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.     

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.     

Effect of ethanol on glutathione concentration in isolated hepatocytes.

1. Ethanol induces a decrease in GSH (reduced glutathione) concentration is isolated hepatocytes. Maximal effects appear at 20 mM-ethanol. The concentration-dependence of this decrease is paralleled by the concentration-dependence of the activity of alcohol dehydrogenase. 2. Pyrazole, a specific inhibitor of alcohol dehydrogenase, prevents the ethanol-induced GSH depletion. 3. Acetaldehyde, above 0.05 mM, also promotes a decrease in GSH concentration in hepatocytes. 4. Disulfiram (0.05 mM), an inhibitor of aldehyde dehydrogenase, potentiates the fall in GSH concentration caused by acetaldehyde. 5. The findings support the hypothesis that acetaldehyde is responsible for the depletion of GSH induced by ethanol. 6. Methionine prevents the effect of alcohol or acetaldehyde on GSH concentration in hepatocytes.     

Evidence that lanthanum ions stimulate calcium inflow to isolated hepatocytes.

LaCl3 stimulated the initial rate of 45Ca2+ exchange measured under steady-state conditions in isolated liver cells. Cu2+ greater than La3+ = Fe3+ greater than Fe2+ = Zn2+ greater Ni2+ greater than Mn2+ also stimulated 45Ca2+ exchange. Compartmental analysis of 45Ca2+-exchange curves obtained in the presence or absence of La3+, and in the presence or absence of adrenaline, showed that the predominant effect of La3+ is to stimulate the inflow of Ca2+ to the cell from the medium. No evidence for an inhibition of Ca2+ outflow from the cell was obtained. In the presence of La3+, adrenaline caused no further stimulation of Ca2+ inflow to the cell. In the absence of adrenaline, La3+ increased the uptake of Ca2+ (measured by atomic-absorption spectroscopy) by isolated hepatocytes incubated at 1 degree C. The proposal that La3+ stimulates Ca2+ inflow to the liver cell by inducing a conformational change in the Ca2+-inflow transporter of the plasma membrane is briefly discussed.     

Interrelationship between drug oxidation ureogenesis and gluconeogenesis in isolated hepatocytes

1. The effect of increased ureogenesis--provoked by NH4Cl and ornithine--on gluconeogenesis and aminopyrine oxidation was studied in isolated hepatocytes prepared from 24 hr starved mice; lactate or fructose was used as gluconeogenic precursor. 2. Increased ureogenesis caused about 40% inhibition both on aminopyrine oxidation and gluconeogenesis when lactate was added as gluconeogenic substrate. 3. On the other hand, only 10% inhibition of aminopyrine oxidation and about 15% inhibition of gluconeogenesis were observed when fructose was used as gluconeogenic precursor. 4. Aminopyrine has been reported to inhibit gluconeogenesis from fructose by 30% and from lactate by 85%. The inhibitory effect of the combined addition of aminopyrine, NH4Cl and ornithine on gluconeogenesis was also dependent on the applied gluconeogenic precursor. 5. The provoked ureogenesis by ammonia and ornithine was not inhibited by aminopyrine. N6, O2-dibutyryl cAMP known to cause an increase of gluconeogenesis a decrease of aminopyrine oxidation enhanced the inhibitory action of increased ureogenesis on aminopyrine oxidation and on gluconeogenesis further. 6. The role of NADPH in the regulation of drug oxidation and ureogenesis is underlined.     

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.     

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.     

Binding of calcium ions to the isolated asialo-glycoprotein receptor. Implications for receptor function in suspended hepatocytes

The binding of calcium ions by the isolated asialoglycoprotein receptor of hepatocytes and the inter-relationship between the calcium ion concentration and receptor function have been studied. The isolated receptor binds calcium ions only in the presence of asialoglycoprotein. The asialo-glycoprotein receptor complex binds 4 calcium ions; the binding exhibits marked positive cooperativity, and the association constant at half-saturation of the binding sites was of the order of 10*5) M-1 as determined from a Hill plot. The isolated receptor was almost saturated at a calcium ion concentration of 0.1 mM. The binding capacity of isolated hepatocytes for asialo-glycoproteins increased, however, even when the calcium concentration was increased above this level. This may be explained by the exposure of increasing numbers of functional receptors on the surface of the cell with increasing membrane potential, and this explanation is supported by analogous observations in the presence of 5 mM La3+.     

Inhibition of gluconeogenesis, ureogenesis and drug oxidation by redox cycler quinone in isolated mouse hepatocytes.

1. The effect of a redox cycler and arylator (menadione) and a pure arylator quinone (benzoquinone) was studied on different NADPH generating and consuming processes in isolated mouse hepatocytes. 2. Menadione inhibited gluconeogenesis from alanine but not from fructose or glycerol. 3. Drug oxidation measured as aniline hydroxylation and aminopyrine N-demethylation could be inhibited by menadione in microsomal membrane and in isolated hepatocytes both from fed or fasted animals. 4. Ureogenesis in isolated hepatocytes from fed mice could not be inhibited even by high concentration of menadione, while in cells from fasted animals menadione was inhibitory at high concentration in the presence of gluconeogenic precursor and at lower concentration in the absence of it. 5. Benzoquinone did not inhibit the above mentioned processes.     

Effect of ethanol on lipid metabolism in cultured hepatocytes.

Isolated rat hepatocytes were cultured in a modified HI-WO/BA medium for 16 h. In the following 24 h oleate or oleate plus ethanol was added to the medium. After this period the medium was changed again and the cultures were further incubated with [1-14C]oleate alone or with [1-14C]oleate plus ethanol for 6 h. This allowed a comparison of effects of short-term (6 h) and long-term (24 + 6 h) exposure to ethanol on fatty acid metabolism. The increased intracellular accumulation of triacylglycerol in the presence of ethanol was quantitatively accounted for by increased fatty acid uptake, by decreased fatty acid oxidation in the tricarboxylic acid cycle and by decreased VLDL (very-low-density lipoprotein)-triacylglycerol secretion. Ketone-body production was not affected. After short-term exposure the rate of accumulation of triacylglycerol was increased by 50%. This increase was accounted for by increased fatty acid uptake (44%), decreased tricarboxylic acid-cycle activity (49%) and decreased VLDL-triacylglycerol secretion (7%). After long-term exposure, the rate of accumulation of triacylglycerol was increased by 74%. This increase was accounted for by increased fatty acid uptake (34%), decreased tricarboxylic acid-cycle activity (34%) and decreased VLDL-triacylglycerol secretion (32%). The larger increase in accumulation of triacylglycerol after long-term exposure to ethanol was entirely accounted for by increased inhibition of secretion of VLDL-triacylglycerol. The biochemical mechanisms underlying the observations are discussed.     

Action of the antiepileptic drug, valproic acid, on fatty acid oxidation in isolated rat hepatocytes

Valproate at 0.1 to 5 mM strongly inhibited oxidation of 1-(14C)-palmitate in isolated rat hepatocytes. Valproate at the same concentrations markedly decreased ketogenesis from 1 mM oleate. Valproate in a dose up to 5 mM did not significantly affect cellular concentration of ATP but lowered beta-hydroxybutyrate/acetoacetate and lactate/pyruvate ratios which paralleled its effect on ketogenesis. Moreover concomitant acetyl-CoA levels were drastically decreased by valproate. From this it may be concluded that inhibition of fatty acid oxidation by valproate results in reduced production of two carbons units and a drop of NADH/NAD+ ratio in rat hepatocyte. This suggests that valproate seriously interferes with beta-oxidation of physiological long-chain fatty acids.     

Effect of ethanol on the redox state of the coenzyme bound to alcohol dehydrogenase studied in isolated hepatocytes.

Human lactase was isolated from solubilized small-intestinal brush-border membranes by a combination of chromatography on concanavalin A-Sepharose, Bio-Gel 1.5m and chromatofocusing, with a yield of approx. 1% and a 750-fold purification. The enzyme appeared to be homogeneous on SDS/polyacrylamide-gel electrophoresis under both reduced and non-reduced conditions, with an apparent Mr of approx. 170,000. On gel filtration, however, it displayed an apparent Mr of approx. 380,000. The protein had a pI of 4.8, as judged by the chromatofocusing experiment, and had a lactase activity whose optimum is at pH 6.0. In addition to the beta-galactosidase activity, the protein also hydrolysed to various extents cellobiose, phlorizin, p-nitrophenyl beta-D-galactoside, p-nitrophenyl beta-D-glucoside, o-nitrophenyl beta-D-galactoside and o-nitrophenyl beta-D-fucoside. Antisera had been raised against the purified enzyme in two rabbits. One of the antibody populations could inhibit the enzyme in a concentration-dependent manner. This antibody population was used to set up an antibody-bound Sepharose column for the use in an immunoaffinity purification of lactase from crude intestinal homogenate. A partially purified preparation of lactase could thus be obtained. The antibody population was also used to set up a radioimmunoassay for quantifying the enzyme. The competition assay could detect about 0.5 micrograms of lactase protein/ml.     

Effect of bile acids on calcium efflux from isolated rat hepatocytes and perfused rat livers

The changes in intracellular Ca2+ concentration [( Ca2+]i) of hepatocytes induced by certain bile acids are biphasic: an initial increase is followed by a more gradual decrease. This latter decline in [Ca2+]i may be due to an efflux of Ca2+ across the plasma membrane. This hypothesis was tested by studying the effect of different bile acids on the efflux of 45Ca from preloaded rat hepatocytes and isolated perfused rat livers. The following bile acids were studied: cholic (C), ursodeoxycholic (UDC), chenodeoxycholic (CDC), and deoxycholic (DC) acids; their taurine (T) conjugates (TC, TUDC, TCDC, and TDC); and the taurine, sulfate (S), and glucuronide (Glu) derivatives of lithocholic acid (TLC, LS, TLS, and LGlu, respectively). At 0.3 mM, all bile acids except C, TC, TCDC, UDC, and TUDC significantly increased 45Ca efflux from preloaded hepatocytes without affecting cell viability. Dose-response studies revealed that the minimum effective concentration needed to induce 45Ca efflux was 0.06 mM for LS, 0.8 mM for TCDC, and 10 mM for TC. Efflux of 86Rb from preloaded hepatocytes was not significantly altered by 0.1 mM LS, indicating relative specificity for calcium. TDC and DC, but not TC, increased 45Ca efflux from preloaded perfused rat livers. These results showed that bile acids known to increase [Ca2+]i (CDC, DC, TDC, and TLC) also increased 45Ca efflux from hepatocytes and perfused livers and that efflux was also stimulated by LS, TLS, and LGlu. The extent of this efflux was related to the hydrophobicity of the steroid nucleus of the bile acid. It is speculated that bile acid-induced increases in [Ca2+]i activate the plasma membrane Ca2+ pump resulting in increased Ca2+ efflux.     

Effect of ornithine and lactate on urea synthesis in isolated hepatocytes.

1. In hepatocytes isolated from 24 h-starved rats, urea production from ammonia was stimulated by addition of lactate, in both the presence and the absence of ornithine. The relationship of lactate concentration to the rate of urea synthesis was hyperbolic. 2. Other glucose precursors also stimulated urea production to varying degrees, but none more than lactate. Added oleate and butyrate did not stimulate urea synthesis. 3. Citrulline accumulation was largely dependent on ornithine concentration. As ornithine was increased from 0 to 40 mM, the rate of citrulline accumulation increased hyperbolically, and was half-maximal when ornithine was 8-12 mM. 4. The rate of citrulline accumulation was independent of the presence of lactate, but with pyruvate the rate increased. 5. The rate of urea production continued to increase as ornithine was varied from 0 to 40 mM. 6. It was concluded that intermediates provided by both ornithine and lactate are limiting for urea production from ammonia in isolated liver cells. It was suggested that the stimulatory effect of lactate lies in increased availability of cytosolic aspartate for condensation with citrulline.     

Copper and zinc ions differentially block asialoglycoprotein receptor-mediated endocytosis in isolated rat hepatocytes.

Asialoglycoprotein receptors on hepatocytes lose endocytic and ligand binding activity when hepatocytes are exposed to iron ions. Here, we report the effects of zinc and copper ions on the endocytic and ligand binding activity of asialoglycoprotein receptors on isolated rat hepatocytes. Treatment of cells at 37 degrees C for 2 h with ZnCl2 (0-220 microM) or CuCl2 (0-225 microM) reversibly blocked sustained endocytosis of 125I-asialoorosomucoid by up to 93% (t1/2 = 62 min) and 99% (t1/2 = 54 min), respectively. Cells remained viable during such treatments. Zinc- and copper-treated cells lost approximately 50% of their surface asialoglycoprotein receptor ligand binding activity; zinc-treated cells accumulated inactive asialoglycoprotein receptors intracellularly, whereas copper-treated cells accumulated inactive receptors on their surfaces. Cells treated at 4 degrees C with metal did not lose surface asialoglycoprotein receptor activity. Exposure of cells to copper ions, but not to zinc ions, blocked internalization of prebound 125I-asialoorosomucoid, but degradation of internalized ligand and pinocytosis of the fluid-phase marker Lucifer Yellow were not blocked by metal treatment. Zinc ions reduced diferric transferrin binding and endocytosis on hepatocytes by approximately 33%; copper ions had no inhibitory effects. These findings are the first demonstration of a specific inhibition of receptor-mediated endocytosis by non-iron transition metals.     

Metabolic responses of isolated hepatocytes to adenosine; dependence on external calcium.

The role of cyclic-adenosine monophosphate (cAMP) and calcium (Ca2+) in the metabolic responses to adenosine was studied in isolated hepatocytes from fed rats. In the presence of 1.2 mM Ca but not in the absence of Ca2+, adenosine stimulated ureagenesis without increasing cAMP. Adenosine inhibited the glucagon mediated increase in cAMP. Adenosine increased free cytoplasmic Ca2+ provided that cells were incubated in the presence of external Ca2+. In the absence of added Ca2+ adenosine did not stimulate ureagenesis or the movements of Ca2+. It is suggested that, in the liver cell, Ca2+ may be a second messenger for adenosine.