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Restoration of oxidative phosphorylation in ‘non-phosphorylating’ submitochondrial particles by oligomycin
BIOCHEMICAL
Vol. 18, No. 4, 1965
RESTORATION OF OXIDATIVE
AND BIOPHYSICAL
PHOSPHORYLATION IN 'NON-PHOSPHORYLATING
SUBMITOCHONDRIAL PARTICLES Chuan-pu Wenner-Gren
Institute,
RESEARCH COMMUNICATIONS
BY OLIGOMYCIN
LeeX and Lars University
Ernster
of Stockholm,
Stockholm,
Sweden
Received December 30, 1964 In a previous
paper
non-phosphorylating* carry
out
with
ATP as the
of respiratory
assayed these but
of
under
suitable
et al.,
1964a)
driven
by aerobically
lating
particles.
amount
of oligomycin
hydrogenaee
of the
finding
suggested
(Fig. %ellow
2):
that
Closer
required
that
activity oligomycin
an inhibition of the
Jane
of the Coffin
can also
Child6
may exhibit
523
19581.
observation
(Fig.
for
Medical
the
of the
trans-
maximal
in-
preparation.
a high-energy for
reaction
1) that
stimulation required
Fund
known
in non-phosphory-
two effects
of
factors*,
transhydrogenase
revealed
that
of
et at.,
previous
same particle
Memorial
of the
intermediates
maximal
when
restoration
(Lardy
the
process,
or 'coupling
amounts
effect
hydrolysis
the
enzymes
by the
oxidative
of this
be shown,
than
of the
perform
reversal
stimulated
to achieve
makes them
we
oligomycin
of this
what
paper
added
was much smaller
ATPase
and that
are still
In this
high-energy
study
particles
with
ADP to ATP.
appropriate
oligomycin
than
primary
was prompted
generated
reaction
hibition
of
more
from
as the
phosphorylation,
investigation
these
can
energy
As will
addition
of oxidative The present
as well
heart
to transfer
particles
no externally
by the
that
of ability
such
beef
so-called
intermediates
energy-coupling,
conditions.
requires
is achieved
inhibitor
ADP to ATP,
from
high-energy
phosphorylate
that
shown that
transhydrogenation
was concluded
lack
to
evidence
activities
(Lee
the
intermediates
phosphorylation
nucleotide
chain-linked is
to present
It
we have
preparations
generated
of energy.
'non-phosphorylating*
wish
1964a)
al.,
pyridine
aerobically
source
high-energy
et
submitochondrial
energy-dependent
efficiently
capable
(Lee
on the
This particles
intermediate, Research
1963-65.
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I
I 0.4
Fig.
~1.
0.8
1.2 1.6 Irg oligcmycin/mg
2.0 2.4 protein
28’
312
Effect
NADP+ reduction bv NADH. ATPase was assayed in a reaction mixture consisting of 160 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 4 mM (prepared in the presence of 2 mhI EDTA, pi-l 8.6) conMgso # particles tain 4 ng 0.2 mg protein, and oligomycin as indicated. Reaction was started by the addition of 5 mM ATP. Final volume, 1 ml, temp., 30°C, time of incubation, 5 min. The reaction mixture for the transhydrogenase assay consisted of 180 mM sucrose, 50 mh! Tris-acetate buffer, 10 mM MgSD , 0.2 mM NADH, 0.15 mhf NADP+, PH 7.5, 3.3 pM rotenone, 1 mM oxidized glutathione, an amoun 4 of glutathione reductose capable of oxidizing 0.5 umoles of NADPHfmin., particles containing 0.6 mg protein and oligomycin as indicated. Reaction was started by the addition of 5 mM succinate. Final volume, 3 ml, temp., 30°C.
succinate
ascorbate
f
I
energy-ckpendent transhydrogenast. ion translocation
high)m oligomycin
[valinomycin]
ATP
Fig. 2. resoiratorv coupling transfer
Hvoothetic scheme of the energy-transfer svstem linked to the chain. C , C , C denote electron carriers at the energyI and X denote hypothetic energy sites of the'resgira s ory chain; carriers (for further definitions, see Ernster and Lee, 1964). u bars indicate site of action of inhibitors; been bar indicates site of stimulation by 2,4-dinitrophenol (DNP). 524
Vol. 18; No. 4, 1965
I-X,
at
BIOCHEMICAL
low concentrations
action
of
the
that
(or
its
presented
below
As shown
in Fig.
only
tion,
in accordance
a very
considerable
occurred
tion,
which
stimulated
the
this
low rate
of
with
previous
prepared
results
only
a certain
within
ATP-supported
amount
reduction
rate
of NAD+ reduction
instead stimulating
of
being
virtually
oligomycin
exceeded
of
1964a).
ATP induced
The reaction
of
(Fig.
concentra-
Oligomycin
needed
for
or ascorbate
constant
as was the This 525
also
+ N,N,lj'N'-
analogous
noticed
by succinate
concentrations.
was
to the
Stimulation of ATPFig. 3. -suooorted succinate-linked + NAD reduction bv oliPomvcin The reaction mixture consisted of 180 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 1.6 mM KCN, 10 mM hlgso , 0.2 mM NAD+, 5 mM succ 4 nate and particles (prepared in the presence of 2 mM KDTA, pH 8.5) containing 0.75 mg protein. Other additions: 3 mM ATP, 0.15 pg oligomycin, 1.6 mk'malonate, and 1.6 /.tM rotenone& Final volume 3 ml, temp., 30 C.
was also
that
a
the
oligomycin 4).
in a fashion
or rotQncnQ
It
When
As anticipated,
range
KDTA exhi-
NAD+ reduc-
of NAD+ by ascorbate
(TMPDI,
NAD+ reduction. of oligomycin
presence
was added,
was inhibited
The
case.
et al.,
protein
it
particles.
NAD+ reduction.
t-nahate
the
(Lee
higher
oxidative
succinate-linked
and rotenone.
reaction
the
inter-
correct,
enhance
in the
ATP-supported
-tetramethyl-D-phenylenediamine
succinate-linked
is
by malonate
the
were
might
indeed
of succinate-linked
stimulation
ATP, at
in non-phosphorylating
3, particles
inhibited
above
interpretation
per mg of particle
rate
of the
Pi and ADP, to yield
this
reversal)
RESEARCH COMMUNICATIONS
and an inhibition
of oligomycin
show that
pg of oligomycin
completely
If
low concentrations
bited
0.2
with
of oligomycin.
phosphorylation data
of oligomycin;
same intermediate
concentrations follows
AND BIOPHYSICAL
maximal
shown)
that,
stimulation,
+ 'IMPD decreased case
is
(not
at or below
consistent
with
when the
with
tine,
maximally the
assumption
Vol. 18, No. 4, 1965
that,
with
becomes
BIOCHEMICAL
increasing
concentrations
increasingly
sequently,
limited
more and
AND BIOPHYSICAL
Similar
though
less
eC Begg,
19591,
whereas
of oligomycin,
by the
dependent
more
striking
RESEARCH COMMUNICATIONS
generation on the
effects
were
octylguanidine
of
I-X
equilibrium
from
with
(II):
1963)
was
temp.,
added
Final
as expected
0P
start
volume,
in replacing
succinate-linked In Fig.
(McMurray was in-
Effect of varvirv amounts Fig. 5. of oliaomvcin on oxidative phosphorvlation with different substraThe reaction mixture conIXS. sisted of 180 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 15 mM NIgso , 3 mh4 ATP, 15 mM glu2 mM 74 units hexokinase, ;"ns (1.2 x lo6 cpdpmole), partfcles (prepared in the presence of 2 mM EDTA, pH 8.6) containing 0.6 mg protein and oligomycin as The srbstrate was indicated. either 0.2 mM NAD , 160 mM ethanol and 16 pg alcohol dehydrogenase; or 5 mM succinate; or 5 mM succinate, 3 c~s antimycin A and 0.2 mM TMP$. Final volume, 3.1 ml, temp., 30 C. 0 consumption was measured with a2Clark electrode and the esterification of P was determined by the isotope d f stribution method (Lindberg & Ernster, 1955).
the
3 ml,
30°C.
effective
the
to
reaction.
ATPase
on ATPase and on the ATP-suooorted reduction of NADf bv succinate and bv ascorbate + TMPD. Assay system for ATPase was the same as in The reaction mixture for the Fig. 1. ATP-supported reduction of NAD by succinate and by ascorbate + TMPD consisted of 180 mM sucrose, 1.6 mM KCN, 10 mM MgSO , 0.2 mM NADf, particles (prepare d in the presence of 2 mM EDTA, pli 8.9) containing 0.6 mg protein and oligomycin as indicated+ In the case of succinate-linked NAD reduction, 5 mM succinate was present; and in the zase of ascorbate + TMPD-linked NAD reduction, 2.5 mM ascorbate and 0.2 mM TMPD were present. 3 mM ATP
latter
NAD+ (ATP)
oliPomvcin
reaction.
ATP, and con-
valinomycin
0.3
(1): Succ. -
of NAD+ reduction
of the
observed
(Pressman,
rate
the
oligomycin,
and even
abolished
the
oligomycin-induced
NAD+ reduction. 5,
phosphorylating
data
are summarized capacity
of
the
concerning particles 526
the
effect
prepared
of oligomycin in the
presence
on of
Vol. 18, No. 4, 1965
BIOCHEMICAL
EDTA.
Low concentrations
either
NADH or succinate
the
case
less
system
where
restored
marked,
also
pronounced.
rise
or ascorbate
the
absence
partially
by DNP.
These
preliminary
control,
or,
in other
taking
place
at the
level
Lee,
19641,
utilization mitochondria For
(or
whereas
the
for
translocation
ion
effect
(Klingenberg, obtaining
the
of 8.5
a subatahtial succinate-linked
effects the
to 9.0.
capacity
(cf.
A, oligowas less
an enhancement
case
of the
succinate-
did
not
affect
respir-
phosphorylation
maximally.
the either
respiration,
when the
exb*bit
Fig.
is
2).
by preventing
hydrolysis
a good only
extent
a slow
formation;
of of respir-
hydrolysis
DNP most probably
C-I
cf.
acts Ernster
of Kg++ may be due to an enhancement , analogous
was
by Kg++ + Pi + ADP, or
that,
there
which
to that
found
& of
with
intact
above,
it
by
I-X
1963).
the
to maintain
inhibited
that
1964b3).
phosphorylation-stimulating
particles
words,
al.,
the
4 and 5).
Figs.
stimulated
suggest
the
over
this
causing
oligomycin
and completely
of C-I
hydrolysis
essential range
greatly
by oligomycin,
this
that
findings
atory
promoting
above,
et
but
as in the
(cf.
A and then
of antimycin uptake,
in
in the
transfer
(Lee
oligomycin
Pi and ADP, however,
by Mg",
blocked
of
same range
in concentrations
of oligomycin
restored
is
amount
employed
of Mg++,
concentrations
in phosphate
4-fold
obtained
by antimycin
presence
with
A significant,
was also
chain
in the
uptake
was about
of electron
respiratory
the
phosphate
succinate.
blocked
NAD+ reduction
conditions
when added
In the
the
was within
+ TMPD-linked
Under ation
cases,
of
a by-pass
to an increase
In all
of phosphorylation
I-X
establishing of the
the
uptake
was first
+ TMPD as substrate,
gave
case
in phosphate
site
RESEARCH COMMUNICATIONS
The enhancement in the
oxidation
energy-coupling
mycin
3-fold
increase
succinate
ascorbate
enhanced
as substrate.
by ThiPD, thus
second
oligomycin
of NADH, and about
though
With
of
AND BIOPHYSICAL
of
oligomycin
pH of the
KDTA-containing
At pH values for
both
NAD+ reduction
below
oxidative even
as described
8.5,
the
particles
phosphorylation
when assayed
527
sonicating
in the
was found
medium
within
may retain
and ATP-supported absence
of oligo-
Vol. 18, No. 4, 1965
mycin; less is
BIOCHEMICAL
at pH values pronounced,
lar
coupling;
(which Haas,
1964)
have
it
is
*non-phosphorylating'
for
the
earlier
(Lee
Of great
recently
and the
three
*site
specific*
act
operation these
oligomycin
of
a missing
are
This work has been We thank Miss Ulla-Britta
present
respiratory
1964a1,
but
for
three
the
and associates
present
sites
Racker of Green
phosphorylation
in the
in the
but
particles.
latter rather
as
results
coupling
factors'
the
cold-labile
& Conover, et
al.
of oxi-
respiratory
present
primarily
factors
species,
presence
of the
of soluble
the
so-called
process
of the
(cf.
that
reduction.
in the
complete
implications
laboratories,
oxida-
energy-coupling,
coupling
mode of action
enzyme
energy-
that
prepared
for
implies
respiratory
results
only
coupling
heart-muscle
NADf
particles
the
factors,
one already
relationships
the
presimi-
no oligomycin-stimulated
succinate-linked from
can restore
as do these
by restituting
for
in different
of Racker
particles
capacity
the
F 1'
that
the
revealed
in the
in principally
possesses
may be the
called
resulted
Keilin-Hartree
involving
studied
have
prepared
with
al.,
of
particles
becomes
phosphorylation
those
not
importance
of oligomycin
whereas
so far
ATPase,
fact
with 1963)
evident
et
interpretation widely
of oxidative
capacity,
phosphorylation
the
stimulation
submitochondrial
of EDTA possess
chain.
as the
or ATP-supported
In conclusion,
dative
effect
effects,
phosphorylation
concluded
stimulating
& Conover,
likewise
RESEARCH COMMUNICATIONS
the
experiments
(Racker
much weaker
preparation
tive
Preliminary
of ammonia but
9.0,
especially
concerned.
sence
above
AND BIOPHYSICAL
1963),
(1963).
same type
The
of
most probably
do not
by facilitating
the
Attempts
to clarify
in progress. supported by a grant from Samuelsson for excellent
the Swedish Cancer Society. technical assistance.
REFERENCES Ernster, L,, and Lee, C.P. (1964) Ann. Rev. Biochem., 3, 729. Green, D.E., Beyer, R.E., Hansen, M,, Smith, A.L., and Webster, G. (1963) Federation Proc., 22, 1460. Haas, D-W, (1964) Biochim. Biophys. Acta, &$ 543. Klingenberg, M. (1963) &: a) Funktionelle und morphologische Organisation der Zelle (P. Karlson, ed., Springer-Verlag, Heidelberg) p. 236; b) Energy-linked Functions of Mitochondria (B. Chance, ed., Academic Press, New York) p. 247. 528
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND 8lOPHYSlCAL
Lardy,
RESEARCH COMMJNlCATlONS
H.A., Johnson, D., and McMurray, W.C. (1958) Arch. Biochem. Biophys., 78, 587, Lee, C.P., Azzone, G.F., and Ernster, L. (1964al Nature, 201, 152. L. (1964b) u An International K., and Ernster, Lee, C.P., Nordenbrand, Symposium on Oxidases and Related Oxidation-Reduction Systems (T-E, King, H.S. Mason, and M. Morrison, eds., Wiley & Sons, New York) in press. Lindberg, O., and Ernster, L. (1955) Meth. Biochem. Anal., 3, 1. McMurray, W.C., and Begg,R.W. (1959) Arch. Biochem. Biophys., 84, 546. Pressman, B.C. (19631 J. Biol. Chem., 238, 401. Racker, E., and Conover, T.E. (1963) Federation Proc,, 22, 1088.
529
Vol. 18, No. 4, 1965
RESTORATION OF OXIDATIVE
AND BIOPHYSICAL
PHOSPHORYLATION IN 'NON-PHOSPHORYLATING
SUBMITOCHONDRIAL PARTICLES Chuan-pu Wenner-Gren
Institute,
RESEARCH COMMUNICATIONS
BY OLIGOMYCIN
LeeX and Lars University
Ernster
of Stockholm,
Stockholm,
Sweden
Received December 30, 1964 In a previous
paper
non-phosphorylating* carry
out
with
ATP as the
of respiratory
assayed these but
of
under
suitable
et al.,
1964a)
driven
by aerobically
lating
particles.
amount
of oligomycin
hydrogenaee
of the
finding
suggested
(Fig. %ellow
2):
that
Closer
required
that
activity oligomycin
an inhibition of the
Jane
of the Coffin
can also
Child6
may exhibit
523
19581.
observation
(Fig.
for
Medical
the
of the
trans-
maximal
in-
preparation.
a high-energy for
reaction
1) that
stimulation required
Fund
known
in non-phosphory-
two effects
of
factors*,
transhydrogenase
revealed
that
of
et at.,
previous
same particle
Memorial
of the
intermediates
maximal
when
restoration
(Lardy
the
process,
or 'coupling
amounts
effect
hydrolysis
the
enzymes
by the
oxidative
of this
be shown,
than
of the
perform
reversal
stimulated
to achieve
makes them
we
oligomycin
of this
what
paper
added
was much smaller
ATPase
and that
are still
In this
high-energy
study
particles
with
ADP to ATP.
appropriate
oligomycin
than
primary
was prompted
generated
reaction
hibition
of
more
from
as the
phosphorylation,
investigation
these
can
energy
As will
addition
of oxidative The present
as well
heart
to transfer
particles
no externally
by the
that
of ability
such
beef
so-called
intermediates
energy-coupling,
conditions.
requires
is achieved
inhibitor
ADP to ATP,
from
high-energy
phosphorylate
that
shown that
transhydrogenation
was concluded
lack
to
evidence
activities
(Lee
the
intermediates
phosphorylation
nucleotide
chain-linked is
to present
It
we have
preparations
generated
of energy.
'non-phosphorylating*
wish
1964a)
al.,
pyridine
aerobically
source
high-energy
et
submitochondrial
energy-dependent
efficiently
capable
(Lee
on the
This particles
intermediate, Research
1963-65.
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I
I 0.4
Fig.
~1.
0.8
1.2 1.6 Irg oligcmycin/mg
2.0 2.4 protein
28’
312
Effect
NADP+ reduction bv NADH. ATPase was assayed in a reaction mixture consisting of 160 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 4 mM (prepared in the presence of 2 mhI EDTA, pi-l 8.6) conMgso # particles tain 4 ng 0.2 mg protein, and oligomycin as indicated. Reaction was started by the addition of 5 mM ATP. Final volume, 1 ml, temp., 30°C, time of incubation, 5 min. The reaction mixture for the transhydrogenase assay consisted of 180 mM sucrose, 50 mh! Tris-acetate buffer, 10 mM MgSD , 0.2 mM NADH, 0.15 mhf NADP+, PH 7.5, 3.3 pM rotenone, 1 mM oxidized glutathione, an amoun 4 of glutathione reductose capable of oxidizing 0.5 umoles of NADPHfmin., particles containing 0.6 mg protein and oligomycin as indicated. Reaction was started by the addition of 5 mM succinate. Final volume, 3 ml, temp., 30°C.
succinate
ascorbate
f
I
energy-ckpendent transhydrogenast. ion translocation
high)m oligomycin
[valinomycin]
ATP
Fig. 2. resoiratorv coupling transfer
Hvoothetic scheme of the energy-transfer svstem linked to the chain. C , C , C denote electron carriers at the energyI and X denote hypothetic energy sites of the'resgira s ory chain; carriers (for further definitions, see Ernster and Lee, 1964). u bars indicate site of action of inhibitors; been bar indicates site of stimulation by 2,4-dinitrophenol (DNP). 524
Vol. 18; No. 4, 1965
I-X,
at
BIOCHEMICAL
low concentrations
action
of
the
that
(or
its
presented
below
As shown
in Fig.
only
tion,
in accordance
a very
considerable
occurred
tion,
which
stimulated
the
this
low rate
of
with
previous
prepared
results
only
a certain
within
ATP-supported
amount
reduction
rate
of NAD+ reduction
instead stimulating
of
being
virtually
oligomycin
exceeded
of
1964a).
ATP induced
The reaction
of
(Fig.
concentra-
Oligomycin
needed
for
or ascorbate
constant
as was the This 525
also
+ N,N,lj'N'-
analogous
noticed
by succinate
concentrations.
was
to the
Stimulation of ATPFig. 3. -suooorted succinate-linked + NAD reduction bv oliPomvcin The reaction mixture consisted of 180 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 1.6 mM KCN, 10 mM hlgso , 0.2 mM NAD+, 5 mM succ 4 nate and particles (prepared in the presence of 2 mM KDTA, pH 8.5) containing 0.75 mg protein. Other additions: 3 mM ATP, 0.15 pg oligomycin, 1.6 mk'malonate, and 1.6 /.tM rotenone& Final volume 3 ml, temp., 30 C.
was also
that
a
the
oligomycin 4).
in a fashion
or rotQncnQ
It
When
As anticipated,
range
KDTA exhi-
NAD+ reduc-
of NAD+ by ascorbate
(TMPDI,
NAD+ reduction. of oligomycin
presence
was added,
was inhibited
The
case.
et al.,
protein
it
particles.
NAD+ reduction.
t-nahate
the
(Lee
higher
oxidative
succinate-linked
and rotenone.
reaction
the
inter-
correct,
enhance
in the
ATP-supported
-tetramethyl-D-phenylenediamine
succinate-linked
is
by malonate
the
were
might
indeed
of succinate-linked
stimulation
ATP, at
in non-phosphorylating
3, particles
inhibited
above
interpretation
per mg of particle
rate
of the
Pi and ADP, to yield
this
reversal)
RESEARCH COMMUNICATIONS
and an inhibition
of oligomycin
show that
pg of oligomycin
completely
If
low concentrations
bited
0.2
with
of oligomycin.
phosphorylation data
of oligomycin;
same intermediate
concentrations follows
AND BIOPHYSICAL
maximal
shown)
that,
stimulation,
+ 'IMPD decreased case
is
(not
at or below
consistent
with
when the
with
tine,
maximally the
assumption
Vol. 18, No. 4, 1965
that,
with
becomes
BIOCHEMICAL
increasing
concentrations
increasingly
sequently,
limited
more and
AND BIOPHYSICAL
Similar
though
less
eC Begg,
19591,
whereas
of oligomycin,
by the
dependent
more
striking
RESEARCH COMMUNICATIONS
generation on the
effects
were
octylguanidine
of
I-X
equilibrium
from
with
(II):
1963)
was
temp.,
added
Final
as expected
0P
start
volume,
in replacing
succinate-linked In Fig.
(McMurray was in-
Effect of varvirv amounts Fig. 5. of oliaomvcin on oxidative phosphorvlation with different substraThe reaction mixture conIXS. sisted of 180 mM sucrose, 50 mM Tris-acetate buffer, pH 7.5, 15 mM NIgso , 3 mh4 ATP, 15 mM glu2 mM 74 units hexokinase, ;"ns (1.2 x lo6 cpdpmole), partfcles (prepared in the presence of 2 mM EDTA, pH 8.6) containing 0.6 mg protein and oligomycin as The srbstrate was indicated. either 0.2 mM NAD , 160 mM ethanol and 16 pg alcohol dehydrogenase; or 5 mM succinate; or 5 mM succinate, 3 c~s antimycin A and 0.2 mM TMP$. Final volume, 3.1 ml, temp., 30 C. 0 consumption was measured with a2Clark electrode and the esterification of P was determined by the isotope d f stribution method (Lindberg & Ernster, 1955).
the
3 ml,
30°C.
effective
the
to
reaction.
ATPase
on ATPase and on the ATP-suooorted reduction of NADf bv succinate and bv ascorbate + TMPD. Assay system for ATPase was the same as in The reaction mixture for the Fig. 1. ATP-supported reduction of NAD by succinate and by ascorbate + TMPD consisted of 180 mM sucrose, 1.6 mM KCN, 10 mM MgSO , 0.2 mM NADf, particles (prepare d in the presence of 2 mM EDTA, pli 8.9) containing 0.6 mg protein and oligomycin as indicated+ In the case of succinate-linked NAD reduction, 5 mM succinate was present; and in the zase of ascorbate + TMPD-linked NAD reduction, 2.5 mM ascorbate and 0.2 mM TMPD were present. 3 mM ATP
latter
NAD+ (ATP)
oliPomvcin
reaction.
ATP, and con-
valinomycin
0.3
(1): Succ. -
of NAD+ reduction
of the
observed
(Pressman,
rate
the
oligomycin,
and even
abolished
the
oligomycin-induced
NAD+ reduction. 5,
phosphorylating
data
are summarized capacity
of
the
concerning particles 526
the
effect
prepared
of oligomycin in the
presence
on of
Vol. 18, No. 4, 1965
BIOCHEMICAL
EDTA.
Low concentrations
either
NADH or succinate
the
case
less
system
where
restored
marked,
also
pronounced.
rise
or ascorbate
the
absence
partially
by DNP.
These
preliminary
control,
or,
in other
taking
place
at the
level
Lee,
19641,
utilization mitochondria For
(or
whereas
the
for
translocation
ion
effect
(Klingenberg, obtaining
the
of 8.5
a subatahtial succinate-linked
effects the
to 9.0.
capacity
(cf.
A, oligowas less
an enhancement
case
of the
succinate-
did
not
affect
respir-
phosphorylation
maximally.
the either
respiration,
when the
exb*bit
Fig.
is
2).
by preventing
hydrolysis
a good only
extent
a slow
formation;
of of respir-
hydrolysis
DNP most probably
C-I
cf.
acts Ernster
of Kg++ may be due to an enhancement , analogous
was
by Kg++ + Pi + ADP, or
that,
there
which
to that
found
& of
with
intact
above,
it
by
I-X
1963).
the
to maintain
inhibited
that
1964b3).
phosphorylation-stimulating
particles
words,
al.,
the
4 and 5).
Figs.
stimulated
suggest
the
over
this
causing
oligomycin
and completely
of C-I
hydrolysis
essential range
greatly
by oligomycin,
this
that
findings
atory
promoting
above,
et
but
as in the
(cf.
A and then
of antimycin uptake,
in
in the
transfer
(Lee
oligomycin
Pi and ADP, however,
by Mg",
blocked
of
same range
in concentrations
of oligomycin
restored
is
amount
employed
of Mg++,
concentrations
in phosphate
4-fold
obtained
by antimycin
presence
with
A significant,
was also
chain
in the
uptake
was about
of electron
respiratory
the
phosphate
succinate.
blocked
NAD+ reduction
conditions
when added
In the
the
was within
+ TMPD-linked
Under ation
cases,
of
a by-pass
to an increase
In all
of phosphorylation
I-X
establishing of the
the
uptake
was first
+ TMPD as substrate,
gave
case
in phosphate
site
RESEARCH COMMUNICATIONS
The enhancement in the
oxidation
energy-coupling
mycin
3-fold
increase
succinate
ascorbate
enhanced
as substrate.
by ThiPD, thus
second
oligomycin
of NADH, and about
though
With
of
AND BIOPHYSICAL
of
oligomycin
pH of the
KDTA-containing
At pH values for
both
NAD+ reduction
below
oxidative even
as described
8.5,
the
particles
phosphorylation
when assayed
527
sonicating
in the
was found
medium
within
may retain
and ATP-supported absence
of oligo-
Vol. 18, No. 4, 1965
mycin; less is
BIOCHEMICAL
at pH values pronounced,
lar
coupling;
(which Haas,
1964)
have
it
is
*non-phosphorylating'
for
the
earlier
(Lee
Of great
recently
and the
three
*site
specific*
act
operation these
oligomycin
of
a missing
are
This work has been We thank Miss Ulla-Britta
present
respiratory
1964a1,
but
for
three
the
and associates
present
sites
Racker of Green
phosphorylation
in the
in the
but
particles.
latter rather
as
results
coupling
factors'
the
cold-labile
& Conover, et
al.
of oxi-
respiratory
present
primarily
factors
species,
presence
of the
of soluble
the
so-called
process
of the
(cf.
that
reduction.
in the
complete
implications
laboratories,
oxida-
energy-coupling,
coupling
mode of action
enzyme
energy-
that
prepared
for
implies
respiratory
results
only
coupling
heart-muscle
NADf
particles
the
factors,
one already
relationships
the
presimi-
no oligomycin-stimulated
succinate-linked from
can restore
as do these
by restituting
for
in different
of Racker
particles
capacity
the
F 1'
that
the
revealed
in the
in principally
possesses
may be the
called
resulted
Keilin-Hartree
involving
studied
have
prepared
with
al.,
of
particles
becomes
phosphorylation
those
not
importance
of oligomycin
whereas
so far
ATPase,
fact
with 1963)
evident
et
interpretation widely
of oxidative
capacity,
phosphorylation
the
stimulation
submitochondrial
of EDTA possess
chain.
as the
or ATP-supported
In conclusion,
dative
effect
effects,
phosphorylation
concluded
stimulating
& Conover,
likewise
RESEARCH COMMUNICATIONS
the
experiments
(Racker
much weaker
preparation
tive
Preliminary
of ammonia but
9.0,
especially
concerned.
sence
above
AND BIOPHYSICAL
1963),
(1963).
same type
The
of
most probably
do not
by facilitating
the
Attempts
to clarify
in progress. supported by a grant from Samuelsson for excellent
the Swedish Cancer Society. technical assistance.
REFERENCES Ernster, L,, and Lee, C.P. (1964) Ann. Rev. Biochem., 3, 729. Green, D.E., Beyer, R.E., Hansen, M,, Smith, A.L., and Webster, G. (1963) Federation Proc., 22, 1460. Haas, D-W, (1964) Biochim. Biophys. Acta, &$ 543. Klingenberg, M. (1963) &: a) Funktionelle und morphologische Organisation der Zelle (P. Karlson, ed., Springer-Verlag, Heidelberg) p. 236; b) Energy-linked Functions of Mitochondria (B. Chance, ed., Academic Press, New York) p. 247. 528
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND 8lOPHYSlCAL
Lardy,
RESEARCH COMMJNlCATlONS
H.A., Johnson, D., and McMurray, W.C. (1958) Arch. Biochem. Biophys., 78, 587, Lee, C.P., Azzone, G.F., and Ernster, L. (1964al Nature, 201, 152. L. (1964b) u An International K., and Ernster, Lee, C.P., Nordenbrand, Symposium on Oxidases and Related Oxidation-Reduction Systems (T-E, King, H.S. Mason, and M. Morrison, eds., Wiley & Sons, New York) in press. Lindberg, O., and Ernster, L. (1955) Meth. Biochem. Anal., 3, 1. McMurray, W.C., and Begg,R.W. (1959) Arch. Biochem. Biophys., 84, 546. Pressman, B.C. (19631 J. Biol. Chem., 238, 401. Racker, E., and Conover, T.E. (1963) Federation Proc,, 22, 1088.
529