artificial inoculation is needed to deter-
mine if these selections are completely resistant, partially resis-
tant or escapes. Evaluation of a broader range of germplasm in each
of these species might discover possible sources of complete resis-
tance. Collections of open-pollinated progeny from centers of divers-
ity of each of these species could be rapidly screened in the green-
house or field by artificial inoculation.

Introduction of complete resistance into sour cherry from
species in other sections 0f.E£!fl!§ should be attempted. Success of
these attempts depends first on development of fertile interspecific

hybrids. The P. dropmoreana clone evaluated in this research, a

 

 

fertile F2 of_P. cerasus x P, pennsylvanica with complete resistance
to 9, hiemalis (14), appears to be a valuable source of resistance.
Backcrosses to sour cherry should be attempted with this clone.
Another promising source of complete resistance is the P, avium_x

P, pseudocerasus rootstock cultivar 'Colt'. At present, it is not

 

known if 'Colt' will produce fertile progeny.
A major concern in any disease resistance breeding program
is the appearance of pathogen strains that can overcome resistance.

The most obvious cause for concern in breeding leaf spot resistant

132

cherries is the reported variability by the pathogen at the species
level of the host (6). Species with complete resistance to strains
of g. hiemalis attacking cultivated cherries may be fully susceptible
to other strains. This should not deter attempts to breed leaf spot
resistant sour cherries, however. Instead, several sources of
resistance should be exploited simultaneously to provide multiple
Options to the plant breeder. Immediate gains can be made by evalua-
tion of partial resistance in advanced selections of sour cherry.

In addition, crosses should be made to incorporate higher levels of
partial resistance from sweet cherry and complete resistance from
other cherry species. Selections should be evaluated in as many
field locations as possible, preferably through interregional coopera-
tive projects. Evidence of erosion in resistance due to the appear-
ance of compatible pathogen strains can be tested by sensitive green-

house pathogen variability evaluations (l3).

LITERATURE CITED

1. Allard, R. W. 1960. Principles of Plant Breeding. John
Wiley and Sons, New York. 485 pp.

2. Andersen, R. L. 1971. Some quantitative genetic considerations
pertinent to breeding asexually propagated crops. Ph.D. thesis,
Univ. Minnesota, St. Paul. 147 pp.

3. Hazel, L. N. and J. L. Lush. 1943. The efficiency of three
methods of selection. J. Hered. 33: 393-399.

4. Hruby, K. 1962. Chromosome behaviour and phylogeny of culti-
vated Cerasus. Preslia 34: 85-97.

5. Kan'shina, M. V. and A. I. Astakhov. 1979. The resistance of
sour cherries to cherry leaf spot (in Russian). Zaschita
Rastenii 6: 29. Abstracted in Hort. Abstr. 49: 711 (1979).

6. Keitt, G. W. 1918. Inoculation experiments with species of
Coccomyces from stone fruits. J. Agric. Res. 13: 539-569.

 

7. Lapins, K. 1970. The Stella cherry. Fruit Var. Hort. Dig. 24:
19-20.

8. Olden, E. J. and N. Nybom. 1968. On the origin of Prunus
cerasus L. Hereditas 59: 327-345.

9. Raptopoulos, T. 1941. Chromosomes and fertility of cherries
and their hybrids. J. Genet. 42: 91-114.

10. Sjulin, T. M. 1981. Field resistance of cherry cultivars and
selections to Coccomyces hiemalis. Chapter I of this disser-
tation.

 

ll. Sjulin, T. M. 1981. Components of partial resistance to
Coccomyces hiemalis in Prunus species. Chapter II of this
dissertation.

 

12. Sjulin, T. M. 1981. Interitance of resistance to Coccomyces
hiemalis in juvenile seedlings of cherry. Chapter III of this
dissertation.

 

133

13.

14.

15.

16.

134

Sjulin, T. M. 1981. Variability of Coccomyces hiemalis to
components of resistance in Prunus species. Chapter IV of this
dissertation.

 

Sjulin, T. M. 1981. Possible sources of complete resistance to
Coccomyces hiemalis in Prunus species. Chapter V of this disser-

 

tation.

Turovtsev, N. I. 1973. Varietal resistance of sweet cherries
to Coccomyces hiemalis (in Russian). Zaschita Rastenii 3: 49-50.
Abstracted in Hort. Abstr. 44: 136 (1974).

 

Wadley, B. N. 1970. Developments in disease resistant sweet
cherries. Proc. Utah State Hort. Soc., 1970: 46-48.