Relation of binding by metabolism of gamma-aminobutyric acid and various reactions of the Krebs cycle in the rat brain

The comparison has been made for the following items: intensity of pyruvate alpha-ketoglutarate, succinate oxidation, the gamma-aminobutyric acid (GABA) formation rate, utilization, total content of GABA, glutamate and alanine, the bound/free form ratio of GABA and glutamate, intensity of binding and desorption of exogenic [I-14C]GABA in homogenates of the cortex, cerebellum and brainstem of the Wistar rats. It is revealed that the intensity of ketoacids oxidation is significantly lower in the cerebellum than in the cortex, but the maximal activity of the enzymes of GABA formation and utilization is higher, due to which considerable oxidation of alpha-ketoglutarate transforming into succinate is possible proceeding the GABA shunt pathway. The cortex homogenates contrary to the cerebellum ones are characterized by the reliably higher intensity of ketoacid oxidation and by insignificant contribution of the GABA-shunt to the succinate production. These differences are in line with the reliably higher content of endogenic bound GABA in the cortex as compared to the cerebellum, with a higher level of binding of exogenic labelled GABA and with less pronounced desorption of the label from neurostructures. An assumption is advanced that the observed differences are related to the known high sensitivity of the cortex and to relative resistance of cerebellum to hypoxia and hypoglycemia.     

Effect of K-ATP channel opener-pinacidil on the liver mitochondria function in rats with different resistance to hypoxia during stress

We have examined the influence of ATP-sensitive potassium (KATP) channel opener pinacidil (0.06 mg/kg) and inhibitor glibenclamide (1 mg/kg) on the changes of energy metabolism in the liver of rats under the stress conditions. The rats were divided in two groups with high and low resistance to hypoxia. The stress was modeled by placing the rats in a cage filled with water and closed with a net. The distance from water to the net was only 5 cm. The effects of KATP opener pinacidil (0.06 mg/kg) and inhibitor glibenclamide (1 mg/kg) on ADP-stimulating mitochondrial respiration by Chance, calcium capacity of organellas and processes of lipid peroxidation in the liver of rats with different resistance to hypoxia under the stress condition have been investigated. We have used the next substrates of oxidation: 0.35 mM succinate and 1 mM alpha-ketoglutarate. The additional analyses were conducted with the use of inhibitors: mitochondrial enzyme complex I 10 mM rotenone and succinate dehydrohenase 2 mM malonic acid. It was shown that the stress condition evoked the succinate oxidation and the decrease of alpha-ketoglutarate efficacy, the increase of calcium mitochondrial capacity and the intensification of lipid peroxidation processes. Under the presence of succinate, the increase of O2 uptake with simultaneous decrease of ADP/O ratio in rats with high resistance under stress was observed. Simultaneously, oxidation of alpha-ketoglutarate, a NAD-dependent substrate, was inhibited. Pinacidil caused the reorganization of mitochondrial energy metabolism in favour of NAD-dependent oxidation and the improvment of the protection against stress. The decrease of the efficacy of mitochondrial energy processes functioning was shown in animals with low resistance to hypoxia. KATP channel opener pinacidil has a protective effect on the processes of mitochondrial liver energy support under stress. These changes deal with the increase of alpha-ketoglutarate oxidation (respiratory rate and ADP/O) and the decrease of lipid peroxidation processes. We concluded about protective effect ofpinacidil on mitochondrial functioning under stress.     

Interrelation of the intracellular oxidation-reduction processes and the organic water balance in experimental peritonitis in rats

Dissociation of oxidative phosphorylation and the lowering of the respiratory control during oxidation of succinate, alpha-ketoglutarate and pyruvate by hepatocyte mitochondria were observed in rats with experimental fecal peritonitis. The initial increase in the oxidation rate of the substrates enumerated is replaced by inhibition, whose degree is maximal as regards alpha-ketoglutarate, being less manifest as regards succinate. In the absence of the manifestations of the total dehydration, the increased water content in liver, skeletal muscle and renal tissues is coupled with relatively high values of the ADP/O and is in a good agreement with the lowering of the respiratory control during alpha-ketoglutarate oxidation.     

Acetylcholine activation of alpha-ketoglutarate oxidation in liver mitochondria

Activation of alpha-ketoglutarate oxidation in the rat liver mitochondria takes place 15 and 30 min after intraperitoneal injection of acetyl choline. This mediator in doses of 25, 50 and 100 micrograms per 100 g of body weight causes a pronounced stimulation of phosphorylation respiration rate and calcium capacity of mitochondria with alpha-ketoglutarate oxidation. Acetyl choline is found to have a moderate inhibitory action on oxidation of lower (physiological) concentrations of succinate. Its stimulating action on alpha-ketoglutarate oxidation is associated with activation of M-cholinoreceptors; atropine, a choline-blocker, removes completely this effect. It is supposed that alpha-ketoglutarate and succinate are included into the composition of two reciprocal hormonal-substrate nucleotide systems.     

Differences between mouse and rat pancreatic islets: succinate responsiveness,malic enzyme,and anaplerosis

Succinic acid methyl esters are potent insulin secretagogues in rat pancreatic islets, but they do not stimulate insulin release in mouse islets. Unlike rat and human islets, mouse islets lack malic enzyme and, therefore, are unable to form pyruvate from succinate-derived malate for net synthesis of acetyl-CoA. Dimethyl-[2,3-(14)C]succinate is metabolized in the citric acid cycle in mouse islets to the same extent as in rat islets, indicating that endogenous acetyl-CoA condenses with oxaloacetate derived from succinate. However, without malic enzyme, the net synthesis from succinate of the citric acid cycle intermediates citrate, isocitrate, and alpha-ketoglutarate cannot occur. Glucose and other nutrients that augment alpha-ketoglutarate formation are secretagogues in mouse islets with potencies similar to those in rat islets. All cycle intermediates can be net-synthesized from alpha-ketoglutarate. Rotenone, an inhibitor of site I of the electron transport chain, inhibits methyl succinate-induced insulin release in rat islets even though succinate oxidation forms ATP at sites II and III of the respiratory chain. Thus generating ATP, NADH, and anaplerosis of succinyl-CoA plus the four-carbon dicarboxylic acids of the cycle and its metabolism in the citric acid cycle is insufficient for a fuel to be insulinotropic; it must additionally promote anaplerosis of alpha-ketoglutarate or two intermediates interconvertible with alpha-ketoglutarate, citrate, and isocitrate.     

Effect of intermittent hypoxic hypoxia on energy supply of rat skeletal muscle during adaptation to physical load

The experiment, on Wistar male rats was carried out to investigate influence of endurance training (swimming with load 7.0 +/- 1.3% body weight, 30 min a day, during 4 weeks) and additional intermittent hypoxic training (12% O2 in N2 - 15 min, 21% O2 - 15 min, 5 sessions a day, during the first 2 weeks) on the following parameters: ADF-stimulated mitochondrial respiration, lactate/pyruvate ratio, succinate dehydrogenase activity, and lipid peroxidation in skeletal muscle. The next oxidation substrates were used: 1 mmol/l succinate and 1 mmol/l alpha-ketoglutarate as well as the next inhibitor succinate dehydrogenase 2 mmol/l malonate. It was shown that physical work combined with intermittent hypoxic training led to the increase of mitochondrial respiration effectiveness in muscle energy supply under alpha-ketoglutarate oxidation in comparison with succinate oxidation as well as to the decrease of succinate dehydrogenase activity and lipid peroxidation. The study suggested that these changes may correct mitochondrial dysfunction under intensive muscular work.     

Polarographic observation of substrate-level phosphorylation and its stimulation by acetylcholine

Substrate-level phosphorylation was observed under the conditions optimal for this process and opposite to those for oxidative phosphorylation. Polarographic registration of Ca2+ stimulated alpha-ketoglutarate oxidation and self-inhibition of uncoupled alpha-ketoglutarate (KG) oxidation was used. Acetylcholine (ACh) administration stimulated KG oxidation and substrate-level phosphorylation in isolated mitochondria. These effects are stronger in tissues with a higher level of endogenous acetylcholine, such as guinea pig liver vs rat liver and pancreas vs liver. The specific stimulation of KG oxidation by ACh is related to a decrease of succinate oxidation and is contrary to the specific stimulating effect of adrenaline on succinate oxidation. Therefore the existence of reciprocal hormone-substrate-nucleotide systems is suggested. The described set of conditions optimal for substrate-level phosphorylation observation by polarographic registration of respiration is as convenient as the ADP test for the investigation of oxidative phosphorylation.     

Effect of tricarboxylic acid cycle intermediates on nitric oxide system during acute hypoxia

Effects Crebs Cycle of exogenous intermediates sodium succinate (50 mg/kg) and sodium alpha-ketoglutarate (200 mg/kg) on processes of mitochondrial ADP-stimulated respiration (using as substrates of oxidation 0.35 mM succinate, 1 mM alpha-ketoglutarate), production of nitric oxide under NO2-, NO3-, as well as carbamide, putrescyne content and processes of lipid peroxidation in the rats liver under acute hypoxia (7% O2 in N2, 30 min) have been studied. It was shown, that the exogenous sodium alpha-ketoglutarate increases nitric oxide content, aminotransferase activation, inhibition of succinatedehydrogenase simultaneously more than exogenous sodium succinate. It correlates with decreasing of processes lipid peroxidation in liver.     

The role of malate in regulating the rate of mitochondrial respiration in vitro

Depletion of endogenous malate by preincubation of mitochondria at 30 degrees C in substrate-free media sharply decreases the rate of citrate oxidation and inhibits mitochondrial respiration in the presence of pyruvate and alpha-ketoglutarate. Addition of catalytic amounts of endogenous malate and its production via succinate oxidation promote rapid oxidation of citrate and pyruvate in the mitochondria and abolishes the lag period with alpha-ketoglutarate Malate increases the rate of membrane potential generation after addition of citrate, pyruvate or alpha-ketoglutarate to mitochondrial suspensions. Studies with controlled malate concentrations revealed that the changes in malate concentrations observed in the mitochondria in the presence of gluconeogenesis-inducing hormones may be due to the influence of these hormones on mitochondrial oxidation.     

Activity of oil isolated from Amaranth seeds on energetic functions of rat liver mitochondria after adrenaline introduction

It has been shown that a three-week feeding of rats with oil derived from seeds of amaranth (Amaranthus cruentus L.) leads to a moderate activation of respiration of coupled and uncoupled rat liver mitochondria (MCh) that oxidize succinate and succinate + glutamate, as well as alpha-ketoglutarate and alpha-ketoglutarate + malonate. In animals receiving the amaranth oil, the injection of adrenaline did not affect the oil-activated respiration of MCh during succinate oxidation; i. e., animals prepared by an oil-enriched diet were resistant to the action of adrenaline, which prevented from possible hyperactivation of mitochondrial functions. In the group of control animals, which received no oil, the injection of adrenaline activated the rate of phosphorylating respiration of MCh during oxidation of succinate or succinate + glutamate: the rate of oxygen uptake in state 3 respiration (by Chance) increased, and the phosphorylation time decreased. The injection of adrenaline did not affect the parameters of respiration of MCh that oxidize a-ketoglutarate; however, in the presence of malonate, the oxidation of alpha-ketoglutarate in state 3 and uncoupled respiration have shown mild but significant increase in response to adrenaline. In animals receiving the amaranth oil, the oil-induced activation of respiration of MCh in response to adrenaline retained but did not increase; however, the phosphorylation time significantly decreased. Thus, concentrated oil of seeds activates the respiration of MCh. In addition, it enhances an energetic function of MCh, which prevents from the hyper-activation of mitochondrial respiration by adrenaline. Therefore an activation of energetic function of MCh by amaranth oil could explain its adaptogenic effect on rats.     

Association between the alpha-ketoglutarate dehydrogenase complex and succinate thiokinase

The kinetic parameters of the individual reaction of pig heart alpha-ketoglutarate dehydrogenase complex, succinate thiokinase and the alpha-ketoglutarate dehydrogenase complex-succinate thiokinase coupled system were studied. The KCoAm of alpha-ketoglutarate dehydrogenase complex and the K-succinyl CoAm of succinate thiokinase decreased in the coupled system when compared to those of the individual enzyme reactions. This phenomenon can be explained by the interaction between the alpha-ketoglutarate dehydrogenase complex and succinate thiokinase. By means of poly(ethylene glycol) precipitation, ultracentrifugation and gel chromatography we were able to detect a physical interaction between the alpha-ketoglutarate dehydrogenase complex and succinate thiokinase. Of the seven investigated proteins only succinate thiokinase showed association with alpha-ketoglutarate dehydrogenase complex. On the other hand, succinate thiokinase did not associate with other high molecular weight mitochondrial enzymes such as pyruvate dehydrogenase complex and glutamate dehydrogenase. On this basis, the interaction between succinate thiokinase and alpha-ketoglutarate dehydrogenase complex was assumed to be specific. These in vitro data raise the possibility that a portion of the citric acid cycle enzymes exists as a large multienzyme complex in the mitochondrial matrix.     

Effect of acetylcholine of substrate oxidation in heart mitochondria

Acetylcholine has been studied for its effect on respiration and oxidative phosphorylation in mitochondria from the heart of a rat and guinea pig. Acetylcholine in doses of 25, 50 and 100 mg per 100 g of the body weight 5, 15 and 30 min after intraperitoneal injection intensifies the rate of phosphorylative respiration at ketoglutarate oxidation and moderately lowers it at succinate oxidation. Malonate increases the activating influence of acetylcholine on oxidation of alpha-ketoglutarate in the heart mitochondria and aminooxyacetate decreases it. Phosphorylative respiration with oxidation of pyruvate and isocitrate is not changed essentially under the action of acetylcholine. Introduction of acetylcholine stimulated most strongly the aminooxyacetate-sensitive portion of respiration, a mixture of aminotransferases in the activation of alpha-ketoglutarate oxidation under effect of acetylcholine. The stimulating action of acetylcholine on alpha-ketoglutarate oxidation is mediated by M- and H-cholinoreceptors, since it is abolished by their blockers: atropine and benzohexonium. Stimulation of alpha-ketoglutarate oxidation by acetylcholine is mostly expressed under introduction of beta-adrenoblocker obsidan which provides prevalence of the parasympathetic nervous system. This stimulation is more intensive in the guinea pig as a more cholinergic animal in comparison with a rat.     

Regulation of insulin release by factors that also modify glutamate dehydrogenase

Leucine and monomethyl succinate initiate insulin release, and glutamine potentiates leucine-induced insulin release. Alanine enhances and malate inhibits leucine plus glutamine-induced insulin release. The insulinotropic effect of leucine is at least in part secondary to its ability to activate glutamate oxidation by glutamate dehydrogenase (Sener, A., Malaisse-Lagae, F., and Malaisse, W. J. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 5460-5464). The effect of these other amino acids or Krebs cycle intermediates on insulin release also correlates with their effects on glutamate dehydrogenase and their ability to regulate inhibition of this enzyme by alpha-ketoglutarate. For example, glutamine enhances insulin release and islet glutamate dehydrogenase activity only in the presence of leucine. This could be because leucine, especially in the presence of alpha-ketoglutarate, increases the Km of glutamate and converts alpha-ketoglutarate from a noncompetitive to a competitive inhibitor of glutamate. Thus, in the presence of leucine, this enzyme is more responsive to high levels of glutamate and less responsive to inhibition by alpha-ketoglutarate. Malate could decrease and alanine could increase insulin release because malate increases the generation of alpha-ketoglutarate in islet mitochondria via the combined malate dehydrogenase-aspartate aminotransferase reaction, and alanine could decrease the level of alpha-ketoglutarate via the alanine transaminase reaction. Monomethyl succinate alone is as stimulatory of insulin release as leucine alone, and glutamine enhances the action of both. Succinyl coenzyme A, leucine, and GTP are all bound in the same region on glutamate dehydrogenase, where GTP is a potent inhibitor and succinyl coenzyme A and leucine are comparable activators. Thus, the insulinotropic properties of monomethyl succinate could result from it increasing the level of succinyl coenzyme A and decreasing the level of GTP via the succinate thiokinase reaction.     

The pattern and kinetics of substrate metabolism of Campylobacter jejuni and Campylobacter coli

AIMS: The main aim was to investigate the patterns and kinetics of substrate oxidation by Campylobacter jejuni and C. coli. METHODS AND RESULTS: Substrate oxidation profiles by 100 strains were determined using oxygen electrode system. All the isolates tested oxidized formate, l-lactate, cysteine, glutamine and serine with high oxidation rates and high affinity but varied in their ability to oxidize citric acid cycle intermediates, aspartic acid and serine. CONCLUSIONS: Based on the oxidation ability of alpha-ketoglutarate, succinate, fumarate and aspartic acid, Campylobacter strains tested were divided into three distinct metabolic categories. The first group was able to metabolize alpha-ketoglutarate, succinate, fumarate and aspartic acid; the second group was unable to oxidize alpha-ketoglutarate; and the third group was unable to oxidize, succinate, fumarate, and aspartic acid. Furthermore, serine oxidation rate enabled the differentiation of C. jejuni and C. coli. SIGNIFICANCE AND IMPACT OF THE STUDY: Overall, the results highlights the extensive metabolic diversity between and within Campylobacter species. In addition, the kinetic data of oxidized substrates obtained may improve the isolation procedures of the organism.     

Nonezymatic formation of succinate in mitochondria under oxidative stress

The products of the reactions of mitochondrial 2-oxo acids with hydrogen peroxide and tert-butyl hydroperoxide (tert-BuOOH) were studied in a chemical system and in rat liver mitochondria. It was found by HPLC that the decarboxylation of alpha-ketoglutarate (KGL), pyruvate (PYR), and oxaloacetate (OA) by both oxidants results in the formation of succinate, acetate, and malonate, respectively. The two latter products do not metabolize in rat liver mitochondria, whereas succinate is actively oxidized, and its nonenzymatic formation from KGL may shunt the tricarboxylic acid (TCA) cycle upon inactivation of alpha-ketoglutarate dehydrogenase (KGDH) under oxidative stress, which is inherent in many diseases and aging. The occurrence of nonenzymatic oxidation of KGL in mitochondria was established by an increase in the CO(2) and succinate levels in the presence of the oxidants and inhibitors of enzymatic oxidation. H(2)O(2) and menadione as an inductor of reactive oxygen species (ROS) caused the formation of CO(2) in the presence of sodium azide and the production of succinate, fumarate, and malate in the presence of rotenone. These substrates were also formed from KGL when mitochondria were incubated with tert-BuOOH at concentrations that completely inhibit KGDH. The nonenzymatic oxidation of KGL can support the TCA cycle under oxidative stress, provided that KGL is supplied via transamination. This is supported by the finding that the strong oxidant such as tert-BuOOH did not impair respiration and its sensitivity to the transaminase inhibitor aminooxyacetate when glutamate and malate were used as substrates. The appearance of two products, KGL and fumarate, also favors the involvement of transamination. Thus, upon oxidative stress, nonenzymatic decarboxylation of KGL and transamination switch the TCA cycle to the formation and oxidation of succinate.     

Synthesis of alpha-ketoglutarate by reductive carboxylation of succinate in Veillonella, Selenomonas, and Bacteriodes species.

Evidence for reductive carboxylation of succinate to synthesize alpha-ketoglutarate was sought in anaerobic heterotrophs from the rumen and from other anaerobic habitats. Cultures were grown in media containing unlabeled energy substrates plus [14C]succinate, and synthesis of cellular glutamate with a much higher specific activity than that of cellular asparate was taken as evidence for alpha-ketoglutarate synthase activity. Our results indicate alpha-ketoglutarate synthase functions in Selenomonas ruminantium, Veillonella alcalescens, Bacteroides fragilis, Bacteroides vulgatus, Bacteroides uniformis, Bacteroides distasonis, and Bacteroides multiacidus. Evidence for this carboxylation was not found in strains representative of 10 other species.     

5-Alkyl(C19-C25) resorcinols as regulators of succinate and NAD-dependent substrate oxidation by mitochondria

The effect of 5-n-alkyl(C19-C25) resorcinols isolated from Azotobacter chroococcum on the oxidation of succinate and NAD-dependent substrates (glutamate, alpha-ketoglutarate, malate, pyruvate) by rat liver mitochondria was studied, using the polarographic technique. With succinate, the above resorcinol lipids activated to some extent the 2,4-dinitrophenol-decoupled mitochondrial respiration, but markedly suppressed it (up to 95%) in the presence of NAD-dependent substrates. The activating and inhibiting effects correlated with the resorcinol lipid/mitochondrial proteins ratio and were observed, when the lipid concentration in the incubation mixture ranged from 2.4.10(-4) to 6.0.10(-4) M. The most striking inhibiting effect was observed with alpha-ketoglutarate as substrate. The results obtained suggest that 5-n-alkyl(C19-C25) resorcinols should be regarded as rotenone type regulators of cell respiration.     

The role of malate in hormone-induced enhancement of mitochondrial respiration

Shortly after the injection of glucagon, epinephrine, norepinephrine, vasopressin, or angiotensin II into fasted rats, mitochondria isolated from their livers contained elevated concentrations of malate and oxidized citrate, alpha-ketoglutarate, and, in some cases, succinate more rapidly than mitochondria from fasted, control rats. The administration of tryptophan, lactate, or ethanol and refeeding of rats fasted 24 h result in similar elevations of mitochondrial malate concentration and oxidation of added substrates. Treatments that resulted in elevated mitochondrial malate resulted also in increased uptake of added citrate, alpha-ketoglutarate, pyruvate, and, in some cases, succinate. It is postulated that the well-documented effect of gluconeogenic hormones on mitochondrial oxidation of carboxylic substrates may be mediated by malate which not only yields oxalacetate to support the tricarboxylic acid cycle but also facilitates the transport of added substrates, and which is regenerated in the tricarboxylic acid cycle.     

Formation of enzyme-bound carbanion intermediate in the isocitrate lyase-catalyzed reaction: enzymatic reaction of tetranitromethane with substrates and its dependence on effector, pH, and metal ions

Isocitrate lyase of germinating castor seed endosperm catalyzes the reactions of succinate and of isocitrate (but not of glyoxylate) with tetranitromethane (TNM), giving rise to the nitroform anion (C-(NO2)3), analogous to the reaction of TNM with carbanions (O.P. Malhotra and U.N. Dwivedi, 1984, Ind. J. Biochem. Biophys. 21, 65-67). The kinetics of this reaction have been investigated under a variety of conditions. At a fixed TNM concentration, the initial rate of reaction exhibits a hyperbolic saturation of the enzyme with isocitrate. The reaction with succinate, however, shows "negative cooperativity" in succinate saturation and the data are consistent with the existence of two sets of succinate binding sites of unequal affinity ("tight" and "loose" sites). Equal reaction rates are observed at enzyme-saturating concentrations of succinate and isocitrate. In every case, the rate of reaction is proportional to the TNM concentration. In the presence of alpha-ketoglutarate, hyperbolic saturation curves are obtained for all the substrates (TNM and succinate or TNM and isocitrate). In the presence of this effector the Km of succinate and TNM are independent of the concentration of the second substrate. On the other hand, sets of parallel straight lines are obtained in the double-reciprocal plots for the enzymatic reaction of TNM with isocitrate in the presence of alpha-ketoglutarate. Studies on the effect of pH on the isocitrate lyase-catalyzed reactions of TNM with succinate, TNM with isocitrate, and succinate with glyoxylate in the absence as well as in the presence of alpha-ketoglutarate show that the proton behaves as an uncompetitive inhibitor in all these reactions, suggesting the presence of a "masked" basic group at the enzyme site, which is protonated in the presence of substrate only. The pKa value of this group lies in the range 6.7-6.9. The enzymatic reactions of TNM with succinate and isocitrate exhibit identical Mg2+ ion dependence. From a comparison of the data on the enzymatic reactions of TNM with the corresponding results on the physiological reaction catalyzed by this enzyme, it has been suggested that an ion pair intermediate (E+ X S-, in which E, S, and S- stand for enzyme, succinate, and succinate carbanion, respectively) lies on the pathway of catalysis by isocitrate lyase.     

Formation of hydrogen peroxide in the mitochondria of skeletal muscles

The generation of H2O2 in skeletal muscle mitochondria during the oxidation of NAD-dependent substrates and succinate is initiated by antimycin A but not by rotenone, which points to H2O2 formation at the respiratory chain site between the rotenone and antimycin blocks. The O2-/H2O2 ratio for alpha-ketoglutarate and succinate oxidation is approximately 1.4, which suggests that in skeletal muscle mitochondria H2O2 is predominantly formed via the superoxide radical generation. Heart and skeletal muscle mitochondria appeared to have the similar values of Vmax for H2O2 production; the catalase activity in skeletal muscle mitochondria is much lower.