Incorporation of the 1-pro-R and the 1-pro-S hydrogen atoms of ethanol into steroids and phosphatidylcholines in vivo.

The transfer of deuterium from chiral 1-monodeuteroethanols to various metabolites formed in the liver was studied in order to investigate the coupling of metabolic reductions to the alcohol dehydrogenase and the aldehyde dehydrogenase reactions. The ethanols were administered to female bile fistula rats for 10 h. The hydrogen at C-2 in the glycerol moiety of newly formed phosphatidylcholine molecules in bile, liver and plasma was derived to 22-25% from the 1-pro-R position and to 5-6% from the 1-pro-S position in the ethanol. sn-Glycerol 3-phosphate isolated from liver had a lower deuterium content at C-2. The ratio between the contributions from the two positions in ethanol to C-2 of free sn-glycerol 3-phosphate was the same as in the phosphatidylcholines. This indicates that the higher degree of labelling of this position in phosphatidylcholines is not due to a specific coupling between alcohol dehydrogenase and the formation of a phosphatidylcholine precursor. Cholesterol and chenodeoxycholic acid in bile became increasingly labelled, and the ratio between the incorporations from the 1-pro-S and the 1-pro-R positions of ethanol was about 0.37 in cholesterol and 0.46 in chenodeoxycholic acid. Thus, these NADPH-dependent reactions utilized hydrogen from the 1-pro-S position to a larger extent than NADH-dependent reactions.     

Incorporation of labelled amino acids into proteins of isolated parenchymal and nonparenchymal rat liver cells in the absence and presence of ethanol.

Parenchymal and nonparenchymal cells were isolated from perfused rat livers and incubated at 37 degrees C in the absence and presence of ethanol (50 mM). 1. Nonparenchymal cells prepared by means of centrifugation showed a higher rate of incorporation of L-[U-14C]valine into protein than nonparenchymal cells prepared by means of pronase. Cells prepared by the former method were used for further studies. 2. Protein degradation was present in suspensions of both parenchymal and nonparenchymal cells evidenced by increasing levels of branched amino acids in the intracellular and extracellular compartment during cell incubation. 3. The rate of cellular protein synthesis (corrected for precursor pool specific radioactivity) was of the same order of magnitude in nonparenchymal and parenchymal cells when expressed as nmol valine incorporated per mg protein. This rate was also close to the value found in intact liver by other workers. 4. Approximately 25% of the total radioactivity incorporated during incubation for 2 h was found in proteins released to the medium from parenchymal cells, while the corresponding figure for nonparenchymal cells was 3.5%. 5. Ethanol inhibited incorporation of labelled valine into stationary and medium proteins of parenchymal cells. No such effects were found in nonparenchymal cells. 6. Nonparenchymal cells did not metabolize ethanol while parenchymal cells did, shown by changes in lactate/pyruvate ratio and medium pH. It was concluded that nonparenchymal cells are capable of synthesizing proteins at a rate comparable to that found in parenchymal cells. Protein synthesis in parenchymal cells was inhibited by ethanol, but nonparenchymal protein synthesis was unaffected. This difference may be linked to the ability of the former cell type to metabolize ethanol.     

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.     

Increased oxidation of p-nitrophenol and aniline by intact hepatocytes isolated from pyrazole-treated rats

Induction of cytochrome P-450 IIE1 by pyrazole has been shown in a variety of studies with isolated microsomes or reconstituted systems containing the purified P-450 isozyme. Experiments were conducted to document induction by pyrazole in intact hepatocytes by studying the oxidation of p-nitrophenol to 4-nitrocatechol or of aniline to p-aminophenol. Hepatocytes prepared from rats treated with pyrazole for 2 days oxidized p-nitrophenol or aniline at rates which were 3- to 4-fold higher than saline controls. To observe maximal induction in hepatocytes, it was necessary to add metabolic substrates such as pyruvate, sorbitol or xylitol, which suggests that availability of the NADPH cofactor may be rate-limiting in the hepatocytes from the pyrazole-treated rats. Carbon monoxide inhibited the oxidation of p-nitrophenol and aniline by hepatocytes from the pyrazole-treated rats and controls, demonstrating the requirement for cytochrome P-450. The oxidation of both substrates by the hepatocyte preparations was inhibited by a variety of agents that interact with and are effective substrates for oxidation by P-450 IIE1 such as ethanol, dimethylnitrosamine, pyrazole and 4-methylpyrazole. Microsomes isolated from pyrazole-treated rats oxidized aniline and p-nitrophenol at elevated rats compared to saline controls. These results indicate that induction by pyrazole of the oxidation of drugs which are effective substrates for P-450 IIE1 can be observed in intact hepatocytes. The extent of induction and many of the characteristics of aniline or p-nitrophenol oxidation observed with isolated microsomes from pyrazole-treated rats can also be found in the intact hepatocytes.     

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.     

Estrogen receptor levels in the liver of intact and gonadectomized rats and in cultured hepatocytes]

The concentrations of hepatic estrogen receptor were determined in intact and gonadectomized male and female rats. The hydroxylapatite assay demonstrated that the ablation of gonads induces, in the liver, an increase of estrogen receptors. The data obtained suggests that the synthesis of these receptors in the liver might be estrogen- and androgen-dependent. The same analysis performed on hepatocyte cytosol, derived from ovariectomized females, and cultured for 24, 48 and 72 hours, showed that time of culture is an important factor in determining a decrease of estrogen receptor concentrations in the cells. The results obtained allowed us to conclude that in the maintenance of the normal levels of the hepatic estrogen receptors, either sexual and non-sexual hormones are involved.     

Ammonia overloading in hepatocytes isolated from liver of fetal and adult rats

Ammonia overloading was investigated during glucose and fructose metabolism in isolated hepatocytes under a variety of metabolic conditions. In all assay conditions, the glycolytic flux and oxygen uptake was not modified by 10 mM ammonia. In hepatocytes isolated from rats fed as libitum, the presence of ammonia caused a decrease in the production of lactate (pyruvate); this effect was not observed in anaerobic incubations, in hepatocytes isolated from starved animals, or in fetal hepatocytes. In spite of an overproduction of urea, ammonia detoxification also takes place by the synthesis of alanine, glutamate and aspartate. Addition of 1 mM aminooxyacetate, an inhibitor of aminotransferases, to the incubation medium prevents the formation of these amino acids, and also prevents the decrease of lactate in hepatocytes isolated from fed animals.     

Incorporation of fatty acids into the outer and inner membranes of isolated rat liver mitochondria

Acyl-CoA: phospholipid acyl-transferase activity as well as phospholipase A activity were detected in inner and outer membrane preparations from rat liver mitochondria. Both enzyme systems have an optimum pH around 8 and act preferentially on phosphatidylethanolamine. While phospholipase A activity is much lower in the inner membrane than in the outer membrane of mitochondria the reverse is true for the incorporation of (14C)-oleic acid into endogenous phosphatidylethanolamine. These results bring an indirect evidence that the inner membrane per se possesses a phospholipase A activity.     

Hydroxyl-radical production and ethanol oxidation by liver microsomes isolated from ethanol-treated rats.

In order to distinguish between the mechanism of microsomal ethanol oxidation and hydroxyl-radical formation, the rate of cytochrome P-450 (P-450)-dependent oxidation of dimethyl sulphoxide (Me2SO) was determined in the presence and in the absence of iron-chelating compounds, in liver microsomes from control, ethanol- and phenobarbital-treated rats. Ethanol treatment resulted in a specific increase (3-fold) of the microsomal ethanol oxidation and NADPH consumption per nmol of P-450. A form of P-450 was purified to apparent homogeneity from the ethanol-treated rats and characterized with respect of amino acid composition and N-terminal amino acid sequence. Specific ethanol induction of a cytochrome P-450 species having a catalytic-centre activity of 20/min for ethanol and consuming 30 nmol of NADPH/min could account for the results observed with microsomes. Phenobarbital treatment caused 50% decrease in the rate of ethanol oxidation and NADPH oxidation per nmol of P-450. The rate of oxidation of the hydroxyl-radical scavenger Me2SO was increased 3-fold by ethanol or phenobarbital treatment when expressed on a per-mg-of-microsomal-protein basis, but the rate of Me2SO oxidation expressed on a per-nmol-of-P-450 basis was unchanged. Addition of iron-chelating agents to the three different types of microsomal preparations caused an 'uncoupling' of the electron-transport chain accompanied by a 4-fold increase of the rate of Me2SO oxidation. It is concluded that ethanol treatment results in the induction of P-450 forms specifically effective in ethanol oxidation and NADPH oxidation, but not in hydroxyl-radical production, as detected by the oxidation of Me2SO.     

Colchicine alters lactate utilization in isolated hepatocytes of rats treated with CCl4 and ethanol

Lactic acidosis has been described in patients with liver disease. Hyperlactacidaemia results from an imbalance in lactate production versus lactate utilization. It is estimated that the liver utilizes approximately 30 percent of the total lactate produced in the body under basal conditions, primarily by gluconeogenesis. The gluconeogenesis from lactate 10 mM and lactacidaemia were determined in order to investigate the effects of CCl₄+ethanol administration in liver injury and, the possible effect of colchicine in our experimental fibrosis model. The tests were determined after 15, 30 or 45 days of treatment. The results indicate that the gluconeogenesis was significantly inhibited in both CCl₄+ethanol groups and CCl₄+ethanol+colchicine groups. By contrast, the lactacidaemia levels were much higher in the CCl₄+ethanol groups than the colchicine groups. Summarising, we have documented that hyperlactacidaemia is due to the inhibition of lactate utilization by the isolated hepatocytes in experimental cirrhosis, and that the improvement in lactacidaemia caused by colchicine is not primarily due to an increase in hepatic lactate utilization.     

Plasma and liver amino acids in rats after administration of ethanol or acetaldehyde

The changes in the level and pattern of free amino acids in plasma and liver after ethanol or acetaldehyde intoxication has been investigated in rats. After administration of 30% (w/v) ethanol, 6 g kg-1, or 1.5% (w/v) acetaldehyde, 0.3 ml kg-1, for 4 weeks we found a decrease in plasma and liver branched-chain amino acids and an increase in plasma aromatic amino acids and methionine. The results are analogous to those found in studies of damaged liver.     

Bile acids secretion and synthesis by isolated rat hepatocytes.

Bile acids secretion and their distribution were studied in isolated rat hepatocytes. Bile acids secretion was linearly related with time for first three hours of incubation and the net secretion rate was 23.2 ± 2.74 nmoles per g cells (wet weight) per minute. Isolated hepatocytes synthesized relatively more chenodeoxycholic acid than cholic acid compared to whole animal. These results suggest that isolated hepatocytes synthesize and secrete bile acids and thus provide experimental system to study the effect of drugs on bile acids secretion and synthesis at cellular level.