A kinetic study of the alpha-keto acid dehydrogenase complexes from pig heart mitochondria.

The kinetic mechanisms of the 2-oxoglutarate and pyruvate dehydrogenease complexes from pig heart mitochondria were studied at pH 7.5 and 25 degrees. A three-site ping-pong mechanism for the actin of both complexes was proposed on the basis of the parallel lines obtained when 1/v was plotted against 2-oxoglutarate or pyruvate concentration for various levels of CoA and a level of NAD+ near its Michaelis constant value. Rate equations were derived from the proposed mechanism. Michaelis constants for the reactants of the 2-oxoglutarate dehydrogenase complex reaction are: 2-oxoglutarate, 0.220 mM; CoA, 0.025 mM; NAD+, 0.050 mM. Those of the pyruvate dehydrogenase complex are: pyruvate, 0.015 mM; CoA, 0.021 mM; NAD+, 0.079 mM. Product inhibition studies showed that succinyl-CoA or acetyl-CoA was competitive with respect to CoA, and NADH was competitive with respect to NAD+ in both overall reactions, and that succinyl-CoA or acetyl-CoA and NADH were uncompetitive with respect to 2-oxoglutarate or pyruvate, respectively. However, noncompetitive (rather than uncompetitive) inhibition patterns were observed for succinyl-CoA or acetyl-CoA versus NAD+ and for NADH versus CoA. These results are consistent with the proposed mechanisms.     

The atypical velocity response by pyruvate carboxylase to increasing concentrations of acetyl-coenzyme A

An investigation was made of the interaction of pyruvate carboxylase with its allosteric effector, acetyl-CoA, and the velocity profile of the deacylation of acetyl-CoA as a function of acetyl-CoA concentration indicated that this ligand does not bind to this enzyme in a positive homotropic co-operative manner. An examination was therefore made of the factors that contribute to the sigmoidicity of the rate curves obtained for pyruvate carboxylation with various concentrations of acetyl-CoA. Hill coefficients for acetyl-CoA obtained with both sheep and chicken liver pyruvate carboxylases were found to be dependent on the fixed pyruvate concentration used in the assay solution. Thus, by varying the acetyl-CoA concentration, the degree of saturation of the enzyme by pyruvate was also changed. A further consequence of non-saturating concentrations of pyruvate was that the non-productive hydrolysis of the enzyme- carboxybiotin complex increased, resulting in an under-estimate of the reaction velocity measured by oxaloacetate formation. Another factor contributing to the sigmoidicity is that, at non-saturating concentrations of acetyl-CoA, the enzyme undergoes inactivation upon dilution to low protein concentrations, again resulting in an under-estimate of the reaction velocity. Under conditions where none of the above factors was operating and the only effect of varying acetyl-CoA concentrations was to alter the proportion of the enzyme catalysing the carboxylation reaction at acetyl-CoA-dependent and -independent rates, the sigmoidicity of the acetyl-CoA velocity profile was completely eliminated.     

Enhancement of acetyl-CoA flux for photosynthetic chemical production by pyruvate dehydrogenase complex overexpression in Synechococcus elongatus PCC 7942

Genetic manipulation in cyanobacteria enables the direct production of valuable chemicals from carbon dioxide. However, there are still very few reports of the production of highly effective photosynthetic chemicals. Several synthetic metabolic pathways (e.g., isopropanol, acetone, isoprene, and fatty acids) have been constructed by branching from acetyl-CoA and malonyl-CoA, which are key intermediates for photosynthetic chemical production downstream of pyruvate decarboxylation. Recent reports of the absolute determination of cellular metabolites in Synechococcus elongatus PCC 7942 have shown that its acetyl-CoA levels corresponded to about one hundredth of the pyruvate levels. In short, one of the reasons for lower photosynthetic chemical production from acetyl-CoA and malonyl-CoA was the smaller flux to acetyl-CoA. Pyruvate decarboxylation is a primary pathway for acetyl-CoA synthesis from pyruvate and is mainly catalyzed by the pyruvate dehydrogenase complex (PDHc). In this study, we tried to enhance the flux toward acetyl-CoA from pyruvate by overexpressing PDH genes and, thus, catalyzing the conversion of pyruvate to acetyl-CoA via NADH generation. The overexpression of PDH genes cloned from S. elongatus PCC 7942 significantly increased PDHc enzymatic activity and intracellular acetyl-CoA levels in the crude cell extract. Although growth defects were observed in overexpressing strains of PDH genes, the combinational overexpression of PDH genes with the synthetic metabolic pathway for acetate or isopropanol resulted in about 7-fold to 9-fold improvement in its production titer, respectively (9.9 mM, 594.5 mg/L acetate, 4.9 mM, 294.5 mg/L isopropanol). PDH genes overexpression would, therefore, be useful not only for the production of these model chemicals, but also for the production of other chemicals that require acetyl-CoA as a key precursor.     

The effect of A23187 on glucose production from methylglyoxal and pyruvate in isolated murine hepatocytes.

1. A23187 increased the glucose production from methylglyoxal in isolated hepatocytes, and maximal stimulation was obtained at 10(-6) M. The effect of A23187 was dependent on the presence of Ca2+. 2. Glucose production from pyruvate (less than 1 mM) in isolated hepatocytes was stimulated by A23187 in the presence of 2.5 mM Ca2+ and was depressed at pyruvate concentrations above 1 mM. Both the virtual Km and the virtual Vmax of glucose production from pyruvate were decreased by A23187.     

Effects of branched chain alpha-ketoacids on the metabolism of isolated rat liver cells. I. Regulation of branched chain alpha-ketoacid metabolism.

alpha-Ketoisocaproate (ketoleucine) is shown to be metabolized to ketone bodies rapidly by isolated rat liver cells. Acetoacetate is the major end product and maximum rates were observed with 2 mM substrate. Studies with 2-tetradecylglycidic acid (an inhibitor of long chain fatty acid oxidation) showed that ketogenesis from alpha-ketoisocaproate and from endogenous fatty acids were additive. With alpha-ketoisocaproate present as soole substrate at 2 mM, leucine production was less than 10% of alpha-ketoisocaproate uptake and only 30% of the acetyl coenzyme A generated was oxidized in the citric acid cycle. Metabolism of alpha-ketoisocaproate was inhibited by fatty acids, alpha-ketoisovalerate, alpha-keto-beta-methylvalerate, and pyruvate. Oxidation of acetyl-CoA generated from alpha-ketoisocaproate was suppressed by oleate and by pyruvate, but was enhanced by lactate. Metabolism between the different branched chain alpha-ketoacids was mutually competitive. When alpha-ketoisocaproate (2 mM) was added in the presence of high pyruvate concentrations (4.4 mM), flux through pyruvate dehydrogenase was decreased, and the proportion of total pyruvate dehydrogenase in the active form (PDHa) also fell. With lactate as substrate, PDHa was only 25% of total activity and was little affected by addition of alpha-ketoisocaproate. These data suggest that enhanced oxidation of acetyl-CoA from alpha-ketoisocaproate by lactate addition is caused by a low activity of pyruvate dehydrogenase combined with increased flux through the citric acid cycle in response to the energy requirements for gluconeogenesis. However, acetyl-CoA generation from pyruvate is apparently insufficiently inhibited by alpha-ketoisocaproate to cause a diversion of acetyl-CoA formed during alpha-ketoisocaproate metabolism from ketone body formation to oxidation in the citric acid cycle. Measurements of the cell contents of CoASH, acetyl-CoA, acid-soluble acyl-CoA, and acid-insoluble fatty acyl-CoA indicated that when the branched chain alpha-ketoacids were added as sole substrate, their oxidation was limited at a step distal to the branched chain alpha-ketoacid dehydrogenase. Acid-soluble acyl-CoA derivatives were depleted after oleate addition in the presence of alpha-ketoisocaproate, suggesting an inhibition of the branched chain alpha-ketoacid dehydrogenase by the elevation of the mitochondrial NADH/NAD+ ratio observed during fatty acid oxidation. This effect was not observed in the presence of oleate and 2-tetradecylglycidic acid.     

Isolated tumoral pyruvate dehydrogenase can synthesize acetoin which inhibits pyruvate oxidation as well as other aldehydes

Oxidation of 1 mM pyruvate by Ehrlich and AS30-D tumor mitochondria is inhibited by acetoin, an unusual and important metabolite of pyruvate utilization by cancer cells, by acetaldehyde, methylglyoxal and excess pyruvate. The respiratory inhibition is reversed by other substrates added to pyruvate and also by 0.5 mM ATP. Kinetic properties of pyruvate dehydrogenase complex isolated from these tumor mitochondria have been studied. This complex appears to be able to synthesize acetoin from acetaldehyde plus pyruvate and is competitively inhibited by acetoin. The role of a new regulatory pattern for tumoral pyruvate dehydrogenase is presented.     

Pyruvate dehydrogenase complex and acetyl-CoA carboxylase in pea root plastids: their characterization and role in modulating glycolytic carbon flow to fatty acid biosynthesis

The pyruvate dehydrogenase complex (PDC) and acetyl-CoA carboxylase(ACC, EC 6.4.1.2 [EC] ) have been characterized in pea root plastids.PDC activity was optimum in the presence of 1.0 mM pyruvate,1.5 mM NAD⁺ 0.1 mM CoA, 0.1 mM TPP, 5 mM MgCl₂, 3.0 mM cysteine-HCl,and 0.1 M Tricine (pH 8.0) and represents approximately 47%of the total cellular activity. ACC activity was greatest inthe presence of 1.0 mM acetyl-CoA, 4 mM NaHCO₃ mM ATP, 10 mMMgCl₂, 2.5 mM dithiothreitol, and 100 mM Tricine (pH 8.0). Bothenzymes were stimulated by reduced sulphydryl reagents and inhibitedby sulphydryl inhibitors. ACC was also inhibited by malonyl-CoAwhile PDC was inhibited by both malonyl-CoA and NADH. Both enzymeswere stimulated by DHAP and UDP-galactose while ACC was alsostimulated by PEP and F₁,6P. Palmitic acid and oleic acid bothinhibited ACC, but had essentially no effect on PDC. Palmitoyl-CoAinhibited both enzymes while PA and Lyso-PA inhibited PDC, butstimulated ACC. The results presented support the hypothesisthat PDC and ACC function in a co-ordinated fashion to promoteglycolytic carbon flow to fatty acid biosynthesis in pea rootplastids. Key words: Pisum sativum L., pyruvate dehydrogenase complex, acetyl-CoA carboxylase, roots, non-photosynthetic plastids     

Activation and inhibition of pyruvate carboxylase from Rhizobium etli

While crystallographic structures of the R. etli pyruvate carboxylase (PC) holoenzyme revealed the location and probable positioning of the essential activator, Mg(2+), and nonessential activator, acetyl-CoA, an understanding of how they affect catalysis remains unclear. The current steady-state kinetic investigation indicates that both acetyl-CoA and Mg(2+) assist in coupling the MgATP-dependent carboxylation of biotin in the biotin carboxylase (BC) domain with pyruvate carboxylation in the carboxyl transferase (CT) domain. Initial velocity plots of free Mg(2+) vs pyruvate were nonlinear at low concentrations of Mg(2+) and a nearly complete loss of coupling between the BC and CT domain reactions was observed in the absence of acetyl-CoA. Increasing concentrations of free Mg(2+) also resulted in a decrease in the K(a) for acetyl-CoA. Acetyl phosphate was determined to be a suitable phosphoryl donor for the catalytic phosphorylation of MgADP, while phosphonoacetate inhibited both the phosphorylation of MgADP by carbamoyl phosphate (K(i) = 0.026 mM) and pyruvate carboxylation (K(i) = 2.5 mM). In conjunction with crystal structures of T882A R. etli PC mutant cocrystallized with phosphonoacetate and MgADP, computational docking studies suggest that phosphonoacetate could coordinate to one of two Mg(2+) metal centers in the BC domain active site. Based on the pH profiles, inhibition studies, and initial velocity patterns, possible mechanisms for the activation, regulation, and coordination of catalysis between the two spatially distinct active sites in pyruvate carboxylase from R. etli by acetyl-CoA and Mg(2+) are described.     

Effect of methylglyoxal on glucose formation, drug oxidation and glutathione content in isolated murine hepatocytes

The first stage in the formation of glucose from acetone involves two oxidation steps catalyzed by isozymes of the cytochrome P-450 II E1 gene subfamily; methylglyoxal formed this way is further converted to pyruvate by a reversible conjugation with reduced glutathione. The effect of methylglyoxal on glucose formation, oxidation of aminopyrine, aniline and on reduced glutathione content was investigated in isolated hepatocytes prepared from (i) fasted or (ii) fasted and acetone (known to induce isozymes of P-450 II E1 gene subfamily) pretreated mice. Glucose formation and drug oxidation were increased by methylglyoxal at concentrations below 1 mM, but were severely decreased above 1 mM. Methylglyoxal also decreased protein synthesis at concentrations above 1 mM. If the addition of methylglyoxal was combined with that of other gluconeogenic precursors and glucose the initial increasing effect on drug oxidation was moderated or diminished and the decreasing effect (at high concentrations) was enhanced. The glutathione content of the cells was decreased by methylglyoxal in a concentration dependent manner. Acetone pretreatment of mice also resulted in a decreased glutathione content of the liver. Based on these observations it is assumed that methylglyoxal has contrasting effects in hepatocytes, and can contribute to the disturbed metabolism under circumstances when the acetone production is elevated.     

Nonhomogeneous labeling of liver mitochondrial acetyl-CoA

The specific activity of carbons 1 and 2 of plasma acetoacetate has been used as a measure of the specific activity of liver mitochondrial acetyl-CoA in tracer studies. To test whether or not acetoacetate actually reflects acetyl-CoA, livers were perfused with a mixture of substrates that are converted to mitochondrial acetyl-CoA: 1 mM lactate, 0.2 mM pyruvate, 0.2 mM acetate, and, where indicated, 0.2 mM octanoate or 0.2 mM alpha-ketoisocaproate. In each experiment, one of these substrates was 13C-labeled. Labeling of mitochondrial acetyl-CoA was assessed by three methods: (i) molar percent enrichment of total tissue acetyl-CoA; (ii) molar percent enrichment of carbons 4 and 5 of tissue citrate, the precursor of which is acetyl-CoA; and (iii) molar percent enrichment of carbons 1 and 2 of perfusate ketone bodies. Nonhomogeneous labeling of liver mitochondrial acetyl-CoA occurred under most conditions, i.e. the enrichments of carbons 4 and 5 of citrate were different from enrichments of carbons 1 and 2 of ketone bodies. Thus, based upon our results obtained in perfused livers, we question the validity of measuring the labeling of carbons 1 and 2 of acetoacetate as a noninvasive probe of liver mitochondrial acetyl-CoA.     

L-alanine: 4,5-dioxovalerate aminotransferase from Pseudomonas riboflavina: purification and inactivation by methylglyoxal

L-Alanine:4,5-dioxovalerate aminotransferase, which catalyzes transamination between L-alanine and 4,5-dioxovalerate to yield delta-aminolevulinate and pyruvate, has been purified from Pseudomonas riboflavina IFO 3140. The enzyme had a molecular weight of 190,000 and consisted of four identical subunits. It was crystallized as pale yellow needles. The enzyme used L-alanine (relative activity 100), beta-alanine (39), and L-ornithine (14) as amino donors. gamma-aminobutyrate (55) and epsilon-aminocaproate (34) were also effective as amino donors. The reaction proceeded according to a ping-pong mechanism and the Km values for L-alanine and 4,5-dioxovalerate were 1.7 and 0.75 mM, respectively. The activity of the enzyme is strongly inhibited by pyruvate, hemin, and methylglyoxal. Methylglyoxal interacted with the enzyme and brought about a complete inactivation.     

Interactions between alpha-ketoisovalerate metabolism and the pathways of gluconeogenesis and urea synthesis in isolated hepatocytes

The mechanism of inhibition of pyruvate carboxylase, pyruvate dehydrogenase, and carbamyl phosphate synthetase induced by alpha-ketoisovalerate metabolism has been investigated in isolated rat hepatocytes incubated with lactate, pyruvate, ammonia, and ornithine as substrates. Half-maximum inhibitions of flux through each of these enzyme steps were obtained with 0.3 mM alpha-ketoisovalerate. The inhibition of pyruvate carboxylase flux by alpha-ketoisovalerate was largely reversed by oleate addition, but pyruvate dehydrogenase flux was inhibited further. Inhibition of flux through pyruvate carboxylase could be attributed mainly to the fall of its allosteric activator, acetyl-CoA, with some additional effect due to inhibition by methylmalonyl-CoA. Tissue acetyl-CoA levels decrease as a result of an inhibition of the active form of pyruvate dehydrogenase. Kinetic studies with the purified pig heart pyruvate dehydrogenase complex showed that methyl-malonyl-CoA, propionyl-CoA, and isobutyryl-CoA were inhibitory, the latter noncompetitive with CoASH with an apparent Ki of 90 microM. The observed inhibition of pyruvate dehydrogenase flux correlated with increases of the acetyl-CoA/CoASH and propionyl-CoA/CoASH ratios and isobutyryl-CoA levels, while increases of the mitochondrial NADH/NAD+ ratio explained differences between the effects of alpha-ketoisovalerate and propionate. Carbamyl phosphate synthetase I purified from rat liver was shown to be inhibited directly by methylmalonyl-CoA (apparent Ki of 5 mM). Inhibition of flux through carbamyl phosphate synthetase during alpha-ketoisovalerate metabolism could be attributed both to a direct inhibitory effect of methyl-malonyl-CoA and to a diminished activation by N-acetylglutamate. Direct effects of various acyl-CoA metabolites on these key enzymes may explain symptoms of hypoglycemia and hyperammonemia observed in patients with inherited disorders of organic acid metabolism.     

Pyruvate dehydrogenase complex of ascites tumour. Activation by AMP and other properties of potential significance in metabolic regulation.

1. AMP is an activator of the pyruvate dehydrogenase complex of the Ehrlich--Lettré ascites tumour, increasing its V up to 2-fold, with Ka of 40 microM at pH 7.4. This activation appears to be an allosteric effect on the decarboxylase subunit of the complex. 2. The pyruvate dehydrogenase complex has a Km for pyruvate within the range 17--36 microM depending on the pH, the optimum pH being approx. 7.4, with a V of approx. 0.1 unit/g of cells. The rate-limiting step is dependent on the transformation of the enzyme--substrate complex. The Km for CoA is 15 microM. The Km for NAD+ is 0.7 mM for both the complex and the lipoamide dehydrogenase. The complex is inhibited by acetyl-CoA competitively with CoA; the Ki is 60 microM. The lipoamide dehydrogenase is inhibited by NADH and NADPH competitively with NAD+, with Ki values of 80 and 90 microM respectively. In the reverse reaction the Km values for NADH and NADPH are essentially equal to their Ki values for the forward reaction, the V for the latter being 0.09 of that of the former. Hence the reaction rate of the complex in vivo is likely to be markedly affected by feedback isosteric inhibition by reduced nicotinamide nucleotides and possibly acetyl-CoA.     

A sensitive radioisotopic assay of pyruvate dehydrogenase complex in human muscle tissue.

A radioactive assay for the determination of pyruvate dehydrogenase complex activity in muscle tissue has been developed. The assay measures the rate of acetyl-CoA formation from pyruvate in a reaction mixture containing NAD+ and CoASH. The acetyl-CoA is determined as [14C]citrate after condensation with [14C]-oxaloacetate by citrate synthase. The method is specific and sensitive to the picomole range of acetyl-CoA formed. In eleven normal subjects, the active form of pyruvate dehydrogenase (PDCa) in resting human skeletal muscle samples obtained using the needle biopsy technique was 0.44 +/- 0.16 (SD) mumol acetyl-CoA.min-1.g-1 wet wt. Total pyruvate dehydrogenase complex (PDCt) activity was determined after activation by pretreating the muscle homogenate with Ca2+, Mg2+, dichloroacetate, glucose, and hexokinase. The mean value for PDCt was 1.69 +/- 0.32 mumol acetyl-CoA.min-1.g-1 wet wt, n = 11. The precision of the method was determined by analyzing 4-5 samples of the same muscle piece. The coefficient of variation for PDCa was 8% and for PDCt 5%.     

The effects of alpha-adrenergic stimulation on the regulation of the pyruvate dehydrogenase complex in the perfused rat liver

The regulation of the pyruvate dehydrogenase multienzyme complex was investigated during alpha-adrenergic stimulation with phenylephrine in the isolated perfused rat liver. The metabolic flux through the pyruvate dehydrogenase reaction was monitored by measuring the production of 14CO2 from infused [1-14C] pyruvate. In livers from fed animals perfused with a low concentration of pyruvate (0.05 mM), phenylephrine infusion significantly inhibited the rate of pyruvate decarboxylation without affecting the amount of pyruvate dehydrogenase in its active form. Also, phenylephrine caused no significant effect on tissue NADH/NAD+ and acetyl-CoA/CoASH ratios or on the kinetics of pyruvate decarboxylation in 14CO2 washout experiments. Phenylephrine inhibition of [1-14C]pyruvate decarboxylation was, however, closely associated with a decrease in the specific radioactivity of perfusate lactate, suggesting that the pyruvate decarboxylation response simply reflected dilution of the labeled pyruvate pool due to phenylephrine-stimulated glycogenolysis. This suggestion was confirmed in additional experiments which showed that the alpha-adrenergic-mediated inhibitory effect on pyruvate decarboxylation was reduced in livers perfused with a high concentration of pyruvate (1 mM) and was absent in livers from starved rats. Thus, alpha-adrenergic agonists do not exert short term regulatory effects on pyruvate dehydrogenase in the liver. Furthermore, the results suggest either that the rat liver pyruvate dehydrogenase complex is insensitive to changes in mitochondrial calcium or that changes in intramitochondrial calcium levels as a result of alpha-adrenergic stimulation are considerably less than suggested by others.     

Pyruvate dehydrogenase and 3-fluoropyruvate: chemical competence of 2-acetylthiamin pyrophosphate as an acetyl group donor to dihydrolipoamide

The pyruvate dehydrogenase component (E1) of the pyruvate dehydrogenase complex catalyzes the decomposition of 3-fluoropyruvate to CO2, fluoride anion, and acetate. Acetylthiamin pyrophosphate (acetyl-TPP) is an intermediate in this reaction. Incubation of the pyruvate dehydrogenase complex with 3-fluoro[1,2-14C]pyruvate, TPP, coenzyme A (CoASH), and either NADH or pyruvate as reducing systems leads to the formation of [14C]acetyl-CoA. In this reaction the acetyl group of acetyl-TPP is partitioned by transfer to both CoASH (87 +/- 2%) and water (13 +/- 2%). When the E1 component is incubated with 3-fluoro[1,2-14C]pyruvate, TPP, and dihydrolipoamide, [14C]acetyldihydrolipoamide is produced. The formation of [14C]acetyldihydrolipoamide was examined as a function of dihydrolipoamide concentration (0.25-16 mM). A plot of the extent of acetyl group partitioning to dihydrolipoamide as a function of 1/[dihydrolipoamide] showed 95 +/- 2% acetyl group transfer to dihydrolipoamide when dihydrolipoamide concentration was extrapolated to infinity. It is concluded that acetyl-TPP is chemically competent as an intermediate for the pyruvate dehydrogenase complex catalyzed oxidative decarboxylation of pyruvate.     

Addendum to a new mathematical approach to metabolism of [14C]glucose: the pyruvate carboxylase reaction

—Previously published equations for analysis of [¹⁴C]glucose metabolism assumed that products of glycolysis enter the citric acid cycle only through acetyl-CoA (Larrabee , 1978). These equations are now extended to include entrance into the citric acid cycle through the pyruvate carboxy-lase reaction as well as via acetyl-CoA and are applied to previously reported data from dorsal root ganglia of 15-day-old chicken embryos. The rate of output of labelled CO₂ in the presence of [2-¹⁴C] glucose could not be accounted for if the flux rate into the citric acid cycle through the pyruvate carboxylase reaction was assumed to be more than about 10–15% of that through acetyl-CoA. It is concluded (1) that the pyruvate carboxylase reaction is a relatively minor source of material for the citric acid cycle in these ganglia and (2) that the previous conclusions about [¹⁴C]glucose metabolism, which ignored the pyruvate carboxylase reaction, need not be modified in the light of this reanalysis.     

Purification and properties of phosphotransacetylase from the eucaryotic green alga Chlorogonium elongatum

Phosphotransacetylase (EC 2.3.1.8) was detected in cell-free crude extracts of starch-fermenting eucaryotic green algae. The enzyme was purified from autotrophically grown Chlorogonium elongatum. The purified enzyme fraction, after affinity chromatography, shows a single protein band upon acrylamide gel electrophoresis and has a molecular weight of 280 000. It consists of six subunits of identical molecular weight (44 000). The pH and temperature optima for the eucaryotic phosphotransacetylase are 7.6 and 28°C, respectively. The K_m values at 25°C (pH 7.6) for acetyl-CoA and phosphate are 0.078 mM and 5.440 mM, respectively, and in the reverse reaction (acetyl-CoA synthesis) for CoA and acetyl phosphate 0.093 mM and 0.310 mM, respectively. The maximum velocity of the forward reaction was 1627 nkat/mg protein and of the reverse reaction 8582 nkat/mg protein. The activity of the eucaryotic phosphotransacetylase strictly depends on the presence of univalent cations (ammonium, K_a = 9 mM; potassium, K_{a = 12.5 mM}). Inactivation studies with iodoacetamide and iodoacetic acid revealed the presence of an essential sulphhydryl group at the catalytic site. Arsenolytic and product inhibition studies indicate a rapid equilibrium random bi-bi reaction mechanism for the enzyme from C. elongatum. The control of the enzyme activity in the forward reaction by both pyruvate and NADH gives evidence for a physiological function of phosphotransacetylase in anaerobic energy metabolism of eucaryotic green algae rather than in aerobic acetate activation.     

Pig liver pyruvate carboxylase. The reaction pathway for the carboxylation of pyruvate

1. The reaction pathway for the carboxylation of pyruvate, catalysed by pig liver pyruvate carboxylase, was studied in the presence of saturating concentrations of K(+) and acetyl-CoA. 2. Free Mg(2+) binds to the enzyme in an equilibrium fashion and remains bound during all further catalytic cycles. MgATP(2-) binds next, followed by HCO(3) (-) and then pyruvate. Oxaloacetate is released before the random release, at equilibrium, of P(i) and MgADP(-). 3. This reaction pathway is compared with the double displacement (Ping Pong) mechanisms that have previously been described for pyruvate carboxylases from other sources. The reaction pathway proposed for the pig liver enzyme is superior in that it shows no kinetic inconsistencies and satisfactorily explains the low rate of the ATP[unk][(32)P]P(i) equilibrium exchange reaction. 4. Values are presented for the stability constants of the magnesium complexes of ATP, ADP, acetyl-CoA, P(i), pyruvate and oxaloacetate.     

Regulation of pyruvate dehydrogenase in rat heart. Mechanism of regulation of proportions of dephosphorylated and phosphorylated enzyme by oxidation of fatty acids and ketone bodies and of effects of diabetes: role of coenzyme A, acetyl-coenzyme A and reduced and oxidized nicotinamide-adenine dinucleotide.

The proportion of active (dephosphorylated) pyruvate dehydrogenase in perfused rat heart was decreased by alloxan-diabetes or by perfusion with media containing acetate, n-octanoate or palmitate. The total activity of the dehydrogenase was unchanged. 2. Pyruvate (5 or 25mM) or dichloroacetate (1mM) increased the proportion of active (dephosphorylated) pyruvate dehydrogenase in perfused rat heart, presumably by inhibiting the pyruvate dehydrogenase kinase reaction. Alloxan-diabetes markedly decreased the proportion of active dehydrogenase in hearts perfused with pyruvate or dichloroacetate. 3. The total activity of pyruvate dehydrogenase in mitochondria prepared from rat heart was unchanged by diabetes. Incubation of mitochondria with 2-oxo-glutarate plus malate increased ATP and NADH concentrations and decreased the proportion of active pyruvate dehydrogenase. The decrease in active dehydrogenase was somewhat greater in mitochondria prepared from hearts of diabetic rats than in those from hearts of non-diabetic rats. Pyruvate (0.1-10 mM) or dichloroacetate (4-50 muM) increased the proportion of active dehydrogenase in isolated mitochondria presumably by inhibition of the pyruvate dehydrogenase kinase reaction. They were much less effective in mitochondria from the hearts of diabetic rats than in those of non-diabetic rats. 4. The matrix water space was increased in preparations of mitochondria from hearts of diabetic rats. Dichloroacetate was concentrated in the matrix water of mitochondria of non-diabetic rats (approx. 16-fold at 10 muM); mitochondria from hearts of diabetic rats concentrated dichloroacetate less effectively. 5. The pyruvate dehydrogenase phosphate phosphatase activity of rat hearts and of rat heart mitochondria (approx. 1-2 munit/unit of pyruvate dehydrogenase) was not affected by diabetes. 6. The rate of oxidation of [1-14C]pyruvate by rat heart mitochondria (6.85 nmol/min per mg of protein with 50 muM-pyruvate) was approx. 46% of the Vmax. value of extracted pyruvate dehydrogenase (active form). Palmitoyl-L-carnitine, which increased the ratio of [acetyl-CoA]/[CoA] 16-fold, inhibited oxidation of pyruvate by about 90% without changing the proportion of active pyruvate dehydrogenase.