Induction of cytochrome P450 enzymes and generation of protein-aldehyde adducts are associated with sex-dependent sensitivity to alcohol-induced liver disease in micropigs.

To assess possible links between ethanol-induced oxidant stress, expression of hepatic cytochrome P450 (CYP) enzymes, and sex steroid status, we used immunohistochemical methods to compare the generation of protein adducts of acetaldehyde (AA), malondialdehyde (MDA), and 4-hydroxynonenal (4-HNE) with the amounts of CYP2E1, CYP2A, and CYP3A in the livers of castrated and noncastrated male micropigs fed ethanol for 12 months. In castrated micropigs, ethanol feeding resulted in accumulation of fat, hepatocellular necrosis, inflammation, and centrilobular fibrosis, whereas only minimal histopathology was observed in their noncastrated counterparts. CYP2A and CYP3A were more prominent in the castrated animals than in the noncastrated micropigs. Ethanol feeding increased the hepatic content of all CYP forms. The most significant increases occurred in CYP2E1 and CYP3A in the noncastrated animals and in CYP2E1 and CYP2A in the castrated animals. Ethanol-fed castrated animals also showed the greatest abundance of perivenular adducts of AA, MDA, and HNE. In the noncastrated ethanol-fed micropigs a low expression of each CYP form was associated with scant evidence of aldehyde-protein adducts. Significant correlations emerged between the levels of different CYP forms, protein adducts, and plasma levels of sex steroids. The present findings indicate that the generation of protein-aldehyde adducts is associated with the induction of several cytochrome enzymes in a sex steroid-dependent manner. It appears that the premature, juvenile, metabolic phenotype, as induced by castration, favors liver damage. The present findings should be implicated in studies on the gender differences on the adverse effects of ethanol in the liver.     

Early Alcoholic Liver Injury: Formation of Protein Adducts with Acetaldehyde and Lipid Peroxidation Products, and Expression of CYP2E1 AND CYP3A

The formation of protein adducts with reactive aldehydes resulting from ethanol metabolism and lipid peroxidation has been suggested to play a role in the pathogenesis of alcoholic liver injury. To gain further insight on the contribution of such aldehydes in alcoholic liver disease, we have compared the appearance of acetaldehyde, malondialdehyde, and 4-hydroxynonenal adducts with the expression of cytochrome P-450IIE1, and cytochrome P-4503A enzymes in the liver of rats fed alcohol with a high-fat diet for 2 to 4 weeks according to the Tsukamoto-French procedure and in control rats (high-fat liquid diet or no treatment). Urine alcohol and serum aminotransferase levels were recorded, and the liver pathology was scored from 0 to 10 according to the presence of steatosis, inflammation, necrosis, and fibrosis. The ethanol treatment resulted in the accumulation of fat, mild necrosis and inflammation, and a mean liver pathology score of 3 (range: 1 to 5). Liver specimens from the ethanol-fed animals with early alcohol-induced liver injury were found to contain perivenular, hepatocellular acetaldehyde adducts. Malondialdehyde and 4-hydroxynonenal adducts were also present showing a more diffuse staining pattern with occasional sinusoidal reactions. In the control animals, a faint positive reaction for the hydroxynonenal adduct occurred in some of the animals fed the high fat diet, whereas no specific staining was observed in the livers from the animals receiving no treatment Expression of both CYP2E1 and CYP3A correlated with the amount of protein adducts in the liver of alcohol-treated rats. Distinct CVP2E1 -positive immunohistochemistry was seen in 3 of 7 of the ethanol-fed animals. In 5 of 7 of the ethanol-fed animals, the staining intensities for CYP3A markedly exceeded those obtained from the controls. The present findings indicate that acetaldehyde and lipid peroxidatjon-derived adducts are generated in the early phase of alcohol-induced liver disease. The formation of protein adducts appears to be accompanied by induction of both CVP2E1 and CVP3A.     

Ethanol feeding of micropigs alters methionine metabolism and increases hepatocellular apoptosis and proliferation

Chronic alcoholism is associated with increased cancer risk that may be related to ethanol-induced alterations in methionine and deoxynucleotide metabolism. These metabolic relationships were studied in micropigs fed diets for 12 months that contained 40% ethanol or cornstarch control with adequate folate. Ethanol feeding altered methionine metabolism without changing mean terminal liver folate levels. After initial equilibration to diet, ethanol feeding significantly increased monthly serum homocysteine levels while reducing serum methionine levels over the time course of the experiment. After 12 months, hepatic methionine synthase activity and the ratio of S-adenosylmethionine (SAM) to S-adenosylhomocysteine (SAH) were significantly reduced in ethanol-fed animals, whereas the ratio of liver deoxyuridine triphosphate (dUTP) to deoxythymidine triphosphate (dTTP) was increased and correlated inversely with methionine synthase activity. These findings were associated with increased frequency of hepatocytes with apoptotic bodies and positivity for proliferating cell nuclear antigen (PCNA) in livers from ethanol-fed minipigs. These studies suggest that chronic ethanol feeding perturbs methionine metabolism by impairment of methionine synthase activity, resulting in deoxynucleoside triphosphate (dNTP) imbalance, increased apoptosis, and regenerative proliferation. These biochemical alterations may provide a promoting environment for carcinogenesis during long-term ethanol exposure. (Hepatology 1996 Mar;23(3):497-505)     

Relaxin and castration in male mice protect from, but testosterone exacerbates, age-related cardiac and renal fibrosis, whereas estrogens are an independent determinant of organ size

This study determined the effects of castration and hormone replacement therapy on the age-related cardiac and renal pathology of male relaxin gene-knockout (RlnKO) and age-matched wild-type (RlnWT) mice and that of aged male aromatase knockout (ArKO) mice, which lack estrogens and have 5-10 times the androgen levels of male wild-type mice. One-month-old RlnWT and RlnKO mice were bilaterally gonadectomized or sham operated and maintained until 12 months. Subgroups of castrated animals received testosterone or 17β-estradiol treatment from 9 to 12 months. Male ArKO mice and aromatase wild-type mice were aged to 12 months. Collected heart and kidney tissues were assessed for changes in organ size and fibrosis. Castration reduced body, heart, left ventricle, and kidney weights in both RlnKO and RlnWT mice, and the cardiac/renal fibrosis that was seen in sham RlnKO animals (all P < 0.05 vs. respective sham). Testosterone normalized organ weights and organ weight to body weight ratio of castrated animals and increased cardiac/renal collagen concentration to levels measured in or beyond that of sham RlnKO mice (all P < 0.05 vs. respective castrated mice). Furthermore, expression of TGF-β1, mothers against decapentaplegic homolog 2 (Smad2), and myofibroblast differentiation paralleled the above changes (all P < 0.05 vs. respective castrated mice), whereas matrix metalloproteinase-13 was decreased in testosterone-treated RlnKO mice. Conversely, 17β-estradiol only restored changes in organ size. Consistent with these findings, intact ArKO mice demonstrated increased cardiac/renal fibrosis in the absence of changes in organ size. These findings suggest that relaxin and castration protect, whereas androgens exacerbate, cardiac and renal fibrosis during ageing, whereas estrogens, in synergy with relaxin, regulates age-related changes in organ size.     

Folate deficiency disturbs hepatic methionine metabolism and promotes liver injury in the ethanol-fed micropig

Alcoholic liver disease is associated with abnormal hepatic methionine metabolism and folate deficiency. Because folate is integral to the methionine cycle, its deficiency could promote alcoholic liver disease by enhancing ethanol-induced perturbations of hepatic methionine metabolism and DNA damage. We grouped 24 juvenile micropigs to receive folate-sufficient (FS) or folate-depleted (FD) diets or the same diets containing 40% of energy as ethanol (FSE and FDE) for 14 wk, and the significance of differences among the groups was determined by ANOVA. Plasma homocysteine levels were increased in all experimental groups from 6 wk onward and were greatest in FDE. Ethanol feeding reduced liver methionine synthase activity, S-adenosylmethionine (SAM), and glutathione, and elevated plasma malondialdehyde (MDA) and alanine transaminase. Folate deficiency decreased liver folate levels and increased global DNA hypomethylation. Ethanol feeding and folate deficiency acted together to decrease the liver SAM/S-adenosylhomocysteine (SAH) ratio and to increase liver SAH, DNA strand breaks, urinary 8-oxo-2'-deoxyguanosine [oxo(8)dG]/mg of creatinine, plasma homocysteine, and aspartate transaminase by more than 8-fold. Liver SAM correlated positively with glutathione, which correlated negatively with plasma MDA and urinary oxo(8)dG. Liver SAM/SAH correlated negatively with DNA strand breaks, which correlated with urinary oxo(8)dG. Livers from ethanol-fed animals showed increased centrilobular CYP2E1 and protein adducts with acetaldehyde and MDA. Steatohepatitis occurred in five of six pigs in FDE but not in the other groups. In summary, folate deficiency enhances perturbations in hepatic methionine metabolism and DNA damage while promoting alcoholic liver injury.     

Deposition of Cellular Fibronectin Increases before Stellate Cell Activation in Rat Liver during Ethanol Feeding

Cellular fibronectin (cFN)—a structural extracellular matrix protein—facilitates cell adhesion, migration, and differentiation during organ development; wound healing; tissue regeneration; and fibrogenic processes. cFN is deposited early in various fibrotic diseases and seems to function as a template for deposition of other extracellular matrix proteins, such as collagen type I and laminin, in the injured area. We have compared the relative changes in cFN levels with other pathogenic markers of alcoholic liver injury over time of ethanol feeding in the rat. Male Wistar rats were allowed free access to a liquid diet containing 36% of total energy as ethanol or pair-fed an isocaloric control diet for 4, 8, and 12 weeks. Serum alanine arnino-transferase activity and total liver lipid were increased in ethanol-fed animals, compared with pair-fed controls after 4,8, and 12 weeks of feeding. Liver lipid content was higher in ethanol-fed rats as early as 4 weeks and was further increased by 12 weeks of feeding. Total fibronectin and cFN protein quantity was greater in liver from ethanol-fed rats after 8 and 12 weeks (fibronectin: 2.3-fold and 2.6-fold; cFN: 4.3-fold and 2.6-fold higher than pair-fed at 8 and 12 weeks, respectively). α-Smooth muscle actin, an indicator of hepatic stellate cell activation, was increased in the liver of ethanol-fed rats after 12 weeks of feeding (344% higher compared with pair-fed), with no differences observed at any earlier time points. In summary, increases in hepatic immunoreactive cFN content were observed subsequent to increased liver lipid concentration, but before hepatic stellate cell activation in rats fed the ethanol-based diet. These data suggest that deposition of cFN in the liver during long-term ethanol consumption may represent an early response to injury similar to that observed in other models of liver injury and wound healing.     

Effects on lipids, coagulation factors and liver histology of long-term ethanol administration to guinea-pigs.

The constant failure to produce a liver cirrhosis that can be ascribed to alcohol in the rat promoted the present study in guinea-pigs. The animals were given 40 per cent of calories as ethanol during 8 months. However, no alcoholic hepatitis or cirrhosis developed. Triglycerides and cholesterol increased in the liver and in serum. The persistance of liver triglyceride increase in spite of a rather low fat content of the diet is in contrast to experiences in the rat. A slight depression of coagulation factors II, VII, X and XI was observed in the ethanol-fed animals.     

Genes that affect cholesterol synthesis, cholesterol absorption, and chylomicron assembly: the relationship between the liver and intestine in control and streptozotosin diabetic rats

Chylomicrons and very low-density lipoproteins (VLDLs) are abnormal in diabetes. The aim of this study was to compare the expression of Niemann-Pick C1-like1 (NPC1L1), adenosine triphosphate-binding cassette (ABC) proteins G5 and G8, microsomal triglyceride transfer protein (MTP), and 3-hydroxy-3-methylglutaryl coenzyme A (HMGCoA) reductase in the fasting and fed states in nondiabetic Sprague-Dawley rats fed a high-fat/cholesterol diet and to examine the messenger RNA (mRNA) expression of these proteins in the liver and intestine of diabetic and control animals using streptozotosin diabetic cholesterol-fed rats. Chylomicron and VLDL concentrations were significantly lower after a 12-hour fast in fasted compared with fed rats (P < .02). There was no change with fasting in mRNA expression of any of the genes in the intestine, but MTP level was significantly lower in the liver after the 12-hour fast (P < .01). There was a positive correlation between intestinal NPC1L1 mRNA and chylomicron cholesterol (P < .01) and between hepatic NPC1L1 mRNA and VLDL cholesterol (P < .01). The diabetic rats had significantly higher chylomicron and VLDL cholesterol, triglyceride, and apolipoprotein B-48 and B-100 levels compared with control rats (P < .0001). They had significantly increased NPC1L1 and MTP mRNA in both liver and intestine (P < .05 and P < .0005, respectively), and ABCG5 and ABCG8 mRNA were significantly reduced (P < .05). HMGCoA reductase mRNA was increased in diabetic animals (P < .01). In conclusion, fasting intestinal gene expression reflects the fed state. In diabetes, intestinal and hepatic gene expression correlates with abnormalities in chylomicron and VLDL cholesterol.     

实验性酒精性肝病时脂多糖结合蛋白和脂多糖受体CD14的表达

目的观察大鼠酒精性肝病时脂多糖结合蛋白(lipopolysaccharide binding protein,LBP)和脂多糖受体CD14的表达及其在酒精性肝损害中的作用.方法随机将Wistar大鼠分为乙醇喂养组和葡萄糖喂养对照组,分剐在饮水中加入乙醇(剂量5-12 g@kg-1@d-1)和相同量的葡萄糖.两组大鼠分别于4周和8周测定其血浆中内毒揪素(LPS)浓度及血清中ALT变化,同时用RT-PCR测定肝组织中LBP和CD14 mRNA的表达,并在光镜和电镜下观察肝脏的形态学改变.结果乙醇喂养组4周和8周时大鼠血浆LPS浓度分别为(129±21)pg/ml和(187±35)Pg/m1,明显高于对照组的(48±9)pg/ml和(53±11)pg/ml(f值分别为11.2和11.6,P＜0.05);乙醇组大鼠血清ALT浓度为(112±15)U/L和(147±22)U/L,也明显高于对照组的(31±12)U/L和(33±9)U/L(t值分别为5.9和20.6,P＜0.05).乙醇组大鼠肝组织中LBP和CD14 mRNA的表达水平明显高于对照组(P＜0.05),其肝组织发生显著的病理变化,主要表现为脂肪变性、炎性细胞浸润及细胞坏死.对照组肝组织中LBP和CD14mRNA无明显表达,其病理变化也不明显.结论乙醇能诱导大鼠血中LPS浓度升高和肝缝织中LBP与CD14 mRNA的表达显著增强,增高的LBP和CD14 mRNA能增加肝脏对LPS的敏感性,可能造成肝脏损害.     

雄激素缺乏及外源性睾酮对雄性小鼠心脏衰老的影响

目的探讨雄激素缺乏是否与心脏衰老有关,以及不同剂量丙酸睾酮对心脏衰老的影响。方法雄性C57BL,/6J小鼠32只随机分为正常组(8只)、去势+安慰剂组(去势组,8只)、去势+生理剂量睾酮组(生理剂量组,8只)、去势+大剂量睾酮组(大剂量组,8只)。治疗3个月后测定各组血清睾酮浓度,分离心肌组织荧光实时定量PCR测定端粒长度以及Western b10t测定去磷酸化Rb蛋白表达量。结果与正常组比较,去势组小鼠睾酮明显降低(P0.01),端粒长度明显缩短(P=0.029),去磷酸化Rb蛋白表达明显增加(P0.01)。治疗3个月后,与去势组比较,生理剂量组小鼠端粒长度明显延长(P0.01);去磷酸化Rb蛋白表达明显减少(P0.05);大剂量组小鼠端粒长度进一步缩短(P0.05);去磷酸化Rb蛋白表达进一步增加(P0.01)。结论雄激素缺乏小鼠心肌组织发生衰老,给予生理剂量睾酮可延缓心脏衰老,大剂量睾酮对心脏衰老有促进作用。     

Dietary Betaine Promotes Generation of Hepatic S-Adenosylmethionine and Protects the Liver from Ethanol-Induced Fatty Infiltration

Previous studies have shown that ethanol feeding to rats alters methionine metabolism by decreasing the activity of methionine synthetase. This is the enzyme that converts homocysteine in the presence of vitamin B₁₂ and N⁵-methyltetrahydrofolate to methionine. The action of the ethanol results in an increase in the hepatic level of the substrate N⁵-methyltetrahydrofolate but as an adaptive mechanism, betaine homocysteine methyltransferase, is induced in order to maintain hepatic S-adenosylmethionine at normal levels. Continued ethanol feeding, beyond 2 months, however, produces depressed levels of hepatic S-adenosylmethionine. Because betaine homocysteine methyltransferase is induced in the livers of ethanolfed rats, this study was conducted to determine what effect the feeding of betaine, a substrate of betaine homocysteine methyltransferase, has on methionine metabolism in control and ethanol-fed animals. Control and ethanol-fed rats were given both betainelacking and betaine-containing liquid diets for 4 weeks, and parameters of methionine metabolism were measured. These measurements demonstrated that betaine administration doubled the hepatic levels of S-adenosylmethionine in control animals and increased by 4-fold the levels of hepatic S-adenosylmethionine in the ethanol-fed rats. The ethanol-induced infiltration of triglycerides in the liver was also reduced by the feeding of betaine to the ethanol-fed animals. These results indicate that betaine administration has the capacity to elevate hepatic S-adenosylmethionine and to prevent the ethanol-induced fatty liver.     

Chronic ethanol consumption causes alterations in the structural integrity of mitochondrial DNA in aged rats.

Chronic ethanol consumption adversely affects the respiratory activity of rat liver mitochondria. It causes increased cellular production of oxygen radical species and selectively decreases mitochondrial glutathione (GSH) levels. Here we show, using Southern hybridization techniques on total rat genomic DNA, that long-term (11-13 months) ethanol feeding, using the Lieber-DeCarli diet, results in a 36% (P <.05; n = 4) decrease in hepatic mitochondrial DNA (mtDNA) levels when compared with paired controls. UV quantitation of mtDNA isolated from hepatic mitochondria showed that chronic ethanol intake (11-13 months) causes a 44% (P <.01; n = 6) decrease in the amount of mtDNA per milligram of mitochondrial protein. No significant decline in mtDNA levels was seen in ethanol-fed animals maintained on the diet for 1 to 5 months. Ethanol feeding caused a 42% (P <.01; n = 4) and a 132% (P <.05; n = 3) increase in 8-hydroxydeoxyguanosine (8-OHdG) formation in mtDNA in animals maintained on the diet for 3 to 6 months and 10 to 11 months, respectively. In addition, agarose gel electrophoresis revealed a 49% increase (P <.05; n = 3) in mtDNA single-strand breaks (SSB) in animals fed ethanol for more than 1 year. These findings suggest that chronic ethanol consumption causes enhanced oxidative damage to mtDNA in older animals along with increased strand breakage, and that this results in its selective removal/degradation by mtDNA repair enzymes.     

Chemokine and Cell Adhesion Molecule mRNA Expression and Neutrophil Infiltration in Lipopolysaccharide-Induced Hepatitis in Ethanol-Fed Rats

Neutrophil infiltration is a feature of alcoholic hepatitis (AH), and although the mechanism by which this occurs is unclear, it may involve a chemotactic gradient. We used lipopolysaccharide (LPS) to induce, in ethanol-fed rats, liver damage similar to that seen in AH. To our knowledge, this study is the first to examine the effect of ethanol on LPS-stimulated chemokine mRNA expression in this model. Hepatic cytokine-induced neutrophil chemoattractant (CINC)-1, CINC-2, monocyte chemoattractant protein-1 (MCP-l), macrophage inflammatory protein (MIP)-1 β, MIP-2, and eotaxin mRNA levels were elevated 1 to 3 hr post-LPS in both groups. Maximal expression of MIP-2 and MCP-1 mRNA was higher in ethanol-fed rats 1 hr post-LPS, whereas CINC-2 mRNA expression was elevated above controls at 12 to 24 hr. Hepatic intercellular adhesion molecule-1 and vascular cell adhesion molecule-1 mRNA levels were elevated in both groups at 1 hr, whereas L-selectin expression in ethanol-fed rats was elevated above controls at 12 to 24 hr. Hepatic neutrophil infiltration was highest during maximal hepatocyte necrosis. These data suggest that cell adhesion molecules, in conjunction with elevated cytokines and the subsequently induced chemokines, may assist in the formation of a chemotactic gradient within the liver, causing the neutrophil infiltration seen both in this model and possibly in AH.     

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 1349, 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°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. The results suggest that ethanol-induced alterations in lysosomal membranes may be partially responsible for their altered capacities for protein hydrolysis. Such changes may result from ethanol-related alterations in lipid metabolism that may affect lysosome biogenesis or the maturation of lysosomes from autophagic vacuoles.     

Effects of castration on adipose tissue growth and regrowth in the male rat

Adipose tissue has been found to regrow in the male rat following surgical removal (lipectomy) of inguinal subcutaneous depots, but the degree of regrowth has varied widely across experiments. It is possible that at least part of the disparity of previous findings occurred because of differences among the experiments in the testicular integrity of experimental animals. To address this possibility, the present study examined effects of castration on adipose tissue regrowth in rats treated either as weanlings or as young adults. Male Sprague-Dawley rats, at either 4 or 15 weeks of age, were subjected to one of four surgical procedures: bilateral lipectomy of the inguinal subcutaneous depots; castration; lipectomy and castration; or sham surgery. Adipose tissue mass and cellularity were examined 6 months later. Castration reduced body weight gain, but castrated rats achieved a higher ratio of adipose weight to body weight than noncastrated rats. In rats lipectomized but not castrated at 15 weeks of age, partial regeneration and a small increase in growth of noninguinal subcutaneous adipose tissue combined to produce substantial restoration of adipose mass. The same surgery in 4-week-old rats did not result in significant restoration because growth of noninguinal subcutaneous adipose tissue was reduced. In rats that were both castrated and lipectomized, regrowth of adipose tissue was substantial regardless of age at time of surgery. Thus, castration is seen to impede body weight gain while sparing ordinary growth of adipose tissue and facilitating regrowth of adipose tissue following lipectomy. Since adipose tissue regrowth varied with age only in noncastrated rats, it appears to be facilitated as well by testicular maturation.     

Covalent adducts of proteins with acetaldehyde in the liver as a result of acetaldehyde administration in drinking water

BACKGROUND/AIMS: Acetaldehyde, the first metabolic product of ethanol, has been suggested to be responsible for several adverse effects of ethanol through its ability to form covalent adducts with proteins and cellular constituents. It has recently been suggested that acetaldehyde derived from microbial ethanol oxidation in the gut could also contribute to the effects of ethanol in the liver. The present work aimed to examine whether modification of proteins by acetaldehyde occurs in rat liver as a result of acetaldehyde administration in drinking water. METHODS: Rats were fed with either 0.7% acetaldehyde (n=10) or water (n=10) for 11 weeks. At the end of the feeding period, liver specimens were processed for immunohistochemistry for protein adducts with acetaldehyde and for hepatic cell type-specific protein markers. RESULTS: Mild fatty change was found in the liver of the acetaldehyde-treated animals but not in the control animals. Immunohistochemical stainings for acetaldehyde adducts revealed intensive positive staining for acetaldehyde adducts in eight (80%) of the animals fed with acetaldehyde. The adducts were predominantly perivenular, although positive staining also occurred along the sinusoids and in the periportal area. Double immunofluorescence staining experiments revealed that hepatocytes were the primary targets of acetaldehyde adduct deposition, although stellate cells and Kupffer cells also showed weak positive reactions. CONCLUSIONS: The present data indicate that acetaldehyde-protein adducts are formed in the liver of animals following acetaldehyde administration in drinking water, which may contribute to the hepatotoxicity of extrahepatic acetaldehyde. These findings should be implicated in studies on the extrahepatic pathways of ethanol oxidation.