Chronic ethanol consumption increases homocysteine accumulation in hepatocytes.

Results of previous studies have shown that chronic ethanol administration impairs methionine synthetase activity and decreases S-adenosylmethionine levels in the liver, indicating interference with homocysteine remethylation. The purpose of the present study was to investigate the effects of chronic ethanol feeding on the accumulation of homocysteine (Hcy), a potentially toxic agent. The research was divided into two experiments. In Experiment A, hepatocytes were isolated from pair-fed control and ethanol-fed rats after 2 weeks of feeding, and the release of Hcy into the medium was determined. Hepatocytes obtained from ethanol-fed rats released twice as much Hcy into the medium as did those obtained from controls. When hepatocytes were challenged by a methionine load, a marked increase in Hcy generation was observed, and the increase was further enhanced in hepatocytes obtained from ethanol-fed rats. In Experiment B, hepatocytes were isolated from pair-fed control and ethanol-fed rats after 4 weeks of feeding (the feeding time required for significant formation of alcoholic fatty liver in rats). In this experiment, similar results were obtained with Hcy generation as in Experiment A. In Experiment B, supplementation of the incubation medium with betaine prevented the increase in generation of Hcy by methionine-treated control cells as well as the generation of Hcy by cells of ethanol-treated rats. These results indicate that betaine may have the potential as a therapeutic agent against toxic Hcy formation.

Malondialdehyde-acetaldehyde-protein adducts increase secretion of chemokines by rat hepatic stellate cells.

Findings obtained from our recent studies have demonstrated that malondialdehyde, a product of lipid peroxidation, and acetaldehyde can react together with proteins in a synergistic manner and form hybrid protein conjugates, which have been designated as malondialdehyde-acetaldehyde (MAA)-protein adducts. These adducts have been detected in livers of ethanol-fed rats and are immunogenic because significant increases in circulating antibody titers against MAA-adducted proteins have been observed in ethanol-fed rats and more recently in human alcoholics. Although immunological factors may tend to perpetuate liver injury, little is known about the direct functional consequences of MAA-adducted proteins on the different cellular populations of the liver. Hepatic stellate cells (HSCs) have been shown to be pivotal in the pathogenesis of fibrosis and in the amplification and self-perpetuation of the inflammatory process. The present study was conducted to determine the effects of MAA-adducted proteins on the function of HSCs. Rat HSCs were exposed to various amounts of MAA-protein adducts and their unmodified controls, and the secretion of two chemokines, monocyte chemoattractant protein (MCP)-1 and macrophage inflammatory protein (MIP)-2, that are involved in the chemotaxis of monocytes/macrophages and neutrophils, respectively, was determined. We observed that bovine serum albumin-MAA induced a dose- and time-dependent increase in the secretion of both of these chemokines. These findings indicate that MAA-adducted proteins may play a role in the modulation of the hepatic inflammatory response and could contribute to the pathogenesis of alcoholic liver disease.

Malondialdehyde-acetaldehyde-adducted bovine serum albumin activates protein kinase C and stimulates interleukin-8 release in bovine bronchial epithelial cells.

Previous study results have demonstrated that cigarette smoke or acetaldehyde rapidly stimulates protein kinase C (PKC)-mediated release of interleukin-8 (IL-8) in bovine bronchial epithelial cells (BECs). Low concentrations of acetaldehyde combine synergistically with malondialdehyde to increase significantly maximal BEC PKC activity at 48 to 96 h stimulation. Because more than 95% of alcoholics are cigarette smokers, we hypothesized that malondialdehyde, an inflammation product of lipid peroxidation, and acetaldehyde, both a product of ethanol metabolism and a component of cigarette smoke, might stimulate PKC-mediated IL-8 release in BECs by malondialdehyde-acetaldehyde (MAA) adduct formation, rather than as free aldehydes. Protein kinase C activity is maximally elevated in BECs treated with 50 microg/ml of BSA-MAA from approximately 1 to 3 h. This activity subsequently begins to decrease by 4 to 6 h, with a return to baseline unstimulated kinase activity levels by 24 h. No activation of cyclic AMP-dependent protein kinase (PKA) or cyclic GMP-dependent protein kinase (PKG) was observed in BSA-MAA-treated BECs. The MAA adduct activation of PKC was followed by a fourfold to tenfold greater release of IL-8 over that observed for both BECs exposed to media only and BSA control-treated BECs. Protein kinase C activation and IL-8 release were blocked by pretreating BECs with 1 microM calphostin C or 100 nM of the PKC alpha-specific inhibitor, Go 6976. Isoform-specific inhibitors to PKC beta, PKC delta, and PKC zeta failed to inhibit completely MAA adduct-stimulated PKC or IL-8 release. Results of these studies indicate that metabolites derived from ethanol and cigarette smoke, such as acetaldehyde and malondialdehyde, form adducts that stimulate airway epithelial cell PKC alpha-mediated release of promigratory cytokines.

Ethanol feeding selectively impairs the spreading of rat perivenous hepatocytes on extracellular matrix substrates.

BACKGROUND: Hepatocytes require attachment and subsequent spreading on an extracellular matrix for their proper growth, function and survival. Our previous studies have shown that ethanol feeding selectively impairs perivenule hepatocyte attachment to various extracellular matrices. This study was undertaken to determine whether zonal differences in hepatocyte spreading in response to ethanol feeding occurs and to ascertain the influence of ethanol consumption on the zonal expression of the beta1 subunit of integrins, which are the major surface receptors responsible for matrix binding and subsequent interactions. METHODS: Hepatocytes from the perivenous and periportal regions of the liver were isolated by digitonin/collagenase perfusion from rats that were pair-fed for 2 to 3 weeks with a liquid diet containing either ethanol or isocaloric carbohydrate. The ability of perivenous and periportal hepatocytes to spread on plates coated with either type IV collagen, laminin, fibronectin or polylysine was determined. In addition, the isolated cells were used for the analysis of total cellular and surface beta1 integrin expression. RESULTS: With all of the matrix substrates tested, the spreading of perivenous hepatocytes isolated from the ethanol-fed animals was markedly impaired, while the spreading of periportal hepatocytes was essentially unaffected by ethanol feeding. Both the total cellular as well as the surface expression of the beta1 integrin subunit in perivenous cells from the ethanol-fed rats were significantly higher than from the perivenous control cells, whereas the total and surface expression of the beta1 integrin in periportal cells isolated from ethanol-fed and control rats were not significantly different. CONCLUSIONS: The results indicated that in addition to impairing hepatocyte attachment, ethanol feeding also impairs another critical step of the adhesion process, that of hepatocyte spreading on extracellular matrix substrates. This defect occurred preferentially in perivenous cells and not periportal cells and was associated with an increase in beta1 integrin expression, suggesting that a compensatory mechanism occurs as an attempt by the perivenous cells to overcome impaired cell-matrix interactions caused by ethanol. Overall, these alterations in extracellular matrix-hepatocyte interactions could lead to alterations of hepatocyte structure and function and potentially play a role in alcoholic liver injury.

Flow cytometric analysis of vesicular pH in rat hepatocytes after ethanol administration.

We examined the effect of ethanol administration on intravesicular pH in intact hepatocytes by applying a flow cytometric technique to detect fluorescein-isothiocyanate-dextran (FITC-dextran) in acidic vesicles. Rats were pair-fed liquid diets containing either ethanol or isocaloric carbohydrate for 1 to 5 weeks. Our study showed that ethanol administration increased the in situ pH of hepatic lysosomes by 0.15 to 0.2 pH units. This pH increase was sufficient to cause a significant reduction in lysosomal protein degradation. Long-term ethanol administration also caused a significant alkalinization of hepatic endosomes, and this increased pH was sustained over the course of vesicular acidification in hepatocytes incubated in vitro. Direct exposure of hepatocytes from rats fed control diet to either 25 mmol/L ethanol or 50 micromol/L colchicine also brought about a rapid alkalinization of acidic vesicles in a manner that resembled that seen in hepatocytes from ethanol-fed rats. These same treatments augmented the vesicular alkalinization already present in cells from ethanol-fed animals. Although ethanol administration had no effect on the content of the hepatic mannose-6-phosphate/IGFII receptor, the results indicate that sustained alkalinization of endosomes could have important functional consequences by impairing M-6-P/IGFII receptor recycling, thereby disrupting the delivery of newly synthesized hydrolases to lysosomes. This decreased complement of hydrolases within lysosomes together with alkalinization of the intralysosomal compartment would result in an overall decrease in lysosomal proteolysis.

Ethanol consumption alters trafficking of lysosomal enzymes and affects the processing of procathepsin L in rat liver.

In order to determine whether ethanol consumption alters the targeting of hepatic lysosomal enzymes to their organelles, we examined the sedimentation properties of lysosomal hydrolases in ethanol-fed rats and their pair-fed controls. Rats were fed a liquid diet containing either ethanol (36% of calories) or isocaloric maltose dextrin for one to five wk. Liver extracts were fractionated by Percoll density gradient centrifugation and fractions obtained were analyzed for the distribution of lysosomal marker enzymes. Heavy lysosomes were further purified from these gradients and the activity of specific hydrolases was determined. Compared with those from controls, isolated lysosomes from ethanol-fed rats showed a 20-50% reduction in the activity of lysosomal acid phosphatase and beta-galactosidase. Decreased intralysosomal hydrolase activity in ethanol-fed rats was associated with a significant redistribution of these enzymes as well as those of cathepsins B and L to lighter fractions of Percoll density gradients. This indicated an ethanol-elicited shift of these enzymes to lower density cellular compartments. In order to determine whether ethanol administration affects the synthesis and proteolytic maturation of hepatic procathepsin L, we conducted immunoblot analyses to quantify the steady-state levels of precursor and mature forms of cathepsin L in hepatic post-nuclear fractions. Ethanol administration caused a significant elevation in the steady-state level of the 39 kDa cathepsin L precursor relative to its 30 kDa intermediate and 25 kDa mature product. These results were confirmed by pulse-chase experiments using isolated hepatocytes exposed to [35S]methionine. Hepatocytes from both control and ethanol-fed rats incorporated equal levels of radioactivity into procathepsin L. However, during the chase period, the ratios of the 39 kDa procathepsin L to its 30 kDa intermediate and 25 kDa mature product in cells from ethanol-fed rats were 1.5-3-fold higher than those in controls. These results demonstrate that ethanol consumption caused a marked impairment in the processing of procathepsin L to mature enzyme, without affecting its synthesis. Taken together, our findings suggest that chronic ethanol consumption caused a deficiency in intralysosomal enzyme content by altering the trafficking and processing of these hydrolases into lysosomes.

Effects of ethanol administration on components of the ubiquitin proteolytic pathway in rat liver.

Hepatic protein accumulation during ethanol administration may result partly from an ethanol-elicited decline in hepatic protein degradation, which we have previously shown. We conducted the current studies to examine the effects of ethanol administration on the levels of hepatic ubiquitin, an 8.5-kd protein which is an important mediator of extralysosomal protein catabolism. Rats were pair-fed liquid diets containing either ethanol (36% of calories) or isocaloric maltose-dextrin for 1 to 5 weeks. Ubiquitin was immunochemically quantified by competitive enzyme-linked immunosorbent assay (ELISA) in crude cytosol fractions from whole liver and in 12,000g supernatants of hepatocyte lysates. Ubiquitin levels in hepatic cytosol fractions of ethanol-fed rats exceeded those of controls by about 30%. Isolated hepatocytes from ethanol-fed animals also showed a 40% to 75% elevation of ubiquitin above that in cells of pair-fed controls and this difference exceeded the relative rise in hepatocellular protein. In hepatocyte lysates subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting, we detected monomeric ubiquitin and higher molecular mass ubiquitin-protein conjugates. However, the immunoblot analyses revealed no quantitative changes in the level of either free or conjugated ubiquitin. The ubiquitin conjugating activity of crude and diethyl aminoethyl-fractionated liver cytosols of ethanol-fed rats had equal capacities to those from controls in catalyzing the formation of ubiquitin-protein conjugates. Our findings indicate that chronic ethanol consumption increased the level of immunoreactive ubiquitin in rat liver. This may have resulted from enhanced ubiquitin production because of an ethanol-elicited stress response and/or decreased catabolism of ubiquitin and its conjugates. Our findings also provide no indication that the ethanol-elicited reduction in hepatic proteolysis is because of a ubiquitin-mediated mechanisms.

Ethanol consumption reduces the proteolytic capacity and protease activities of hepatic lysosomes.

Chronic ethanol consumption causes decreased hepatic protein degradation, resulting in protein accumulation within hepatocytes. In this investigation, we sought to determine whether chronic ethanol feeding alters the degradative capacity and protease activities of isolated hepatic lysosomes. Male Sprague-Dawley-derived rats were fed a liquid diet containing either ethanol (36% of calories) or isocaloric maltose-dextrin for 1-5 wk. Hepatic lysosomes were isolated by differential centrifugation and purified through Percoll gradients. Lysosomes obtained from livers of ethanol-fed rats degraded both endogenous protein substrates and the exogenously added radioactive substrate, 125I-RNase A, 26-42% more slowly than lysosomes from pair fed controls. The ethanol-elicited reduction in proteolytic capacity appeared to result in part, from a deficiency of the lysosomal cathepsins B, L, and H. Compared with controls, the specific activities of these enzymes were 31-45% lower in lysosomes from ethanol-fed rats. Immunoblot analyses also revealed that the intralysosomal as well as the intracellular content of cathepsin B was significantly lower in ethanol-fed rats. In contrast, ethanol consumption did not affect the cellular quantity of cathepsin L but lowered its amount in isolated lysosomes. Our findings suggest that chronic ethanol consumption causes a deficiency in lysosomal cathepsins by altering their biosynthesis and/or their trafficking into lysosomes.

Ethanol administration alters the proteolytic activity of hepatic lysosomes.

Protein accumulation in liver cells contributes to alcohol-induced hepatomegaly and is the result of an ethanol-elicited deceleration of protein catabolism (Alcohol Clin Exp Res 13:49, 1989). Because lysosomes are active in the degradation of most hepatic proteins, the present studies were conducted to determine whether ethanol administration altered the proteolytic activities of partially purified hepatic lysosomes. Rats were fed liquid diets containing either ethanol (36% of calories) or isocaloric maltodextrin for periods of 2-34 days. Prior to death, all animals were injected with [3H]leucine to label hepatic proteins. Rats subjected to even brief periods of ethanol feeding (2-8 days) exhibited significant hepatomegaly and hepatic protein accumulation compared with pair-fed control animals. Crude liver homogenates and isolated lysosomal-mitochondrial and cytosolic subfractions were incubated at 37 degrees C, and the acid-soluble radioactivity generated during incubation was measured as an index of proteolysis. At neutral pH, in vitro protein breakdown in incubated liver homogenates and subcellular fractions from control and ethanol-fed rats did not differ significantly. The extent of protein hydrolysis increased when samples were incubated at pH 5.5, which approximates the pH optimum for catalysis by lysosomal acid proteases. Under the latter conditions, partially purified lysosomes from control animals had 2-fold higher levels of proteolysis than corresponding fractions from ethanol-fed rats. The difference in proteolytic capacity appeared to be related to a lower latency and a higher degree of fragility of lysosomes from ethanol-fed rats at the acidic pH.(ABSTRACT TRUNCATED AT 250 WORDS)