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The role of malic enzyme in bovine adrenal cortex mitochondria
Vol. 31, No. 1, 1968
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE ROLEOF MALIC ENZYMEIN BOVINEADRENALCORTEXMITOCHONDRIA* Evan R. Simpson+, Wendy Cammerz,and Ronald W. Estabrook Department of Biophysics and Physical Biochemistry Johnson Research Foundation University of Pennsylvania, Philadelphia 19104
Received March 7, 1968 The oxidative first
decarboxylation
of malate to pyruvate and carbon dioxide was
observed by Moulder, Vennesland, and Evans (1945) and by Ochoa, Mehler,
and Kornberg (1947). reverse direction
The possibility to effect
that the reaction might operate in the
the fixation
Ochoa, Mehler, and Kornberg (1.948).
of carbon dioxide was suggested by
The enzyme catalyzing
enzyme (L-malate : NADPoxidoreductase (decarboxylating) fied frcm pigeon liver
and characterized
was found to occur in the cytosol fraction intracellular
location,
this reaction, 1.1.1.40),
by Hsu and Lardy (1967). of pigeon liver.
malic
was puriThe enzyme
Because of this
Young, Shrago, and Lardy (1964) suggested that in liver
and adipose tissue malic enzyme activity
was important as a source of NADPHfor
lipogenesis. Steroid mixed-function
oxidases also require NADPH,but in the adrenal
cortex three of these enzyme reactions are mitochondrial, hydroxylase terol
(Sweat, 1951; Brownie and Grant, 1954), 18-hydroxylase
side-chain cleavage system (Psychoyos, Tallan,
Halkerston,
namely the llg-
Eichhorn, and Hechter, 1961).
and choles-
and Greengard, 1966;
The source of NADPHfor these sys-
tems is not known, but evidence has been presented to suggest that the mixedfunction
oxidase electron transport
linked to the main respiratory
chain of adrenal cortex mitochondria is
chain by an energy-dependent transhydrogenase,
* Supported in part by U.S.P.H.S. Research Grants GMI2202 and 2G277. + Permanent address: Department of Biochemistry, Medical School, University Edinburgh, Great Britain. $ Present address: Department of Pharmacology, Albert Einstein College of Medicine, The Bronx, New York
113
of
Vol. 31, No. 1,1968
BIOCHEMICAL
and that reducing equivalents
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
generated during succinate oxidation
coupled to this by reversed electron of the respiratory 1966; Koritz,
flow along the NADH-dehydrogenaseportion
chain (Harding and Nelson, 1966; P&on, McCarthy, and Guerra,
1966; and Hall,
1967).
In contrast,
the generation of NADPHfor l&3-hydroxylation enzyme activity
can be
Grant (1956) suggested that
might be associated with malic
in the mitochondria of the adrenal cortex.
The purpose of this communication is to show that bovine adrenal cortex contains two distinct
malic enzymes, one in the cytoaol and one in the mito-
chondria, and to present evidence that the mitochondrialmalic is the source of NADPHfor llg-hydroxylation. linked reactions
enzyme activity
The hypothesis that energy
occurring during auccinate oxidation
play a significant
in the generation of NADPHis not supported by the results
role
presented in this
paper. Methods Bovine adrenal cortex mitochondria were prepared as previously (Cammerand Eatabrook, 1967).
Malic enzyme activity
NADPHformation using an Bppendorf fluorimeter ment as described by Estabrook and Maitra
described
was assayed by meansof
with compensating voltage attach-
(1962).
Alternatively,
the increase
in absorption at 340 rnp was observed using an Aminco-Chance dual wavelength split
beam spectrophotameter.
oxygen electrode
Oxygen uptake was determined using a Clark
(Clark, Wolf, Granger, and Taylor,
was by the method of Estabrook and Maitra
1963).
Pyruvate estimation
(lg&).
Results and Discussion -Differential
centrifugation
of a hanogenate of bwine adrenal cortex
revealed that malic enzyme activity
was located in the mitochondria as well as
in the cytosol.
in the mitochondria was about one-fifth
The total
activity
that in the cytoaol, the cytoaol respectively).
whereas the specific activity was about one-half that in -1 -1 -1 mg prot-1 and 40 rnp moles (25 rnp moles min min mg prot The mitochondrial
activity,
howwer, was only manifest when the
mitochondria were subjected to ultraaonication,
114
which aolubilized
the enzyme,
Vol. 3 1, No. 1, 1968
thus indicating
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
that the enzyme was located within
not merely absorbed on the outer surface, i.e.
the mitochondrion and was
the mitochondrial
activity
was
not due to contamination fran the cytosol enzyme. The mitochondrial have been purified
and cytoplasmic malic enzymes of bovine adrenal cortex
by ammoniumsulphate fractionation
Sephadex G-100 and DEAE-cellulose. purified
seventy fold.
In this way, the mitochondrial
That the bimodal distribution
in the tissue was due to two distinct their
and by chrcmatography on
of malic enzyme activity
species of enzyme protein was shown by
chromatographic behaviour on DEAE-cellulose (Fig.
behaved similarly elution
to the pigeon liver
of the mitochondrial
Kinetic mitochondrial
enzyme was
1).
The cytosol enzyme
enzyme of Hsu and Lady
enzyme required a buffer
studies indicated a further
difference
enzymes. Measurements of the ratio
(1967), but
of higher ionic strength. between the cytoplasmic and
of the maximuminitial
veloci-
ties for the forward and reverse reactions:
malate + TPN+indicated marked differences
forward
pyruvate
+ CO2 + TPNH+ H+
for the two enzymes. The ratio
PJmax1reverSe for the mitochondrial
Wmax)fomara/
enzyme was 105, whereas the ratio
for the
cytoplasmic enzyme was 2.5. An interesting
property
of the mitochondrial
tion observed in the presence of the respiratory dicumarol.
The inhibition
enzyme was the strong inhibiuncouplers dinitrophenol
by dicumarol was apparently
to malate with a Ki of 15 $I.
(Ki for dicumarol = 51 $4).
presence of a malic enzyme in the mitochondrial
fraction
uncoupling agents raised the question of the validity that NADPHwas generated during succinate oxidation electron transport, critical
competitive with respect
The supernatant enzyme was also inhibited
these reagents, but to a much smaller extent
inhibited
The
by
via energy-linked
reverse
considered most
of this pathway, is the inhibitory
115
by
of the interpretation
since one of the experimental results,
for the evaluation
and
effect
of
Vol. 31, No. 1, 1968
BIOCHEMICAL
8
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1’6 24
32 40
Fraction
Number
48
54
Figure 1. Chrcmatography of a mixed sample of mitochondrial and cytosol malic enzymes on DEAE-cellulose. O.lml samples fran each fraction were assayed in a final volume of 3 ml in the presence of 8 mML-malate, 300 fl TPN, and 5 mM Mgc12. s-
cytosolmalic
M- mitochondrial
enzyme. malic enzyme.
uncouplers on the succinate-supported and McCarthy,
ll&hydroxylation
of DOC(Guerra, P&on,
1966).
Experiments were then carried out to measure pyruvate formation during malate-
or succinate-supported
mitochondria. cxidase
and rotenone to inhibit
in Figure 2, the llg-hydroxylation of pyruvate
rate of pyruvate
situation
reaction,
NADHdehydrogenase.
As
pyruvate can be seen
of DOCin the presence of succinate produced
formation as a result
formation was sufficient
the hydroxylation A similar
of DOCby adrenal cortex
Arsenite was added to the reaction mediumto inhibit
activity,
a stimulation
l&3-hydrcncylation
of malic enzyme activity.
to provide all the IiADPH required for
as measured by the stimulation
was found if rotenone was omitted.
obtained when malate was used as substrate.
The
of oxygen uptake.
Canparable results were
Thus bovine adrenal cortex contains,
in addition to the normal cytoplasmic enzyme, a second malic enzyme located in
116
Vol. 31, No. 1, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Mitochondrio
/JLx7?&
Minutes
Figure 2. Oxygen uptake and pyruvate formation during succinate-supported IL@hydroxylation of DCC. Oxygen uptake was measured in the chamber of a Clark oxygen electrode. In a parallel experiment sampleswere taken for pyruvate Concentrations in the final mixture were: estimation as described in the text. 8m~ succinate; 135 $4 DOC; 2 mMarsenite; and 3 pg/ml of rotenone. Oxygen uptake is shown as a continuous line, pyruvate formation as solid circles. The num!frs on the figure are rates of oxygen uptake or pyruvate formation in $4 min .
the mitochondria, mixed-function
the function
reactions.
uncoupler-sensitive
of which is to provide NADPHfor mitochondrial
Previous conclusions regarding the role of an
energy-dependent succinate-linked
reduction of NAD+,
coupled with an energy-dependent transhydrogenase for formation of NADPH,need not be considered as an obligatory
requirement for the mixed-function
oxidase
reaction.
REFERENCFaS Brownie, A. C., and Grant, J. K., Biochem. J. x, 255 (1954). Cammer,W., and Estabrook, R. W., Arch. Biochem. Biophys. z, 721 (1967). Clark, L. C. Jr., Wolf, R., Granger, D., and Taylor, Z., J. Appl. Physiol. _6, 189 (1953). Estabrook, R. W., and Maitra, P. K., Anal. Biochem. 2, 369 (1962). Grant, J. K., Biochem. J. 64, 559 (1956). Guerra, F., P&on, F. C., and McCarthy, 3. L., Biochim. Biophys. Acta llJ, 433 (1966). Halkerston, I. D. IL, Eicbhorn, J., and Hechter, O., J. Biol. C&m. 236, 374
(1961).
Hall, P. F., Biochem. Biopbys. Res. Ccmmun.6, 320 (1967). Harding, B. W., and Nelson, D. H., J. Biol. Chem.2&, 2212 (1966).
117
Vol. 31, No. 1, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Hsu, R. Y., and Lardy, H. A., J. Biol. Chem.242, 520 (1967). Koritz, S. B., Biochem. Biophys. Res. Ccmmuu.3, 485 (1966). Moulder, J. W., Vennesland, B., and Evans, E. A. Jr., J. Biol.
Chem.160, 305
Ochoa(1z45)* ., Mehler, A. H., and Kornberg, A., J. Biol. Chem. Ochoa' S Mehlrr, A. H., and Kornberg, A., (l&j: P&on: FI'C., McCarthy, J. L., and Guerra, I?., Biochim. Biophys. Acta 3, (1966).
Psychoybs, S., Tallan, H. H., and Greengard, P., J. Biol. Chem.2& 2949 0966). Sweat, M. L., J. Am. Chem. Sot. z, 4056 (1~1). Young, J. W., Shrago, E., and Lardy, H. A., Biochemistry 2, 1687 (1964).
118
450
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE ROLEOF MALIC ENZYMEIN BOVINEADRENALCORTEXMITOCHONDRIA* Evan R. Simpson+, Wendy Cammerz,and Ronald W. Estabrook Department of Biophysics and Physical Biochemistry Johnson Research Foundation University of Pennsylvania, Philadelphia 19104
Received March 7, 1968 The oxidative first
decarboxylation
of malate to pyruvate and carbon dioxide was
observed by Moulder, Vennesland, and Evans (1945) and by Ochoa, Mehler,
and Kornberg (1947). reverse direction
The possibility to effect
that the reaction might operate in the
the fixation
Ochoa, Mehler, and Kornberg (1.948).
of carbon dioxide was suggested by
The enzyme catalyzing
enzyme (L-malate : NADPoxidoreductase (decarboxylating) fied frcm pigeon liver
and characterized
was found to occur in the cytosol fraction intracellular
location,
this reaction, 1.1.1.40),
by Hsu and Lardy (1967). of pigeon liver.
malic
was puriThe enzyme
Because of this
Young, Shrago, and Lardy (1964) suggested that in liver
and adipose tissue malic enzyme activity
was important as a source of NADPHfor
lipogenesis. Steroid mixed-function
oxidases also require NADPH,but in the adrenal
cortex three of these enzyme reactions are mitochondrial, hydroxylase terol
(Sweat, 1951; Brownie and Grant, 1954), 18-hydroxylase
side-chain cleavage system (Psychoyos, Tallan,
Halkerston,
namely the llg-
Eichhorn, and Hechter, 1961).
and choles-
and Greengard, 1966;
The source of NADPHfor these sys-
tems is not known, but evidence has been presented to suggest that the mixedfunction
oxidase electron transport
linked to the main respiratory
chain of adrenal cortex mitochondria is
chain by an energy-dependent transhydrogenase,
* Supported in part by U.S.P.H.S. Research Grants GMI2202 and 2G277. + Permanent address: Department of Biochemistry, Medical School, University Edinburgh, Great Britain. $ Present address: Department of Pharmacology, Albert Einstein College of Medicine, The Bronx, New York
113
of
Vol. 31, No. 1,1968
BIOCHEMICAL
and that reducing equivalents
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
generated during succinate oxidation
coupled to this by reversed electron of the respiratory 1966; Koritz,
flow along the NADH-dehydrogenaseportion
chain (Harding and Nelson, 1966; P&on, McCarthy, and Guerra,
1966; and Hall,
1967).
In contrast,
the generation of NADPHfor l&3-hydroxylation enzyme activity
can be
Grant (1956) suggested that
might be associated with malic
in the mitochondria of the adrenal cortex.
The purpose of this communication is to show that bovine adrenal cortex contains two distinct
malic enzymes, one in the cytoaol and one in the mito-
chondria, and to present evidence that the mitochondrialmalic is the source of NADPHfor llg-hydroxylation. linked reactions
enzyme activity
The hypothesis that energy
occurring during auccinate oxidation
play a significant
in the generation of NADPHis not supported by the results
role
presented in this
paper. Methods Bovine adrenal cortex mitochondria were prepared as previously (Cammerand Eatabrook, 1967).
Malic enzyme activity
NADPHformation using an Bppendorf fluorimeter ment as described by Estabrook and Maitra
described
was assayed by meansof
with compensating voltage attach-
(1962).
Alternatively,
the increase
in absorption at 340 rnp was observed using an Aminco-Chance dual wavelength split
beam spectrophotameter.
oxygen electrode
Oxygen uptake was determined using a Clark
(Clark, Wolf, Granger, and Taylor,
was by the method of Estabrook and Maitra
1963).
Pyruvate estimation
(lg&).
Results and Discussion -Differential
centrifugation
of a hanogenate of bwine adrenal cortex
revealed that malic enzyme activity
was located in the mitochondria as well as
in the cytosol.
in the mitochondria was about one-fifth
The total
activity
that in the cytoaol, the cytoaol respectively).
whereas the specific activity was about one-half that in -1 -1 -1 mg prot-1 and 40 rnp moles (25 rnp moles min min mg prot The mitochondrial
activity,
howwer, was only manifest when the
mitochondria were subjected to ultraaonication,
114
which aolubilized
the enzyme,
Vol. 3 1, No. 1, 1968
thus indicating
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
that the enzyme was located within
not merely absorbed on the outer surface, i.e.
the mitochondrion and was
the mitochondrial
activity
was
not due to contamination fran the cytosol enzyme. The mitochondrial have been purified
and cytoplasmic malic enzymes of bovine adrenal cortex
by ammoniumsulphate fractionation
Sephadex G-100 and DEAE-cellulose. purified
seventy fold.
In this way, the mitochondrial
That the bimodal distribution
in the tissue was due to two distinct their
and by chrcmatography on
of malic enzyme activity
species of enzyme protein was shown by
chromatographic behaviour on DEAE-cellulose (Fig.
behaved similarly elution
to the pigeon liver
of the mitochondrial
Kinetic mitochondrial
enzyme was
1).
The cytosol enzyme
enzyme of Hsu and Lady
enzyme required a buffer
studies indicated a further
difference
enzymes. Measurements of the ratio
(1967), but
of higher ionic strength. between the cytoplasmic and
of the maximuminitial
veloci-
ties for the forward and reverse reactions:
malate + TPN+indicated marked differences
forward
pyruvate
+ CO2 + TPNH+ H+
for the two enzymes. The ratio
PJmax1reverSe for the mitochondrial
Wmax)fomara/
enzyme was 105, whereas the ratio
for the
cytoplasmic enzyme was 2.5. An interesting
property
of the mitochondrial
tion observed in the presence of the respiratory dicumarol.
The inhibition
enzyme was the strong inhibiuncouplers dinitrophenol
by dicumarol was apparently
to malate with a Ki of 15 $I.
(Ki for dicumarol = 51 $4).
presence of a malic enzyme in the mitochondrial
fraction
uncoupling agents raised the question of the validity that NADPHwas generated during succinate oxidation electron transport, critical
competitive with respect
The supernatant enzyme was also inhibited
these reagents, but to a much smaller extent
inhibited
The
by
via energy-linked
reverse
considered most
of this pathway, is the inhibitory
115
by
of the interpretation
since one of the experimental results,
for the evaluation
and
effect
of
Vol. 31, No. 1, 1968
BIOCHEMICAL
8
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1’6 24
32 40
Fraction
Number
48
54
Figure 1. Chrcmatography of a mixed sample of mitochondrial and cytosol malic enzymes on DEAE-cellulose. O.lml samples fran each fraction were assayed in a final volume of 3 ml in the presence of 8 mML-malate, 300 fl TPN, and 5 mM Mgc12. s-
cytosolmalic
M- mitochondrial
enzyme. malic enzyme.
uncouplers on the succinate-supported and McCarthy,
ll&hydroxylation
of DOC(Guerra, P&on,
1966).
Experiments were then carried out to measure pyruvate formation during malate-
or succinate-supported
mitochondria. cxidase
and rotenone to inhibit
in Figure 2, the llg-hydroxylation of pyruvate
rate of pyruvate
situation
reaction,
NADHdehydrogenase.
As
pyruvate can be seen
of DOCin the presence of succinate produced
formation as a result
formation was sufficient
the hydroxylation A similar
of DOCby adrenal cortex
Arsenite was added to the reaction mediumto inhibit
activity,
a stimulation
l&3-hydrcncylation
of malic enzyme activity.
to provide all the IiADPH required for
as measured by the stimulation
was found if rotenone was omitted.
obtained when malate was used as substrate.
The
of oxygen uptake.
Canparable results were
Thus bovine adrenal cortex contains,
in addition to the normal cytoplasmic enzyme, a second malic enzyme located in
116
Vol. 31, No. 1, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Mitochondrio
/JLx7?&
Minutes
Figure 2. Oxygen uptake and pyruvate formation during succinate-supported IL@hydroxylation of DCC. Oxygen uptake was measured in the chamber of a Clark oxygen electrode. In a parallel experiment sampleswere taken for pyruvate Concentrations in the final mixture were: estimation as described in the text. 8m~ succinate; 135 $4 DOC; 2 mMarsenite; and 3 pg/ml of rotenone. Oxygen uptake is shown as a continuous line, pyruvate formation as solid circles. The num!frs on the figure are rates of oxygen uptake or pyruvate formation in $4 min .
the mitochondria, mixed-function
the function
reactions.
uncoupler-sensitive
of which is to provide NADPHfor mitochondrial
Previous conclusions regarding the role of an
energy-dependent succinate-linked
reduction of NAD+,
coupled with an energy-dependent transhydrogenase for formation of NADPH,need not be considered as an obligatory
requirement for the mixed-function
oxidase
reaction.
REFERENCFaS Brownie, A. C., and Grant, J. K., Biochem. J. x, 255 (1954). Cammer,W., and Estabrook, R. W., Arch. Biochem. Biophys. z, 721 (1967). Clark, L. C. Jr., Wolf, R., Granger, D., and Taylor, Z., J. Appl. Physiol. _6, 189 (1953). Estabrook, R. W., and Maitra, P. K., Anal. Biochem. 2, 369 (1962). Grant, J. K., Biochem. J. 64, 559 (1956). Guerra, F., P&on, F. C., and McCarthy, 3. L., Biochim. Biophys. Acta llJ, 433 (1966). Halkerston, I. D. IL, Eicbhorn, J., and Hechter, O., J. Biol. C&m. 236, 374
(1961).
Hall, P. F., Biochem. Biopbys. Res. Ccmmun.6, 320 (1967). Harding, B. W., and Nelson, D. H., J. Biol. Chem.2&, 2212 (1966).
117
Vol. 31, No. 1, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Hsu, R. Y., and Lardy, H. A., J. Biol. Chem.242, 520 (1967). Koritz, S. B., Biochem. Biophys. Res. Ccmmuu.3, 485 (1966). Moulder, J. W., Vennesland, B., and Evans, E. A. Jr., J. Biol.
Chem.160, 305
Ochoa(1z45)* ., Mehler, A. H., and Kornberg, A., J. Biol. Chem. Ochoa' S Mehlrr, A. H., and Kornberg, A., (l&j: P&on: FI'C., McCarthy, J. L., and Guerra, I?., Biochim. Biophys. Acta 3, (1966).
Psychoybs, S., Tallan, H. H., and Greengard, P., J. Biol. Chem.2& 2949 0966). Sweat, M. L., J. Am. Chem. Sot. z, 4056 (1~1). Young, J. W., Shrago, E., and Lardy, H. A., Biochemistry 2, 1687 (1964).
118
450