Rate-limiting factors in the oxidation of ethanol by isolated rat liver cells.

The oxidation of ethanol by isolated liver cells from starved rats is limited by the rate of removal of reducing equivalents generated in the cytosol by alcohol dehydrogenase. Evidence is presented suggesting that, in these cells, transfer of reducing equivalents from the cytosol to the mitochondria is regulated by the intracellular concentrations of the intermediates of the malate-aspartate and glycerol 3-phosphate cycles, as well as by flux through the respiratory chain. In liver cells isolated from fed rats, the availability of substrate increased the cell content of intermediates of the hydrogen-transfer cycles, and enhanced ethanol uptake. Under these conditions, ethanol consumption is limited by the availability of ADP for oxidative phosphorylation.     

The contribution of CNS MHPG to plasma MHPG in the rat

Two different experimental approaches were used to determine the central nervous system (CNS) contribution to plasma total 3-methoxy-4-hydroxyphenylglycol (MHPG) levels in the rat. One experiment, using intracisternal injection of 6-hydroxydopamine (6-OHDA), depleted total forebrain norepinephrine (NE) and MHPG to 26 and 34% of control values, respectively. In spite of the substantial reduction in CNS MHPG, plasma MHPG was not significantly different from control values. The second experiment used clonidine and debrisoquine to differentially impair central and peripheral NE metabolism. The results of this experiment confirm those of the 6-OHDA experiment in suggesting that the CNS contribution to plasma MHPG in the rat is negligeable.     

The effect of acute ethanol treatment on rates of oxygen uptake, ethanol oxidation and gluconeogenesis in isolated rat hepatocytes.

In hepatocytes isolated from fed rats, acute ethanol pretreatment (at a dose of 5.0 g/kg body wt.) did not change rates of O2 uptake. In cells from starved animals, acute ethanol pretreatment increased O2 uptake by 17-29%. The increased O2 uptake in hepatocytes from starved rats was not accompanied by increased rates of ethanol oxidation, but was accompanied by increased rates of gluconeogenesis under some conditions. The provision of ethanol (10 mM) as a substrate to cells from fed or starved rats decreased O2 uptake in the absence of other substrates or in the presence of lactate, and increased it in the presence of pyruvate or lactate and pyruvate. The results of this study show that the acute effects of ethanol on liver O2 uptake are dependent on the physiological state of the liver. Previously reported large (2-fold) increases in O2 uptake after acute ethanol pretreatment may have been an artefact owing to low control uptake rates (approximately 1.8 micromol/min per g wet wt. of cells) in the liver preparation used. The ATP contents (2.4-2.6 micromol/g wet wt. of cells) and rates of O2 uptake (2.5-5.0 micromol/min per g wet wt. of cells) of cells used in the present study were the same as values reported under conditions close to those in vivo. Therefore the increase in O2 uptake in cells from starved rats after acute ethanol pretreatment is likely to be of physiological significance.     

The characteristics of the `peroxidatic'' reaction of catalase in ethanol oxidation

Ethanol oxidation by rat liver catalase (the ;peroxidatic' reaction) was studied quantitatively with respect to the rate of H(2)O(2) generation, catalase haem concentration, ethanol concentration and the steady-state concentration of the catalase-H(2)O(2) intermediate (Compound I). At a low ratio of H(2)O(2)-generation rate to catalase haem concentration, the rate of ethanol oxidation was independent of the catalase haem concentration. The magnitude of the inhibition of ethanol oxidation by cyanide was not paralleled by the formation of the catalase-cyanide complex and was altered greatly by varying either the ethanol concentration or the ratio of the rate of H(2)O(2) generation to catalase haem concentration. The ethanol concentration producing a half-maximal activity was also dependent on the ratio of the H(2)O(2)-generation rate to catalase haem concentration. These phenomena are explained by changes in the proportion of the ;catalatic' and ;peroxidatic' reactions in the overall H(2)O(2)-decomposition reaction. There was a correlation between the proportion of the ;peroxidatic' reaction in the overall catalase reaction and the steady-state concentration of the catalase-H(2)O(2) intermediate. Regardless of the concentration of ethanol and the rate of H(2)O(2) generation, a half-saturation of the steady state of the catalase-H(2)O(2) intermediate indicated that about 45% of the H(2)O(2) was being utilized by the ethanol-oxidation reaction. The results reported show that the experimental results in the study on the ;microsomal ethanol-oxidation system' may be reinterpreted and the catalase ;peroxidatic' reaction provides a quantitative explanation for the activity hitherto attributed to the ;microsomal ethanol-oxidation system'.     

Mechanism of the stimulatory effect of fructose on ethanol oxidation in perfused rat liver.

The stimulatory effect of fructose on ethanol oxidation was studied in livers from fasted rats perfused with Krebs-Henseleit-bicarbonate buffer in a non-recirculating system. Two series of experiments were performed: (A) ethanol was infused with stepwise increasing concentrations (0.1-20 mM) in the presence of 4 mM fructose; (B) fructose was infused with stepwise increasing concentrations (0.5-10 mM) in the presence of 2 mM ethanol. From measured metabolic rates the following parameters were calculated: energy-rich phosphates consumed for fructose metabolism which were provided from oxidative phosphorylation (delta approximately P); reducing equivalents derived from stimulated ethanol utilization which were disposed by mitochondrial oxidation (delta2H). Under the various conditions studied a linear relationship between these parameters was observed. The ratio delta approximately P/delta2H was about 2.0. It is suggested that fructose stimulates ethanol oxidation indirectly by increasing the energy consumption of the liver due to the production of glucose from fructose. Consequetnly, the rate of oxidative phosphorylation is increased and, therefore, the capacity of the respiratory chain for oxidizing reducing equivalents derived from ethanol is enhanced. The data support the more general hypothesis that the rate of ethanol oxidation depend upon the rate of hepatic energy consumption in a given metabolic state.     

Stereospecificity of ethanol oxidation

The stereospecificity of ethanol oxidation via alcohol dehydrogenase, the microsomal ethanol oxidizing system (MEOS) and catalase was determined using stereospecific ethanol-1-³H. All systems showed the same stereospecificity towards ethanol. All pathways displayed an isotope effect, but the effect with MEOS and catalase was greater than with alcohol dehydrogenase.     

Effect of natural amino acids on ethanol oxidation in isolated rat hepatocytes]

The effects of the various naturally occurring amino acids on ethanol oxidation in hepatocytes from starved rats was systematically studied. In order to minimize the non ADH pathways, the ethanol concentration used was 4 mmol/litre, the amino acids being added at the same concentration. In hepatocytes from fasted rats, alanine, arginine, asparagine, aspartate, citrulline, cysteine, glutamate, glutamine, glycine, histidine, hydroxyproline, ornithine and serine increase significantly ethanol consumption. The stimulatory effect of glutamine being much less pronounced than the asparagine one and proline being devoid of action, the influence of ammonium chloride addition on ethanol consumption in the presence of these amino acids was studied. Ammonium chloride determines an enhancement of ethanol oxidation in these conditions, the results showing no apparent correlation between intracellular glutamate concentration and ethanol oxidation rate, contrarily to previous data. In hepatocytes from fed rats, only alanine, asparagine, cysteine, glycine, hydroxyproline, ornithine and serine increase ethanol oxidation, although to a lesser extent than in cells from starved rats.     

Enzymatic oxidation of ethanol in the gaseous phase

The enzymatic conversion of gaseous substrates represents a novel concept in bioprocessing. A critical parameter in such systems is the water activity, A(w) The present article reports the effect of A(w) on the catalytic performance of alcohol oxidase acting on ethanol vapors. Enzyme activity in the gas-phase reaction increases several orders of magnitude, whereas the thermostability decreases drastically when A(w) is increased from 0.11 to 0.97. The enzyme is active on gaseous substrates even at hydration levels below the monolayer coverage. Enhanced thermostability at lower hydrations results in an increase in the optimum temperature of the gas-phase reaction catalyzed by alcohol oxidase. The apparent activation energy decreases as A(w) increases, approaching the value obtained for the enzyme in aqueous solution. The formation of a pread-sorbed ethanol phase on the surface of the support is not a prerequisite for the reaction, suggesting that the reaction occurs by direct interaction of the gaseous substrate with the enzyme. The gas-phase reaction follows Michaelis-Menten kinetics, with a K(m) value almost 100 times lower than that in aqueous solution. Based on vapor-liquid equilibrium data and observed K(m) values, it is postulated that during the gas-phase reaction the ethanol on the enzyme establishes an equilibrium with the ethanol vapor similar to that between ethanol in water and ethanol in the gas phase.     

The effect of dimethylsulfoxide and other hydroxyl radical scavengers on the oxidation of ethanol by rat liver microsomes

The NADPH-dependent oxidation of ethanol by rat liver microsome preparations was studied in the presence of azide to inhibit the peroxidatic activity of catalase. Dimethylsulfoxide, benzoate, mannitol and thiourea, four compounds that react rapidly with hydroxyl radicals, each inhibited the oxidation rate of ethanol. Inhibition was competitive with respect to ethanol. In contrast, urea, a compound that reacts poorly with hydroxyl radicals, was essentially without effect. Dimethylsulfoxide at concentrations that inhibited the oxidation of ethanol had no effect on the xanthine oxidase-mediated oxidation of ethanol or on aniline hydroxylase or aminopyrine demethylase activity of microsomes. These results suggest that ethanol oxidation by microsomes can be dissociated from drug metabolism and that the mechanism of ethanol oxidation may involve, in part, the interaction of ethanol with hydroxyl radicals that are generated by microsomes during the oxidation of NADPH.     

The inhibition of acetate oxidation by ethanol in Acetobacter aceti

Ethanol grown Acetobacter aceti differed from acetate grown. In ethanol grown cells, acetate uptake, caused by the oxidation of acetate, was completely inhibited by ethanol, in acetate grown cells only to 20%. This was correlated with a 65-fold higher specific activity of the membrane bound NAD(P)-independent alcohol dehydrogenase in ethanol grown than in acetate grown cells. In comparison with ethanol grown cells, acetate grown cells showed a 3-fold higher acetate respiration rate and 3-fold higher specific activities of some tricarboxylic acid cycle enzymes tested. Both adaptations were due to induction by the homologous and not to repression by the heterologous growth substrate. A. aceti showed a membrane bound NAD(P)-independent malate dehydrogenase and no activity of a soluble NAD(P)-dependent one, as was known before from A. xylinum. A hypothesis was proposed explaining the observed inhibition of malate dehydrogenase and of functioning of the tricarboxylic acid cycle in the presence of ethanol or butanol or glucose by a competition of two electron currents for a common link in the convergent electron transport chains. The electrons coming from the quinoproteins, alcohol dehydrogenase and glucose dehydrogenase on the one side and those coming from the flavoproteins, malate dehydrogenase and succinate dehydrogenase via ubiquinonecytochrome c reductase on the other side are meeting at cytochrome c. Here the quinoproteins may be favoured by higher affinity and so inhibit the flavoproteins. Inhibition could be alleviated in the cell free system by increasing the oxygen supply.Dedicated to Professor Carl Martius on the occasion of his 80th birthday, March 1st 1986     

The contribution of serum triacylglycerol to hepatic triacylglycerol turnover in the starved rat.

The present study was undertaken to evaluate quantitatively the turnover of serum triacylglycerol (triglyceride) in the starved rat and to determine whether serum triacylglycerol recycled to liver contributes a significant fraction of the total hepatic triacylglycerol turnover. Serum was labelled in vitro with [3H]trioleoylglycerol (glycerol [3H]trioleate) to provide uniform labelling of all lipoprotein species. By using the curves describing disappearance of isotope from serum and its appearance in liver, rate constants for movement of triacylglycerol out of serum (0.29 min-1) and the uptake of serum triacylglycerol by liver (0.22 min-1) were calculated. The total rate of movement (flux) of triacylglycerol in these processes, the product of rate constant and serum pool size, was calculated to be 0.39 and 0.29 mg/min per 100 g body wt. respectively. A model is postulated for whole-body triacylglycerol metabolism consistent with the present data as well as most observations in the literature. From the model it can be predicted that: (1) the entire turnover of liver triacylglycerol in the starved rat can be accounted for on the basis of contributions from serum non-esterified fatty acid and serum triacylglycerol; (2) the entire turnover of the serum triacylglycerol pool can be accounted for quantitatively on the basis of contributions from intestine and liver; (3) the release rate for triacylglycerol from liver should be 0.34 to 0.35 mg/min per 100 g body wt.; (4) triacylglycerol synthesized by liver from non-esterified fatty acid of serum and by intestine can account quantitatively for the irreversible disposal rate of triacylglycerol from serum.     

Lactate-stimulated ethanol oxidation in isolated hepatocytes

1. Hepatocytes isolated from starved rats and incubated without other substrates oxidized ethanol at a rate of 0.8-0.9mumol/min per g wet wt. of cells. Addition of 10mm-lactate increased this rate 2-fold. 2. Quinolinate (5mm) or tryptophan (1mm) decreased the rate of gluconeogenesis with 10mm-lactate and 8mm-ethanol from 0.39 to 0.04-0.08mumol/min per g wet wt. of cells, but rates of ethanol oxidation were not decreased. From these results it appears that acceleration of ethanol oxidation by lactate is not dependent upon the stimulation of gluconeogenesis and the consequent increased demand for ATP. 3. As another test of the relationship between ethanol oxidation and gluconeogenesis, the initial lactate concentration was varied from 0.5mm to 10mm and pyruvate was added to give an initial [lactate]/[pyruvate] ratio of 10. This substrate combination gave a large stimulation of ethanol oxidation (from 0.8 to 2.6mumol/min per g wet wt. of cells) at low lactate concentrations (0.5-2.0mm), but rates remained nearly constant (2.6-3.0mumol/min per g wet wt. of cells) at higher lactate concentrations (2.0-10mm). 4. In contrast, owing to the presence of ethanol, the rate of glucose synthesis was only slightly increased (from 0.08 to 0.12mumol/min per g wet wt. of cells) between 0.5mm- and 2.0mm-lactate and continued to increase (from 0.12 to 0.65mumol/min per g wet wt. of cells) with lactate concentrations between 2 and 10mm. 5. In the presence of ethanol, O(2) uptake increased with increasing substrate concentration over the entire range. 6. Changes in concentrations of glutamate and 2-oxoglutarate closely paralleled changes in the rate of ethanol oxidation. 7. In isolated hepatocytes, rates of ethanol oxidation are lower than those in vivo apparently because of depletion of malate-aspartate shuttle intermediates during cell preparation. Rates are returned to those observed in vivo by substrates that increase the intracellular concentration of shuttle metabolites.