EC:6.4.1.1 - FACTA Search

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Query: EC:6.4.1.1 (pyruvate carboxylase)
1,516 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Control properties of the gluconeogenic pathway in hepatocytes isolated from starved rats were studied in the presence of glucose. The following observations were made. (1) Glucose stimulated the rate of glucose production from 20 mM-glycerol, from a mixture of 20 mM-lactate and 2 mM-pyruvate, or from pyruvate alone; no stimulation was observed with 20 mM-alanine or 20 mM-dihydroxyacetone. Maximal stimulation was obtained between 2 and 5 mM-glucose, depending on the conditions. At concentrations above 6 mM, gluconeogenesis declined again, so that at 10 mM-glucose the glucose production rate became equal to that in its absence. (2) With glycerol, stimulation of gluconeogenesis by glucose was accompanied by oxidation of cytosolic NADH and reduction of mitochondrial NAD+ and was insensitive to the transaminase inhibitor amino-oxyacetate; this indicated that glucose accelerated the rate of transport of cytosolic reducing equivalents to the mitochondria via the glycerol 1-phosphate shuttle. (3) With lactate plus pyruvate (10:1) as substrates, stimulation of gluconeogenesis by glucose was almost additive to that obtained with glucagon. From an analysis of the effect of glucose on the curves relating gluconeogenic flux and the steady-state intracellular concentrations of gluconeogenic intermediates under various conditions, in the absence and presence of glucagon, it was concluded that addition of glucose stimulated both phosphoenolpyruvate carboxykinase and pyruvate carboxylase activity.
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PMID:Stimulation by glucose of gluconeogenesis in hepatocytes isolated from starved rats. 366 84

Isolated sheep hepatocytes were used to obtain estimates of kinetic parameters, identify substrate preference and interactions and study regulation of gluconeogenesis. Respective Vmax estimates for propionate, pyruvate and alanine conversion to glucose were 59.5, 12.8 and 21.5 mol glucose formed X (h X g dry weight)-1. Respective KS estimates for propionate and pyruvate were 1 mM and 18 to 40 microM. Rates of lactate utilization varied among cell preparations, possibly because of loss of lactate dehydrogenase during isolation. Dihydroxyacetone and glycerol were utilized for glucose synthesis at similar rates of 8.6 and 8.7 mumol glucose formed X (h X g dry weight)-1, respectively. Respective rates of glucose synthesis from 5 mM fructose and 10 mM galactose were 63.2 and 31.4 mumol X (h X g dry weight)-1. Maximum rates of pyruvate carboxylase and phosphoenolpyruvate carboxykinase were estimated to be 101.6 and 160.4 mumol substrate converted X (h X g dry weight)-1, respectively. Neither butyrate nor acetate accelerated gluconeogenesis from propionate while acetate increased glucose synthesis from pyruvate, presumably through activation of pyruvate carboxylase. Glucagon stimulated gluconeogenesis from propionate. Dibutyrylcyclic AMP mimicked the effect of glucagon, implying that the glucagon effect is translated via the adenyl cyclase system as in rats. The kinetic parameters established in these experiments should be useful in future experiments and in computer modeling analyses of ruminant liver and whole animal metabolism where Michaelis-Menten type equations are widely used.
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PMID:Gluconeogenesis in isolated lamb hepatocytes. 381 90

13C NMR has been used to study the competition of pyruvate dehydrogenase with pyruvate carboxylase for entry of pyruvate into the tricarboxylic acid (TCA) cycle in perfused liver from streptozotocin-diabetic and normal donor rats. The relative proportion of pyruvate entering the TCA cycle by these two routes was estimated from the 13C enrichments at the individual carbons of glutamate when [3-13C]alanine was the only exogenous substrate present. In this way, the proportion of pyruvate entering by the pyruvate dehydrogenase route relative to the pyruvate carboxylase route was determined to be 1:1.2 +/- 0.1 in liver from fed controls, 1:7.7 +/- 2 in liver from 24-fasted controls, and 1:2.6 +/- 0.3 in diabetic liver. Pursuant to this observation that conversion of pyruvate to acetyl coenzyme A (acetyl-CoA) was greatest in perfused liver from fed controls, the incorporation of 13C label into fatty acids was monitored in this liver preparation. Livers were perfused under steady-state conditions with labeled substrates that are converted to either [2-13C]acetyl-CoA or [1-13C]acetyl-CoA, which in the de novo synthesis pathway label alternate carbons in fatty acids. With the exception of the repeating methylene carbons, fatty acyl carbons labeled by [1-13C]acetyl-CoA (from [2-13C]pyruvate) gave rise to resonances distinguishable on the basis of chemical shift from those observed when label was introduced by [3-13C]alanine plus [2-13C]ethanol, which are converted to [2-13C]acetyl-CoA. Thus, measurement of 13C enrichment at several specific sites in the fatty acyl chains in time-resolved spectra of perfused liver offers a novel way of monitoring the kinetics of the biosynthesis of fatty acids.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:13C NMR study of effects of fasting and diabetes on the metabolism of pyruvate in the tricarboxylic acid cycle and the utilization of pyruvate and ethanol in lipogenesis in perfused rat liver. 382 25

A single-gene nuclear mutant has been isolated in Saccharomyces cerevisiae which cannot grow on minimal medium supplemented with ethanol, acetate, pyruvate, aspartate, or oxaloacetate as sole carbon sources. It will grow on complete medium with these carbon sources, and on minimal medium with dextrose as carbon source. The only supplement which will permit growth on minimal medium with ethanol or pyruvate is aspartate, so the mutant is an aspartate auxotroph when grown on these nonfermentable substrates. It exhibits enhanced levels of phosphoenolpyruvate carboxykinase (EC 4.1.1.49) when grown on dextrose. The mutant can survive as an alcohol dehydrogenase-negative, indicating that the defect is not in the Krebs Cycle or in electron transport. When grown on pyruvate, it produces two to three times as much free alanine and half as much aspartate plus asparagine as the wild type. Two different assays show that the mutant phenotype is due to a deficiency of pyruvate carboxylase (EC 6.4.1.1), an important anaplerotic enzyme. Inferences that can be drawn from the characteristics of this mutant include (a) the glyoxylate cycle is probably located entirely outside the mitochondria, (b) the inner mitochondrial membrane appears to be impermeable to oxaloacetate, and (c) a succinate-malate exchange across the inner mitochondrial membrane connects the glyoxylate and Krebs cycles when yeast is grown on minimal medium with ethanol as a sole carbon source.
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PMID:Pyruvate carboxylase deficiency in yeast: a mutant affecting the interaction between the glyoxylate and Krebs cycles. 388 52

The fasting hypoglycemia (1.78 +/- 0.29 mmol/l) which develops in 48-h-old pigs is partially reversed (3.85 +/- 0.55 mmol/l) after gastric administration of long-chain triglycerides (LCT). The increase in blood glucose induced by LCT feeding was not secondary to a decreased glucose utilization because glucose disappearance rate increased in LCT-fed piglets but resulted from a twofold increase in glucose appearance. By using the crossover-plot technique, the stimulation of hepatic gluconeogenesis induced by LCT feeding has been localized at 1) the level of pyruvate carboxylase owing to the twofold increase in hepatic acetyl-CoA concentration and 2) the level of glyceraldehyde-3-phosphate dehydrogenase secondary to the increase in reducing equivalents (NADH), which displaces this equilibrium reaction in the direction of gluconeogenesis. As blood lactate, pyruvate, and alanine concentrations increased after LCT feeding, the possible effects of LCT on pyruvate dehydrogenase in peripheral tissues are discussed. These data demonstrate that fatty acids stimulate hepatic gluconeogenesis in 48-h-old fasting piglets and underline the role of fat provision in the regulation of glucose homeostasis during the neonatal period in the pig.
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PMID:Effect of intragastric triglyceride administration on glucose homeostasis in newborn pigs. 389 65

Hepatocytes were isolated from the livers of fed rats and incubated, in the presence and absence of 100 nM-glucagon, with a substrate mixture containing glucose (10 mM), fructose (4 mM), alanine (3.5 mM), acetate (1.25 mM), and ribose (1 mM). In any given incubation one substrate was labelled with 14C. Incorporation of 14C into glucose, glycogen, CO2, lactate, alanine, glutamate, lipid glycerol and fatty acids was measured after 20 and 40 min of incubation under quasi-steady-state conditions [Borowitz, Stein & Blum (1977) J. Biol. Chem. 252, 1589-1605]. These data and the measured O2 consumption were analysed with the aid of a structural metabolic model incorporating all reactions of the glycolytic, gluconeogenic, and pentose phosphate pathways, and associated mitochondrial and cytosolic reactions. A considerable excess of experimental measurements over independent flux parameters and a number of independent measurements of changes in metabolite concentrations allowed for a stringent test of the model. A satisfactory fit to the data was obtained for each condition. Significant findings included: control cells were glycogenic and glucagon-treated cells glycogenolytic during the second interval; an ordered (last in, first out) model of glycogen degradation [Devos & Hers (1979) Eur. J. Biochem. 99, 161-167] was required in order to fit the experimental data; the pentose shunt contributed approx. 15% of the carbon for gluconeogenesis in both control and glucagon-treated cells; net flux through the lower Embden-Meyerhof pathway was in the glycolytic direction except during the 20-40 min interval in glucagon-treated cells; the increased gluconeogenesis in response to glucagon was correlated with a decreased pyruvate kinase flux and lactate output; fluxes through pyruvate kinase, pyruvate carboxylase, and phosphoenolpyruvate carboxykinase were not coordinately controlled; Krebs cycle activity did not change with glucagon treatment; flux through the malic enzyme was towards pyruvate formation except for control cells during interval II; and 'futile' cycling at each of the five substrate cycles examined (including a previously undescribed cycle at acetate/acetyl-CoA) consumed about 26% of cellular ATP production in control hepatocytes and 21% in glucagon-treated cells.
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PMID:Quantitative analysis of intermediary metabolism in hepatocytes incubated in the presence and absence of glucagon with a substrate mixture containing glucose, ribose, fructose, alanine and acetate. 391 12

2-(3-Methyl-cinnamyl-hydrazono)-propionate (MCHP) is a new compound which effectively lowers the blood glucose level in guinea pigs. 0.04 mmol/l MCHP inhibited glucose formation from lactate, pyruvate and alanine, but not from dihydroxyacetone in the perfused guinea pig liver. In the presence of both hexanoic acid and alanine, 0.04 mmol/l MCHP did not effect hepatic gluconeogenesis. Gluconeogenesis was probably reduced by an inhibition of the pyruvate carboxylase: The pattern of hepatic metabolite concentrations indicated a block between pyruvate and the triose phosphates. The intrahepatic concentration of acetyl-CoA was consistently decreased. The decrease of the acetyl-CoA concentration could be explained by an influence of MCHP on the fatty acid oxidations, which occurred at the carnitine palmitoyl transferase (CPT) step. This hypothesis is supported by the fact that a medium chain fatty acid not requiring CPT reversed the inhibition of gluconeogenesis by MCHP. From all results reported it is concluded that transamination and oxidative phosphorylation were not effected to a degree relevant for the inhibition of gluconeogenesis by 0.04 mmol/l MCHP.
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PMID:Hydrazonopropionic acids, a new class of hypoglycemic substances. 5. Inhibition of hepatic gluconeogenesis by 2-(3-methylcinnamyl-hydrazono)-propionate in the rat and guinea pig. 392 63

Previous attempts to account for the labelling in vivo of liver metabolites associated with the citrate cycle and gluconeogenesis have foundered because proper allowance was not made for the heterogeneity of the liver. In the basal state (anaesthetized after 24h starvation) this heterogeneity is minimal, and we show that labelling by [14C]bicarbonate can be interpreted unambiguously. [14C]Bicarbonate was infused to an isotopic steady state, and measurements were made of specific radioactivities of blood bicarbonate, alanine, glycerol and lactate, of liver alanine and lactate, and of individual carbon atoms in blood glucose and liver aspartate, citrate and malate. (Existing methods for several of these measurements were extensively modified.) The results were combined with published rates of gluconeogenesis, uptake of gluconeogenic precursors by the liver, and citrate-cycle flux, all measured under similar conditions, and with estimates of other rates made from published data. To interpret the results, three ancillary measurements were made: the rate of CO2 exchange by phosphoenolpyruvate carboxykinase (PEPCK; EC 4.1.1.32) under conditions that simulated those in vivo; the 14C isotope effect in the pyruvate carboxylase (EC 6.4.1.1) reaction (14C/12C = 0.992 +/- 0.008; S.E.M., n = 8); the ratio of labelling by [2-14C]- to that by [1-14C]-pyruvate of liver glutamate 1.5 min after injection. This ratio, 3.38, is a measure of the disequilibrium in the mitochondria between malate and oxaloacetate. The data were analysed with due regard to experimental variance, uncertainties in values of fluxes measured in vitro, hepatic heterogeneity and renal glucose output. The following conclusions were reached. The results could not be explained if CO2 fixation was confined to pyruvate carboxylase and there was only one, well-mixed, pool of oxaloacetate in the mitochondria. Addition of the other carboxylation reactions, those of PEPCK, isocitrate dehydrogenase (EC 1.1.1.42) and malic enzyme (EC 1.1.1.40), was not enough. Incomplete mixing of mitochondrial oxaloacetate had to be assumed, i.e. that there was metabolic channelling of oxaloacetate formed from pyruvate towards gluconeogenesis. There was some evidence that malate exchange across the mitochondrial membrane might also be channelled, with incomplete mixing with that in the citrate cycle. Calculated rates of exchange of CO2 by PEPCK were in agreement with those measured in vitro, with little or no activation by Fe2+ ions.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[14C]bicarbonate fixation into glucose and other metabolites in the liver of the starved rat under halothane anaesthesia. Metabolic channelling of mitochondrial oxaloacetate. 392 30

This paper describes an experimental protocol designed to optimize 13C NMR spectra from the liver of the living anesthetized rat at 1.9 T. The protocol involves the use of a Helmholtz NMR coil which is positioned around the liver after surgical exposure. 1H decoupling is facilitated by double tuning this coil to both the 1H and the 13C frequencies. The protocol was shown to be suitable for studying the hepatic metabolism of 13C-labeled substrates in vivo by investigating the metabolism of [3-13C]alanine. Labeled glucose, glutamate, glutamine, and aspartate were formed and detected by 13C NMR in vivo in this experiment. The labeling patterns in these metabolites provided evidence that the major flow of alanine carbon into the Krebs cycle is via the pyruvate carboxylase reaction rather than through pyruvate dehydrogenase.
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PMID:Hepatic gluconeogenesis from alanine: 13C nuclear magnetic resonance methodology for in vivo studies. 395 87

Oxamate, a structural analog of pyruvate, known as a potent inhibitor of lactic dehydrogenase, lactic dehydrogenase, produces an inhibition of gluconeogenic flux in isolated perfused rat liver or hepatocyte suspensions from low concentrations of pyruvate (less than 0.5 mM) or substrates yielding pyruvate. The following observations indicate that oxamate inhibits flux through pyruvate carboxylase: accumulation of substrates and decreased concentration of all metabolic intermediates beyond pyruvate; decreased levels of aspartate, glutamate, and alanine; and enhanced ketone body production, which is a sensitive indicator of decreased mitochondrial free oxaloacetate levels. The decreased pyruvate carboxylase flux does not seem to be the result of a direct inhibitory action of oxamate on this enzyme but is secondary to a decreased rate of pyruvate entry into the mitochondria. This assumption is based on the following observations: Above 0.4 mM pyruvate, no significant inhibitory effect of oxamate on gluconeogenesis was observed. The competitive nature of oxamate inhibition is in conflict with its effect on isolated pyruvate carboxylase which is noncompetitive for pyruvate. Fatty acid oxidation was effective in stimulating gluconeogenesis in the presence of oxamate only at concentrations of pyruvate above 0.4 mM. Since only at low pyruvate concentrations its entry into the mitochondria occurs via the monocarboxylate translocator, from these observations it follows that pyruvate transport across the mitochondrial membrane, and not its carboxylation, is the first nonequilibrium step in the gluconeogenic pathway. In the presence of oxamate, fatty acid oxidation inhibited gluconeogenesis from lactate, alanine, and low pyruvate concentrations (less than 0.5 mM), and the rate of transfer of reducing equivalents to the cytosol was significantly decreased. Whether fatty acids stimulate or inhibit gluconeogenesis appears to correlate with the rate of flux through pyruvate carboxylase which ultimately seems to rely on pyruvate availability. Unless adequate rates of oxaloacetate formation are maintained, the shift of the mitochondrial NAD couple to a more reduced state during fatty acid oxidation seems to decrease mitochondrial oxaloacetate resulting in a decreased rate of transfer of carbon and reducing power to the cytosol.
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PMID:Interaction of oxamate with the gluconeogenic pathway in rat liver. 396 16

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