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The reversible activation of mitochondrial ATPase by high pH
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
77-KPEVEPSIBLEACTIVATION OF IIITOCilONDIZI.4L ATPase by IIIGH pH A. Fonyo*, L. Szende and Ilona ilezei Experimental &sear&
Dapartment, Universitv Bud&est, I-Iunga~.
Yedical School,
ReceivedJanuary 25, 1966 no general theories of oxidative The high-energy intermediate review:
phosphorylation
theory,
exist presently.
formulated seine 15 years ago (for
Lehninger, 1964) and the recent "chemi-osmotic-coupling"
(Mitchell,
1961; Yiitchell
and %yle,
1965).
hjjrpothesis
The two theories differ
in
the postulated role of ATPase. In the high-energy intermediate theory ATPase is supposedto function hydrolytic
only under artificial
uncouplers; (Penefsky et al. hypothesis, function,
in one of the transfer
tne "vectorial"
reactions and is
conditions (as in the presence of 1960).
In the chemi-osmotic-coupling
ATPase has a postulated central role,
driven by proton translocation
through the mitochondrial
membrane,would result
in the synthesis of ATP.
of importance to by,
what conditions favor the ATP-hydrolysis
may 'W the mechanismfor tne activation Activation
of mitochondrial
by %anson (1956) and later present paner, the similaritv
For botn theories
and what
ATPasebv increased p?I ;%lasfirst
confimd
it is
of the hydrolysis. *nor-ted
by ?TIers and Slater (1957). In fne
of this r3II ion activation
caused @I the uncoupler 2,4-dinitmphenol =erimental
Its
to the activation
(LNP) has been studied.
Procedure,
lhe experiments were Frformed
on 2 ws
of preparations:
intact
rat
heart mitochondria isolated in 0,25 M sucrose, and rat heart mitochondrial ik Pwsent address: Pediatric Research I!epa&nent, Baltimore, Maryland, U.S.A.
511
University
of Maryland,
Vol. 22, No. 5, 1966
fragments,
BIOCHEMICAL
The latter
muscle preparation
was a modification
of the Keilin and Hartree heart
as adapted for rat heart and performed in the cold: the
heart was washedwith distilled buffer,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
water and subsequentl;l r,rith 0,02 M phosphate
homogenized in 0,02 M phosphate buffer
genizer,
centrifuged
p!I 7,2 in an all glass homo-
at 600 g for 20 min.; the suparnatant was centrifuged
at 8500 ,g for 15 min., the sediment washed in 0,25 M sucrose, recentrifuged at 20,000 g for 15 min. and finally preparation
shoded only a slight
Vith succinate the P:O ratio could be activated
by IW,
susnendedin 0,25 M sucrose. capacity to oxidatively
was about 0,l.
induced ATPase was about one third
ATPase activity 50 mMtris-Cl
buffer,
mitochondria 0,15 mg mitochondr&l
of this IXJP
heart mitochondria.
results.
5 mMATP, in the case of intact
protein
The concentration
and in the case of fragments,
of DJP employed was 0,2 ml-i. The
incubation time was 10 min. and ATPase activity basis of inorganic phosphate liberated protein/l0
ATPase
was determined at 30° in a mediumthat contained
or tris-acetate
0,20 mg protein.
activity
that of intact
Both types of preparations yielded similar
phosphorylate.
)Jevertheless, its
although the specific
This
was calculated on the
and expressed asmle
p/m,g
min.
Results. Tine ATPase of both intact
mitochondria and fragments was activated
by raising the pH; this activation In Fig. 1 the buffer
took place in the absence of Mg2+ ions.
above pH 9.5 with tris,
but the activation
1-propanol-Cl and Annonia-Cl buffers. 'Ihe actitition
No measurementcouldbe.
used was tris-Cl.
performed
was similar with 2-amino-2-methyl-
The activity
decreased above pH 9.5.
also occurred in the absence of added buffer when the pH
of the reaction mixture was adjusted to pH 9.0 - 9.5 by the addition of NaOH. Tnis "high pH activated to the ATPase activated by high concentrations
ATPase" was inmany respects quite similar
at pH 7.4 by CNP. They were similarly of sucrose (Fig.21,
512
inhibited
oligomycin (Fig.31 and by aging
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
2-
I,
5
Fig.1.
6
7 PH
9
6
Effect of -pII on ATPase activity mitochondrial fraqkents.
A
7
of heart muscle
pMol I’
%5cx--Jo mM SUCROSE
Fig. 2.
Effect
of sucrose on ATPase of heart muscle pH
0
:
pH
7,4,
5
mMMg2+;* -
513
7,4,
0,2 mMDIP; pH 9,5, 5 ti
Ng2+.
Vol. 22, No. 5, 1966
BIOCHEMICAL
A/d01
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
P
41
OLIGOMYCIN Arc)/ml.
Fig. 3.
Effect
of oligomycin A on ATPase of heart
LO
at
(Fig.4).
37
inhibit.
pH 7,4, 5 m?lb@+;*-.
The non-ionic
muscle
pH 9,5, 5 mMMg2'
detergent TRITON-X-100 and azide also
This is in sharp contrast with the behavior of the ;4g2+ activated
ATPase, which is inhibited or by aging.
very slightly
if at all by sucrme, TRITOSX-100
These data suggest that the high pH activated
different
fxm the Mg2+ activated
identical
with the enzyme or system which responds to DIP,
The activating
effect
ATPase and may be closely related
to or
of high pH is to a large degree reversible
Part A is a control,
shows the activity
pH 9,5 and the effect
of neutralization
no difference
ATPase is
(Fig.5).
in the presence of 0.2 m?4DIJPat of a sample to pH 7,4
exists between the activities.
at
2,s
min.
-
In part B of this figure
the
lowest line represents the ATPase at pH 7,4, the upper line at pH 9,s.
At
514
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-
60 min
Fig. 4. Effect of aging on high pH activated and DNPactivated ATPase heart muscle mitochondrial fragments preincubated in 0.25 M sucrose pH 7,4. ATPase measured at: xv pH 7,4;I-+I-]pH 9,5, AA pH 7,4 0.2 mMDNP -
6 5 4 3 2 '
t l!!Lk 2'30' 5'
w--' 7’30’
IO'
2'30"5'
7’30”
IO'
Fig. 5. Reversibility of high pH activated ATPase heart muscle mitochondrial fragments. A: pH 9,5, 0,2 mMDNP At the arrow HCl was added to bring the pH to 7,4 B: x-x pH 7,4;1-1 -l-lpH 9,s; At the arrow HCI wa?.added tg bring the pH to 7,4
515
Vol. 22, No. 5, 1966
BIOCHEMICAL
the arrows a titrated
axxnt
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of HCl yas added in a very
reaction mediumat pri 9,5 to bring the pH to 7,4. the rate of ATP-splitting after
neutralization
decreased significantly,
does not precisely
that the reversibility
parallel
of the activation
After
VOGUE to the
small
neutralization
Tne fact that the rate the control rate,
suggests
is about 60 per cent complete.
Ihe apparent l$,, values for ATP differed
at 7,4 (in the presence of IMP)
and at 9,5: at pH 7,4 the apparent Kmwas of the order of 10-4 3 and at pH 9,s it was 6,4. 10e3 M. This sugests that the lmorehighly ionized ATP molecule may be less tightly
bound to the enzyme at the hipjer
ph.
Discussion. Those enzymes which play a role in ATP synthesis can catalyze hydrolysis under certain artificial
conditions such as in the presence of the usual un-
couplers of ox&dative phosphorylation strated whether the high pH itself There are several different the activation
or by high pH. It remains to be demon-
acts as a reversible theoretical
of ATP hydrolysis
possibilities
at high pH,
uncoupler, which might explain
The degree of ionization
of
substrates and products at pH 7,4 and ~1-19,5 may markedly influence the catalytic
activity
of the enzyme, ATP which is more highly ionized at pH 9,5
may be more susceptible to enzyrnic hydrolysis possibilities
than ATP at pH 7,4.
These
are weakened but not ruled out by the I$, data which indicates
that the less ionized species is the preferred substrate for hydrolysis, Another possibility reversibly
is that the structure
at high pII.
create an active and favoring
Tne ionization
of a dissociable group might
center causing a change in the catalytic
reaction with water,
uncouplers may operate bv a similar et al. 1964).
of the enzyme is altered
An alternative
a possible explanation,
ma&anism
It has been suggested that some group-ionizing
mechanism(Bovell
view, the chemi-osmotic theory,
According to its newest formulation
Moyle, 1965; Jagendorf, pers. ccn-m.1protons are translocated mitochondrially
during electron transport.
516
also gives (Mitchell extra-
The proton gradient frmn
and
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
outside to inside tnus created, coupled with a reversible, oriented,
spatially-
membranelocated ATPase is the cause of ATP svnthesis.
One
might expect, that diminishing or reversing the proton gradient by increasing the external hydrolysis.
pH might direct
AT&se in the direction
This rmrk is consistent with such a mechanism, but does not
rule out a possibility
of alterations
in enzyme structure,
Xle authors wish to express appreciation A. Jagendorf and B.C. Layne for helpful of the manuscript, gratefully
of
lhe expert technical
to Drs. S.P. Bessman,
discussions during the preparation assistance of I%s. S. Lip&h is
acknowledged.
References Bovell, C.R., Packer, L,, and Schonba~, S.R., Arch. Biochem. Biophys, UN, 458, 1964, Lehni:nSer, A.L.,
The I%tochondrion.
'?J.A. Benjamin, NewYork - Pmsterdan, 1964.
Mitchell,
P., Nature, 191, 144, 1961.
fitchell,
P., and Hoyle,J.,
Xyers, D.K., and Slater,
Nature, 208, 147, 1965.
E.C., Biochem. J. 67, 559, 1357.
Penefsky, H.S., Pullman, M.E., Datta, A., and Racker, E., J. Biol. 3330, 1960. Swanson, iq.A., &xhim.
Biophys. Acta, 20, 85, 1956.
517
Chem,235,
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
77-KPEVEPSIBLEACTIVATION OF IIITOCilONDIZI.4L ATPase by IIIGH pH A. Fonyo*, L. Szende and Ilona ilezei Experimental &sear&
Dapartment, Universitv Bud&est, I-Iunga~.
Yedical School,
ReceivedJanuary 25, 1966 no general theories of oxidative The high-energy intermediate review:
phosphorylation
theory,
exist presently.
formulated seine 15 years ago (for
Lehninger, 1964) and the recent "chemi-osmotic-coupling"
(Mitchell,
1961; Yiitchell
and %yle,
1965).
hjjrpothesis
The two theories differ
in
the postulated role of ATPase. In the high-energy intermediate theory ATPase is supposedto function hydrolytic
only under artificial
uncouplers; (Penefsky et al. hypothesis, function,
in one of the transfer
tne "vectorial"
reactions and is
conditions (as in the presence of 1960).
In the chemi-osmotic-coupling
ATPase has a postulated central role,
driven by proton translocation
through the mitochondrial
membrane,would result
in the synthesis of ATP.
of importance to by,
what conditions favor the ATP-hydrolysis
may 'W the mechanismfor tne activation Activation
of mitochondrial
by %anson (1956) and later present paner, the similaritv
For botn theories
and what
ATPasebv increased p?I ;%lasfirst
confimd
it is
of the hydrolysis. *nor-ted
by ?TIers and Slater (1957). In fne
of this r3II ion activation
caused @I the uncoupler 2,4-dinitmphenol =erimental
Its
to the activation
(LNP) has been studied.
Procedure,
lhe experiments were Frformed
on 2 ws
of preparations:
intact
rat
heart mitochondria isolated in 0,25 M sucrose, and rat heart mitochondrial ik Pwsent address: Pediatric Research I!epa&nent, Baltimore, Maryland, U.S.A.
511
University
of Maryland,
Vol. 22, No. 5, 1966
fragments,
BIOCHEMICAL
The latter
muscle preparation
was a modification
of the Keilin and Hartree heart
as adapted for rat heart and performed in the cold: the
heart was washedwith distilled buffer,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
water and subsequentl;l r,rith 0,02 M phosphate
homogenized in 0,02 M phosphate buffer
genizer,
centrifuged
p!I 7,2 in an all glass homo-
at 600 g for 20 min.; the suparnatant was centrifuged
at 8500 ,g for 15 min., the sediment washed in 0,25 M sucrose, recentrifuged at 20,000 g for 15 min. and finally preparation
shoded only a slight
Vith succinate the P:O ratio could be activated
by IW,
susnendedin 0,25 M sucrose. capacity to oxidatively
was about 0,l.
induced ATPase was about one third
ATPase activity 50 mMtris-Cl
buffer,
mitochondria 0,15 mg mitochondr&l
of this IXJP
heart mitochondria.
results.
5 mMATP, in the case of intact
protein
The concentration
and in the case of fragments,
of DJP employed was 0,2 ml-i. The
incubation time was 10 min. and ATPase activity basis of inorganic phosphate liberated protein/l0
ATPase
was determined at 30° in a mediumthat contained
or tris-acetate
0,20 mg protein.
activity
that of intact
Both types of preparations yielded similar
phosphorylate.
)Jevertheless, its
although the specific
This
was calculated on the
and expressed asmle
p/m,g
min.
Results. Tine ATPase of both intact
mitochondria and fragments was activated
by raising the pH; this activation In Fig. 1 the buffer
took place in the absence of Mg2+ ions.
above pH 9.5 with tris,
but the activation
1-propanol-Cl and Annonia-Cl buffers. 'Ihe actitition
No measurementcouldbe.
used was tris-Cl.
performed
was similar with 2-amino-2-methyl-
The activity
decreased above pH 9.5.
also occurred in the absence of added buffer when the pH
of the reaction mixture was adjusted to pH 9.0 - 9.5 by the addition of NaOH. Tnis "high pH activated to the ATPase activated by high concentrations
ATPase" was inmany respects quite similar
at pH 7.4 by CNP. They were similarly of sucrose (Fig.21,
512
inhibited
oligomycin (Fig.31 and by aging
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
2-
I,
5
Fig.1.
6
7 PH
9
6
Effect of -pII on ATPase activity mitochondrial fraqkents.
A
7
of heart muscle
pMol I’
%5cx--Jo mM SUCROSE
Fig. 2.
Effect
of sucrose on ATPase of heart muscle pH
0
:
pH
7,4,
5
mMMg2+;* -
513
7,4,
0,2 mMDIP; pH 9,5, 5 ti
Ng2+.
Vol. 22, No. 5, 1966
BIOCHEMICAL
A/d01
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
P
41
OLIGOMYCIN Arc)/ml.
Fig. 3.
Effect
of oligomycin A on ATPase of heart
LO
at
(Fig.4).
37
inhibit.
pH 7,4, 5 m?lb@+;*-.
The non-ionic
muscle
pH 9,5, 5 mMMg2'
detergent TRITON-X-100 and azide also
This is in sharp contrast with the behavior of the ;4g2+ activated
ATPase, which is inhibited or by aging.
very slightly
if at all by sucrme, TRITOSX-100
These data suggest that the high pH activated
different
fxm the Mg2+ activated
identical
with the enzyme or system which responds to DIP,
The activating
effect
ATPase and may be closely related
to or
of high pH is to a large degree reversible
Part A is a control,
shows the activity
pH 9,5 and the effect
of neutralization
no difference
ATPase is
(Fig.5).
in the presence of 0.2 m?4DIJPat of a sample to pH 7,4
exists between the activities.
at
2,s
min.
-
In part B of this figure
the
lowest line represents the ATPase at pH 7,4, the upper line at pH 9,s.
At
514
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-
60 min
Fig. 4. Effect of aging on high pH activated and DNPactivated ATPase heart muscle mitochondrial fragments preincubated in 0.25 M sucrose pH 7,4. ATPase measured at: xv pH 7,4;I-+I-]pH 9,5, AA pH 7,4 0.2 mMDNP -
6 5 4 3 2 '
t l!!Lk 2'30' 5'
w--' 7’30’
IO'
2'30"5'
7’30”
IO'
Fig. 5. Reversibility of high pH activated ATPase heart muscle mitochondrial fragments. A: pH 9,5, 0,2 mMDNP At the arrow HCl was added to bring the pH to 7,4 B: x-x pH 7,4;1-1 -l-lpH 9,s; At the arrow HCI wa?.added tg bring the pH to 7,4
515
Vol. 22, No. 5, 1966
BIOCHEMICAL
the arrows a titrated
axxnt
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of HCl yas added in a very
reaction mediumat pri 9,5 to bring the pH to 7,4. the rate of ATP-splitting after
neutralization
decreased significantly,
does not precisely
that the reversibility
parallel
of the activation
After
VOGUE to the
small
neutralization
Tne fact that the rate the control rate,
suggests
is about 60 per cent complete.
Ihe apparent l$,, values for ATP differed
at 7,4 (in the presence of IMP)
and at 9,5: at pH 7,4 the apparent Kmwas of the order of 10-4 3 and at pH 9,s it was 6,4. 10e3 M. This sugests that the lmorehighly ionized ATP molecule may be less tightly
bound to the enzyme at the hipjer
ph.
Discussion. Those enzymes which play a role in ATP synthesis can catalyze hydrolysis under certain artificial
conditions such as in the presence of the usual un-
couplers of ox&dative phosphorylation strated whether the high pH itself There are several different the activation
or by high pH. It remains to be demon-
acts as a reversible theoretical
of ATP hydrolysis
possibilities
at high pH,
uncoupler, which might explain
The degree of ionization
of
substrates and products at pH 7,4 and ~1-19,5 may markedly influence the catalytic
activity
of the enzyme, ATP which is more highly ionized at pH 9,5
may be more susceptible to enzyrnic hydrolysis possibilities
than ATP at pH 7,4.
These
are weakened but not ruled out by the I$, data which indicates
that the less ionized species is the preferred substrate for hydrolysis, Another possibility reversibly
is that the structure
at high pII.
create an active and favoring
Tne ionization
of a dissociable group might
center causing a change in the catalytic
reaction with water,
uncouplers may operate bv a similar et al. 1964).
of the enzyme is altered
An alternative
a possible explanation,
ma&anism
It has been suggested that some group-ionizing
mechanism(Bovell
view, the chemi-osmotic theory,
According to its newest formulation
Moyle, 1965; Jagendorf, pers. ccn-m.1protons are translocated mitochondrially
during electron transport.
516
also gives (Mitchell extra-
The proton gradient frmn
and
Vol. 22, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
outside to inside tnus created, coupled with a reversible, oriented,
spatially-
membranelocated ATPase is the cause of ATP svnthesis.
One
might expect, that diminishing or reversing the proton gradient by increasing the external hydrolysis.
pH might direct
AT&se in the direction
This rmrk is consistent with such a mechanism, but does not
rule out a possibility
of alterations
in enzyme structure,
Xle authors wish to express appreciation A. Jagendorf and B.C. Layne for helpful of the manuscript, gratefully
of
lhe expert technical
to Drs. S.P. Bessman,
discussions during the preparation assistance of I%s. S. Lip&h is
acknowledged.
References Bovell, C.R., Packer, L,, and Schonba~, S.R., Arch. Biochem. Biophys, UN, 458, 1964, Lehni:nSer, A.L.,
The I%tochondrion.
'?J.A. Benjamin, NewYork - Pmsterdan, 1964.
Mitchell,
P., Nature, 191, 144, 1961.
fitchell,
P., and Hoyle,J.,
Xyers, D.K., and Slater,
Nature, 208, 147, 1965.
E.C., Biochem. J. 67, 559, 1357.
Penefsky, H.S., Pullman, M.E., Datta, A., and Racker, E., J. Biol. 3330, 1960. Swanson, iq.A., &xhim.
Biophys. Acta, 20, 85, 1956.
517
Chem,235,