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Effect of ion-transporting antibiotics on the energy-linked reactions of submitochondrial particles
Vol. 34, No. 1 t 1969
5lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
EFFECT OF ION-TRANSPORTING ENERGY-LINKED
ANTIBIOTICS
ON THE
REACTIONS OF SUBMITOCHONDRIAL PARTICLES*
M. Montal,
B. Chance,
C. P. Lee,
and A. Azzi
Johnson Research Foundation School of Medicine University of Pennsylvania Philadelphia, Pennsylvania 19104
Received December 2, 1968
Certain natural
antibiotics
have the property
and artificial
elucidation
membranes
of the relationship
mechanisms
in mitochondria
are still
capable
and are
(2)
coupling
and energy
disruption
energy system
and ion
as a tool
and chromatophores
by sonic
a more elementary
energy
reported
of the valinomycin
the
derived
phenomena
transport
in the
coupling (3,4,5).
of mitochondria
coupling
in which
across
and oxidative to understand
across
the
inner
the mito-
membrane. The data
actions
chloroplasts
particles
between
chondrial
membrane
of respiratory-chain-linked
phosphorylation, relationship
in
ion movements
They have been utilized
between (1)
Submitochondrial
(1).
of activating
in this
and nigericin
of submitochondrial
current
hypotheses
paper type
show that strongly
affect
The results
particles. of energy
ion-transporting
coupling
antibiotics
the energy-linked are discussed
in oxidative
re-
in terms
of
and photosynthetic
phosphorylation. MATERIALS AND METHODS EDTA particles described
previously
derived (6).
from
beef
heart
Oxygen consumption
*Supported by the National Institutes F05 TW-01291), the Jane Coffin Childs the National Institute for Scientific
mitochondria
were
prepared
was measured
polarographically
of Health (GM 12202, 1 K4 GM 38822, Memorial Fund for Medical Research, Research (Mexico).
104
as
and and
Vol.34,No.1,1969
with
BIOCHEMICAL
a Clark
hydrogenation were
--et al. Dr.
(7)
assayed
responses
electrode.
oxygen
(IO),
to Ernster
measured
nucleotide
trans-
of NAD+ by succinate
The energy-linked
and Lee.
by Chance
Valinomycin
of this
pyridine
reduction
as described
respectively.
B. C. Pressman
RESEARCH COMMUNICATIONS
The energy-linked
and the ATP-supported
according
were
ANDBIOPHYSICAL
and Mela
and nigericin
(8)
BTB* and ANS
(9)
and by Azzi,
kindly
were
supplied
by
laboratory. RESULTS
Lee and Ernster
(11)
of respiration
in E-SMP,
the presence
of oligomycin
have shown which there
supported
energy-linked
reduction
of NAD+ by succinate,
Fig.
1, the
release
as a function
the
control.
system
50%, in
carrier
question,
comparison these
other
pyridine
2 shows
antibiotics
nigericin
alone
in
alone
the presence
in
induced
transfer
alone
the
acting
re?eased
about
reactions
were
of the
In order
reaction.
of k about
50% of
and/or
of respiration
by
The question
arises
of the electron
trans-
to elucidate
this
studied.
antibiotics
to 95% inhibition the presence
level
plotted
combination
although
alone.
at the
is
control,
stimulation
by either
process.
of K+ inhibits
control
uncouplers,
the oligomycin
in a further
are
the effect
leads
other
In
by uncouplers.
of FCCP to the valinomycin-
transhydrogenase
antibiotics
while
resulted
chain
and of the energy-linked inhibited
and nigericin
addition
energy-linked
nucleotide
of both
released
in
respiratory
respiratory
Like
to that
or the energy
Figure
are also
an inhibition
furthermore,
of the
reaction
of the oligomycin-induced
Furthermore,
as to whether fer
a stimulation
which
had no effect,
nigericin-treated about
is
induces
by uncouplers;
transhydrogenase
and nigericin alone
oligomycin
released
of KC1 concentration.
of valinomycin va'linowcin
is
that
on the energy-linked As can be seen,
of the
rate
There
presence
of NADPH formation,
has no effect, 50%.
the
is
and valinomycin no effect
of the
'Abbreviations used: BTB, bromthymol blue, 3,3" dibromothymolsulfonphthalein; E-SMP, EOTA submitochondrial particles; ANS, N-arylaminonaphthalene sulfonate; FCCP, carbonyl cyanide p-trifluoromethoxyphenylhydrazone.
105
Vol. 34, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0.
. IO
0
I
I
I
I
I
50
30
KCLmM
Figure 1. Effect of valinomycin and nigericin on the oligomycin-induced respiratory control as a function of KC1 concentration. The reaction mixture contained 0.1 mg protein per ml of E-SMP, 0.25 M sucrose, 20 mM Tris-HCl, pH 7.4, 0.6 pM valinomycin, and 0.06 uM nigericin. Final volume, 3 ml. Temperature, 30" C.
0
I
2 Min
3
4
Effect of valinomycin and nigericin on the energy-linked The reaction mixture contained pnuc!eotlde transhyd rogenatlon. 1 mg protein per ml of t-SMP 0.25 M sucrose, 0.05 M Tris-HCl, pH 7.4, 0105 M KCl, 0.5 ug per ml of oiigomycin, 3.3 pM rotenone, 135 uM NADH, 5 mM succinate. Final volume, 10 ml. Temperature, 30' C. The reaction was started by the addition of 180 pM NADP. Assays were done according to the method of Lee and Ernster (7).
Vol. 34, No. 1, 1969
antibiotics
BIOCHEMICAL
on the
non energy-linked
BTB (9,12), indicators
effect
of the
and ANS (upper oxidation
cycles
are
duration. bited;
is
The effect
by succinate
the of the
antibiotics
studied.
100% of the
only
the
3c shows that
the
and 50% shorter
in
to that
induced
by FCCP under
alone
in the
on the Valinomycin
reaction,
and valinomycin
cycle
presence about
is
and nigericin
in
alone
similar
50%. reduction
nigericin
95% inhi-
of Kt (not
energy-linked
whereas
of
in the presence
the
only
alone
in the presence
the
of NAD+ presence
in
the pres-
of Kt
50%.
366+560mp Fluorescence InCEOSe
t 618-700mp Absorbance 1 Increase IObpM
NADH
IOQM
NADH
-d
t
I IOOpM
oligomygin,
25' C.
(cl6sec
Nigerian
ID
366+560mp Fluorescence lncreose 618;7OOmp Absorbonce Increase
NADH
IpM Vahomycin
Effect sr;;po~
70nM
of nigericin and valinomycin on the energy-linked BTB 0 9 mg protein per ml of E-SMP in 0.3 M mannitolris-Hi1 pH 7.4 supplemented with 0.5 ug per ml of ! PM BTB, aid 10 uM'ANS. Final volume, 1 ml. Temperature,
107
3
trace)
cycle
of valinomycin,
BTB and ANS responses
ence of Kt had no effect, inhibited
was added. in amplitude
of valinomycin
was also
of KC1 inhibited
comparable
as a control,
as
Figure
BTB (lower
of NADH oxidation
30% larger
the addition is
to inhibit
a cycle
to act
particles.
energy-linked
3Ashows,
70 nM nigericin
inhibition
The effect
on the
3Bis
now approximately
have been shown
of submitochondrial
responses.
In 3l& after this
ANS (lo),
antibiotics
thereafter,
conditions. shown)
trace)
state
of 100 uM NADH.
of 20 njrl KCl;
reaction.
and more recently,
of the energized
shows the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
VoL34,No.
1,1969
BIOCHEMICAL AND BIOPHYSICALRESEARCH
The well-documented Nat
(1,13)
by the
reactions
in a medium
was partially
specificity strictly
of valinomycin
is demonstrated
energy-linked Nigericin
specificity
(1).
effective
The effect
dependent
complete
lack
in which
on the presence
to K+ rather
of inhibition
the
than
of all
according
on addition
of both
to
the
Kt has been replaced
in a Nat medium,
observed
COMMUNICATIONS
by Na+.
to its
known
antibiotics
was
of K+.
DISCUSSION
Previous (tentatively during
studies identified
coupled
tt of Ca inconsistent
the (9)
and direct
drial
evidence
of a cation to the Ht uptake
supported
inward
in submitochondrial
of the
Ht movements
(18);
the cation
movement particles
described
is by
pumps seem to
here
afford
indirect
in submitochondrial
of electron
particles
between
transfer
evidence
that (9,18)
monovalent
and energy
the cation may be Kt,
cation
conservation
movements in submitochon-
particles.
an uncoupled of the
system
Kt/Ht
maximal
rate
and K' of the
in fact on the
to an influence
rate
of electron
rate
of oxygen
of the
it
is evident
Kt or low Ht concentration
is
a requirement
in
environment
Due to the
transport.
by nigericin,
promoted
ionic
uptake
that
the presence for
having
effect
of
a
of respiration.
The effect valinonlycin
chain
exchange a high
by nigericin points
respiratory
of either
linked
opposite
and Moyle
of an interaction
The stimulation
known
(14)
direction
reported
Ht movements
and the process
movement
and Racker
inward
requirement
directions.
The results for
the
The succinate
and Mitchell
in opposite
required
Cat+) (9).
by Loyter
with
and Mela
operate
with
respiration
observed
Chance
have considered
of valinomycin
and nigericin
reactions
in
and K+ and the synergistic the presence
in submitochondrial
of Kt,
particles,
inhibiting suggests
several as well
energya close
Vol. 34, No. 1, 1969
interaction
BIOCHEMICAL
between
ion
One mechanism activated
outward
movements
is
based
movement
the transhydrogenase,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
and energy
conservation.
upon the above
of K' which
the BTB-ANS
is
mentioned
valinomycin-
responsible
responses
for
and the
the inhibition
reversal
of
of electron
transfer. The combined energy
dissipating
nigericin
ion
would
the activity presence
effects
of valinomycin
movement
be to restore
across the
and nigericin the membrane,
Kt content
as proposed
for
in which
inside
a cyclic
the effect
of
depleted
by
the vesicle
of a pump or of a membrane potential,
of valinomycin,
suggest
that operates
mitochondria
(1)
the
effect
in the
and chromatophores
(3,5,16,17). An additional
explanation
carrying
antibiotics
constant
of the membrane,
case,
uncoupling
binding
of ionic
inhibitory conformational
effect
is
that
is to transport
would species
which
result
are not
into
required
by cyclic
regions for
transport,
indicated
and nigericin
This
of the
ion
of low dielectric
energy
in such an environment.
of valinomycin changes
ions
combined
coupling. but is
In this
due to the simple supported
in the presence
of k
by the on the
by ANS and BTB.
SUMMARY
The effects of ion-transporting antibiotics on the energy-linked reactions of submitochondrial particles were studied. It was found that valinomycin and nigericin in the presence of K' led to the release of the oligomycin-induced respiratory control, and to a virtually complete inhibition of the four energy-linked reactions: pyridine nucleotide transhydrogenation, BTB and ANS responses, and reversal of electron transfer. Valinomycin alone in the presence of K+ did not release the oligomycin-induced control, but inhibited the energy-linked reactions by approximately 50%. Nigericin alone in the presence of Kt stimulated the oligomycin-inhibited respiration by approximately 50%, but did not affect the energy-linked reactions. The results are discussed in terms of current hypotheses of energy coupling in oxidative and photosynthetic phosphorylation.
109
Vol. 34, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGEMENTS
The authors are indebted discuss-ions, and to Miss Birgitta
to Dr. B. C. Pressman for stimulating Johansson for valuable assistance.
REFERENCES
1. 2. 3. 4. 5. 6. L: 1:: ;:: 13.
ii: 16. 17. 18.
Pressman, B. C., Harris, E. J., Jagger, W. S., and Johnson, J. H. Proc. Natl. Acad. Sci., g, 1949 (1967). A. Shavit, N., Dilley, R. A., and San Pietro, Biochemistry, 7-, 2356 (1968). Thore, A., Keister, D. L., Shavit, N., and San Pietro, A. Biochemistry, 7, 3499 (1968). in press. Nishimura, M., and Pressman, B. C. Biochemistry, A. R., and Von Stedingk, L. V. Jackson, J. B., Crofts, European J. Biochem., a, 41 (1968). lo, 543 (1967). Lee, C. P., and Ernster, L. Methods in Enzymol., Biophys. Acta, 81, 187 (1964). Lee, C. P., and Ernster, L. Biochim. l& 729 (1967). Ernster, L., and Lee, C. P. Methods in Enzymol., Chance, B., and Mela, L. J. Biol. Chem., 242, 830 (1967). Aizi, A., Chance, B., Lee, C. P., and Radda, G. K. Proc. Natl. Acad. Sci., in press. Lee, C. P., and Ernster, L. BBA Library 7, 218 (1966). D. R. Arch. Biochem. Biophys., 126, 722 Kurup, C. K. R., and Sanadi, (1968). In Biochemistry of Mitochondria Chappell, J. B., and Haarhoff, K. (E. C. Slater, 2. Kaniuga, and L. Wojtczak, Eds.) London: Academic Press, 1967. p. 75. Trans. N. Y. Acad. Sci., in press. Loyter, A., and Racker, E. Lardy, H. A., Graven, S. N., and Estrada-O., S. Fed. Proc., 26, 1355 (1967). Coupling in Oxidative and Photosynthetic Mitchell, P. Chemiosmotic Phosphorylation. Glynn Research, Bodmin, Cornwall, 1966. Mitchell, P. Chemiosmotic Coupling and Energy Transduction. Glynn Research, Bodmin, Cornwall, 1968. Mitchell, P., and Moyle, J. Nature, 208, 1205 (1965).
110
5lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
EFFECT OF ION-TRANSPORTING ENERGY-LINKED
ANTIBIOTICS
ON THE
REACTIONS OF SUBMITOCHONDRIAL PARTICLES*
M. Montal,
B. Chance,
C. P. Lee,
and A. Azzi
Johnson Research Foundation School of Medicine University of Pennsylvania Philadelphia, Pennsylvania 19104
Received December 2, 1968
Certain natural
antibiotics
have the property
and artificial
elucidation
membranes
of the relationship
mechanisms
in mitochondria
are still
capable
and are
(2)
coupling
and energy
disruption
energy system
and ion
as a tool
and chromatophores
by sonic
a more elementary
energy
reported
of the valinomycin
the
derived
phenomena
transport
in the
coupling (3,4,5).
of mitochondria
coupling
in which
across
and oxidative to understand
across
the
inner
the mito-
membrane. The data
actions
chloroplasts
particles
between
chondrial
membrane
of respiratory-chain-linked
phosphorylation, relationship
in
ion movements
They have been utilized
between (1)
Submitochondrial
(1).
of activating
in this
and nigericin
of submitochondrial
current
hypotheses
paper type
show that strongly
affect
The results
particles. of energy
ion-transporting
coupling
antibiotics
the energy-linked are discussed
in oxidative
re-
in terms
of
and photosynthetic
phosphorylation. MATERIALS AND METHODS EDTA particles described
previously
derived (6).
from
beef
heart
Oxygen consumption
*Supported by the National Institutes F05 TW-01291), the Jane Coffin Childs the National Institute for Scientific
mitochondria
were
prepared
was measured
polarographically
of Health (GM 12202, 1 K4 GM 38822, Memorial Fund for Medical Research, Research (Mexico).
104
as
and and
Vol.34,No.1,1969
with
BIOCHEMICAL
a Clark
hydrogenation were
--et al. Dr.
(7)
assayed
responses
electrode.
oxygen
(IO),
to Ernster
measured
nucleotide
trans-
of NAD+ by succinate
The energy-linked
and Lee.
by Chance
Valinomycin
of this
pyridine
reduction
as described
respectively.
B. C. Pressman
RESEARCH COMMUNICATIONS
The energy-linked
and the ATP-supported
according
were
ANDBIOPHYSICAL
and Mela
and nigericin
(8)
BTB* and ANS
(9)
and by Azzi,
kindly
were
supplied
by
laboratory. RESULTS
Lee and Ernster
(11)
of respiration
in E-SMP,
the presence
of oligomycin
have shown which there
supported
energy-linked
reduction
of NAD+ by succinate,
Fig.
1, the
release
as a function
the
control.
system
50%, in
carrier
question,
comparison these
other
pyridine
2 shows
antibiotics
nigericin
alone
in
alone
the presence
in
induced
transfer
alone
the
acting
re?eased
about
reactions
were
of the
In order
reaction.
of k about
50% of
and/or
of respiration
by
The question
arises
of the electron
trans-
to elucidate
this
studied.
antibiotics
to 95% inhibition the presence
level
plotted
combination
although
alone.
at the
is
control,
stimulation
by either
process.
of K+ inhibits
control
uncouplers,
the oligomycin
in a further
are
the effect
leads
other
In
by uncouplers.
of FCCP to the valinomycin-
transhydrogenase
antibiotics
while
resulted
chain
and of the energy-linked inhibited
and nigericin
addition
energy-linked
nucleotide
of both
released
in
respiratory
respiratory
Like
to that
or the energy
Figure
are also
an inhibition
furthermore,
of the
reaction
of the oligomycin-induced
Furthermore,
as to whether fer
a stimulation
which
had no effect,
nigericin-treated about
is
induces
by uncouplers;
transhydrogenase
and nigericin alone
oligomycin
released
of KC1 concentration.
of valinomycin va'linowcin
is
that
on the energy-linked As can be seen,
of the
rate
There
presence
of NADPH formation,
has no effect, 50%.
the
is
and valinomycin no effect
of the
'Abbreviations used: BTB, bromthymol blue, 3,3" dibromothymolsulfonphthalein; E-SMP, EOTA submitochondrial particles; ANS, N-arylaminonaphthalene sulfonate; FCCP, carbonyl cyanide p-trifluoromethoxyphenylhydrazone.
105
Vol. 34, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0.
. IO
0
I
I
I
I
I
50
30
KCLmM
Figure 1. Effect of valinomycin and nigericin on the oligomycin-induced respiratory control as a function of KC1 concentration. The reaction mixture contained 0.1 mg protein per ml of E-SMP, 0.25 M sucrose, 20 mM Tris-HCl, pH 7.4, 0.6 pM valinomycin, and 0.06 uM nigericin. Final volume, 3 ml. Temperature, 30" C.
0
I
2 Min
3
4
Effect of valinomycin and nigericin on the energy-linked The reaction mixture contained pnuc!eotlde transhyd rogenatlon. 1 mg protein per ml of t-SMP 0.25 M sucrose, 0.05 M Tris-HCl, pH 7.4, 0105 M KCl, 0.5 ug per ml of oiigomycin, 3.3 pM rotenone, 135 uM NADH, 5 mM succinate. Final volume, 10 ml. Temperature, 30' C. The reaction was started by the addition of 180 pM NADP. Assays were done according to the method of Lee and Ernster (7).
Vol. 34, No. 1, 1969
antibiotics
BIOCHEMICAL
on the
non energy-linked
BTB (9,12), indicators
effect
of the
and ANS (upper oxidation
cycles
are
duration. bited;
is
The effect
by succinate
the of the
antibiotics
studied.
100% of the
only
the
3c shows that
the
and 50% shorter
in
to that
induced
by FCCP under
alone
in the
on the Valinomycin
reaction,
and valinomycin
cycle
presence about
is
and nigericin
in
alone
similar
50%. reduction
nigericin
95% inhi-
of Kt (not
energy-linked
whereas
of
in the presence
the
only
alone
in the presence
the
of NAD+ presence
in
the pres-
of Kt
50%.
366+560mp Fluorescence InCEOSe
t 618-700mp Absorbance 1 Increase IObpM
NADH
IOQM
NADH
-d
t
I IOOpM
oligomygin,
25' C.
(cl6sec
Nigerian
ID
366+560mp Fluorescence lncreose 618;7OOmp Absorbonce Increase
NADH
IpM Vahomycin
Effect sr;;po~
70nM
of nigericin and valinomycin on the energy-linked BTB 0 9 mg protein per ml of E-SMP in 0.3 M mannitolris-Hi1 pH 7.4 supplemented with 0.5 ug per ml of ! PM BTB, aid 10 uM'ANS. Final volume, 1 ml. Temperature,
107
3
trace)
cycle
of valinomycin,
BTB and ANS responses
ence of Kt had no effect, inhibited
was added. in amplitude
of valinomycin
was also
of KC1 inhibited
comparable
as a control,
as
Figure
BTB (lower
of NADH oxidation
30% larger
the addition is
to inhibit
a cycle
to act
particles.
energy-linked
3Ashows,
70 nM nigericin
inhibition
The effect
on the
3Bis
now approximately
have been shown
of submitochondrial
responses.
In 3l& after this
ANS (lo),
antibiotics
thereafter,
conditions. shown)
trace)
state
of 100 uM NADH.
of 20 njrl KCl;
reaction.
and more recently,
of the energized
shows the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
VoL34,No.
1,1969
BIOCHEMICAL AND BIOPHYSICALRESEARCH
The well-documented Nat
(1,13)
by the
reactions
in a medium
was partially
specificity strictly
of valinomycin
is demonstrated
energy-linked Nigericin
specificity
(1).
effective
The effect
dependent
complete
lack
in which
on the presence
to K+ rather
of inhibition
the
than
of all
according
on addition
of both
to
the
Kt has been replaced
in a Nat medium,
observed
COMMUNICATIONS
by Na+.
to its
known
antibiotics
was
of K+.
DISCUSSION
Previous (tentatively during
studies identified
coupled
tt of Ca inconsistent
the (9)
and direct
drial
evidence
of a cation to the Ht uptake
supported
inward
in submitochondrial
of the
Ht movements
(18);
the cation
movement particles
described
is by
pumps seem to
here
afford
indirect
in submitochondrial
of electron
particles
between
transfer
evidence
that (9,18)
monovalent
and energy
the cation may be Kt,
cation
conservation
movements in submitochon-
particles.
an uncoupled of the
system
Kt/Ht
maximal
rate
and K' of the
in fact on the
to an influence
rate
of electron
rate
of oxygen
of the
it
is evident
Kt or low Ht concentration
is
a requirement
in
environment
Due to the
transport.
by nigericin,
promoted
ionic
uptake
that
the presence for
having
effect
of
a
of respiration.
The effect valinonlycin
chain
exchange a high
by nigericin points
respiratory
of either
linked
opposite
and Moyle
of an interaction
The stimulation
known
(14)
direction
reported
Ht movements
and the process
movement
and Racker
inward
requirement
directions.
The results for
the
The succinate
and Mitchell
in opposite
required
Cat+) (9).
by Loyter
with
and Mela
operate
with
respiration
observed
Chance
have considered
of valinomycin
and nigericin
reactions
in
and K+ and the synergistic the presence
in submitochondrial
of Kt,
particles,
inhibiting suggests
several as well
energya close
Vol. 34, No. 1, 1969
interaction
BIOCHEMICAL
between
ion
One mechanism activated
outward
movements
is
based
movement
the transhydrogenase,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
and energy
conservation.
upon the above
of K' which
the BTB-ANS
is
mentioned
valinomycin-
responsible
responses
for
and the
the inhibition
reversal
of
of electron
transfer. The combined energy
dissipating
nigericin
ion
would
the activity presence
effects
of valinomycin
movement
be to restore
across the
and nigericin the membrane,
Kt content
as proposed
for
in which
inside
a cyclic
the effect
of
depleted
by
the vesicle
of a pump or of a membrane potential,
of valinomycin,
suggest
that operates
mitochondria
(1)
the
effect
in the
and chromatophores
(3,5,16,17). An additional
explanation
carrying
antibiotics
constant
of the membrane,
case,
uncoupling
binding
of ionic
inhibitory conformational
effect
is
that
is to transport
would species
which
result
are not
into
required
by cyclic
regions for
transport,
indicated
and nigericin
This
of the
ion
of low dielectric
energy
in such an environment.
of valinomycin changes
ions
combined
coupling. but is
In this
due to the simple supported
in the presence
of k
by the on the
by ANS and BTB.
SUMMARY
The effects of ion-transporting antibiotics on the energy-linked reactions of submitochondrial particles were studied. It was found that valinomycin and nigericin in the presence of K' led to the release of the oligomycin-induced respiratory control, and to a virtually complete inhibition of the four energy-linked reactions: pyridine nucleotide transhydrogenation, BTB and ANS responses, and reversal of electron transfer. Valinomycin alone in the presence of K+ did not release the oligomycin-induced control, but inhibited the energy-linked reactions by approximately 50%. Nigericin alone in the presence of Kt stimulated the oligomycin-inhibited respiration by approximately 50%, but did not affect the energy-linked reactions. The results are discussed in terms of current hypotheses of energy coupling in oxidative and photosynthetic phosphorylation.
109
Vol. 34, No. 1, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGEMENTS
The authors are indebted discuss-ions, and to Miss Birgitta
to Dr. B. C. Pressman for stimulating Johansson for valuable assistance.
REFERENCES
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ii: 16. 17. 18.
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