Formation of glycine and aminoacetone from L-threonine by rat liver mitochondria

Threonine is a precursor of glycine in the rat, but the metabolic pathway involved is unclear. To elucidate this pathway, the biosynthesis of glycine, and of aminoacetone, from L-threonine were studied in rat liver mitochondrial preparations of differing integrities. In the absence of added cofactors, intact mitochondria formed glycine and aminoacetone in approximately equal amounts from 20 mM L-threonine, but exogenous NAD+ decreased and CoA increased the ratio of glycine to aminoacetone formed. In intact and freeze-thawed mitochondria, the ratio of glycine to aminoacetone formed was markedly sensitive to the concentration of L-threonine, glycine being the major product at low L-threonine concentrations. Disruption of mitochondrial integrity by sonication (1 min) decreased the ratio of glycine to aminoacetone formed, and in 20000 X g supernatant fractions from sonicated (3 min) mitochondria, aminoacetone was the major product. The main non-nitogenous two-carbon compound detected when intact mitochondria catabolized L-threonine to glycine was acetate, which was probably derived from deacylation of acetyl-CoA. These results suggest that glycine formation from L-threonine in rat liver mitochondria occurred primarily by the coupled activities of threonine dehydrogenase and 2-amino-3-oxobutyrate CoA-ligase, the extent of coupling between the enzymes being dependent upon a close physical relationship and upon the flux through the dehydrogenase reaction. In vivo glycine synthesis would predominate, and aminoacetone would be a minor product.     

Catabolism of threonine in mammals by coupling of l-threonine 3-dehydrogenase with 2-amino-3-oxobutyrate-CoA ligase

There is doubt about the l-threonine 3-dehydrogenase (EC 1.1.1.103) and threonine aldolase (EC 2.1.2.1) catabolic pathways of l-threonine in mammals which are believed to produce aminoacetone and glycine plus acetaldehyde, respectively. l-Threonine 3-dehydrogenase in disrupted guinea-pig liver mitochondria was investigated in a reaction mixture containing l-threonine without and with CoA and oxaloacetate; l-[U-¹⁴C]threonine was included in four similar experiments for autoradiograms. Threonine aldolase was examined in similar mitochondria from liver and kidney. CoA reduced the aminoacetone formed from l-threonine to 10–14% and CoA plus oxaloacetate produced citrate (from CoASAc) in approximately equal amounts to the decrease in aminoacetone. Autoradiograms confirmed the decrease in aminoacetone with the simultaneous appearance of citrate and glycine. No evidence was obtained that threonine aldolase catabolised l-threonine at the concentration used to assay the dehydrogenase. It is concluded that 2-amino-3-oxobutyrate (precursor of aminoacetone), which is produced from l-threonine by l-threonine 3-dehydrogenase, undergoes CoA-dependent cleavage to glycine and CoASAc by 2-amino-3-oxobutyrate-CoA ligase. The results suggest that the coupling of these enzymes provides a new pathway for the catabolism of threonine in mammals.     

Catabolism of threonine in mammals by coupling of l-threonine 3-dehydrogenase with 2-amino-3-oxobutyrate-CoA ligase

There is doubt about the l-threonine 3-dehydrogenase (EC 1.1.1.103) and threonine aldolase (EC 2.1.2.1) catabolic pathways of l-threonine in mammals which are believed to produce aminoacetone and glycine plus acetaldehyde, respectively. l-Threonine 3-dehydrogenase in disrupted guinea-pig liver mitochondria was investigated in a reaction mixture containing l-threonine without and with CoA and oxaloacetate; l-[U-¹⁴C]threonine was included in four similar experiments for autoradiograms. Threonine aldolase was examined in similar mitochondria from liver and kidney. CoA reduced the aminoacetone formed from l-threonine to 10–14% and CoA plus oxaloacetate produced citrate (from CoASAc) in approximately equal amounts to the decrease in aminoacetone. Autoradiograms confirmed the decrease in aminoacetone with the simultaneous appearance of citrate and glycine. No evidence was obtained that threonine aldolase catabolised l-threonine at the concentration used to assay the dehydrogenase. It is concluded that 2-amino-3-oxobutyrate (precursor of aminoacetone), which is produced from l-threonine by l-threonine 3-dehydrogenase, undergoes CoA-dependent cleavage to glycine and CoASAc by 2-amino-3-oxobutyrate-CoA ligase. The results suggest that the coupling of these enzymes provides a new pathway for the catabolism of threonine in mammals.     

Utilization of l-threonine by a species of Arthrobacter. A novel catabolic role for `aminoacetone synthase''

1. A species of Arthrobacter (designated Arthrobacter 9759) was isolated from soil by its ability to grow aerobically on l-threonine as sole source of carbon atoms, nitrogen atoms and energy; the organism also grew well on other sources of carbon atoms including glycine, but no growth was obtainable on aminoacetone or dl-1-aminopropan-2-ol. 2. During growth on threonine, (14)C from l-[U-(14)C]threonine was rapidly incorporated into glycine and citrate, and thereafter into serine, alanine, aspartate and glutamate. 3. With extracts of threonine-grown cells supplied with l-[U-(14)C]threonine, evidence was obtained of the NAD and CoA-dependent catabolism of l-threonine to produce acetyl-CoA plus glycine. Short-term incorporation studies in which [2-(14)C]acetate and [2-(14)C]glycine were supplied (a) to cultures growing on threonine, and (b) to extracts of threonine-grown cells, showed that the acetyl-CoA was metabolized via the tricarboxylic acid cycle and glyoxylate cycle whereas the glycine was converted into pyruvate via the folate-dependent ;serine pathway'. 4. The threonine-grown organism contained ;biosynthetic' threonine dehydratase and a potent NAD-linked l-threonine dehydrogenase but possessed no l-threonine aldolase activity. 5. Evidence was obtained that the acetyl-CoA and glycine produced from l-threonine had their immediate origin in the alpha-amino-beta-oxobutyrate formed by the threonine dehydrogenase; the CoA-dependent cleavage of this compound was catalysed by an alpha-amino-beta-oxobutyrate CoA-ligase, which was identified with ;aminoacetone synthase'. A continuous spectrophotometric assay of this enzyme was developed, and it was found to be inducibly synthesized only during growth on threonine and not during growth on acetate plus glycine. 6. By using a reconstituted mixture of separately purified l-threonine dehydrogenase and alpha-amino-beta-oxobutyrate CoA-ligase (i.e. ;aminoacetone synthase'), l-[U-(14)C]threonine was broken down to [(14)C]glycine plus [(14)C]acetyl-CoA (trapped as [(14)C]citrate). 7. There was no evidence of aminoacetone metabolism by Arthrobacter 9759 even though a small amount of this amino ketone appeared in the culture medium during growth on threonine.     

Purification and properties of aminoacetone synthetase from beef liver mitochondria

Aminoacetone synthetase from beef liver mitochondria was purified to homogeneity and shown to be a member of the pyridoxal 5'-phosphate-dependent family of enzymes. This enzyme catalyzes the condensation of glycine and acetyl-CoA to produce CO2, CoA, and the stable product aminoacetone. Bovine aminoacetone synthetase is a dimer (Mr 56,000) of identical subunits and contains 2 mol of pyridoxal phosphate/mol of dimer. The holoenzyme was resolved by dialysis against cysteine and has a pI of 5.2. The holoenzyme shows an absorption maximum at 428 nm which undergoes a shift to 335 nm when reduced with sodium borohydride. The Km values of glycine and acetyl-CoA were 22 mM and 53 microM, respectively. Initial velocity studies indicate that the condensation reaction proceeds by an ordered mechanism. With the exception of aminomalonate, bovine aminoacetone synthetase acts specifically on glycine and acetyl-CoA. Coupled reactions of purified bovine aminoacetone synthetase and porcine L-threonine dehydrogenase demonstrated the interconversion of threonine and glycine.     

Inhibition of glycine oxidation by pyruvate, alpha-ketoglutarate, and branched-chain alpha-keto acids in rat liver mitochondria: presence of interaction between the glycine cleavage system and alpha-keto acid dehydrogenase complexes

Pyruvate, alpha-ketoglutarate, and branched-chain alpha-keto acids which were transaminated products of valine, leucine, and isoleucine inhibited glycine decarboxylation by rat liver mitochondria. However, glycine synthesis (the reverse reaction of glycine decarboxylation) was stimulated by those alpha-keto acids with the concomitant decarboxylation of alpha-keto acid added in the absence of NADH. Both the decarboxylation and the synthesis of glycine by mitochondrial extract were affected similarly by alpha-ketoglutarate and branched-chain alpha-keto acids in the absence of pyridine nucleotide, but not by pyruvate. This failure of pyruvate to have an effect was due to the lack of pyruvate oxidation activity in the mitochondrial extract employed. It indicated that those alpha-keto acids exerted their effects by providing reducing equivalents to the glycine cleavage system, possibly through lipoamide dehydrogenase, a component shared by the glycine cleavage system and alpha-keto acid dehydrogenase complexes. On the decarboxylation of pyruvate, alpha-ketoglutarate, and branched-chain alpha-keto acids in intact mitochondria, those alpha-keto acids inhibited one another. In similar experiments with mitochondrial extract, decarboxylations of alpha-ketoglutarate and branched-chain alpha-keto acid were inhibited by branched-chain alpha-keto acid and alpha-ketoglutarate, respectively, but not by pyruvate. NADH was unlikely to account for the inhibition. We suggest that the lipoamide dehydrogenase component is an indistinguishable constituent among alpha-keto acid dehydrogenase complexes and the glycine cleavage system in mitochondria in nature, and that lipoamide dehydrogenase-mediated transfer of reducing equivalents might regulate alpha-keto acid oxidation as well as glycine oxidation.     

Interaction between L-threonine dehydrogenase and aminoacetone synthetase and mechanism of aminoacetone production

A mixture of threonine dehydrogenase and aminoacetone synthetase will catalyze the conversion of L-threonine to glycine. The overall reaction likely involves the conversion of L-threonine, NAD+, and CoA to glycine, NADH, and acetyl-CoA. Physical separation of L-threonine dehydrogenase from aminoacetone synthetase results in the formation of aminoacetone and CO2 from their substrates. A physical interaction between threonine dehydrogenase and aminoacetone synthetase has been demonstrated by gel permeation chromatography and fluorescence polarization. Polarization of fluorescence measurements of threonine dehydrogenase and aminoacetone synthetase labeled with fluorescein isothiocyanate indicated the formation of a soluble active complex, with an apparent dissociation constant (Kd) of 5-10 nM and an apparent stoichiometry of 2 aminoacetone synthetase dimers/1 threonine dehydrogenase tetramer. Chemical experiments have identified aminoacetone as the enzymatic product of L-threonine dehydrogenase acting on L-threonine. These experiments involved trapping pyrrole derivatives, [3H]NaBH4 reduction, and coupling with plasma amine oxidase. Kinetic experiments also showed NADH, CO2, and aminoacetone to inhibit threonine dehydrogenase in a manner consistent with an ordered Bi-Ter kinetic mechanism. NAD+ is the lead substrate followed by threonine, and the products are released in the order: CO2, aminoacetone, and NADH.     

Cell-free synthesis of a putative precursor to the rat liver mitochondrial glycerol-3-phosphate dehydrogenase

Antibodies to purified glycerol-3-phosphate dehydrogenase were raised in rabbits and purified from serum by affinity chromatography on enzyme-bound Sepharose columns. RNA from membrane-free polyribosomes, or poly(A)+ RNA (total cellular RNA) of rat liver, was translated in a rabbit reticulocyte protein-synthesizing system in the presence of [35S]methionine, and the glycerol-3-phosphate dehydrogenase synthesized was isolated by immunoprecipitation using the antibody. The in vitro product moved on sodium dodecyl sulfate-polyacrylamide gels as a polypeptide that was about 5,000 daltons larger than the subunit of the mature enzyme (74,000 daltons). Digestion of both the mature and the in vitro newly synthesized forms of the enzyme yielded respective sets of peptide fragments which had similar patterns upon sodium dodecyl sulfate-gel electrophoresis. When the presumptive precursor that had been synthesized in vitro was incubated with isolated intact rat liver mitochondria, it was converted to "mature" subunits that were no longer susceptible to externally added proteases. Import of the presumptive precursor is dependent upon an electrochemical potential across the inner mitochondrial membranes. The mature form of the protein is assembled in its native location (the outer surface of the inner mitochondrial membrane).     

A comparison of the regulation of pyruvate dehydrogenase in mitochondria from rat brain and liver.

The total activity of pyruvate dehydrogenase in mitochondria isolated from rat brain and liver was 53.5 and 14.2nmol/min per mg of protein respectively. Pyruvate dehydrogenase in liver mitochondria incubated for 4 min at 37 degrees C with no additions was 30% in the active form and this activity increased with longer incubations until it was completely in the active form after 20 min. Brain mitochondrial pyruvate dehydrogenase activity was initially high and did not increase with addition of Mg2+ plus Ca2+ or partially purified pyruvate dehydrogenase phosphatase or with longer incubations. The proportion of pyruvate dehydrogenase in the active form in both brain and liver mitochondria changed inversely with changes in mitochondrial energy charge, whereas total pyruvate dehydrogenase did not change. The chelators citrate, isocitrate, EDTA, ethanedioxybis(ethylamine)tetra-acetic acid and Ruthenium Red each lowered pyruvate dehydrogenase activity in brain mitochondria, but only citrate and isocitrate did so in liver mitochondria. These chelators did not affect the energy charge of the mitochondria. Mg2+ plus Ca2+ reversed the pyruvate dehydrogenase inactivation in liver, but not brain, mitochondria. The regulation of the activation-inactivation of pyruvate dehydrogenase in mitochondria from rat brain and liver with respect to energy charge is similar and may be at least partially regulated by this parameter, and the effects of chelators differ in the two types of mitochondria.     

Transport of proteins into mitochondrial matrix. Evidence suggesting a common pathway for 3-ketoacyl-CoA thiolase and enzymes having presequences

Rat liver 3-ketoacyl-CoA thiolase, a mitochondrial matrix enzyme which catalyzes a step of fatty acid beta-oxidation, was synthesized in a rabbit reticulocyte lysate cell-free system. The in vitro product was apparently the same in molecular size and charge as the subunit of the mature enzyme. The enzyme synthesized in vitro was transported into isolated rat liver mitochondria in an energy-dependent manner. In pulse experiments with isolated rat hepatocytes at 37 degrees C, the radioactivity of the newly synthesized enzyme in the cytosolic fraction remained essentially unchanged during 5-20 min of incubation, whereas that of the enzyme in the particulate fraction increased with time during the incubation. The pulse-labeled enzyme disappeared with an apparent half-life of less than 3 min from the cytosolic fraction, in pulse-chase experiments. Purified 3-ketoacyl-CoA thiolase inhibited the mitochondrial uptake and processing of the precursors of the other matrix enzymes, ornithine carbamoyltransferase, medium-chain acyl-CoA dehydrogenase and acetoacetyl-CoA thiolase. These results indicate that 3-ketoacyl-CoA thiolase has an internal signal which is recognized by the mitochondria and suggest that this enzyme and the three others are transported into the mitochondria by a common pathway.     

Threonine degradation by Serratia marcescens.

The wild strain of Serratia marcescens rapidly degraded threonine and formed aminoacetone in a medium containing glucose and urea. Extracts of this strain showed high threonine dehydrogenase and "biosynthetic" threonine deaminase activities, but no threonine aldolase activity. Threonine dehydrogenase-deficient strain Mu-910 was selected among mutants unable to grow on threonine as the carbon source. This strain did not form aminoacetone from threonine, but it slowly degraded threonine. Strain D-60, deficient in both threonine dehydrogenase and threonine deaminase, was derived from strain Mu-910 and barely degraded threonine. A glycine-requiring strain derived from the wild strain grew in minimal medium containing threonine as the glycine source, whereas a glycine-requiring strain derived from strain Mu-910 did not grow. This indicates that threonine dehydrogenase participates in glycine formation from threonine (via alpha-amino-beta-ketobutyrate) as well as in threonine degradation to aminoacetone.     

Regulation of pyruvate dehydrogenase by fatty acid in isolated rat liver mitochondria.

The mechanism by which fatty acid addition leads to the inactivation of pyruvate dehydrogenase in intact rat liver mitochondria was investigated. In all cases the fatty acid octanoate was added to mitochondria oxidizing succinate. Addition of fatty acid caused an inactivation of pyruvate dehydrogenase in mitochondria incubated under State 3 conditions (glucose plus hexokinase), in uncoupled, oligomycin-treated mitochondria, and in rotenone-menadione-treated mitochondria, but not in uncoupled mitochondria or in mitochondria incubated under State 4 conditions. A number of metabolic conditions were found in which pyruvate dehydrogenase was inactivated concomitant with an elevation in the ATP/ADP ratio. This is consistent with the inverse relationship between the ATP/ADP ratio and the pyruvate dehydrogenase activity proposed by various laboratories. However, in several other metabolic conditions pyruvate dehydrogenase was inactivated while the ATP/ADP ratio either was unchanged or even decreased. This observation implies that there are likely other regulatory factors involved in the fatty acid-mediated inactivation of pyruvate dehydrogenase. Incubation conditions in State 3 were found in which the ATP/ADP and the acetyl-CoA/CoASH ratios remained constant and the pyruvate dehydrogenase activity was correlated inversely with the NADH/NAD+ ratio. Other State 3 conditions were found in which the ATP/ADP and the NADH/NAD+ ratios remained constant while the pyruvate dehydrogenase activity was correlated inversely with the acetyl-CoA/CoASH ratio. Further evidence supporting these experiments with intact mitochondria was the observation that the pyruvate dehydrogenase kinase activity of a mitochondrial extract was stimulated strongly by acetyl-CoA and was inhibited by NAD+ and CoASH. In contrast to acetyl-CoA, octanoyl-CoA inhibited the kinase activity. These results indicate that the inactivation of pyruvate dehydrogenase by fatty acid in isolated rat liver mitochondria may be mediated through effects of the NADH/NAD+ ratio and the acetyl-CoA/CoASH ratio on the interconversion of the active and inactive forms of the enzyme complex catalyzed by pyruvate dehydrogenase kinase and pyruvate dehydrogenase phosphatase.     

Calcium sensitive isocitrate and 2-oxoglutarate dehydrogenase activities in rat liver and AS-30D hepatoma mitochondria

NAD+-isocitrate dehydrogenase and 2-oxoglutarate dehydrogenase in extracts of mitochondria from the highly malignant AS-30D rat hepatoma cell line demonstrate Ca2+ sensitivities and affinities for substrates similar to those of normal liver mitochondria. However, the maximal activities of NAD+- and NADP+-dependent isocitrate dehydrogenase were found to be 8 and 3.5 fold higher in hepatoma mitochondrial extracts than those of liver mitochondria, whereas maximal activities of succinate and 2-oxoglutarate dehydrogenases were similar in the two tissues. At pyridine nucleotide concentrations giving the lowest physiological NADH/NAD+ ratio, NAD+-isocitrate dehydrogenase activity in hepatoma mitochondrial extracts was completely inhibited at subsaturating concentrations of Ca2+, substrate, and NAD+, in contrast to rat liver mitochondrial extracts which retained significant activity.     

The pathway of glutamine and glutamate oxidation in isolated mitochondria from mammalian cells

1. Pyruvate strongly inhibited aspartate production by mitochondria isolated from Ehrlich ascites-tumour cells, and rat kidney and liver respiring in the presence of glutamine or glutamate; the production of (14)CO(2) from l-[U-(14)C]glutamine was not inhibited though that from l-[U-(14)C]glutamate was inhibited by more than 50%. 2. Inhibition of aspartate production during glutamine oxidation by intact Ehrlich ascites-tumour cells in the presence of glucose was not accompanied by inhibition of CO(2) production. 3. The addition of amino-oxyacetate, which almost completely suppressed aspartate production, did not inhibit the respiration of the mitochondria in the presence of glutamine, though the respiration in the presence of glutamate was inhibited. 4. Glutamate stimulated the respiration of kidney mitochondria in the presence of glutamine, but the production of aspartate was the same as that in the presence of glutamate alone. 5. The results suggest that the oxidation of glutamate produced by the activity of mitochondrial glutaminase can proceed almost completely through the glutamate dehydrogenase pathway if the transamination pathway is inhibited. This indicates that the oxidation of glutamate is not limited by a high [NADPH]/[NADP(+)] ratio. 6. It is suggested that under physiological conditions the transamination pathway is a less favourable route for the oxidation of glutamate (produced by hydrolysis of glutamine) in Ehrlich ascites-tumour cells, and perhaps also kidney, than the glutamate dehydrogenase pathway, as the production of acetyl-CoA strongly inhibits the first mechanism. The predominance of the transamination pathway in the oxidation of glutamate by isolated mitochondria can be explained by a restricted permeability of the inner mitochondrial membrane to glutamate and by a more favourable location of glutamate-oxaloacetate transaminase compared with that of glutamate dehydrogenase.     

Studies on the metabolism of glycolyl-CoA

Glycolyl-CoA can be formed during the course of the beta-oxidation by rat liver mitochondria of 4-hydroxybutyrate. The existence of this beta-oxidation has been previously supported by the occurrence of 4-hydroxybutyrate and its beta-oxidation catabolites in urine from patients with 4-hydroxybutyric aciduria, an inborn error of gamma-aminobutyric acid metabolism due to the deficiency of succinic semialdehyde dehydrogenase. The characteristics of the mitochondrial beta-oxidation of 4-hydroxybutyrate were, in rat liver, compared with those of the mitochondrial beta-oxidation of butyrate. The inhibition by malonate of the oxidation of 4-hydroxybutyrate was about twofold weaker than that of oxidation of butyrate, whereas both oxidations were abolished by preincubating the mitochondria with 1 mM valproic acid, a known inhibitor of mitochondrial beta-oxidation. Mitochondria from rat kidney cortex were demonstrated to catalyse, as previously shown for hepatic mitochondria, the carnitine-dependent oxidation of 12-hydroxylauroyl-CoA-omega-Hydroxymonocarboxylyl-CoAs are thus concluded to be precursors of glycolyl-CoA also in rat kidney cortex. In addition, 3-hydroxypyruvate was found to be a precursor of glycolyl-CoA, since it was oxidized by bovine heart pyruvate dehydrogenase with a cofactor requirement similar to that of pyruvate oxidation. Glycolyl-CoA was a substrate of carnitine acetyltransferase (pigeon breast muscle). Pig heart citrate synthase was capable of catalyzing the condensation of glycolyl-CoA with oxaloacetate. The product of this reaction induced low NADH production rates dependent on the addition of porcine heart aconitase and isocitrate dehydrogenase.     

Biosynthesis of four rat liver mitochondrial acyl-CoA dehydrogenases: in vitro synthesis, import into mitochondria, and processing of their precursors in a cell-free system and in cultured cells

The synthesis, translocation, processing, and assembly of rat liver short chain acyl-CoA, medium chain acyl-CoA, long chain acyl-CoA, and isovaleryl-CoA dehydrogenases were studied. These four acyl-CoA dehydrogenases are homotetrameric flavoproteins which are located in the mitochondrial matrix. They were synthesized in a cell-free rabbit reticulocyte lysate system, programmed by rat liver polysomal RNA, as precursor polypeptides which are 2-4 kDa larger than their corresponding mature subunits (Mr 41,000-45,000). When the radiolabeled precursors were incubated with intact rat liver mitochondria, they appeared to bind tightly to the mitochondrial outer membrane. At this stage they were completely susceptible to the action of exogenous trypsin. The precursors bound to mitochondria at 0 degrees C were translocated into the mitochondria and processed when the temperature was raised to 30 degrees C. No reaction occurred when the temperature was kept at 0 degrees C, however, suggesting that the binding of the precursors is temperature independent while the subsequent steps of the pathway are energy dependent. Indeed, the translocation reaction was inhibited by compounds such as dinitrophenol and rhodamine 6G which inhibit mitochondrial energy metabolism. The newly imported (mature) enzymes were inaccessible to the proteolytic action of added trypsin. The processing of the precursors to mature subunits was proteolytically carried out in the mitochondrial matrix, and the processed mature subunits mostly assembled to their respective tetrameric forms. Newly synthesized larger precursors of each of the four acyl-CoA dehydrogenases were recovered from intact, cultured Buffalo rat liver cells in the presence of dinitrophenol. When dinitrophenol was removed in a pulse-chase protocol, the accumulated precursors were rapidly (t1/2 3-5 min) converted to their corresponding mature subunits. On the other hand, when the chase was performed in the presence of the inhibitor, the labeled precursors disappeared with t1/2 of greater than 4 h for long chain acyl-CoA dehydrogenase and 1-2 h for the other three enzyme precursors.     

Oxaloacetate translocator in plant mitochondria

(1) Mitochondria were prepared from leaves of spinach, green and etiolated seedlings and roots of pea, potato tuber and rat liver and heart. In the case of leaf mitochondria, an improved isolation procedure resulted in high respiratory rates (460–510 nmol/mg protein per min) and good respiratory control ratio (6.8–9.8) with glycine as substrate. (2) In these mitochondria oxaloacetate transport was studied either by following the inhibitory effect of oxaloacetate on the respiration of NADH-linked substrates or by determining the consumption of [4-¹⁴C]oxaloacetate. (3) Studies of the competition by other carboxylates and effect of inhibitors on the oxaloacetate transport demonstrate that mitochondria from spinach leaves, green pea seedlings, etiolated pea seedlings and pea roots contain a specific translocator for oxaloacetate with a very high affinity to its substrate (K_m = 3–7 μM) and an even higher sensitivity to its competitive inhibitor phthalonate (K_i = 3–5 μM). The V_max values ranged from 150 to 180 nmol/mg protein per min for mitochondria from etiolated pea seedlings and pea roots and from 550 to 570 nmol/mg protein per min for mitochondria from spinach leaves and green pea seedlings. In mitochondria from potato tuber, the K_m was about one order of magnitude higher (V_max = 450 nmol/mg protein per min). In mitochondria from rat liver and rat heart, a specific translocator for oxaloacetate was not found. (4) The oxaloacetate translocator enables the functioning of a malate-oxaloacetate shuttle for the transfer of reducing equivalents across the inner mitochondrial membrane. (5) This malate-oxaloacetate shuttle appears to play a role in the photorespiratory cycle in catalyzing the transfer of reducing equivalents generated in the mitochondria during glycine oxydation to the peroxysomal compartment for the reduction of β-hydroxypyruvate. (6) Interaction between the mitochondrial and the chloroplastic malate oxaloacetate shuttles would make it possible for surplus-reducing equivalents, generated by photosynthetic electron transport, to be oxidized by mitochondrial electron transport.     

Possibility of mitochondrial-cytosolic cooperation in gluconeogenesis from serine via hydroxypyruvate

Intracellular localization of D-glycerate dehydrogenase (D-glycerate : NAD⁺ oxidoreductase, EC 1.1.1.29), one of the enzymes of the pathway for gluconeogenesis from serine via hydroxypyruvate, was studied by differential centrifugation. Almost all enzyme activity was found in cytosol. Since the major activities of two other enzymes, serine : pyruvate aminotransferase (EC 2.6.1.51) and glycerate kinase (ATP : D-glycerate 2-phosphotransferase, EC 2.7.1.31), of the pathway via hydroxypyruvate are localized in mitochondrial inner membrane and/or matrix, the possible localization of D-glyceratedehydrogenase in mitochondria was examined. Detailed analysis of mitochondrial fraction prepared by differential centrifugation indicated that rat liver mitochondria do not contain any D-glycerate dehydrogenase activity. Based on these results, a cooperative connection between mitochondria and cytosol in gluconeogenesis from serine via hydroxypyruvate is proposed. Possible mechanisms for transport of intermediates of the pathway via hydroxypyruvate across the mitochondrial membranes are also discussed.     

Calpain inhibition by peptide epoxides.

The protein activator of phosphorylated branched-chain 2-oxo acid dehydrogenase complex was purified greater than 1000-fold from extracts of rat liver mitochondria; the specific activity was greater than 1000 units/mg of protein (1 unit gives half-maximum re-activation of 10 munits of phosphorylated complex). Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis gave two bands (Mr 47700 and 35300) indistinguishable from the alpha- and beta-subunits of the branched-chain dehydrogenase component of the complex. On gel filtration (Sephacryl S-300), apparent Mr was 190000. This and other evidence suggests that activator protein is free branched-chain dehydrogenase; this conclusion is provisional until identical amino acid composition of the subunits has been demonstrated. Activator protein (i.e. free branched-chain dehydrogenase) was inhibited (up to 30%) by NaF, whereas branched-chain complex was not inhibited. There was no convincing evidence for interconvertible active and inactive forms of activator protein in rat liver mitochondria. Activator protein was detected in mitochondria from liver (ox, rabbit and rat) and kidney (ox and rat), but not in rat heart or skeletal-muscle mitochondria. In rat liver mitochondrial extracts, branched-chain complex sedimented with the mitochondrial membranes, whereas activator protein remained in the supernatant. Activator protein re-activated phosphorylated (inactive) particulate complex from rat liver mitochondria, but it did not activate dephosphorylated complex. Liver and kidney, but not muscle, mitochondria apparently contain surplus free branched-chain dehydrogenase, which is bound by the complex with lower affinity than is the branched-chain dehydrogenase intrinsic to the complex. It is suggested that this functions as a buffering mechanism to maintain branched-chain complex activity in liver and kidney mitochondria.     

水生动物和大鼠线粒体的呼吸链比较

用陆生哺乳动物线粒体呼吸链与水生动物线粒体呼吸链相比较的研究方法,探讨了呼吸链的功能与环境相适应的关系。研究了淡水中生活的草鱼肝丝线粒体,观察到琥珀酸脱氢酶的活性非常低,而ＮＡＤＨ脱氢酶和泛醌细胞色素Ｃ还原酶的活性较高。但海洋生物海绵的线粒体ＮＡＤＨ脱氢酶和琥垢酸脱氢酶的活性都非常低。