GROWTH, RESPIRATION, IINeEIIERGETIcs 0F
NITROBACTER AeILIs IN; ,
THE PRESENCE OF SELECTED PESTICIDES A
Thesis for the Degree of Ph;jD.. '7
MICHIGAN STATE UNIVERSITY. ‘ - ,

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GROWTH, RESPIRATION, AND ENERGETICS OF
NITROBACTER AGILIS IN THE PRESENCE OF

SELECTED PESTICIDES
presented by

Carl L. Winely }

has been accepted towards fulfillment '
of the requirements for ‘

Ph.D. degree in_m£2121_0108y 5‘
Public Health

/ZJ/m( awe é,“

rMajor professor
C.L. San Clemente

Date 18 May 1970

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ABSTRACT

GROWTH, BESPIRATION, AND ENERGETICS or
W m IN THE PRESENCE or SELECTED PESTICIDES

by Carl L. Winely

The purpose of this study was to determine the mode
of action of several pesticides on both the growth of
‘flifizgpgggg: agilis in aerated cultures and on the respiration
of g. agilis cell suspensions in the Warburg respirometer.
Those compounds which inhibited both growth and respiration
were tested for an effect on several enzymatic activities
to characterize the site of inhibition.

Two pesticides (aldrin and simazine) were not
inhibitory to growth of Nitgobactgr, but five compounds
(CIPC, chlordane, DDD, heptachlor, and lindane) prevented
growth when added to the medium at a concentration of 10 ug
per ml.

Whereas CIPC (110 ug/ml) and eptam (275 ug/ml)
prevented nitrite oxidation by cell suspensions, the addition
of DDD (500 ug/ml) and lindane (500 ug/ml) resulted in only
partial inhibition of the oxidation. Heptachlor (500 ug/ml)
and chlordane (500 ug/ml) also caused only partial inhibi-
tion of oxidation with Nitrobagter cell suspensions, but were
more toxic with cell-free extract nitrite oxidase.

None of the pesticides inhibited the nitrate reductase
activity of cell-free extracts, but most of them, especially
heptachlor, caused some repression of cytochrome c oxidase

30t1V1tye

Carl L. Winely

Two of the herbicides (CIPC and eptam) exerted an
uncoupling effect on the oxidative phosphorylation linked to
nitrite oxidation in Nitzobgcte; agil; . Although nitrite
oxidation was inhibited, the more severe effect on phos-
phorylation caused decreased P/O ratios (umoles of 32F
incorporation per uatom of oxygen uptake). A 50% reduction
in the P/O ratio occurred at approximately 2.3 x 10'“ M CIPC
and at 8 x 10'“ M eptam.

A classical phosphorylation uncoupler, 2,u-dinitro-
phenol (DNP), affected the oxidative phosphorylation in
u. agilig in a manner similar to that observed with the
herbicides. Again, oxygen uptake was inhibited, but P/O
ratios were lowered because of a greater effect on phosphate
esterification. A USS reduction in the P/O ratio occurred
at 2.5 x 10’“ M DNP.

The maximum P/O ratio obtained was 0.36. This low
P/O ratio was attributed to disruption of the internal
integrity of the phosphorylating particle since an active
ATPase was observed when the yeast hexokinase and glucose
trapping system was omitted from the reaction system.

The actual modes of action of chlordane, DDD, hepta-
chlor, and lindane on y. agilis were not determined, but
were shown to be on biosynthetic processes of the cell rather
than nitrite oxidation. In the case of the two herbicides,
CIPC and eptam, uncoupling of oxidative phosphorylation in a
manner ana10gous to 2," dinitrOphenol is suggested as the

mode of inhibition in Nitrobacter.

GROWTH, RESPIRATION, AND ENERGETICS OF NITROEACTER
AGILIS IN THE PRESENCE OF SELECTED PESTICIDES

By

Carl L. Winely

A THESIS

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

DOCTOR OF PHILOSOPHY

Department of Microbiology and Public Health

1970

L7 ‘- 4/17 [,I/ 1) ./ I! I...
' J

./../“'“{7« I“)

DEDICATION

This thesis is affectionately dedicated to my
wife whose patience and encouragement made this achieve-

ment possible.

ACKNOWLEDGMENTS

The author gratefully acknowledges the constant
guidance and assistance of his major adviser, Dr. C. L.
San Clemente, throughout the course of this investigation.

Thanks are also extended to Dr. H. N. Costilow,
Dr. H. L. Sadoff, Dr. A. B. Welcott, Dr. C. H. Cunningham,
Dr. C. H. Suelter, Dr. F. J. Malveaux, A. in Garretson,

W. L. Muth, and A. E. Stoekland who contributed useful
suggestions, help, or encouragement which assisted in

completion of this thesis.

ii

TABLE OF CONTENTS
Page
ACKNOWLEGMENTS. O O O O O O O O O O O O O O O O O O O 11

LIST OF TABLES e c e e e c e c c c e e e e c e c e e e V
LIST OF FIGURES. e e e e c e e c c c e c c e e e e e 0 v1
INTRODUCTIOK e e e e e e e c e c e e e c e e c e e c e 1
LITEBAIUBE REVIEW. 0 c e c c c e e e c c c c c c c c e 3
Media and Culture TeChniqueS e e c c c c c e c 3
Inorganic Amendments to Medium . . . . . . . . 5
Molybdenum. e c c e e e c c e e c e e 5

Yeast extract and casamino acids. . . . . 5

Acetate and formate e e c e c c c c e e e 6

BiOtlne e c e c c c e c e e c c c c e e c 6

Obligate or Facultatlve AutotrOph e e e e c e e 7
Nitrite 0X1dasec e e e e e e e c e e c c e e e 9
CYtOChromOS inv01vedc c e e e e e c c e e 9

Coupled oxidative phosphorylat tion . . . . 10

Source of NADHZ e e c e e e c e c e c e e 11

Nitrate BOduCDasee e e e e e c c e e e e e e 13

Mode of Action of Pesticides . . . . . . . . . 13
IUSQCtiOidOBe c c c e c e c e c e e e c e 13

HerbicidGSc c e c e e c e c c e e e e c e 1“

Effect of Pesticides on Nitrification. . . . . 16
IflSOCthldCSc c e e c c c e c e e e e e c 16

Herbicides. e e e c e e c e e e e c e e e 17

MATERIALS AND METHODSe c e e c c e e e e c e e e c c c 19
PeStlcideS e c e e e e e e e e e e e e e c e c 19
IUBCCtiCldeSe c e e e e e c e c c e c c o 19

Herbicides. c e c c e e e o e e e e c e e 19

Medium 0 e e c e c e c e c c e e e e e e o c 20

GrO'th Effects 0 c c e c e c e c e e c e o e 20
Large-Scale Cultivation. e e e c e e c c e e c 21
Preparation of Cell-Free Extracts. . . . . . . 22

Purity of Cultures e e c e c e c c c e e e c c 23
OXLdation Of Nitrite e e e e c c e e e c e e e 23

Nitrate Reductasee e e c e c c c c e e c e e c 2“

111

Page

NADH ox1d83€e e e e c e c c e e c e e c e c e 25
SpectrOphOtometrlc assay. 0 e e e c c c c 25
Besplrometer assay. 0 c e c c c c e c e e 25

CYtOOhrome C 011(1883 c c e c e e e c c e e c 26

Oxidative Phosphorylation Coupled To Nitrite

Oxidation. e e 320 e e e e e e e c e e 26
Assay by KZHPOu- P incorporation . . . . 26
Glucose-6-phosphate dehydrogenase assay . 28

Analytical MQEhOdS e c e e c e c e e e e e e e 28
HBXOklnasee e c e e c c e e e e c e e e e 28
PrOtein e e c e c e e c c e e e e c e e e 29

BEWLTS. O O O O O O O O O O O O O O O O O O O

O
I
O
O
‘63

GrOWth Effects 0 e c e e e e e c e c 30
Oxidation Studies with Cell SuSpensions and
Coll-Free EXtraOtS e c e e c c e e c e c e 30

Cells grown in ld-liter carboys . . . . . 30
Cells grown in MF-lh microferm
fermentor e e c e e e c e e c c c c c c 33
Kinetics Of 011dat10nc e e e e c c e e e e e c 40
Nitrate Boduotase. e c e c e e e e e e e e c e “1
NADHZ Oxidase. e e e c e c e c c c e e e e c c an
Cytochrome C Oxidase c e c e e e e c e e “8
Oxidative Phosphorylation Coupled to Nitrite
OXIdBtionc e e e e e c c c c e e e e c c e e 50
Preparation of cell-free extract. . . . . 50
Effect Of CIPC and Optame c e e e e c e c 53
Effect Of 2,#-dinltr0phenol e c e e c c e 53
Necessity of trapping system. . . . . . . 56

Efficiency of inorganic phosphate
eXtraCtione c e c e e e c e e c e 56
Phosphorylation Coupled to the Oxidation
Of NADHZ e e e e c e e e c e c c e c e c e c 58
DISCUSSION 0 O O O O O O O O O O O O O O O O O O O O O 62

BIBLIWRAPHY O O O O O O O O O O O O O O O O O O O O O 73

iv

Table
l.

2.

3.
u.

5.

6.

7.
8.

LIST OF TABLES
Page

Effect of pesticides on growth of Nitrobacter
gaillfl 1n aerated cultures. 0 e e e c e c e e e 31

Effect of pesticides on nitrite oxidation by
cell suspensions and cell-free extracts of

Elizghfisigg EE;;;§0 e c e c c e e e e e e c e c 37

Effect of pesticides on cytochrome c oxidase. . #9

Effect of CIPC and eptam on oxidative phos-
phorylation in N. agilis cell-free extracts . . 5h

The effect of 2,“ dinitrOphenol on oxidative
phosphorylation 1n E. 881113. c e e e e e e c e 55

Necessity for trapping system for oxidative
phOSphOIYlation e c e e e c e c e e e e e e e c 57

NADH2 oxidase activity of N. agilis . . . . . . 59

The effect of CIPC and eptam on NADH2
Olldatlcn e e e e e e e e c c e e e c e e c e 61

Figure
1.

2.

3.

4.

5.

6.

LIST OF FIGURES
Page

The effect of pesticides on nitrite oxidation
by Nitrobacter agilis cell suspensions. . . . . 3h

The effect of pesticides on nitrite oxidation
by Nitrobacter agilis cell-free extracts. . . . 35

The nature of the inhibition of nitrite
oxidation by three different pesticides . . . . #3

The effect of pesticides on NADH2 oxidase
activity ofN Nit robactgr agilig cell-free

OXtraOtBe c c e c c c e e e c c “6

The effect of eptam on NADH oxidase activity
of Nitrobacter agilis cell- ree extracts. . . . 47

Rate of nitrite oxidation and cell growth in
large-scale culturCSc e c c c e e c e c e e c c 51

Turbidity as a function of nitrite oxide!
tion in large-scale cultures. 0 e e e c e e c c 52

vi

INTRODUCTION

BiOIOgical nitrification, the oxidation of the
ammonium ion to nitrate ion, is largely caused by the auto-
trOphic soil bacteria of the genera Nitrogomongs and 51222?
2322:.

Most of the experiments to study the effects of
various pesticides on nitrification used field trials or
determinations in the soil perfusion unit deve10ped by Lees
and Quastel (19h6). Some (Hale at al., 1957; Quastel and
Scholefield, 1951; Farmer gt a;., 1965; and others) have used
both the perfusion apparatus and a manometric technique to
measure the effect of pesticides on the nitrifers. When
respiration studies were made, soil which had been percolated
with an ammonium salt solution to increase the nitrifying
pepulation was usually added to the Warburg vessels and either
the oxidation of ammonium or the appearance of nitrate was
measured. Seldom were pesticides tested for an effect on
respiration with concentrated cell suspensions of either
Nitzgggngng§,or fiitngggtgg. Likewise, aerated liquid cultures
of these organisms were used infrequently as a test system for
pesticides. In these studies the effect of the pesticides was
reported only with regard to oxidation of the NH“+ or N02“ sub-
strate; nothing was stated concerning effects upon biosynthetic

processes of the organisms.

2

The purpose of this study was to determine the mode
of action of several pesticides on both the growth of
Eitxggggtgz agilig in aerated cultures and on the respiration
of N. agilig cell suspensions in the Warburg respirometer.
Characterization in terms of several enzymatic activities
with respect to the site of inhibition was attempted with
pesticides which inhibited both growth and respiration.

LITERATURE REVIEW

M211fi_é d ul u T ch es

£1222h22£2£.§811l§ is a chemoautotrOph which derives

its energy from the oxidation of nitrite to nitrate accord-
ing to the following equation:
N02 + $02 —-) no"3 + 17.8 kcal

Although Nitrobacter was first isolated in 1890 by
Winogradsky, culturing difficulties have impeded knowledge
concerning the metabolism of the organism. For instance,
the first biochemical investigation was not carried out
until 1957 (Lees and Simpson) and this was performed with
impure cultures. One of the main problems confronting early
investigators was particulate matter in the medium which was
thought to be required for growth. Aleem and Alexander (1958)
were the first to culture the organism successfully in partic-
ulate-free medium and they obtained relatively high cell
yields. They established minimum concentrations of individual
ions required for maximum growth. There were 5 ug per m1 of
phosphorus, 5 ug per ml of magnesium, and 7 ug per liter of
iron.

The results that Aleem and Alexander obtained with
nitrite illustrated the need for additions of the substrate

3

u
during growth rather than the addition of a large initial
nitrite concentration. As long as the original nitrite
concentration did not exceed no ug of nitrite-nitrogen per
m1, no lag phase occurred in growth, but at 130 ug of nitrite-
nitrogen per ml, the lag phase was prolonged by two or three
days. Additions of up to 500 ug NOE-N per ml could be made
to logarithmic phase cultures without suppressing the growth
and the logarithmic phase lasted until about 1500 ug NOZ-N
per ml were oxidized.

Since one explanation for limited growth of Nitrobacter
was the accumulation of nitrate during growth, Aleem and
Alexander (1960) added various concentrations of nitrate to
the medium. With an initial concentration of 1000 to 2000 ug
Neg-N per ml the lag phase was prolonged and at 2000 ug
NOS-N per m1 no growth occurred. Gould and Lees (1960)
observed a greater effect, however, as some inhibition of
nitrite oxidation occurred after accumulation of 500 ug NOB-N
per m1. Finstein and Delwiche (1965) observed decreased
efficiency of growth due to nitrate accumulation, but only
after a concentration in excess of about 0.1 M.

Other attempts at increasing yields included dialysis
to remove nitrate (Gould and Less, 1960; Boon and Laudelout,
1962) and growth in continuous culture (Gould and Lees, 1960).
Only slight increases in yield were obtained by removing Nd',
but the continuous culture technique was an improvement as
l g dry weight of cells could be obtained per week from a

5 1 culturee

5

o n c m s 0 Medium

Molybdenum. Both inorganic and organic amendments
to the inorganic medium (Aleem and Alexander, 1960) were
sought which would increase cell yield. Perhaps the most
noteworthy results were obtained on the addition of mo1ybdenum.
Using chemically purified medium, Finstein and Delwiche (1965)
showed that Nit;gbgg§gg,has an absolute requirement for
molybdenum. In addition, molybdenum induced an 11 fold
increase in both nitrite utilization and cell-mass develop-
ment. With short term studies, concentrations as low as
10‘9 M caused the maximal response and 10"6 M was usually
added to large-scale cultures.

Aleem and Alexander (1958) reported the oxidation of
100 umoles nitrite in 9 days, Gould and Lees (1960) observed
1&0 umoles oxidized in 10 days while Einstein and Delwiche
(1965) by adding molybdenum obtained oxidation of 250 umoles
Nd; per ml in 10 days. However, since the presence of molyb-
denum decreased the efficiency of substrate utilization
rapidly after oxidation of approximately 120 umoles of nitrite
per ml, the cultures were usually harvested after h days of
active growth. Finstein and Delwiche reported that a procedure
was now available whereby large masses of Nitrobacter cells
could be obtained with relative ease. Approximately 0.5 g
(dry weight) of cells was obtained from 18 liters of culture.

3 t t d s no i . Various organic

amendments to inorganic medium have also stimulated growth

6

of the organism. Delwiche and Einstein (1965) found that
addition of yeast extract (75 ug/ml) and casamino acids
(200 ug per ml) to a medium adequate in minerals resulted
in approximately 50% stimulation as Judged by nitrite consumed
per unit time, Optical density, and plate count. Ashed
yeast extract also stimulated growth if added to molybdenum-
free medium, but a molybdenum concentration equivalent to
the ash caused the same effect.

ta d o a . Delwiche and Finstein (1965)
noted that formate and also acetate contributed some carbon
to the cells. Since the formate contribution to cell carbon
was small and Malavolta, Delwiche, and Burge (1962) had
observed strong formate oxidation by Nitrobacter cell-free
extracts, it was suggested that the formate was first reduced
to carbon dioxide which in turn was fixed. In contrast to
formate, acetate contributed strongly to cell carbon (Delwiche
and Finstein, 1965) and under certain conditions stimulated
growth. Neither formate nor acetate could substitute for
002 as the sole carbon source. 0f the several amino acids
which were tested by these workers, none stimulated growth
but on the other hand, valine and threonine were inhibitory
at 10-3 M.

Biotin. With four strains of E. agilig the addition
of biotin (150 ug per 1) to nitrite mineral medium increased
nitrite oxidation by 2 to h fold and resulted in 100 to 1000
fold greater pepulations of cells (Krulwiok and Funk, 1965).

7

Incubation of the four strains at 37 C imposed an absolute
necessity for biotin requiring daily additions of 150 ug
per 1 of medium. The stimulatory effects of the vitamin at
30 C suggested to these authors that in N. agilig, the

synthesis of biotin was rate limiting for growth.

0 1 t or cul t we gtotr02n

Several investigators have attempted to find an
organic substrate for Nitrobacter; these substances included
acetate and formate primarily although certain other carbon
and nitrOgen compounds were studied. A significant report
on acetate assimilation was made by Ida and Alexander (1965).
They assumed that the inability of Nitrobacter to grow
heterotrOphically was caused by either: (i) impermeability
of the cell to organic compounds; (ii) lack of apprOpriate
enzymes to metabolize permeable organic molecules; or
(iii) inability of the organism to derive energy from
permeable organic compounds. Consequently, several com-
pounds were tested for permeability and assimilation.
Although none of the compounds tested could substitute for
either CO2 as a sole carbon source or nitrite as an energy
source, the organism was permeable to acetate and some other
simple carbon compounds. Other workers also found that
acetate was converted to a number of products (Delwiche and
Einstein, 1965). Since Nitrobacter was permeable to organic

compounds and was also capable of metabolizing acetate, Ida

8

and Alexander concluded that the obligate chemoautotrOphic
nature of Nitrgbgqtg; is probably associated with the inability
of the organism to derive sufficient energy to sustain growth
from the organic oxidations that it can perform.

Soon after these two reports of obligate autotrOphy,
formate was reported as an energy source for Nitrobacter
(Van Cool and Laudelout, 19663). It had already been estab-
lished that formate was oxidized by Nitrobacter (Silver,
1960; Malavolta, Delwiche, and Burge, 1962), but Van 6001
and Laudelout found that, in addition, formate was also
utilized as an energy source by Nitrobacter. The energy was
used for CO2 fixation and growth. The heterotrophic growth
was much less than autotrOphic growth as evidenced by a
generation time of lhh hours with formate and 18 hrs with
nitrite.

Another report of heterotrOphic growth by Nitrobacter
was given by Smith and Hoare (1968). Although acetate had
no effect on the rate of nitrite oxidation or exponential
growth, the compound was assimilated in the presence of
nitrite. The assimilation of acetate was particularly marked
since 33 to 39% of newly synthesized cell carbon was derived
from acetate. Carbon from acetate was incorporated into all
of the major cell constituents, including most of the amino
acids of cell protein and poly-B-hydroxybutyrate. Cell
suspensions were able to assimilate acetate in the absence

of bicarbonate and even in the absence of nitrite. Contrary

9
to previous reports, however, Nitrobacter was able to grow
heterotrOphically through seven transfers in a medium con-
taining acetate and casein hydrolysate in the absence of
nitrite and bicarbonate. With autotrOphic and heterotrOphic
growth, the generation times were 20 hours and 90 hours,
respectively. The authors concluded that N. agilis is a

facultative autotroph rather than an obligate autotroph.

Nitrl 0 ideas

Cytochromes involved. After improved cultural tech-
niques allowed investigators to obtain high yields of the

organisms (#0 to 50 mg dry weight per liter), much attention
was given to the physiology of the organism, particularly
the nitrite oxidase system.

Using cell suspensions which were contaminated with
a heterotrOphic organism (approximately 2% by cell count),
Lees and Simpson (1957) reported that a cytochrome with an
absorption maximum at 551 appeared to be intimately associated
with nitrite oxidation by Nitrobacter. Aleem and Alexander
(1958) obtained cell-free extracts of Nitrobacter which
oxidized nitrite to nitrate. When the extract was separated
into particulate and soluble fractions by centrifugation at
1nu,ooo x g, all of the nitrite oxidase (67% of the original)
was associated with the particles. This particulate nitrite-
oxidase was examined for cytochrome participation (Aleem and
Mason, 1959). With the addition of nitrite, cell-free

extracts showed absorption maxima representative of the

10
alpha and beta peaks of a cytochrome of the c-type (550 and
520 nm) and representative of the alpha and gamma peaks of
a cytochrome a-type (585 to 590 nm and #38 nm); therefore,
both cytochrome c- and cytochrome al-like components appeared
to be necessary for nitrite oxidase activity. Since a flavin
did not seem to be involved, the transfer of electrons to
oxygen via cytochrome c- and cytochrome al-like components
was preposed as indicated in the following sequence:

NO-ZMcytochrome g ———>cytochrome a1———> O2

Coupled oxidative phosphorylation. Some of the main

problems needing resolution included the thermodynamics of
a cytochrome linked oxidation of nitrite and the nature and
succession of steps by which electrons are carried from
nitrite to oxygen.

In 1960 Aleem and Nason reported that oxidative
phosphorylation was linked to nitrite oxidation. The highest
phosphate esterification to oxygen uptake (P/O) ratio obtained
was 0.2. Attempts at uncoupling the phosphorylation from
nitrite oxidation with 2,4 dinitrOphenol, thyroxine, and

6 M to 5 x 10-5 M

dicumarol in various concentrations from 10'
were unsuccessful. In fact, dinitrophenol at a final concentra-
tion of 5 x 10'“ M and thyroxine and dicumarol each at
5 x 10-5 M completely inhibited nitrite oxidation and accom-
paning phosphorylation.

In a study by Malavolta 2; a1. (1960), the P/O ratio
observed from the phosphorylation linked to nitrite oxidation

Iwas 0.5. The phosphorylation was uncoupled by 10"“ M

11
dinitrOphenol with no inhibition of nitrite oxidation. An
ATPase was also reported to be active in the cell-free
preparations.

Fischer and Laudelout (1965) obtained a maximum P/O
ratio of 0.17 for nitrite oxidation by Nitrobacter winogrgdskyi.
Attempts at purifying the particles by centrifugation depressed
the ratio below 0.1. Since an active ATPase was present in
the cell-free preparations, glucose and hexokinase were added
to the reaction system to incorporate the esterified phosphate
into g1ucose-6-phosphate.

Source of NADHZ. In 1965 Aleem reported that energy

 

from nitrite oxidation was required for the reduction of
nicotinamide-adenine dinucleotide (NAD). The requirement
for ATP and NADH2 in the reduction of 002 by cell-free
extracts of Nitrobacter could be replaced by additions of
ADP and NAD if 02 and NO; were present. The data thus
indicated that nitrite oxidation resulted in the generation
of not only ATP, but also NADH. It was concluded that some
of the ATP generated by nitrite oxidation is required for
the reduction of NAD.

The first seemingly satisfactory model for linking
the nitrite oxidation to the generation of ATP and NADH was
prOposed by Kiesow (196“). Under anaerobic conditions, a
reversal of the normal reaction of ELEEBPEQEEE occurred;
nitrate was reduced to nitrite in the presence of NADH2 as
the electron donor. A coupled synthesis of ATP occurred

with two moles of ATP being formed per mole of NO3 reduced.

12
DinitrOphenol (1.2 x 10"3 M) uncoupled this phOSphorylation
without inhibiting electron transport. Consequently, Kiesow
preposed that in the normal reaction, nitrite oxidation,
NAD is reduced at the cost of two units of ATP. Since NADH2
was shown to be oxidized aerobically with the formation of
three units of ATP per unit of NADH2 oxidized, Kiesow preposed
the following mechanism:

NADH2 + 502 + BADP + 3P1~————) NAD + H20 + 3ATP
No"2 + 2ATP + NAD + H20 ——) no"3 + 2ADP + NADH2 + 2P1

This sequence is essentially cyclic with the products of one
reaction being the reactants of the other. The novel feature
of this scheme is that the conversion of nitrite to nitrate
reduces NAD; while the real source of metabolic energy is the
oxidation of NADH2 by an electron transport system in the

usual way. The thermodynamic difficulty of this scheme is

that the reduction of NAD by nitrite oxidation requires only
two ATP units; however, the 750 mv difference in electron
potential of the two systems (NAD/NADH2 and NOE/NOB) represents

an energy equivalent of 3h,500 calories.

A mechanism which is consistent with the thermo-
dynamic considerations of NAD reduction by nitrite oxidation
was preposed by Aleem (1968). Contrary to earlier studies
(Lees and Simpson, 1957; Aleem and Nason, 1960), Aleem
reported that nitrite enters the nitrite oxidase system at
cytochrome a1 instead of cytochrome c. The coupled phosphoryla-

tion approached a P/O value of 1.0. These improved P/O ratios

13
were attributed to the culturing techniques employed and
the procedure used in the disruption of the intact cells.
The ATP generated in the oxidation of nitrite was then shown
to cause reduction of NAD by reverse electron flow (Sewell
and Aleem, 1969). Since the stoichiometry of the reduction
was 5 moles of ATP required per mole of NAD reduced, the
results were in agreement with the calculated 35 kcal free

energy difference.

Nit t R duotas

Although much is now known about the nitrite oxidase
system in Nitrobacter, almost nothing is known about the
further metabolism of nitrate. Recently, Street and Nason
(1965) reported the isolation, solubilization, partial
purification, and partial characterization of a particulate
enzyme from E12I0b§2§°l which catalyzes the reduction of
nitrate to nitrite. The enzyme, designated as nitrate
reductase, was shown to involve the transfer of electrons
via the cytochrome pathway of the bacterium and consequently
falls into the category of a respiratory-type nitrate reduc-
tase. This enzyme differs from most respiratory type reduc-
tases, however, because oxygen does not inhibit nitrate
reduction. Nitrate reduction was shown not to be merely the

reverse of nitrite oxidation in the organism.

M d o A tion 0 estic d s

Insecticides. Aldrin, chlordane, and heptachlor are

in
all cyclodienes. At present the specific mode of action of
these compounds has not been established, but on the basis
of symptomdhmw'and the effects of the compounds on isolated
nerve endings, the cyclodienes appear to be neurotoxicants
(O'Brien, 1967).

Lindane, a hexachlorocyclohexane, likewise appears
to be a neuroactive agent as the gross symptoms of poisoning
involve tremors, ataxia, convulsions, and prostration (O'Brien,
1967). Also, excessive electrical activity was seen in
lindane poisoned axions (Lalonde and Brown, 195“)-

No reports were found explaining the mode of action
of the chlorinated hydrocarbon DDD. However, since this
compound is the reductive dechlorinated analog of DDT, it
seems reasonable to assume the modes of action of the two
chemicals are similar. Contrary to DDD, DDT has been intensely
studied. Although the specific mode of action of DDT has not
yet been elucidated, all present evidence indicates that the
compound is a neurotoxicant (O'Brien, 196?).

Herbicide . The herbicide CIPC was shown to inhibit
protein synthesis in plants at points after the transport of
amino acids across the cell membrane (Mann, gt 21., 1965).

It was not determined whether there was inhibition on one

of the steps directly involved in polypeptide formation or

on the synthesis of one of the necessary cofactors such as

ATP or messenger RNA. Mann gt 91. (1967) later concluded that

CIPC inhibited the synthesis of an effector substance needed

for germination; messenger RNA seemed likely. Another

 

15
possibility for the mode of action of CIPC is uncoupling of
oxidative phosphorylation. In cabbage mitochondria,
CIPC at 10-3 M and 10-2 M severely inhibited the esterifica-
tion of inorganic phOSphate with a less severe inhibition of
oxygen uptake (Lotlikar, gt 51., 1968).

Ashton (1963) attempted to determine the mode of
action of eptam. Long exposure of plants to relatively high
concentrations of eptam (100 ug per m1) inhibited 01402
fixation, but did not alter the relative distribution of
C1“ in the various labeled compounds. When he measured phos-
phate esterification by cucumber mitochondria, Ashton observed
a marked inhibition of both oxygen uptake and phosphorylation
at 10"2 M eptam with a slight affect at 10"3 M. Since the
reduction of phosphate esterification was greater than the
depression of oxygen uptake, lower P/O ratios were obtained
in the presence of the herbicide. Similar results were
obtained when oxidative phosphorylation by cabbage mitochon-
dria was measured in the presence of 10-3 M eptam (Lotlikar,
1968).

Simazine appears to affect the Hill reaction in
susceptible plants. Moreland 2; al. (1959) found that the
toxic effect of simazine for barley could be circumvented
by supplying glucose through the leaf-tips of the simazine-
treated barley plants. These results were confirmed by
Allen and Pramer (1963) who noted that leaf-feeding glucose,

sucrose, maltose and aspartate protected the simazine-treated

barley. In a study of susceptible and resistant lines of

16

corn, Eastin 25 al. (196“) also reported protection of the
susceptible plants by leaf-feeding glucose and sucrose.
This information along with the findings of Moreland gt a1.
(1962) concerning the effect of simazine on isolated
chloroplasts of barley and corn supports the theory that
the s-triazines inhibit the Hill reaction and thereby stop
photosynthetic production of carbohydrates.

E e t o s id 8 o t on
Ingggtigidgg. Applications of 200 and 1000 ug of

aldrin per gram of soil resulted in a slightly greater nitrite
accumulation (Fletcher and Bollen, 195h). In most of the
trials nitrate formation was not consistently decreased.

Shaw and Robinson (1960) obtained similar results as no

effect on nitrification was noted with applications of 10

to 100 lbs of aldrin per acre to a Cumberland silt loam soil.
Likewise, Eartha 23.21- (1967) observed no inhibition of
nitrification in laboratory trials at an application rate of
300 ug of aldrin per gram of soil.

Brown (195h) reported significant retardation of
nitrification at 500 and 5000 ug chlordane per gram of soil,
but Shaw and Robinson (1960) reported that applications of
30 to 300 ug of eptam per gram of soil had no effect on
nitrification.

The chlorinated hydrocarbon, DDD, had no detrimental

effect on nitrification in either field trials (Eno and

17
Everett, 1958) at application rates of 12.5, 50, and 100 ug
per gram of soil or in laboratory studies (Eartha, gt a;.,
1967) with applications of 300 ug per gram of soil.

In laboratory trials heptachlor did not affect
nitrification with additions of the compound equivalent to
200 lb per acre (Shaw and Robinson, 1960), but it did cause
a significant decrease in nitrate formation with additions
of 5000 ug per gram of soil (Brown, 1954). With field
applicants equivalent to 12.5, 50, and 100 ug of heptachlor
per gram of soil, a severe decrease in nitrate production
was noted at 1 month, but was no longer evident at 16 months
(Eno and Everett, 1958).

Although the nitrate concentration was depressed
in soil samples taken 1 month after field applications of
lindane (100 ug per gram of soil), the nitrate concentration
was normal after 16 months (Eno and Everett, 1958). In
laboratory trials nitrification was significantly retarded
by the addition of 5000 ug of lindane per gram of soil (Brown,
1954), but no effect was observed with 1000 ug of lindane
per gram of soil (Bollen gt al__., 195“).

Herbicides. Using a soil perfusion technique,
Quastel and Scholefiebd(l953) obtained a prolonged lag period
(32 days) for nitrate formation by adding CIPC (3.3 x 10"3 M).
This inhibition of nitrification by CIPC was confirmed by
Eartha 22.51. (1967) since additions of 300 ug of both CIPC
and eptam per gram of soil severely reduced nitrate formation

in soil samples.

l8

Conflicting results have been obtained for the
effect of simazine on nitrification. Using a perfusion
technique, Farmer gt 1. (1965) obtained inhibition of
nitrite formation with 6 and 9 ug of simazine per m1 of
medium. In addition, 6 ug of simazine per m1 of medium
inhibited the oxidation of nitrite by Nitrobacter in pure
culture studies. Contrary to these results, Volk and Eno
(1962) observed no significant decrease in nitrate formation
with additions of simazine up to 1024 ug per gram of soil.
Likewise, Shaw and Robinson (1960) and Eartha gt’gt. (196?)
have observed no inhibition of nitrification with additions

of 100 lb per acre and 300 ug per gram of soil, reapectively.

MATERIALS AND METHODS

Pesticides

Insectigides. The five insecticides investigated
in this study were: 1, 2, 3, 4, 10, 10-hexachloro-1, 4, 4a,
5, 8, 8a-hexahydro-l, 4-gngg-gtg 5, 8-dimethanonaphthalene
(aldrin); l, 2, 3, 5, 6, 7, 8, 8-ootachloro-2, 3, 3a, 4,
7, 7a-hexahydro-4, 7-methanoindene (chlordane); 1, 4, 5,
6, 7, 8, 8-heptachloro-3a, 4, 7, 7a-tetrahydro-4, 7-gtggr
methanoindene (heptachlor); gamma isomer of l, 2, 3, 4,
5, 6-hexachlorocyclohexane (lindane); and 1, 1-dichloro-2,
2,-bis (p-chlorOphenyl) ethane (DDD). Based on chemical
configuration the three groups of insecticides represented
are: (i) cyclodiene (aldrin, chlordane, and heptachlor),
(ii) hexachlorocyclohexane (lindane); and (iii) chlorinated
hydrocarbon (DDD) groups.

Hetbigides. Is0pr0py1 N-(3-chlor0pheny1) carbamate
(CIPC), S-ethyl di-N, N-prOpyl-thiocarbamate (eptam), and
2-chloro-4, 6-bis (ethyl-amino)-grtriazine (simazine) are
the three herbicides which were investigated and they belong
to the phenylcarbamate, thiolcarbamate, and s-triazine groups

respectively.

19

20

Mggigm
Nttgobagtg: ggilis (ATCC 14123), kindly supplied by

David Pramer, Rutgers University, New Brunswick, N. J., was

grown in the clear inorganic medium of Aleem and Alexander

(1960) supplemented with NaMoOu'ZHZO as suggested by Einstein

and Delwiche (1965). The basal medium contained 0.3 g NaNOz,

0.175 g KZHPOU’ 0.2 g MgSOu'7H20, 0.1 g NaCl, 1.5 g KHCOB,

35 ug FeSOu‘7H20, and 25 ug NaMoOu'ZHZO in 1.0 1 of water.
For large-scale cultures, the medium was modified

to include 1 mg FeSOa°7H20 and 10 mg CaCl2 per 1 of medium.

Solutions of potassium phosphate, potassium bicarbonate,

and calcium chloride were each autoclaved separately and then

added to the other constituents in order to obtain a clear

medium.

Growth Efgects

To determine the effect of the pesticides on growth
of N. ggtttgg the chemicals were dissolved in acetone and
0.1 ml was added to 50 m1 of sterile medium in a 250 m1
Erlenmeyer flask. For simazine only, 12.5 mg of the dry
chemical was added to the culture flasks. Control flasks
received 0.1 m1 of acetone. Inocula (1% v/v) were taken
from log phase cultures which had oxidized 80 ug of nitrite-N
per ml. The cultures were incubated at 30 C on a rotary
Shaker. Growth was determined every 12 hr by measuring the

disappearance of nitrite by the method of Rider and Mellon

21
(1946). The range of pesticide concentrations tested was
1 to 250 ug added per ml and the duration of the experiments

was 9 days.

r -S C 1 v on

Before acquisition of a MF-l4 microferm fermentor
(New Brunswick Scientific Co.) cell suspensions and cell-free
extracts were obtained by cultivating y. ggtttg at room
temperature in glass carboys containing 18 liters of medium.
Air from the laboratory supply line was sterilized by passage
through concentrated sulfuric acid. Inocula of 1% (v/v)
were taken from 8-day stock cultures which had oxidized
200 ug nitrite-N/ml. Samples from the large cultures were
assayed every 12 hours for nitrite by the method of Rider
and Mellon (1946). Sodium nitrite was added as needed and
10 liters of culture (about 1 g wet weight of cells) were
removed and replaced by sterile medium after 1500 ug NOZ-N/ml
had been oxidized. Cells were harvested at 4 C by continuous-
flow centrifugation (Sorvall Model SS-l centrifuge equipped
with the Szent-Gyorgyi and Blum continuous flow system).
The sedimentated cells were washed three times with cold
distilled water and then suspended in 0.1 M tris (hydroxymethyl)
aminomethane hydrochloride (Tris) buffer (pH 8.0) at a concentra-
tion of l g (wet weight) per ml of buffer.

When the MF-14 microferm was used, 400 ml cultures
which had oxidized 1 mg of nitrite-nitrogen per ml were used

as inocula for 10 liters of medium. The fermentor was

22
operated at 30 C with an aeration rate of 6 liters of air
per min and a propeller speed of 200 r.p.m. Additional
sodium nitrite (10 or 20 grams) was added to the cultures
as needed. After oxidation of about 3.6 mg of nitrite-
nitrOgen per ml, cultures were harvested by continuous flow
centrifugation. The usual yield obtained after 7 to 9 days
of active growth was approximately 3 g wet weight of cells
from the 10 liters of culture.

e 0 Ce - t ts

Cell pastes were suspended in either 0.1 M tris
(hydroxy-methyl) amino methane (Tris)-hydrochloride buffer
(pH 8.0) or the slightly modified isotonic sonication medium
of Aleem (1968) at a concentration of 1 g wet weight of cells
per ml of buffer. The isotonic medium contained 50 mM Tris-
HCl buffer (pH 8.0), 250 mM sucrose, and 1 mM reduced
glutathione.

Cell-free extracts were prepared by sonic disruption
of the cells for 3 min (30 sec of sonic treatment alternated
with 30 sec of cooling) with a loo-w ultrasonic disintegrator
(Measuring and Scientific Equipment, Ltd., London, England).
The debris was removed by centrifugation at either 15,000 x g
for 15 min or 40,000 x g for 20 min in a Sorvall (model RC-2)
refrigerated centrifuge (Ivan Sorvall, Inc., Norwalk, Conn.)

and the supernatant fluid was stored at 4 C.

23; t t es

Since Nitzotggte; cannot grow on heterotrOphic
media, all cultures were routinely examined for heterotrOphic
contaminants by inoculating nutrient broth in quadruplicate
and incubating one pair at 30 C and the other at 37 C for
7 days. In addition, each of the large-scale cultures was
tested for purity by inoculation of (i) nutrient agar,
(ii) nutrient agar with 1% yeast extract, (iii) Czapek Dox
solution agar, (iv) basal salt medium (see page 20) with
agar and 0.5% yeast extract, (v) basal salt medium with agar,
nutrient broth (0.1%) and glucose (0.2%). Duplicate plates
were incubated for 7 days at 30 C and another set was incubated
at 37 C. Absence of growth was used as the criterion for

purity and whenever a culture was found to be contaminated,

it was discarded.

id ion 0 N it

The effect of pesticides on nitrite oxidation was
determined in the Warburg respirometer. The cell suspensions
and cell-free extracts were diluted so that 50 to 60 ul of
02 were consumed per hour. Usually, approximately 1.3 mg
dry weight of cells and 1.0 to 2.5 mg of protein were required
per Warburg vessel. The reaction system contained 0.1 m1
of either diluted cell suspension or diluted cell-free
extracts, 0.5 m1 of 2 x 10'“2 M NaNOZ, 0.3 m1 of 1 M Tris

buffer (pH sec), and 1e9 m1 deionized, distilled Watere

24
The center well contained 0.2 m1 of 20% (w/v) KOR.
Pesticides, dissolved in acetone, were normally added to
the Warburg vessels in 10 ul or less. The control flasks
received an equivalent volume of acetone. The reaction was
started by tipping the nitrite from the side arm and the
initial oxidation rates were determined after subtracting
the endogenous oxidation.. These initial activities obtained

in the presence and absence of pesticides were compared.

t to u t s

The procedure of Straat and Mason (1965) was
modified for determining the nitrate reductase activity.
In a total of 1.0 ml the reaction mixture contained 0.5 ml
of 0.1 M acetate buffer (pH 6.0), 0.2 ml of 0.1 M KNOB, 0.1
ml of suitably diluted cell-free extract, 0.15 ml of 1% (v/v)
mammalian cytochrome c (Sigma Chemical Co., St. Louis, Mo.)
and 0.25 ml of 2 x 10'5 M sodium ascorbate. The reaction,
maintained at 30 C, was started by addition of KNOB; the
nitrite formed was measured at the end of 10 min. Briefly,
the nitrite was measured by first stopping the reaction
with the addition of 0.5 ml of 1% (w/v) sulfanilic acid in
2 N HCl. Denatured protein was then removed by centrifugation
and 0.5 m1 of 0.12% (w/v) N-(naphthyl)ethylenediamine dihydro-
chloride was added. The volume was adJusted to 2.4 ml with

distilled water and the absorbence at 540 nm was determined

25
after 10 minutes. Amounts of nitrite ranging from 10'3
to 10'1 umoles contained in the final volume of 2.4 ml were

used for preparation of a standard curve.

NADHZ Oxidase

 

Spegtgothotomgtggg agsay. Reduced nicotinamide
adenine dinucleotide (NADHZ) oxidase was measured by the

method of Smith and Hoare (1968). The assay solution con-
tained 0.1 ml of mums2 (10‘3 m), 0.1 m1 of 0.5 M MgClz, 0.1
ml of l M Tris (pH 8.0), apprOpriate dilutions of enzyme,
and distilled water to 1.0 ml. The decrease in absorbance
of NADH2 at 340 nm produced by the cell-free extract was
either measured at 30-sec intervals for a lO-min period with
a Beckman model DU spectrOphotometer or measured by a Gilford—
2000 multiple sample absorbance recorder attached to a
Beckman.DU spectrOphotometer. The initial activities were
calculated as the decrease in absorbance per min. Since the
pesticides were added in acetone, the control cuvettes
received an equal volume of acetone (usually 10 ul or less).
Activities were corrected by subtracting the slight decrease
in absorbance which occurred in the absence of cell-free

CXtraOte

ngpl;gmgtg;_ggggy. Cell-free extracts were measured
for NADHZ oxidase activity and concomitant esterification

of inorganic phosphate in the Warburg respirometer. Oxygen
uptake was determined by the usual Warburg technique and

26
esterification of inorganic phosphate was measured in the
same reaction vessel. In a final volume of 2.3 ml the main
compartment of the Warburg contained 50 umoles glucose,
15 umoles MgClz, 2 umoles ADP, 150 umoles Tris-hydrochloride
buffer (pH 8.0), 20 umoles KZHPOu-32P(0.3 ucurie), 1 mg
hexokinase, and 4.4 mg N. ggtltg cell-free extract. Addi-
tion of 0.5 ml NADHZ (20 umoles) from the side arm started
the reaction. The center well contained 0.2 ml of 20% KOH
(w/v).

toch ome C 0 d 8

To measure cytochrome c oxidase activity, the follow-
ing reaction system was used: 0.1 ml of 1.0 M Tris buffer
(pH 8.0), 0.1 ml cell-free extract (0.36 mg protein), 0.3 ml
of 1% (w/v) cytochrome c, 0.3 ml of 2 x 10-5 M sodium
ascorbate, and 0.3 ml of deionized, distilled water. The
reaction was started by addition of cell-free extract and
the decrease in absorbance was measured at 550 nm with a
Gilford-ZHD multiple sample absorbance recorder attached
to a Beckman model DU spectrOphotometer. Initial activities
were corrected by subtracting the decrease in absorbance
which occurred in separate cuvettes without the enzyme.
Because the pesticides were added in acetone, an equivalent

amount of acetone was added to the control cuvettes.

Oxidativg Phosphorylation Cougled
To Nitritg Oxtdgtton

Assay by KZHPoB-32P incorporation. Oxidative

 

27

phosphorylation coupled to nitrite oxidation by Nttggtggtg;
ggtttg was tested by slight modifications of the method of
Fischer and Laudelout (1965). Oxygen uptake was determined
by the usual Warburg technique and esterification of inorganic
phosphate was measured in the same reaction flask. The
reaction system contained 50 umoles glucose, 15 umoles
MgClz, 2 umoles ADP, 150 umoles tris(hydroxy-methy1) amino-
methane (Tris)-hydrochloride buffer (pH 8.0), 20 umoles
KZHPOu-BZP (0.3 ucurie), 1 mg hexokinase, and 1 to 2 mg
N. ggtttg cell-free extract in 2.3 ml. The reaction was
started by addition of 0.5 m1 NaNO2 (20 umoles) from the
side arm.

After 60 minutes incubation at 30 C, the reaction
was stappcd by addition of 0.5 ml of 20% ice cold trichloro-
acetic acid. Aftcr removal of denatured protein by centrifuga-
tion, inorganic phosphate was separated from the organic
phosphate by the method of Rose and Ochoa (1956). This
separation procedure involved adding 0.5 m1 of 10 N H230“
and 1.0 m1 of 5% (w/v) ammonium molybdate to an aliquot of
protein-free supernatant (0.4 to 0.8 ml). After the samples
were diluted to 5 ml with distilled water, 5 m1 of isobutanol
were added. The samples were mixed well and allowed to
stand for 15 min before discarding the upper isobutanol layer.
The sides of the tubes were washed with 2.0 m1 of isobutanol,
and the upper layer was again removed. Extracted samples
(1.0 ml) were taken to 15 m1 final volume with the scintilla-

tion fluid described by Bray (1960) and were then assayed

28

for radioactivity in a Model 6860 liquid scintillation system
(Nuclear-Chicago). Since more quenching occurred in
extracted samples than occurred in unextracted samples,
the results were calculated as disintegrations per min by
employing internal standards.

glggose-é-Rhosphgte dghydrogengse gssay. In some
instances, esterification of inorganic phosphate was deter-
mined by a g1ucose-6-phosphate dehydrogenase assay (Pinchot,
1953). The phosphorylation reactions were stOpped by addi-
tion of 0.1 ml of 35% (w/v) HClOu. After being stored in
ice for 30 min, the solutions were neutralized by addition
of 0.1 m1 of 3.5 N KOH. Denatured protein was removed by
centrifugation and the glucose-6-phosphate concentrations
were determined by assaying samples (0.2 ml) in a reaction
system containing 100 umoles Tris (pH 7.4), 10 umoles MgClz,
2 umoles EDTA, and l umole NADP. The reaction was started
by addition of 0.5 units of g1ucose-6-phosphate dehydrogenase
(Sigma Chemical Co.). The umoles of glucose-6-P0u present
in the samples were determined from the increase in absorbance
at 340 nm which occurred in 10 minutes. The molar extinction

coefficient of NADPH at auo nm is 6.22 x 103.

thtytiggl Nethods

ngoggggse. Hexokinase (Sigma Chemical Co., St.
Louis, Mo.) was assayed by the method of Darrow and Colowick

(1962).

29
fizgtgtn. Protein concentrations were estimated by
the method of Lowry gt gt. (1951). Crystallized, bovine
fraction V albumin (Sigma Chemical Co.) was used as protein
standard.

RESULTS

Gtowth Effects

Each pesticide was tested to determine its effect
on the growth of N. 351115 in aerated cultures. The range
of pesticide concentrations tested was 1 to 250 ug/ml and the
duration of the experiment was 9 days. The results of this
experiment are illustrated in Table 1. Only two compounds,
aldrin and simazine, were not inhibitory under the conditions
of the experiment. The other six compounds: lindane, DDD,
chlordane, heptachlor, CIPC, and eptam prevented nitrite
oxidation for 9 days, while control flasks exhausted the
nitrite within 3 days. Based on the concentration of
pesticide required for 100% inhibition, the compounds were
arranged in the following order: DDD (5 ug/ml), chlordane
(5 ug/ml), CIPC (10 ug/ml), heptachlor (10 ug/ml), lindane
(10 ug/ml), and eptam (75 ug/ml).

Oxiggtton Studies with Cell figspensions
gtd Ce Free Ettrgcts

gg1;§ gggwg in 18-11ter carboys. The possible effect
of growth inhibitors upon the nitrite oxidase activity of

N. ggilis was studied in the Warburg reapirometer by measuring

the nitrite oxidized by whole cell suspensions. When cells
30

31

o 0 cm N: CH

 

 

 

 

 

 

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maimm mm mm N: N: ms nu sauce
0 o m mm H
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N: Na N: m: 0H
m ca me as as ms nu omHo
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N: m: we m: n
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m.moaspHso concave sH MAHAMd

ummmnmmMmHz no corona so ccoacaococ co cocccm .H names

32

on» c>ono mm: pH momma pmos 2H

.HeoeH soaHanche

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.Ha non zumbz ms N: no: mammHu HHm sH :oHpmnpmoosoo opHnuH: HchHch

 

 

 

 

 

   

 

 

 

 

o o 0 mm Hoapsoo
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coacacnoo .H mqm<e

33

were grown in 18-1iter carboys at room temperature,
approximately 1 g wet weight of cells was obtained from 10
liters of medium after two to three weeks of growth. Upon

the addition of aldrin, DDD, CIPC, eptam, heptachlor, and
simazine to these cell suspensions, no effect on nitrite
oxidation was observed with aldrin and simazine (250 ug per
m1), but DDD, CIPC, eptam, and heptachlor were inhibitory
(Fig. l). CIPC at 90 ug/ml inhibited nitrite oxidation by
56%, and at 180 ug/ml caused 100% inhibition. Eptam caused
52% and 100% inhibition at 180 ug/ml and 270 ug/ml, reapec-
tively. The oxidation rate was reduced by 45% with heptachlor
concentrations from 180 to 540 ug/ml, and only 58% at 720 ug/ml.
The compound DDD was one of the most inhibitory pesticides

in aerated cultures since no growth occurred at 5 ug/ml, but
in the Warburg study only 54% inhibition resulted with 540
ug/ml.

The effects of pesticides on nitrite oxidation by
cell-free extracts (Fig. 2) were similar to the results
obtained with cell suspensions. CIPC completely inhibited
nitrite oxidation at 180 ug/ml with 49% inhibition occurring
at 90 ug/ml. DDD caused only 59% inhibition at 430 ug/ml.
Heptachlor was slightly inhibitory with 33% inhibition at
535 ug/ml. Eptam was similar to CIPC as no oxidation was
observed at 360 ug/ml and 33% inhibition occurred at 180 ug/
ml.

Cells grown in MF-l4 microferm fermentgt. After

acquiring an MP-l4 microferm fermentor, we noted that the

 

34

50 50-

l

02 (Ml)

N
O

l

Uptake of

 

 

o. , , are...MIMI.itLLJIEQTsImLQJfigmmvm

I I -
‘ .._.__..___._.

IO 20 30 4O 50

50

40_

(u!)
U
0

2

I

Uptake of O
to
O

 

 

 

 

      

 

 

IO_
0 wing?!)Isatmuaqisnma I ,
I,, . I c mrh.ax. _____ “_ ‘ r
20 30 40 3C
0 ‘0 2l‘)viinutesgo 40 5O 0 10 Minutes
FIG. 1. The effect of pesticides on nitrite oxidation by
EEEESEEEEEE agilis cell suspensions.

 

    
    

 

 

 

 

 

 

 

 

 

 

35
so _ so -
40 y
E
30 _
N
o
3
320_
2
O.
2)
10
o r - went-..“ -mWLEhJQQ uglmlWClPC
.J.;~‘_.._Lr_____. _*~_~LI :-__I~-_-Yl_.~_.,lI yum,“ ,1;
o 10 20 3 0 4o 5 o
70 _
60 g
50 _
340_
ON
B
.2 30 _
2
c.
D
20 _
Io _
0 g "mummy“... ” . ' bonunlm'l .E ‘ tam fl. .
-- -—I~‘ *‘r ,__~_:~:::L'_:51~0:1 filL“iv..;;~__‘"“"L|'!‘.‘ILl.."1“ 1 ‘____r ___- __
0 I0 20 30 4o 50 0 IO 20 30 4'0 5'0
Minutes Minutes

FIG. 2. The effect of pesticides on nitrite oxidatiOn

by Nitrobacter ggiltg cell-free extracts.

 

36
improved aeration and temperature control, as compared with
the lB-liter carboys, resulted in a significant increase in
Nttggtggtg; cell yields. About 3 g wet weight of cells were
now obtained after 7 to 9 days growth. In addition, the
stability of the cell suspensions was maintained by suspending
the cells in the isotonic medium of Aleem (1968) in which
the oxidase activity was stable for 7 days at 5 C and for
over 2 weeks at -20 C. When the cells were suspended in
0.1 M Tris-hydrochloride buffer (pH 8.0), the nitrite oxidase
activity normally decreased by 50% within 4 days at 5 C.

In order to determine whether the improved growth
rate altered the effects of pesticides for cell suspensions
and cell-free extracts, the earlier experiments were repeated
(Table 2). Of the four pesticides previously tested, hepta-
chlor was the only compound which affected both cell suspen-
sions equally, whereas the other three chemicals were more
inhibitory for the nitrite oxidase from the cells grown in

the fermentor.

In spite of the increased inhibition in this latter
experiment, high concentrations of the pesticides were still
required for significant inhibition of the nitrite oxidation.

Of the six pesticides which inhibited growth, only CIPC and
eptam appreciably affected the nitrite oxidase activity of

cell suspensions (Table 2). However, 110 ug/ml CIPC and

275 ug/ml eptam were required for total inhibition of oxidation,

 

 

 

 

 

an .34 R 2: in
on m~.N on o.o~ con man mm mm.H em m.HH cow can
on w.H mm m.oN omH om No.m No o.m~ ooH
0H «6 NH e6 com 3 H.~ mm w.mH omm
a m.o o o.o cmm occonoHso mm oH.H om o.m com occonoano
mm ms.~ mm e.m~ on
wH mm.o mm w.~H mm
mm mo.m am 0.0m om HH Hm.o 5H 0.x om
m mm.o o o.o ooH m mN.o mH m.m ooH
o o.o o 0.0 mNH umHo o 0.0 o o.o oHH umHo
ooH H.e ooH N.ee ocoz ooH mm.e ooH o.me ocoz
In“ .ILM BRI IuPI
huH>Huo< muHuuH: muH>Huo< N compo opHoHummm huH>Huo< ouHuqu muH>Huo< N compo mpHoHumom
o>Huchm mmH081 m>HumHmm oa Ha\w1 o>HumHmm mmHoaa m>HumHmm 00 Ha\w1
ooasmcou muHuqu oxmuma ammwxo e meSmCou muHuqu oxmuma auwwwo
I
a myfiqmflHHHMflflAHmulwflmmm

 

 

 

 

 

 

 

.mHHHmm nouwwoouuww mo

muomuuwm mmumnHHoo one naondmamSc HHmo

kn COHumvon muHuuHC do movHoHumoa mo uoomwm

.N NHQ<H

38

 

 

Non mo.e cod o.ms omN ocaaneaam
mm e.m on c.mm com oneness em ma.a as e.- com canoes;
AN :4 n: as: o2 3 ma 8 Nam mi
N m o o o o ooN mm o n no o on cam
N L.o o o.o omm connoecaom em as.~ as o.H~ com ecnaoancom
as AH.~ ms c.o~ can
on Am.H LN ~.oH com
co LA.“ on o.Hm can NH“ mm.o mH o.m mNN
NH as.o AN H.NH omm nHH am.o N e.m omN
NH m.o o o.o mam apnea o o.o o o.o mam space
an oc.~ ca m.mm man
an m; as Com o2 écacov can
IuFII MK IMP, In?
seaeaco< cannons scaonco< N emcee oesoscaoa acasaco< ceases: soasnco< N cocoa oeaoancca
o>HumHmm moHoan m>HumHmm 00 Ha\w1 m>HumHmm mmH081 m>HumHmm oo Ha\m1

 

eoasaaoo ocaaoaz

 

oxmuos sowhxo

 

 

oossccoo conconz

 

mxmum: ommmmo

 

 

A

muomwuxm omumuHHoo

 

 

accommoonsm HHoo oHoa3

 

.possHucoo

.N mHm<H

39

.Honwnpoa no oBsHo> ucoawbaauc ca cobaoooh mHommob Honpcoo .0 on p6
awashno on copanomm>o on“ Hocmnuoa no as N :a mammmob wnsnumz on nouns mm: ocaumadmo

.mocaoapmon on» spas Oman and AH: OHV econoow no oncomonn on» ma

cocaaHOpoc one: mop¢u msoccwonso can vacuoom H: OH copaooou maonpnoo .o:ouoo¢ as 0H
ad conga one: mooaoapmoa one .nopaz ooaaapmao go as m.a can Ao.m may kahuna mans

2 H go as m.o .Amoaoas oav Nozaz z uoa x o.~ go He m.o .Acdopoun ma mo.av pomuuum
conuldaoo no Annmaox 590 we Hm.mv mHHoo nosuam no as H.o conadpnoo Hommob noamn.d

.nsoz Hon
adoponn we non coasmcoo opdupdn mvaoa: ma cad No H: mm commonaxo .Opmn coauaoauon

.Hsos non mHHoo no
unwaok hue we hug cOBSmcoo ouahpas moHoau mm and No a: mu commonguo .opan nodpdoaxoa

.Uoundvcoo .N m4m<B

no
but only 10 ug of CIPC per ml and 75 mg of eptam per ml were
required for cessation of growth (Table 1).

The nitrite oxidase activity of cell-free extracts
was then tested in the presence of pesticides. Eptam, CIPC,
DDD, and lindane affected both cell suspension and cell-free
extract activities from fermentor grown cells similarly
(Table 2), but heptachlor and chlordane were more inhibitory
for the nitrite oxidase in the cell-free extracts. The
extract activity was completely inhibited by the addition
of 250 ug of chlordane per m1 and 200 ug of heptachlor per
ml, but the nitrite oxidase of cell suspensions was inhibited
by only 50% and 75-80% with 500 ug of heptachlor and chlordane
respectively. Neither‘DDD nor lindane at 500 ug/ml caused
cessation of nitrite oxidation by either cell suspension or
cell-free extracts.

When nitrite oxidase activity was measured by nitrite
disappearance, the results were in close agreement with the
oxygen consumption data (Table 2). Slight differences were
noted, but these were expected since oxygen uptake was
calculated as initial rate whereas the nitrite concentration
was determined at the end of the l-hr assay period. In some
instances the initial oxidation rate was zero, but a small

amount of oxygen was consumed before completion of the assay.

K t s of O i a 0

Using cell suspensions, three pesticides, CIPC,

eptam, and DDD were selected for further study in the

41
respirometer. The amount of the pesticides added were:
25 ug/ml of CIPC, '70 ug/ml of eptam, and 200 ug/ml of DDD.
The concentrations of nitrite added to the Warburg flasks
varied from 1.5 to 12 umoles. The types of inhibition which
occurred (Fig. 3) were noncompetitive, competitive, and
uncompetitive with CIPC, eptam, and DDD respectively. The
Michaelis constant (Km) for the nitrite oxidation without
pesticides was 3.76 mM, while the Michaelis constants for
the inhibited reactions were: CIPC, 3.76 mm; eptam, 5.h9 mm;
and DDD, 1.68 mM.

Nitrate Bedggtggg

Although the metabolism of flitggpggtg;,depends on
the oxidation of nitrite to nitrate, the microorganism con-
tains an enzyme capable of reducing nitrate to nitrite
(Straat and Nason, 1965). Since these authors have established
that the reduction is not merely the reverse of nitrite
oxidation, the enzyme could have physiological importance.
When the nitrate reductase activity in cell-free extracts
of Nitrobacter was measured with each of the pesticides which
affected the nitrite oxidase activity, no deleterious effect
occurred with any of the compounds up to 500 ug per m1. A
representative value for the nitrite produced by the cell-
free extracts during the 10 min reaction was 0.025 umoles

per mg of protein.

#2

FIG. 3. The nature of the inhibition of
nitrite oxidation by three different pesticides.
Each Warburg flask contained 0.1 m1 of Nitrobacter
agilig cell suspensions (1.3 mg dry weight), 0.5 ml
of NaNO2 (2 to 12 umoles), and 0.3 ml of Tris
buffer (pH 8.0). The center well contained 0.2 ml
of 20% (w/v) KOH.

.05

q

 

 

 

 

 

 

 

nu

NADHZ Oxidase

 

Although Smith and Hoare (1968) postulated that
NADH oxidase is not involved in the autotrOphic growth of
flitrgbggtgr, Aleem (1968) showed that NADH2 oxidation in
Eltxghagtgz,proceeds by an electron transport chain analogous
to the mitochondrial respiratory chain reported by Chance
gt 1. (1967). Consequently, the NADHZ oxidase activity was
measured in the presence of pesticides to obtain an indica-
tion of electron transport inhibition. The results of the
preliminary experiment are shown in Fig. h. At 500 ug
pesticide per ml, heptachlor did not affect the reaction;
DDD stimulated the oxidase activity; but CIPC and eptam were
inhibitory (67% and 100% respectively). The experiment was
repeated with various concentrations of eptam to determine
the minimum concentration causing complete inhibition. As
illustrated in Fig. 5 this phenomenon occurred with 375 ug
eptam per ml. However, since the change in absorbance was
only 0.05 per min per mg of protein, it was possible that
NUDE was reducing flavoproteins instead of the electron trans-
port chain. To test this possibility, the reaction was
repeated with another cell-free extract. A decrease in
absorbance of 0.18 per mg of protein was noted at 10 min,
but this activity was not affected by the addition of 10
umoles azide. A slightly increased rate (A Optical density
of 0.25 per mg protein) was obtained by additions of either

flavin mononucleotide (PMN) or flavin adenine dinucleotide (PAD)

“5

FIG. 4. The effect of pesticides on NADH2
oxidase activity of yitggpagtgz_ggilig cell-free
extracts. The reaction system contained 10'3 H NADHZ,
0.1 ml; 0.5 M MgClz, 0.1 ml; 1 M Tris buffer (pH 8.0),
0.1 ml; cell-free extract, 0.02 1111 (0.1.9 mg protein);
and water to 1.0 m1. Pesticides were added in 10 ul

acetone. Decrease in absorbance of NADHZ was measured

at 3h0 nm.

46

 

 

 

 

 

 

T l I l
.030h.
.025 ..
3020 _
c
0
¢
8"...
[grins _
c
a
'9.
3
.n
<t£fl0 _
<1
.005 -
o lI~:35121-~—v:__.x,;;g,;i',WmWnrh 5001503?! Emam
0 15 30 45 60

Seconds

u?

 

.030. 0‘ —‘ ‘ __ ' ' _

b
to
u:

A Absorbcncy (340 nm)

.005-

 

 

 

‘ . . -.‘..-' .- A .u 5' " 5 ’1‘." ‘nr ’. at. :‘ -
[animus-em ”acme“... -—---- "--

0 15 ' .30 45 00

 

FIG. 5. The effect of eptam on NADHZ oxidase
activity of W m cell-free extracts.

Conditions were the same as those described on Pig. ‘0.

“8

at 2 x 10'“ h final concentration, but control cuvettes with
aside (10 uncles) had equivalent rates. Likewise, using a
phosphate buffer (0.05 h) at pH 7 and 8 resulted in no
apparent NNMBZ oxidase.activity; consequently, the absorbance
decrease observed at 300 nm was probably caused by the
reduction of flavOproteins.

In support of this conclusion was the observation
of diaphorase activity in the cell-free extracts with 2,6-
dichlorcphenolindophenol (1.2 x 10’” n) as the electron
acceptor. A.decrease in absorbance of 6.6 per min per mg

of protein.was noted at 600 nm.

W

Pesticides which affected the nitrite oxidase activity
of cell-free extracts were tested for an effect on cytochrome
c oxidase. host of the pesticides tested inhibited cyto-
chrome c oxidase to some degree but none completely suppressed
the activity (Table 3). Heptachlor, the most inhibitory,
decreased cytochrome c oxidation by 76$ at 500 ug/nl, but
completely suppressed nitrite oxidase at 200 ug/ml (Table 2).
At 500 ug/ml, DDD caused a similar effect on both oxidaees as
relative activities of 56% and 661 were obtained for nitrite
oxidase and cytochrome c oxidase, respectively. Eptam was
unique in this series of compounds because a slight, but

reproducible, stimulation of cytochrome c oxidase was noted.

#9
TABLE 3. Effect of pesticides on cytochrome c

 

 

oxidase.

Concentration Relative

Compound (final) Activityb Activity
ug/ml fl

Control --- 0.139 100
Chlordane 500 0.081 58
CIPC 500 0.069 50
DDD 500 0.092 66
Eptam 500 0.167 120
Heptachlor 500 0.033 2b‘

aReaction mixture contained 0.1 m1 of 1.0 M
Tris buffer (pH 8.0), 0.1 ml cell-free extract (0.36 mg
protein), 0.3 ml of 15 (w/v) cytochrome c, 0.3 m1 of
2 x 10'5 n sodium ascorbate, and 0.3 ml distilled water.
Sodium.cyanide (10 umoles)completely inhibited the reac-

tione

bActivity expressed as decrease in absorbance

at 550 nm per min per mg of protein.

d o ho c o
W
W- Aleem (1968)

recently reported P/0 ratios which approached 1.0 for the
esterification of inorganic phosphate coupled to nitrite
oxidation in £12222§2££I.§Ell$§- Aleem felt the high P/O
ratios were caused by two important factors: (1) the
cultural conditions of the organism and (ii) the procedures
used for disruption of the cells. He stated that actively
growing cultures must oxidize three additions of 20 mM
nitrite per day for at least two days or the P/O ratios
will be low. The cells obtained from such cultures were
suspended in an isotonic sucrose-EDTApGSB solution and
disrupted by sonication for 3 min.

In accordance with these suggestions, only cultures
which oxidized at least 60 mM nitrite per day for two or
more days were used for phosphorylation studies. The
turbidity (#20 nm) and nitrite oxidation of such cultures
during growth is illustrated in Fig. 6.

The generation time (27.6 hrs) was calculated from
the time required for a doubling of absorbency during the
active phase of growth. When the turbidity (420 nm) was
measured as a function of the nitrite oxidized (Fig. 7), the
growth efficiency (ratio of absorbancy increase per unit of
nitrite consumed) appears to decrease after oxidation of
about 90 mmoles of nitrite per liter. The cells obtained
from these cultures were suspended in the isotonic medium

and sonicated for 3 mins.

0.35

(D
is
u:

.0
to
o

0.15

Absorbmncy C420 nm)

0.10

O. 05

 

 

”“45”“ "
I J ‘11. l 1 l

I

p
M
CD

I

.0
u:
U:

0.1 0

0.05

 

 

1.0 2.0 3.0 4.0 5.0 . 6.0
Days

7.0

FIGe 6e Rate of nitrit. ”idfltion (’A‘A-) and

turbidity (-o-o-) in large-scale cultures.

52

 

 

 

I I

0.35 ,.‘

0.30 F

0.25 t.
A is
E ;
=
° 2
«0.20 _
‘f a
V O
>M 7‘
U :
s. m/
.0 "5 " o . 3
.s. 5
C) 3
m. a
g- .
.10 _ .3
‘
°
0.05. _
0 4L? l J l 1 3 L

 

-O 0.05 0.10 p 0.15 0.233
, 'thrij’e Oxidized G‘dofiesiiifiov)
_§IG. 7. Turbidity as a function of I

- nitrite oxidation in large-scale cultures.

53

E££22£.21.2122_221_222sns CIPC and eptam. the two
herbicides which inhibited the growth of yitzgpggtgr in

flask cultures (Table 1), caused reduced P/O ratios with
cabbage (Lotlikar, gt,g;., 1968) and cucumber mitochondria
(Ashton, 1963). When nitrite oxidation and the concomitant
esterification of inorganic phosphate were investigated in the
presence of CIPC and eptam, both the nitrite oxidation and
phosphate esterification were inhibited (Table h). At 50 ug
CIPC per ml, oxygen uptake was inhibited by 16$, but phos-
phorylation was reduced by 53%. With 75 ug of CIPC per m1,
51$ inhibition of oxidation was accompanied by an 85% reduc-
tion in phosphorylation. With eptam (200 ug/ml) phosphoryla-
tion was inhibited by 93%, but oxidation was reduced by only
h7%. Since reduced P/0 ratios were obtained, both pesticides
exerted an uncoupling effect on the oxidative phosphoryla-
tion linked to nitrite oxidation in ELLIQDBQEII.EELLL£-
EtIgg§_gz_§‘fl;ginitzgpngngl. The inhibition of oxygen
uptake in Eitzgpggtgg,by CIPC and eptam (Table 0) is not
necessarily inconsistent with the observed uncoupling of phos-
phorylation since several workers (Butt and Less, 1960; Aleem
and Nason, 1960) have reported inhibition of nitrite oxidation
in yitzghggtgg'by 2,0-dinitrOphenol (DNP). When various
concentrations of DNP were tested for an effect on oxygen
uptake and phosphorylation by flingggqtg; cell-free extracts,

oxygen uptake was decreased by 18% and 37% at 2.5 x 10'“

M and
1 x 10'3 M respectively (Table 5). However, since phosphoryla-
tion was inhibited by 07% (2.5 x 10'” n) and 100% (10"3 n), the

P/O ratios decreased with increased concentrations of DNP.

Sh

TABLE 0. Effect of CIPC and eptam on oxidative
phosphorylation in y. agilig cell-free

 

 

extracts.a
Pes- 02 uptake , Esterification b
ticide Concn. Rel. Act. Bel. Act. P/O
ug/ml uatom 1 umole %
None --- 8.52 100 1.35 100 0.16
CIPC 25 8.“ 98 1.09 81 0.13
50 7.1 8b 0.58 #3 0.08
75 0.2 09 0.20 15 0.05
100 1.7 20 0.00 0 0.00
100 7.9 92 0.83 62 0.11
150 6.5 77 0.3“ 25 0.05
200 5.0 58 0.08 6 0.02
300 2.” 29 0.00 0 0.00

 

aThe reaction system in 2.8 ml contained 50 umoles
glucose, 15 umoles MgClz, 2 umoles ADP, 150 umoles Tris
(pH 8.0), 20 umoles xzapou-p32, 20 umoles NaNOz, 1 mg
hexokinase, and 1.2 mg cell-free extract.

bRatio of umoles of phosphate esterified to uatom of

oxygen consumed.

55

TABLE 5. The effect of 2,h dinitrOphenol on
oxidative phosphorylation in 3. 551115.

 

 

Concn. Oxygen uptakeb Esterificationb P/Oa
of DNP Rel. Act. Bel. Act.
mM uatom % umole %
None 8.1 100 1.u5 100 0.18
0.10 6.7 8b 0.86 60 0.13
0.25 6.6 82 0.69 #7 0.10
0.50 6.6 82 0.19 13 ' 0.03
1.0 5.1 ' 63 0.0 0 " 0.00
2.0 3.3 ui 0.0 0 0.00

 

a"Values corrected for endogenous rates. Reaction
system was same as with Tab1e«h. Protein concentration was

1.1 mg per Warburg vessel.

bRatio of umoles esterified phosphate to uatom oxygen

consumed.

56
Since the amounts of glucose-6-phosphate formed in these
experiments were determined by assay with glucose-6-phosphate
dehydrogenase, the dehydrogenase and hexokinase activities
were tested in the presence of DNP to ascertain that the
inhibitory effect observed with DNP was definitely on
3131223933; phosphorylation. Neither hexokinase activity

nor glucose-6-phosphate dehydrOgenase activity was affected
by DNP.

N22g§§L§z_2£_§:apping_§z§tgn.' Since an ATPase has
been reported in NLIIQRIQE ; cell-free extracts (Malavolta
gt g1., 1960; Fischer and Laudelout, 1965), a hexokinase
trapping system was included in our phosphorylation study.
When hexokinase and glucose were excluded from the reaction
system, the P/O ratios were reduced by approximately ROS
(Table 6). Consequently, an ATPase was present in our
cell-free extracts.

WW- 'Ihe
P/0 ratios obtained for H1222222£2I cell-free extracts with-
out pesticides ranged from 0.16 to 0.33. Since these ratios
were lower than the ratio recently reported by Aleem (1968).
the procedure for extraction of the inorganic phosphate was
tested to determine if any organic phosphate was lost in the
inorganic phosphate fraction. Glucose-6-phosphate was
synthesized in a reaction mixture containing 0 umoles of
uniformly Cl“ labeled glucose, 20 umoles of ATP, 20 umoles
of potassium phosphate, 10 umoles of MgClz, 150 umoles of
Tris (pH 8.0). and 1 mg of hexokinase in 1.8 m1 final volume.

57

TABLE 6. Necessity for trapping system for

oxidative phosphorylation.

 

Oxygen

Inorganic

 

 

Systema uptakeb phosphateb P/O
esterified
uatom umole

Ie Complete 9e0 1eh8 Gel?
Minus hexokinase 10.1 0.89 0.09
IIe Complete 12e1 “.30 0e36
Minus hexokinase 10.7 3.5h 0.2“

8Complete system was the same as for Table‘h. The

system without hexokinase also contained no glucose, but

contained 10 umoles ADP.

The above results were obtained

with two separate cell-free extract preparations (I and II).

Protein concentration in both cases was 2.1 mg per Warburg

vessel.

bValues were corrected by endogenous flasks with and

without hexokinase.

58
After 30 minutes incubation, 0.2 ml of TCA (20%) was added
to stOp the reaction. The radioactivity present in extracted
samples was then compared with the radioactivity in equivalent
volumes of unextracted samples. After the results were
corrected by the use of internal standards, 106% of the total

radioactivity was obtained in the organic phosphate fraction.

Phosphorylation Coupled to the Oxidation of NADHZ'

 

Phosphorylation coupled to the oxidation of reduced
nicotinamide adenine dinucleotide (NADBZ) was tested to
determine whether the pesticides were inhibiting electron
transport in addition to phosphorylation. Earlier attempts
to show the presence of NADH2 oxidase activity by a spectro-
photometric assay were unsuccessful, but when the oxygen
uptake of cell-free extracts was measured in the Warburg
respirometer with NADH2 as the substrate, azide (10 umoles)
inhibited the reaction by 02% (Table 7). Since the azide
inhibition is a measure of the oxidation occurring via the
electron transport chain, it was assumed that 2 umoles of
hMDH were oxidized by NADH2 oxidase and 2.8 umoles were
oxidized via flavoprotein reduction. Although CIPC (100 ug/
ml) and eptam (300 ug/ml) inhibited the reaction by 50 and
60% respectively, the results are inconclusive for determining
whether the pesticides are electron transport inhibitors.

If all of the oxidation in the presence of the pesticides
was by flavoprotein reduction, both compounds are potent

inhibitors of NADH2 oxidase; however, if only the flavOprotein

59

TABLE 7. NADHZ oxidase activity of g. agilig.

 

 

Oxygen Rel.
Description Uptakea Activity
uatom %
Complete system (CS) “.8 100
as with 100 ug/ml 2.» 50
CIPC
CS with 300 ug/ml 1.7 36
Eptam
CS with 10 umoles 2.8 3 58
Azide

 

.‘Corrected for endogenous uptake. Reaction system
essentially the same as with Table 0 with 10 umoles of
NADH2 used as substrate instead of NaNOZ. The protein

concentration was “.14 mg.

60
reduction was inhibited by the chemicals, NADH2 oxidase was
not affected. Consequently, the oxidation was measured in
the presence of both the herbicide and azide. Since no
phosphorylation was observed in the initial study, FMN (10"7 M),
menadione (10"6 M) and cytochrome c (5 x 10'3%) were included
in the complete reaction system. Again no phosphorylation
was observed, but the pesticides did not inhibit electron
transport (Table 8). Since CIPC, eptam, and azide inhibited
NADH2 oxidation by h6i. 39$. and 23% respectively, the
inhibitions caused by CIPC combined with azide and also
eptam combined with azide should have been 69% and 61% if
flavOprotein reduction rather than electron transport was
affected. The actual inhibitions were 67% (CIPC with azide)
and 69% (eptam with azide); consequently, CIPC and eptam did
not inhibit electron transport.

61

TABLE 8. The effect of CIPC and eptam on NADH2 oxidation.

 

 

Description Oxygen Uptakeb Inhibition of
O2 Uptake
uatom %
Complete Reactiona 6.1 0

System (CBS)

CBS with 10 umoles h.7 23
Azide
one with CIPC 3.3 u6

(100 ug/ml)

CBS with CIPC and 2.0 67
Azide
CBS With Eptam 307 39

(300 ug/ml)

ass with Eptam 1.9 69
and Azide

‘— ‘ A

8Complete reaction system contained 10 umoles NADHZ,
10 umoles KZHPoh-BZP, 20 umoles glucose, 2 umoles ADP,
100 umoles Tris buffer (pH 8.0), 10 umoles MgClz, 3 umoles
menadione, 0.3 umoles flavin mononucleotide, 0.15 mg cyto-

chrome c, 2 mg yeast hexokinase, and 0.0 mg cell-free extract.

bValues corrected by endogenous uptake.

DISCUSSION

The eight pesticides considered in this report are
currently recommended for agricultural uses. Field studies
or laboratory investigations with 3011 systems have indicated
no inhibition of nitrification by aldrin (Fletcher and
Bollen, 195“; Shaw and Robinson, 1960; Bertha gt 91., 1967),
simazine (Bartha 2; 51., 1967), or DDD (Eno and Everett,
1960; Eartha 33 al., 1967). The two chemicals (CIPC and
eptam) which inhibited both the growth of Nitrobactg; and
nitrite oxidation were also inhibitory to nitrification in
soil studies (Eartha 31.31., 1967; Quastel and Scholefield,
1953). By applying 5000 ug of lindane and chlordane per
gram of soil, Brown (1954) observed retardation of nitrifica-
tion, but Shaw and Robinson (1960) observed no effect with
chlordane at 300 ug per gram of soil and Bollen 33 al. (195“)
reported lindane at 1000 ug per gram of soil did not inhibit
nitrate formation. ’

We were particularly concerned in determining whether
a correlation existed between oxidation studies with cell
suspensions and the growth experiments. Aldrin and simazine
neither affected growth in aerated cultures nor nitrite
oxidation by cell suspensions or cell-free extracts. Among
the six other pesticides tested which caused cessation of

62

63
growth, eptam was the least inhibitory (75 ug/ml were required
for complete inhibition), whereas only CIPC and eptam were
completely inhibitory for the nitrite oxidase of cell suspen-
sions. Although various degrees of nitrite oxidase inhibition
were observed with 500 ug/ml of chlordane, DDD, heptachlor,
and lindane, inhibition of nitrite oxidase activity was
probably not the mode of action of these chemicals on
Nitngggt ; since 5 to 10 ug/ml stapped growth. Even with
CIPC and eptam, inhibition of nitrite oxidase might not be
the main mechanism of action since the concentrations of
CIPC and eptam required for cessation of nitrite oxidase were
approximately 10-fold and h-fold greater, respectively, then
the concentrations necessary for inhibiting growth.

It is noteworthy that heptachlor and chlordane were
more inhibitory to oxidation by cell-free extract than by
cell suspension. Complete inhibition of the nitrite oxidase
activity in cell-free extracts was effected by 250 ug/ml
chlordane and 200 ug/ml heptachlor, but additions of 500 ug/
ml to cell suspensions resulted in 80% inhibition with chlor-
dane and 50% inhibition with heptachlor. This difference in
inhibition could be due to an impermeability of the cell
suspensions to these two compounds or to binding of protein
in the cell-free extracts since both chemicals are insoluble
at the concentrations used. Likewise, sorption of cells or
protein by insoluble pesticide particles could be responsible
for the linear effect noted in the respiration experiments
with increasing concentrations of the pesticides even though

the solubility levels of the chemicals were exceeded.

6#

Since marked inhibition of nitrite oxidase in cell-
free extracts occurred with CIPC, chlordane, eptam, and
heptachlor, the pesticides were tested for an effect on the
cytochrome c oxidase activity in the cell-free extracts.
Aleem and Nason (1960) and Lees and Simpson (1957) indicated
that nitrite oxidation in Nitngggtgg is mediated by cyto-
chrome of c-like and a-like components, but Aleem (1968)
recently showed that N0; oxidation is mediated by cytochrome
a and cytochrome oxidase components with the reduction of
cytochrome c being energy dependent. None of the pesticides
examined by us affected the cytochrome c oxidase activity
sufficiently to account for the nitrite oxidase inhibition
observed with cell suspensions and cell-free extracts. The
percent relative cytochrome c oxidase activity obtained with
500 ug heptachlor per ml was similar to cell suspension
respiration results, but heptachlor caused total inhibition
of cell-free extract nitrite oxidase at 200 ug/ml. Thus,
effects observed with heptachlor were probably only partially
due to cytochrome c oxidase inhibition.

One complicating factor in comparing the nitrite
oxidase and cytochrome c oxidase inhibitions is the relative
insolubility of most of the compounds tested. However, CIPC
is soluble at 100 ug/ml and eptam at #00 ug/ml. Since nitrite
enters the cytochrome system at cytochrome a (Aleem, 1968),
an inhibitor of nitrite oxidase should affect cytochrome
oxidase unless the inhibition is competitive. As CIPC was

shown to be a noncompetitive inhibitor of nitrite oxidase,

65
inhibition of cytochrome oxidase was expected. Failure,
to obtain greater than 50% inhibition of cytochrome c oxidase
by CIPC suggests the presence of more than one terminal
oxidase in Nitrgggqtgz. Straat and Nason (1965) likewise
suggested that two terminal oxidases are present in the
organism.

Another enzyme chosen for study was NADH2 oxidase.
Although it is probable that this oxidase is used for auto-
traphic growth only by the hydrogen bacteria (Smith gt 31.,
1968), Aleem (1968) showed that NADH2 oxidation in Nitropggte;
proceeds by an electron transport chain analogous to the
mitochondrial respiratory chain reported by Chance gt 3;.
(1967). Consequently, we were interested in studying the
effects of pesticides on the oxidase as an indication of
cytochrome inhibition. However, we were unable to detect
NADH2 oxidase activity in our preparations by spectrophotomet-
rio assay. A slight decrease in absorbance observed at 3#0 nm
was preswmed to be caused by reduction of flavoproteins.

No deleterious effect on nitrate reductase by the
pesticides was noted in our system. Straat and Nason (1965)
have postulated that the enzymatic reduction of nitrate in
fligzghagtgzgmight be the first step of a sequence for provide
ing nutritional nitrogen, or it could be a means of recycling
nitrite for further oxidation.

Though growth, nitrite oxidase, and enzyme studies
were unsuccessful in characterizing the inhibitions caused
by the pesticides studied, our results indicate that growth

studies with low concentrations of pesticides were more suitable

66
than the measurement of nitrite oxidation as indexes of the
toxicity of pesticides for Nitzgpngtg; agilig. Growth studies
detect inhibition of biosynthetic reactions, whereas only
inhibition of energy assimilation is detected by nitrite
oxidation studies. The W growth studies indicated
that chlordane, CIPC, DDD, eptam, heptachlor, and lindane
would be expected to inhibit nitrification in the soil,
whereas the nitrite oxidase studies suggested that only two
of the pesticides, CIPC and eptam, would be inhibitory.

The oxidative phosphorylation coupled to nitrite
oxidation was investigated as a possible site of action for
two of the herbicides (CIPC and eptam). Both CIPC and eptam
had previously been investigated for their mode of inhibition
in plants. Ashton (1963) reported an uncoupling effect by
eptam in cucumber mitochondria since the compound inhibited
phosphate esterification more severely than oxygen uptake
at 10'”2 and 10"3 M. when added to cabbage mitochondria, 10"3 M
eptam caused 77% inhibition of oxygen uptake and 100% inhibi-
tion of phosphate esterification, whereas 10"3 M CIPC reduced
oxygen uptake and phosphate esterification by 85% and 91$,
respectively (Lotlikar 21.21-9 1968). Mann 31 a1. (1965)
obtained evidence for CIPC inhibiting protein synthesis at
points after the transport of amino acids across cell mem-
branes.

In microorganisms suggestive evidence for CIPC
inhibition of oxidative phosphorylation was obtained by
Bartha 33 51. (1967). The identical 002 production patterns
(obtained after applications of CIPC and DNP to soil samples

67
caused Bertha £5,31. to propose that CIPC might be an uncoupler
of oxidative phosphorylation in microorganisms.

Both CIPC and eptam exerted an uncoupling effect on
oxidative phosphorylation by Nitzgpaqu; at concentrations
of the chemicals similar to those required for uncoupling
cabbage mitochondria phosphorylation. At 2.3 x 10'“ M, CIPC
inhibited Nitngggt I phosphate esterification by 53% and
oxygen uptake by 16%. Complete inhibition of phosphorylation
occurred at #.6 x 10'“ M CIPC, but oxygen uptake was reduced
by only 80%. Eptam at 10"3 M depressed oxygen uptake by #2%
but reduced phosphate esterification by 97%.

It was of interest to determine whether 2,#-dinitro-
phenol, a classical phosphorylation uncoupler, affected
oxidative phosphorylation in Nitrogggte; in a manner similar
to that observed with the two herbicides. An inhibition of
nitrite oxidation in Nitzgpggtg;,has been reported previously
with DNP at various concentrations. Aleem and Alexander (1958)
reported 8#% inhibition of oxygen uptake by Nitgopgcter cell-

free extracts at 10"2

M DNP. In 1960, Aleem and Nason were
unable to demonstrate uncoupling of oxidative phosphorylation
with DNP, but complete inhibition of nitrite oxidation occurred
at 5 x 10’“ M DNP. Using Nitngggtg; cell suspensions, Butt

and Less (1960) obtained 6#% inhibition of nitrite oxidation

at 2 x 10"”3 M DNP. Van Cool and Laudelout (1966b) reported

50% inhibition of nitrite oxidation at 5 x 10'“ M and 9 x 10'“ M
DNP with Nitrobacteg cell suspensions and cell-free extracts,

respectively.

68
Nitrite oxidation by our cell-free extracts was

1‘ M and 10'3 M DNP, respec-

reduced by 18% and #7% at 5 x 10-
tively. Since these oxygen uptake reductions were accompanied
by inhibitions of phosphate esterification of 85% and 100% at
5 x 10’“ M DNP and 10"3 M DNP respectively, we concluded that
the two herbicides and dinitrOphenol had similar mechanisms

of inhibition in Nitrgbggtgr.

Because the phosphorylation occurring with nitrite
oxidation is atypical in regard to inhibition of nitrite
oxidation by an uncoupling agent, it is interesting to recall
the scheme prOposed by Kiesow (196#). Kiesow postulated that
in nitrite oxidation the electrons from nitrite are utilized
to reduce NAD with the consumption of two moles of ATP. The
NADH is oxidized in the presence of O2 and yields 3 moles of
ATP with a not yield of one mole of ATP for the oxidation
of nitrite to nitrate. In addition to explaining the inhibi-
tion of nitrite oxidation by uncoupling agents, this scheme
also illustrates a need for NADH oxidase in autotrophio growth.

Various values have been reported for phosphoryla-
tion linked to NADH oxidation in Nitrobacter. In 1960, Aleem
and Nason reported a P/O ratio of 0.05, but values approach-
ing 2.0 (Aleem, 1968) and 3.0 (Kiesow, 196#) were obtained
more recently. Because of these recent reports, the oxidap
tion of NADH by Nitrgpgqtg; cell-free extracts was studied
to determine the effects of the two herbicides on both elec-
tron transport and oxidative phosphorylation occurring in this

reaction. Although we were unsuccessful in measuring NADH2

oxidase activity by a spectrOphotometric assay, increased

69

protein concentrations in a respirometer assay indicated an
NADH2 oxidase activity of 0.3 to 0.5 umoles per hour per mg
of protein. We observed no esterification of inorganic phos-
phate coupled to the oxidation. Although both pesticides did
inhibit oxygen uptake with NADH as the substrate, a.maJor
portion of the oxidation proceeded via flavOprotein reduction.
When each herbicide was used in combination with azide, the
combined effect substantiated an inhibition of flavOprotein
reduction and not an inhibition of electron transport by CIPC
and eptam.

The modes of action of chlordane, DDD, heptachlor
and lindane for Nitgghgqtg; were not determined, but were
shown to be on biosynthetic processes of the cell rather
than nitrite oxidation. With CIPC and eptam, the results
suggest an uncoupling of oxidative phosphorylation as the
mode of action for both herbicides since phosphorylation was

reduced by 57% with CIPC at 2.3 x 10"“

eptam at 8 x 10’“ M. Nitrite oxidase was also affected by

M and by 75% with

the chemicals, but uncoupling of oxidative phosphorylation
with a less severe inhibition of nitrite oxidase was also
observed with 2,# dinitrOphenol.

Although the P/O ratios of our cell-free extracts
(0.16 to 0.36) were consistent with the maximum value of
0.2 obtained by Aleem and Nason (1960) and 0.17 reported by
Fischer and Laudelout (1965) for Nitrobacter winogradskyi,
they were lower than we expected. In 1968 Aleem listed two

criteria for obtaining P/O ratios approaching 1.0 for the

70

oxidative phosphorylation linked to nitrite oxidation in
N. agilig: (i) cultures must oxidize at least three addi-
tions of 20 mM nitrite per day for two days and (ii) cells
should be suspended in an isotonic medium and disrupted for
only 3 min. Even though these criteria were met, we obtained
a maximum value of 0.36. It was also noted that the nitrite
oxidase activity was more stable than the coupled phosphoryla-
tion. After four days at 5 C no decrease was noted in the
nitrite oxidase activity, but the P/O ratios usually decreased
by about 50%.

To determine whether the low P/O ratios were caused
by the loss of organic phosphate during removal of the
inorganic phosphate, a reaction system containing uniformly
labeled ll‘C--g1ucose--6«-phosphate was extracted in the usual
manner. When the values were corrected by the use of internal
standards, 106% of the radioactivity was obtained. Apparently
the low P/O values were caused by destruction of the struc-
tural integrity of the phosphorylating particles during
disruption of the cells. Proof of such destruction was the
Presence of an active ATPase.

Menadione (10"6 M), FMN (10"7 M), and cytochrome c
(1.5 x 10'3%) failed to increase the P/O values when added
singly or in combination. However, no increase was expected
since nitrite oxidation involves only cytochrome a- and a1-
1ike components (Aleem, 1968). One possibility for slight
increases in the P/O values might be additions of flavin and
cytochrome b inhibitors (i.e. rotenone and antimycin A) which

would prevent the expenditure of ATP in reduction of the

71
cytochrome c, cytochrome b, and flavin components of the
cytochrome system.

In the large-scale cultures a cell yield of 2.86 gm
wet weight was obtained from the oxidation of 2.61 moles of
NaNOz (average of five determinations). Assuming the cells
contained 80% water, the molar growth yield was 220 mg dry
weight of cell material per mole of substrate. These values
were in close agreement with the 231 mg dry weight per mole
of substrate and 0.5 g dry weight of cells from 18 liters
obtained by Einstein and Delwiche (1965). Using the P/O ratio
of 0.36, the yield per mmole ATP (YATP) was 0.22/0.36 or
0.6 mg per mmole ATP. Fischer and Laudelout with 3132223222;
ginggggdgxzi obtained a YATP value of 2 mg per mmole of ATP.
For heterotrophs the average YATP is 10.5 mg per mmole of
ATP (Bauchcp and Elsden, 1960).

The higher IATP reported by Fischer and Laudelout
can be attributed to a lower P/O ratio and a higher efficiency
of growth with N. wingglgdgkxi_than.we obtained with N. agil_§.
Since Fischer and Laudelout obtained #0 mg dry weight with
the oxidation of 0.1 M nitrite, their cultures had a maximum
efficiency of growth of 11.7% when calculated by the method
of Baas-Booking and Parks (1927). In a study of the
molybdenum requirements of Nitgopactgr, Finstein and Delwiche
(1965) reported essentially the same efficiency (11.2%) for
cultures after 5 days of active growth. However, with 8 days
of active growth the cultures had no increase in cell yield
and an efficiency of only 6.#%. This decreased efficiency

was apparently caused by nitrate accumulation in excess of

72
0.1 M. .Although we did not measure cell weight at intervals
during growth, turbidimetric measurements indicated only a
slight decrease in efficiency after oxidation of 0.09 M
nitrite: active growth continued even after oxidation of
0.2 M nitrite. After 5 days of active growth our cultures
had an efficiency of only 6.2%.

Aleem,

Aleem,

Aleem,

Aleem,

Aleem,

Aleem,

Allen,

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