[Alpha-adrenergic regulation of two calcium signal pathways in adipocytes].

Using selective receptor's agonist and antagonists we show that mouse white fat cells express alpha1A-, alpha2-adrenergic receptors, which activation with noradrenaline is capable of causing calcium responses different by formation mechanism. Adipocyte's calcium responses to alpha1-adrenoreceptor agonists are caused by alpha1A-type adrenoreceptor and suppressed by inhibitors of PLC-dependent pathway. Calcium responses to alpha2-adrenoreceptors agonists are realized only in the presence of more than 200 microM of L-arginine and suppressed by inhibitors of NOS-PKG-RyR pathway. The incubation of cells with L-arginine creates conditions for switching on the signal pathway with participation of eNOS --> NO --> sGC --> cGMP --> PKG --> CD38 --> RyR --> Ca2+ and for switching of the PLC - IP3R-dependent pathway. Adipocyte's calcium response to L-arginine represents a sharp impulse of the big amplitude and is mediated by alpha2-adrenoreceptors. L-arginine activating alpha2-adrenoreceptors and being the substrate of eNOS, realizes two functions in this pathway.

[Destabilization of the cytosolic calcium level and cardiomyocyte death in the presence of long-chain fatty acid derivatives].

It has been shown using the fluorescent microscopy technique that long-chain fatty acid derivatives, myristoylcarnitine and palmitoylcarnitine, exert the most toxic effect on rat ventricular cardiomyoctes. The addition of 20-50 microM acylcarnitines increases calcium concentration in cytoplasm ([Ca2+]i) and causes cell death after the 4-8 min lag-period. This effect is independent on extracellular calcium and L-type calcium channel inhibitors. Free acids (myristic and palmitic acids) at a concentration of 300-500 microM have a little effect on [Ca2+]i within 30 min. We suggest that the toxic effect is due to the activation of sarcoplasmic reticulum calcium channels by acylcarnitines and resulting acyl-CoA. Mitochondria play a role of calcium-buffer system in these conditions. The calcium capacity of this buffer determines the lag-period. Phosphate increases the calcium capacity of mitochondrial and the lag-period. In the presence of rotenone and oligomycin the elevation of [Ca2+]i after the addition of acylcarnitines occurs without the lag-period. The exhaustion of the mitochondrial calcium-buffer capacity or significant depolarization of mitochondrial leads to a rapid release of calcium from mitochondria and cell death. Thus, the activation of reticular calcium channels is the main reason of the toxicity of myristoylcarnitine and palmitoylcarnitine.

Stoichiometric traps in the tricarboxylic acid cycle. I. Self-inhibition and triggering phenomena.

The steady-state oxidation of 2 mM pyruvate in pigeon and rat heart mitochondria in the presence of ADP-glucose-hexokinase load can be strongly inhibited by excess (10-40 mM) of pyruvate or beta-hydroxybutyrate. This inhibition is accompanied by the accumulation of alpha-ketoglutarate and a decrease of malate. The mechanism of such substrate inhibition may be associated with the limitation of the tricarboxylic acid cycle flux by low levels of oxaloacetate and free CoA due to their being trapped as alpha-ketoglutarate and acetyl-CoA. Contrary to pyruvate, the ketone bodies in the absence of other substrates produce self-inhibition of their oxidation at as low concentrations as 0.5-1 mM. At 10-15 mM of acetoacetate, a complete suppression of respiration may develop. At a high load (preset by ADP or the uncoupler CCCP), the suppression is characterised by the accumulation of malate and a decrease of alpha-ketoglutarate. At low loads, the reverse distribution of the intermediates takes place. It is concluded that the system of ketone body oxidation in heart mitochondria is an example of biochemical triggers (systems with two alternative stable states).

Regulation of the tricarboxylic acid cycle and beta-oxidation by excess substrates.

A simple mathematical model is proposed to explain the inhibition of beta-oxidation and of the tricarboxylic acid cycle by excess of fatty acids. This model is based on the peculiar stoichiometry of beta-oxidation reactions, which accounts for the formation of dynamical traps for free CoA and its esters in the form of 3-ketoacyl-CoA derivatives. It follows from the analysis of the model that the fatty acids can produce 100% inhibition of respiration at some critical concentrations depending on their chain lengths. This conclusion was confirmed by experiments with rat liver mitochondria. The critical concentrations determined at high respiratory rates (85% of state 3 respiration) for palmitoylcarnitine, capric acid and caproic acid were found to be 0.45 mM, 1.8-2 mM and 3 mM, respectively.

[Substrate inhibition in the tricarboxylic acid cycle]. / Substratnoe ugnetenie v tsikle trikarbonovykh kislot.

It has been shown in the experiments on rat liver mitochondria under glucose hexo-kinase load that excess of substrates of (1-20 mM) pyruvate, acetate, propionate, pent-4-enoate and malate may induce oxidation of NAD(P)H and inhibition of mitochondrial respiration (by 20-50% and more) due to a decreased rate of hydrogen production by tricarboxylic acid cycle. It has been concluded from the analysis of mathematical models and metabolite-testings which remove this inhibition that for pyruvate and acetate this inhibition is an autocatalytic one. It is related to a decreased level of CoA and oxaloacetate due to the formation of "traps" such as acetyl-CoA and alpha-kotoglutarate. For propionate and pent-4-enoate in the bicarbonate-free medium suppression of the flux in the cycle is concerned with a decreased level of CoA, acetyl-CoA and succionoyl CoA due to the accumulation of propionyl-CoA. It seems to be also concerned with the inhibition of citrate-synthetase and alpha-ketoglutarate-dehydrogenase by propionyl-CoA. Malate (in the presence of malonate) can inhibit respiration at the expense of direct inhibition of citrate-synthetase.

[Mechanisms of the regulation of muscle energy metabolism on oxidation of glucose and fatty acids. A mathematical model]. / Mekhanizmy reguliatsii myshecgnogo energeticheskogo obmena pri okislenii gliukozy i zhirnykh kislot. Matematicheskaia model'.

A mathematical model was used to study the role of various allosteric regulatory mechanisms in the oxidation of glucose and fatty acids by muscle energy metabolism. A large number of such mechanisms were shown to be involved in simultaneous oxidation of both substrates: glycolysis is regulated by the ATP/ADP ratio at the phosphofructokinase (PFK) step; the control over pyruvate dehydrogenase is exercised by the NADHm/NADm+ and CoAsAc/CoAsH ratios as well as by the level of pyruvate; the Krebs cycle is regulated by oxaloacetate and citrate concentrations in the citrate synthase reaction and by the ATP/ADP and NADHm/NADm+ ratios in the isocitrate dehydrogenase reaction. The inhibition of PFK and pyruvate dehydrogenase by excess of CoAsAcyl as well as the inhibition of PFK by citrate are additional equivalent regulatory mechanisms. When glucose alone is oxidized, the levels of citrate, CoAsAcyl, NADHm and CoAsAc decrease drastically within the whole range of physiological ATPase loads; the only regulating factors that remain efficient are the ATP/ADP ratio in glycolysis, the level of pyruvate at the pyruvate dehydrogenase step, the ATP/ADP ratio and the levels of CoAsAc, oxaloacetate and isocitrate in the Krebs cycle.

[Mechano-metabolic coupling in the myocardium in response to electric stimulation]. / Issledovanie mekhano-metabolicheskogo sopriazheniia v miokarde pri élektricheskom stimuliatsii.

Fluorescent and mechanical responses to a series of electrical impulses of papillary muscle bands of the rabbit right ventricle during glucose oxidation were investigated. The kinetics of fluorescent responses consists of two phases: the primary one--the fall, and secondary one--the rise of NADN fluorescence up to the initial level and higher (overshoot). The fluorescence change in the first phase and overshoot value increase in response to an increased mechanical load, as well as to an increased concentration of extracellular Ca++ or adrenaline injection. No fluorescent response is observed after cyanide injection. Monoiodacetate eliminates overshoot initiation. Prolonged stimulation under large mechanical loads is accompanied by the stationary level of fluorescence above the initial one. This effect is interpreted on the basis of mathematical models [1, 2], as a result of pyruvate level control of the rate of NADN production by the Krebs cycle.

[Ratio between carbohydrate and lipid metabolism in muscle cell energy metabolism during ATPase loading. Mathematical model]. / Sootnosheni uglevodnogo i lipidnogo obmenov v énergetike myshechynkh kletok pri deistvii ATFaznoi nagruzki. Matematicheskaia model'.

A mathematical model is proposed to describe the interaction between glycolysis, the Krebs cycle and 3-oxidation (beta OX). The model incorporates the activations of phosphofructokinase by AMP and of isocitrate dehydrogenase by ADP as well as the inhibitions of citrate synthase by citrate, of acyl CoA synthase by excess CoAsAcyl, of pyruvate dehydrogenase (PDH) and the beta OX helix by the products CoAsAc and NADH. These regulations have been shown to provide consecutive triggering of the fatty acid and glucose oxidation systems with an increase in the ATPase load, the beta OX of fatty acids being a major source of energy at small loads. The steady state rates of glycolysis and PDH-reaction begin to increase at larger loads when the rate of beta OX is close to its maximum value. At maximum ATPase loads, the glucose oxidation accounts for more than 80% of the total energy production. Under limited fatty acid supply, the transfer to glucose oxidation gives rise to a region of the ATPase loads, where in the steady state levels of NADH and CoAsAc increase with load.

[Mathematical model for carbohydrate energy metabolism. Mechanism of the Pasteur effect]. / Matematicheskaia model' uglevodnogo energeticheskogo obmena. Mekhanizm effekta Pastera.

The simple mathematical model based on the stoichiometric structure of carbohydrate metabolism and the only allosteric regulation presented, i. e. activation of phosphofructokinase by AMP, was used to study the mechanism of the Pasteur effect, e. g. interrelationship of glycolysis, the Krebs cycle and H-transporting shuttles at varying rates of oxidative phosphorylation and ATPase load. It was shown that the mechanism of the Pasteur effect is based on the presence of two negative feed-back mechanisms in carbohydrate metabolism, namely by the level of ATP in glycolysis and by the level of mitochondrial NADH in the Krebs cycle and H-transporting shuttles. It was also shown that the value and sign of the Pasteur effect depend on the level of ATPase load. The role of this phenomenon in stabilization of ATP in the cell is discussed. The effects of changes in the allosteric properties of phosphofructokinase and low activity of H-transporting shuttles on the Pasteur effect was studied. It was shown that the low values of the pasteur effect in tumour tissues are mainly determined by an insufficient activity of oxidative phosphorylation.

[Mathematical model of carbohydrate energy metabolism. Interaction between glycolysis, the Krebs cycle and the H-transporting shuttles at varying ATPase load]. / Matematicheskaia model' uglevodnogo energeticheskogo obmena. Vzaimodeistvie glikoliza, tsikla krebsa i H-transportnykh chelnokov pri izmenenii nagruzki ATPazy.

A simple mathematical model for carbohydrate energy metabolism based on the stoichiometic structure of glycolysis, the Krebs cycle and oxidative phosphorylation is proposed. The only allosteric regulation involved in the model is phosphofructokinase activation by AMP. Simple as it is, the model can explain the following properties of carbohydrate metabolism: a drastic rise of the rate of glucose consumption during transition to a higher level of ATPase load; stabilization of ATP and an increase of the steady state rates of glycolysis and oxidation of cytoplasmic NADH by the H-transporting shuttles and of pyruvate in the Krebs cycle with increasing rate of the ATPase load; activation of glycolysis and a decrease of the rate of oxidative phosphorylation following an inhibition of the H-transporting shuttles. The mechanisms of the coordinated changes in the steady state rates of glycolysis, the H-transporting shuttles and the Krebs cycle at varying ATPase load in the cell are discussed.

[Effect of NAD recirculation on the mechanism of ATP stabilization in cytoplasm. Mathematical models]. / Vliianie retsirkuliatsii NAD na mekhanizm stabilizatsii ATP v tsitoplazme. Matematicheskiae modeli.

A mathematical model of the glycolytic system with the cytoplasmic coenzymes NAD+ and NADH as essential variables is proposed. It has been shown that any increase in the steady-state concentration of NADH will reduce the range of activity of the "generalized" ATPase, wherein the level of ATP is stabilized. Such a reduction in the range of ATP stabilization may be caused by an increasing rate of the pyruvate loss into non-glycolytic pathways, in particular, into mitochondria. This effect may be compensated by increasing oxidation of NADH by the dehydrogenases of H+-transferring cytosol-mitochondrial shuttles (malate-aspartate or alpha-glycerophosphate). The properties of the complete model were compared with those of its simplified version, which takes account only of the phosphotransferase reactions of glycolysis. The effects of various factors, which do not alter the level of NADH in the system, may be studied within the scope of the simplified model.

[A mathematical model of the pyruvate oxidation in liver mitochondria. 1. Regulation of the Krebs cycle by adenine and pyridine nucleotides]. / Matematicheskaia model' okisleniia piruvata v mitokhondriiakh pecheni. Reguliatsiia tsikla krebsa adeninovymi i piridinovymi nukleotidami.

A mathematical model is proposed to describe the behavior of the pyruvate metabolic reactions, Krebs cycle and oxidative phosphorylation over a wide range of changes in the pyruvate influx rate and the activities of ATPase and NADH-reoxidating dehydrogenase. The role of adenine and pyridine nucleotides in various allosteric regulations of the Krebs cycle enzymes is discussed. The accumulation of ATP and NADH has been shown to proceed in definite succession, which makes the allosteric regulation of the Krebs cycle enzymes successive too. First "works" the inhibition by ATP, then by NADH. It has been shown that the properties of the model are in qualitative agreement with the experimental data (Garber A., Hanson R. [1]) on pyruvate oxidation by mitochondria from guinea pig liver, when allosteric regulation of isocitrate dehydrogenase by adenine nucleotides is taken into account.

[Double-frequency oscillation in the glycolytic system. Mathematical model]. / Dvukhchastotnye kolebaniia v glikoliticheskoi sisteme. Matematicheskaia model'

A mathematical model describing the generation mechanism of double-frequency oscillations in the glycolytic system is proposed. Interaction of two connected glycolytic oscillation generators are put in the basis of this mechanism. It is assumed in the model that the first oscillation generator is formed due to product activation of phosphofructokinase (PFK) with adenosine diphosphate (ADP), while the second one is based on substrate inhibition of glyceraldehydephosphatededhydrogenase (GAPDH) with glyceraldehydephosphate (GAP).

[Oscillator generator in the lower portion of the glycolytic system]. / Generator kolebanii v nizhnei chasti glikoliticheskoi sistemy

A mathematical model explaining the mechanism of autooscillation generation in the lower part of the glycolytic system is suggested. The model is based on substrate inhibition of glyceraldehydephosphatedehydrigenase (GAPDH) with glyceraldehydephosphate (GAP). Pyrimidinenucleotides (NADplus and NADH) are shown not to play an important role in the given oscillation mechanism and can not be considered to simplify the model.