The activation of adrenal cortex mitochondrial malic enzyme by Ca2+ and Mg2+.

Adrenal cortex mitochondria prepared by a standard method do not exhibit malic enzyme activity. Addition of physiological concentrations of Ca2+ and Mg2+ enables these mitochondria to reduce added NADP+ by malate to form free NADPH. Half-maximum activation of the mitochondrial malic enzyme requires 0.3 mM Ca2+ and 1 mM Mg2+. Solubilized mitochondrial malic enzymes is independent of Ca2+ and has a K M of 0.2 mM for Mg2+. The Ca2+ effect is dependent on an initial period of active Ca2+ uptake which also causes other changes in respiratory properties similar to those observed with mitochondria from other tissues. After Ca2+ accumulation has taken place, free Ca2+, but not additional accumulation, is still required for malic enzyme activity. The requirement for Mg2+ can be met by Mn2+ (1 mM). This concentration of Mn2+ alone yielded only a slight activation of mitochondrial malic enzyme while higher concentrations of Mn2+ alone gave good activation of the mitochondrial malic enzy.e The NADPH generated by the Ca2+-Mg2+ activated malic enzyme effectively supports the 11beta-hydroxylation of deoxycorticosterone, whereas in the presence of malate, or malate plus Mg2+ but absence of Ca2+, the energy linked transhydrogenase supplies all the required NADPH. The activated malic enzyme appears to be more efficient than transhydrogenase in generating NADPH to support 11beta-hydroxylation. Cyanide and azide have been found to inhibit solubilized mitochondrial malic enzyme.     

The cytochrome c oxidase and its mitochondrial function in the whiteleg shrimp Litopenaeus vannamei during hypoxia

Cytochrome c oxidase (COX), which is located in the inner membrane of mitochondria, is a key constituent of the electron transport chain that catalyzes the reduction of oxygen. The Pacific whiteleg shrimp Litopenaeus vannamei is constantly exposed to hypoxic conditions, which affects both the central metabolism and the mitochondrial function. The purpose of this study was to isolate shrimp mitochondria, identify the COX complex and to evaluate the effect of hypoxia on the shrimp mitochondrial function and in the COX activity. A 190 kDa protein was identified as COX by immunodetection techniques. The effect of hypoxia was confirmed by an increase in the shrimp plasma L-lactate concentration. COX activity, mitochondrial oxygen uptake and protein content were reduced under hypoxic conditions, and gradually restored as hypoxia continued, this suggests an adaptive mitochondrial response and a highly effective COX enzyme. Both mitochondrial oxygen uptake and COX activity were completely inhibited by KCN and sodium azide, suggesting that COX is the unique oxidase in L. vannamei mitochondria.     

Investigation by amperometric methods of intracellular reduction of 2,6-dichlorophenolindophenol in normal and transformed hepatocytes in the presence of different inhibitors of cellular metabolism

The reduction of 2,6-dichlorophenolindophenol (DCIP) was measured by amperometric methods in Morris hepatoma 3924A cells, normal isolated rat hepatocytes and in mitochondria isolated from normal rat liver. The influence of aerobic and anaerobic atmospheres and of various inhibitors of cellular metabolism, especially of the respiratory chain (KCN, NaN3, oligomycin), on DCIP-reduction were studied using glucose, succinate, beta-hydroxybutyrate, alpha-keto-glutarate and oxalacetate as substrates. Under the influence of KCN and oligomycin the velocity of DCIP-reduction was increased in both cell types. Azide showed a similar effect on tumour cells and to a lower extent on hepatocytes. Using isolated mitochondria total DCIPred was increased by KCN and azide using various mitochondrial metabolites as substrates and with ADP/Pi present. The effects of KCN, azide and oligomycin could be explained by taking DCIP as an artificial coupling site in mitochondria which is only used when oxygen is absent or when the respiratory chain is blocked by inhibitors of cytochrome oxidase. Evaluation of the reaction kinetics revealed differences between normal and transformed cells in terms of the pseudo-first-order rate constants and the activity of overall oxidoreductases. The results apparently reflect quantitative differences in enzymatic equipment and the metabolic pathways predominating in normal and neoplastic cells.     

Changes of the NADP-linked malic enzyme in the developing rat skeletal muscle

The activities of NADP-linked malic enzyme, hexose monophosphate shunt dehydrogenases and NADP-linked isocitrate dehydrogenase were studied during development of skeletal muscle and compared with those in the liver. The variation patterns of malic enzyme activity in the liver and in the skeletal muscle were very similar, however the amplitude of the changes was different. The enzyme activity increased approx 16-fold in the liver and about 2-fold in skeletal muscle at the same stage of development. In skeletal muscle the increase of the malic enzyme activity was only slightly higher than of lactic dehydrogenase and citrate synthase. Studies on the intracellular distribution of malic enzyme in skeletal muscle showed that both mitochondrial and extramitochondrial enzymes increased between 20th and 37th day of life, the increase of the extramitochondrial enzyme being more pronounced. The hexose monophosphate shunt dehydrogenases activity showed an increase in the liver but no change was observed in the skeletal muscle at the weaning time. Changes in the activity of the liver and skeletal muscle isocitrate dehydrogenase were not significant between 10th and 80th day of life. The results suggest that the malic enzyme in the liver is playing a different physiological role than in the skeletal muscle.     

Regulation of mitochondrial and cytosolic malic enzymes from cultured rat brain astrocytes

Malate has a number of key roles in the brain, including its function as a tricarboxylic acid (TCA) cycle intermediate, and as a participant in the malate-aspartate shuttle. In addition, malate is converted to pyruvate and CO₂ via malic enzyme and may participate in metabolic trafficking between astrocytes and neurons. We have previously demonstrated that malate is metabolized in at least two compartments of TCA cycle activity in astrocytes. Since malic enzyme contributes to the overall regulation of malate metabolism, we determined the activity and kinetics of the mitochondrial and cytosolic forms of this enzyme from cultured astrocytes. Malic enzyme activity measured at 37°C in the presence of 0.5 mM malate was 4.15±0.47 and 11.61±0.98 nmol/min/mg protein, in mitochondria and cytosol, respectively (mean±SEM, n=18–19). Malic enzyme activity was also measured in the presence of several endogenous compounds, which have been shown to alter intracellular malate metabolism in astrocytes, to determine if these compounds affected malic enzyme activity. Lactate inhibited cytosolic malic enzyme by a noncompetitive mechanism, but had no effect on the mitochondrial enzyme. -Ketoglutarate inhibited both cytosolic and mitochondrial malic enzymes by a partial noncompetitive mechanism. Citrate inhibited cytosolic malic enzyme competitively and inhibited mitochondrial malic enzyme noncompetitively at low concentrations of malate, but competitively at high concentrations of malate. Both glutamate and aspartate decreased the activity of mitochondrial malic enzyme, but also increased the affinity of the enzyme for malate. The results demonstrate that mitochondrial and cytosolic malic enzymes have different kinetic parameters and are regulated differently by endogenous compounds previously shown to alter malate metabolism in astrocytes. We propose that malic enzyme in brain has an important role in the complete oxidation of anaplerotic compounds for energy.These data were presented in part at the meeting of the American Society for Neurochemistry in Richmond, Virginia, March 1993     

The effect of respiratory inhibitors on the fermentative ability of Pichia stipitis,Pachysolen tannophilus and Saccharomyces cerevisiae under various conditions of aerobiosis

Summary The growth and ethanol production by the d-xylose-fermenting yeasts Pichia stipitis and Pachysolen tannophilus under various conditions of aerobiosis responded similarly to the addition of the respiratory inhibitors potassium cyanide (KCN), antimycin A (AA), sodium azide and rotenone. However, the d-glucose-fermenting yeast Saccharomyces cerevisiae differed markedly from these yeasts in response to the inhibitors. In general the growth of the d-xylose-fermenting yeasts was inhibited by the respiratory inhibitors while ethanol production was either stimulated (especially when oxygen was available) or unaffected or inhibited by rotenone or AA or KCN and sodium azide, respectively. However, by exception KCN and AA stimulated ethanol production under aerobic conditions by Pichia stipitis and Pachysolen tannophilus respectively. Stimulatory or inhibitory effects by respiratory inhibitors were less marked in S. cerevisiae. These data suggest that unimpaired mitochondrial function is necessary for growth on d-xylose and optimal d-xylose fermentation. A requirement for membrane generated energy during d-xylose utilisation is indicated by 2,4-dinitrophenol inhibition of growth and fermentation.     

Nicotinamide-adenine dinucleotide-linked "malic" enzyme in flight muscle of the tse-tse fly (Glossina) and other insects.

1. A high activity of NAD-linked "malic" enzyme was found in homogenates of flight muscle of different species of tse-tse fly (Glossina). The activity was the same as, or higher than, that of malate dehydrogenase and more than 20-fold that of NADP-linked "malic" enzyme. A similar enzyme was found in the flight muscle of all other insects investigated, but at much lower activities. 2. ACa2+-stimulated oxaloacetate decarboxylase activity was present in all insect flight-muscle preparations investigated, in constant proportion to the NAD-linked "malic" enzyme. 3. A partial purification of the NAD-linked "malic" enzyme from Glossina was effected by DEAE-cellulose chromatography, which separated the enzyme from malate dehydrogenase and NADP-linked "malic" enzyme, but not from oxaloacetate decarboxylase. 4. The intracellular localization of the NAD-linked "malic" enzyme was predominantly mitochondrial; latency studies suggested a localization in the mitochondrial matrix space. 5. Studies on the partially purified enzyme demonstrated that it had a pH optimum between 7.6 and 7.9. It required Mg2+ or Mn2+ for activity; Ca2+ was not effective. The maximum rate was the same with either cation, but the concentration of Mn2+ required was 100 times less than that of Mg2+. Acitivity with NADP was only 1-3% of that with NAD, unless very high (greater than 10mM) concentrations of Mn2+ were present. 6. It is suggested that the NAD-linked "malic" enzyme functions in the proline-oxidation pathway predominant in tse-tse fly flight muscle.     

The role of mitochondria in carbon catabolite repression in yeast

Summary The role of mitochondria in carbon catabolite repression in Saccharomyces cerevisiae was investigated by comparing normal, respiratory competent (RHO) strains with their mitochondrially inherited, respiratory deficient mutant derivatives (rho). Formation of maltase and invertase was used as an indicator system for the effect of carbon catabolite repression on carbon catabolic reactions. Fermentation rates for glucose, maltose and sucrose were the same in RHO and rho strains. Specific activities of maltase and invertase were usually higher in the rho-mutants. A very pronounced difference in invertase levels was observed when cells were grown on maltose; rho-mutants had around 30 times more invertase than their RHO parent strains.The fact that rho-mutants were much less sensitive to carbon catabolite repression of invertase synthesis than their RHO parents was used to search for the mitochondrial factor(s) or function(s) involved in carbon catabolite repression. A possible metabolic influence of mitochondria on this system of regulation was tested after growth of RHO strains under anaerobic conditions (no respiration nor oxidative phosphorylation), in the presence of KCN (respiration inhibited), dinitrophenol (uncoupling of oxidative phosphorylation) and of both inhibitors anaerobic conditions and dinitrophenol had no effect on the extent of invertase repression. KCN reduced the degree of repression but not to the level found in rho-mutants. A combination of both inhibitors gave the same results as with KCN alone. Erythromycin and chloramphenicol were used as specific inhibitors of mitochondrial protein synthesis. Erythromycin prevented the formation of mitochondrial respiratory systems but did not induce rho-mutants under the conditions used. However, repression of invertase was as strong as in the absence of the inhibitor. Chloramphenicol led only to a slight reduction of the respiratory systems and did not affect invertase levels. A combination of both antibiotics had about the same effect as growth in the presence of KCN.The results showed that mitochondria are involved in carbon catabolite repression and they cause an increase in the degree of repression. These effects cannot be due to mere metabolic activities nor to factors made on the mitochondrial protein synthesizing machinery. This regulatory role of mitochondria is observed as long as an intact mitochondrial genome is maintained.     

Clofibrate feeding increases cytoplasmic but not mitochondrial malic enzyme activity in rat kidney cortex

Administration of clofibrate for 21 days to rats increased the malic enzyme activity in the kidney cortex by about 80 per cent. This effect seems to be specific since the drug did not alter significantly the activity either of lactate dehydrogenase, citrate synthase or total mitochondrial protein content in this organ. The increase in activity of malic enzyme in the 13,000 g supernatant (extramitochondrial) fraction in rats treated with the drug was about 80 per cent, whereas in the pellet (mitochondrial fraction) it was about 40 per cent. The specific activity of malic enzyme in the kidney cortex cytosol from clofibrate-treated rats was about twice that in controls. In contrast clofibrate treatment did not affect its specific activity in isolated mitochondria. Calculations showed that 0.57 and 0.53 mumoles min-1 g-1 wet tissue of mitochondrial malic enzyme was obtained in control and clofibrate-treated rats respectively. Thus, clofibrate feeding increases the amount of cytoplasmic but not mitochondrial malic enzyme activity.     

Kinetic mechanism of the cytosolic malic enzyme from human breast cancer cell line.

The kinetic mechanism of the cytosolic NADP(+)-dependent malic enzyme from cultured human breast cancer cell line was studied by steady-state kinetics. In the direction of oxidative decarboxylation, the initial-velocity and product-inhibition studies indicate that the enzyme reaction follows a sequential ordered Bi-Ter kinetic mechanism with NADP+ as the leading substrate followed by L-malate. The products are released in the order of CO2, pyruvate, and NADPH. The enzyme is unstable at high salt concentration and elevated temperature. However, it is stable for at least 20 min under the assay conditions. Tartronate (2-hydroxymalonate) was found to be a noncompetitive inhibitor for the enzyme with respect to L-malate. The kinetic mechanism of the cytosolic tumor malic enzyme is similar to that for the pigeon liver cytosolic malic enzyme but different from those for the mitochondrial enzyme from various sources.     

Differential characteristics of the cytosol and mitochondrial isozymes of malic enzyme from bovine brain. Effects of dicarboxylic acids and sulfhydryl reagents

The cytosol and mitochondrial isozymes of bovine brain malic enzyme were studied with respect to their sensitivity towards a series of dicarboxylic acids and sulfhydryl reagents. While no effects were obtained with the dicarboxylic acids in the case of the cytosol enzyme, the activity of the mitochondrial variant was increased considerably when either succinate, 2-mercaptosuccinate, or l-aspartate were tested at low concentrations of l-malate. The activation was associated with a clear decrease in the Hill coefficient for l-malate, and this has been taken as an indication of the presence of an allosteric site on the mitochondrial enzyme. The presence of l-malate or a dicarboxylate anion analog is required at this site in order to achieve optimal velocity. The activators were also effective in increasing the reductive carboxylation of pyruvate by the mitochondrial enzyme and had no effect on the cytosol variant. The two isozymes also showed a clear differential sensitivity to 5,5′-dithiobis(2-nitrobenzoic acid) and Hg²⁺, since the mitochondrial malic enzyme was inhibited by concentrations of these reagents far below those required in order to achieve an effect on the activity of the malic enzyme found in the cytosol.     

On the regulation of cold-labile cytosolic and of mitochondrial acetyl-CoA hydrolase in rat liver

The discovery of a cold-labile cytosolic acetyl-CoA hydrolase of high activity in rat liver by Prass et al. [(1980) J. Biol. Chem. 255, 5215-5223] has questioned the importance of mitochondrial acetyl-CoA hydrolase for the formation of free acetate [Grigat et al. (1979) Biochem. J. 177, 71-79] under physiological conditions. Therefore this problem has been reevaluated by comparing various properties of the two enzymes. Cold-labile cytosolic acetyl-CoA hydrolase bands with an apparent Mr of 68000 during SDS/polyacrylamide gel electrophoresis, while the native enzyme elutes in two peaks with apparent Mr of 136000 and 245000 during gel chromatography in the presence of 2 mM ATP. The mitochondrial enzyme elutes under the same conditions with an apparent Mr of 157000. Under conditions where the cold-labile enzyme binds strongly to DEAE-Bio-Gel and ATP-agarose, the mitochondrial enzyme remains unbound. The cold-labile enzyme can be activated 14-fold by ATP, half-maximal activation occurring already at 40 microM ATP. AdoPP[NH]P, AdoPP[CH2]P and GTP have a similar though weaker effect. ADP as well as GDP can completely inhibit the cold-labile enzyme with 50% inhibition occurring for both nucleotides at about 1.45 microM. The binding of ATP and ADP is competitive. Acetyl phosphate and pyrophosphate have no effect on the activity of the cold-labile enzyme. The mitochondrial acetyl-CoA hydrolase is not affected by these nucleotides. CoASH is a strong product inhibitor (approximately equal to 80% inhibition at 40 microM CoASH) of the cold-labile enzyme, but only a weak inhibitor of the mitochondrial enzyme. Under in vivo conditions the activity of the cold-labile cytosolic acetyl-CoA hydrolase can be no more than 7% of the activity calculated for mitochondrial acetyl-CoA hydrolase under the same conditions. Accordingly the mitochondrial enzyme seems to be mainly responsible for the formation of free acetate by the intact liver, especially in view of the fact that the substrate specificity of the mitochondrial enzyme is much higher (activity ratios acetyl-CoA/butyryl-CoA 4.99 and 1.16 for the mitochondrial and the cold-labile enzyme respectively). Alloxan diabetes neither increased the activity of the cold-labile enzyme nor that of the mitochondrial enzyme. No experimental support has been found yet for the hypothesis that the acetyl-CoA hydrolase activity of the cold-labile enzyme represents the side-activity of an acetyl-transferase.     

Evidence for the role of malic enzyme in the rapid oxidation of malate by cod heart mitochondria

Mitochondria isolated from the heart of cod (Gadus morrhua callarias) oxidized malate as the only exogenous substrate very rapidly. Pyruvate only slightly increased malate oxidation by these mitochondria. This is in contrast with the mitochondria isolated from rat and rabbit heart which oxidized malate very slowly unless pyruvate was added. Arsenite and hydroxymalonate (an inhibitor of malic enzyme) inhibited the respiration rate of mitochondria isolated from cod heart, when malate was the only exogenous substrate. Inhibition caused by hydroxymalonate was reversed by the addition of pyruvate. In the presence of arsenite, malate was converted to pyruvate by cod heart mitochondria. Cod heart mitochondria incubated in the medium containing Triton X-100 catalyzed the reduction of NADP+ in the presence of L-malate and Mn2+ at relatively high rate (about 160 nmoles NADPH formed/min/mg mitochondrial protein). The oxidative decarboxylation of malate was also taking place when NADP+ was replaced by NAD+ (about 25 nmol NADH formed per min per mg mitochondrial protein). These results suggest that the mitochondria contain both NAD+- and NADP+-linked malic enzymes. These two activities were eluted from DEAE-Sephacel as two independent peaks. It is concluded that malic enzyme activity (presumably both NAD+- and NADP+-linked) is responsible for the rapid oxidation of malate (as the only external substrate) by cod heart mitochondria.     

The effect of clofibrate feeding on the NADP-linked dehydrogenases activity in rat tissue

Administration of clofibrate to the rat increased several fold the activity of malic enzyme in the liver. Clofibrate treatment resulted also in an increased activity of the hepatic hexose monophosphate shunt dehydrogenases but was without effect on NADP-linked isocitrate dehydrogenase. The increased activity of malic enzyme in the liver resulting from the administration of clofibrate was inhibited by ethionine and puromycin, which suggests that de novo synthesis of the enzyme protein did occur as the result of the drug action. In contrast to the liver malic enzyme, the enzyme activity in kidney cortex increased only two-fold, whereas in the heart and skeletal muscle the activity was not affected by clofibrate administration.     

Genetic variation of the cytoplasmic and mitochondrial malic enzymes in the monkey Macaca nemestrina

Electrophoretic variation of both the cytoplasmic and mitochondrial forms of the malic enzyme is described in Macaca nemestrina. Pedigree analysis of the observed phenotypes demonstrates that the two subcellular forms of the malic enzyme are genetically independent. The identity of the electrophoretic phenotypes in brain, heart muscle, liver, kidney, adrenal, and spleen from any given individual shows that each subcellular form is determined by the same genetic locus in a wide variety of tissues. After separation by ion exchange chromatography, the cytoplasmic and mitochondrial malic enzymes were shown to be distinct in their heat stability and K _m for malate, but no significant differences were found among the variants of the cytoplasmic enzyme or among the variants of the mitochondrial enzyme. It is possible that the polymorphism of the mitochondrial malic enzyme is selectively neutral.This study was supported by grant GM-15253 from the National Institutes of Health. One of us (G.S.O.) was a Special Fellow, U.S. Public Health Service (5F3 HD 43, 122-02); Fellow, National Genetics Foundation.     

Mitochondrial NADP-dependent malic enzyme of cod heart. Rate of forward and reverse reaction

The mitochondrial NADP-dependent malic enzyme (EC 1.1.1.40) was purified about 300-fold from cod Gadus morhua heart to a specific activity of 48 units (mumol/min)/mg at 30 degrees C. The possibility of the reductive carboxylation of pyruvate to malate was studied by determination of the respective enzyme properties. The reverse reaction was found to proceed at about five times the velocity of the forward rate at a pH 6.5. The Km values determined at pH 7.0 for pyruvate, NADPH and bicarbonate in the carboxylation reaction were 4.1 mM, 15 microM and 13.5 mM, respectively. The Km values for malate, NADP and Mn2+ in the decarboxylation reaction were 0.1 mM, 25 microM and 5 microM, respectively. The enzyme showed substrate inhibition at high malate concentrations for the oxidative decarboxylation reaction at pH 7.0. Malate inhibition suggests a possible modulation of cod heart mitochondrial NADP-malic enzyme by its own substrate. High NADP-dependent malic enzyme activity found in mitochondria from cod heart supports the possibility of malate formation under conditions facilitating carboxylation of pyruvate.     

Involvement of diminution of glutathione, produced by deficiency of methionine in the diet, in the elevation of malic enzyme level in rat liver

Rats fed on a low protein diet show an increase in the specific activity of malic enzyme and a concomitant decrease of glutathione concentration. We have studied the effect on malic enzyme activity of supplementing of low protein diet with essential amino acids. Only when methionine was excluded from the diet did the specific activity of malic enzyme increase to the same extent as found in rats fed with low protein diet. Immunoprecipitation of malic enzyme indicated that specific activity changes are the result of changes in the amounts of enzyme. Under all dietary conditions studied, the increase in malic enzyme activity is associated with a decrease in the concentration of GSH. To evaluate the possible causative role of GSH in malic enzyme induction, the specific activity of malic enzyme was measured in rats treated with BSO, an inhibitor of GSH biosynthesis. The results show that in BSO-treated rats the decrease of GSH levels is also accompanied by an increase in the activity of malic enzyme.     

Manipulation of malic enzyme in Saccharomyces cerevisiae for increasing NADPH production capacity aerobically in different cellular compartments

The yeast Saccharomyces cerevisiae is an attractive cell factory, but in many cases there are constraints related with balancing the formation and consumption of redox cofactors. In this work, we studied the effect of having an additional source of NADPH in the cell. In order to do this, two strains were engineered by overexpression of malic enzyme. In one of them, malic enzyme was overexpressed as its wild-type mitochondrial form, and in the other strain a short form lacking the mitochondrial targeting sequence was overexpressed. The recombinant strains were analyzed in aerobic batch and continuous cultivations, and the basic growth characteristics were generally not affected to a great extent, even though pleiotropic effects of the manipulations could be seen by the altered in vitro activities of selected enzymes of the central metabolism. Moreover, the decreased pentose-phosphate pathway flux and the ratios of redox cofactors showed that a net transhydrogenase effect was obtained, which can be directed to the cytosol or the mitochondria. This may find application in redirecting fluxes for improving specific biotechnological applications.     

Mitochondrial malate dehydrogenase and malic enzyme: Mendelian inherited electrophoretic variants in the mouse

Malate dehydrogenase and malic enzyme each possess supernatant and mitochondrial molecular forms which are structurally and genetically independent. We describe electrophoretic variants of the mitochondrial enzymes of malate dehydrogenase and malic enzyme in mice. Progeny testing from genetic crosses indicated that the genes which code for mitochondrial malate dehydrogenase and malic enzyme were not inherited maternally but as independent unlinked nuclear autosomal genes. The locus for mitochondrial malic enzyme was located on linkage group I. Linkage analysis with a third mitochondrial enzyme marker, glutamic oxaloacetic transaminase, showed that the nuclear genes which code for the three mitochondrial enzymes were not closely linked to each other. This evidence suggests that clusters of nuclear genes coding for mitochondrial function are unlikely in mice.Supported by U.S. Public Health Service grants 5F2 HD-35,531 and GM-09966.     

Changes of malic enzyme activity in the developing rat brain are due to both the increase of mitochondrial protein content and the increase of specific activity.

1. The pattern of NADP-linked malic enzyme activity estimated in the whole brain homogenate did not parallel that found in liver of developing rat. 2. Studies on intracellular distribution of malic enzyme in brain showed that the mitochondrial enzyme increased about three-fold between 10th and 40th day of life. Thereafter, a slow gradual increase to the adult level was observed. 3. The extramitochondrial malic enzyme from brain, like the liver enzyme, increased at the time of weaning, although to a lesser extent. At day 5 the brain malic enzyme was equally distributed between mitochondria and cytosol. 4. During the postnatal development, the contribution of the mitochondrial malic enzyme in the total activity was increasing, reaching the value approx. 80% at day 150 after birth. 5. The increase with age of the malic enzyme specific activity was observed in both synaptosomal and non-synaptosomal mitochondria, the changes in the last fraction being more pronounced. 6. The activity of citrate synthase developed markedly between 10-40 postnatal days, increasing about five-fold, while the specific activity of the enzyme did change neither in the synaptosomal nor in non-synaptosomal mitochondria at this period. 7. We conclude that the changes in malic enzyme activity in the developing rat brain are mainly due both to the increase of mitochondrial protein content and to the increase of specific activity of the mitochondrial malic enzyme.