Papers by Jesus Villanueva
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Hepatology, 1994
The micropig model of chronic alcoholism was used to study the relationship of lipid composition ... more The micropig model of chronic alcoholism was used to study the relationship of lipid composition and physical properties in three different tissue membranes from the same animals. Ethanol feeding reduced membrane anisotropy, as measured with the diphenylhexatriene probe, in liver plasma and kidney brush-border membranes but not in jejunal brushborder membranes. Preincubation with ethanol reduced anisotropy in each of the three control membranes, whereas all three membranes from the ethanol-fed group were relatively tolerant to the acute effect of ethanol. In liver and kidney membranes, ethanol feeding increased levels of linoleic (18:2ω6) acid and decreased levels of arachidonic (20:4ω6) and docosahexaenoic (22:6ω3) acids and their specific double-bond positions, consistent with reduced activities of Δ6 and Δ5 fatty acid desaturases. In liver and kidney membranes, anisotropy parameters and the acute effect of ethanol correlated inversely with levels of linoleic acid and directly with levels of arachidonic and docosahexaenoic acids and their specific double bonds. Levels of docosahexaenoic acid correlated with the acute effect of ethanol in all three membranes. Phospholipid fatty acid profiles were similar in jejunal brush-border membranes and terminal bile samples, suggesting that the effects of ethanol on jejunal fatty acids and physical properties are modulated by intraluminal biliary phospholipids. The effect of ethanol on anisotropy could not be attributed to changes in membrane cholesterol/phospholipid ratios. These studies affirm the value of this new animal model of chronic alcoholism and provide comprehensive evidence for the central role of fatty acid desaturation in the membrane-associated effects of ethanol exposure. (HEPATOLOGY 1994;19:1229–1240.)
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Digestive Diseases and Sciences, 1999
We studied the sequential immunohistochemicalappearance of androgen-dependent carbonic anhydrase ... more We studied the sequential immunohistochemicalappearance of androgen-dependent carbonic anhydrase (CAIII) during the development of ethanol-induced liverinjury using liver samples from castrated andnoncastrated male micropigs. In castrated micropigs, thebaseline expression of CA III was either low or absent,while distinct positive immunoreactions were found inzone 3 hepatocytes at 5 and 12 months after the initiation of the ethanol diet. The CA IIIenzyme and protein adducts of lipid peroxidation-derivedaldehydic products, malondialdehyde and4-hydroxynonenal, appeared together in the perivenousregion, suggesting that the enzyme functions in anoxidative environment. The positive staining became moreabundant and widespread during the progression ofalcoholic liver disease. After 12 months, CA III was significantly more abundant in both theethanol-fed noncastrated and castrated micropigs than inthe control animals (P < 0.001, P < 0.05,respectively). CA III content was strikingly high in the ethanol-fed noncastrated animals, consistentwith a potential role of androgens in the regulation ofethanol-induced CA III expression. The strongly positiveCA III immunoreactions in the ethanol-fed noncastrated micropigs were associated with scant evidenceof aldehydic protein adducts and minimal histopathology.Thus, enhanced expression of CA III during ethanolconsumption may also account in part for gender differences in the susceptibility foralcohol-induced liver injury.
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Alcoholism-clinical and Experimental Research, 2001
Background: Folate deficiency is common in alcoholic patients, in part due to abnormal transport ... more Background: Folate deficiency is common in alcoholic patients, in part due to abnormal transport across membranes relevant to folate homeostasis. The reduced folate carrier (RFC) transports monoglutamyl folates across tissue membranes and could be affected by chronic exposure to ethanol. The micropig model is suitable to study the effect of alcoholism on RFC and folate transport across membranes.Methods: The membrane transport of [3H]-folic acid was measured by a vacuum filtration method in jejunal brush border (JBB), liver plasma membrane (LPM), and kidney brush border (KBB) membranes vesicles from micropigs fed control or 40% ethanol diets for 12 months. RFC transcripts were analyzed by reverse transcription polymerase chain reaction in jejunal mucosa, liver, and kidney from the same animals.Results: When we compared results from three relevant membranes in control animals, the transport of [3H]-folic acid was highest in LPM, 3-fold lower in KBB (p < 0.001), and 6-fold lower in JBB (p < 0.001). The concentration of RFC transcripts per total RNA was greatest in liver, followed by kidney and jejunum. The transport of [3H]-folic acid by JBB vesicles from chronic ethanol-fed animals exhibited 2-fold lower Km and Vmax (p < 0.05), whereas there was no ethanol effect on the Vmax of [3H]-folic acid transport by LPM or KBB. RFC transcript levels were 10-fold lower in jejunal mucosa from ethanol-fed animals than in control-fed animals (p < 0.005).Conclusions: Although our findings demonstrate different RFC transcript amounts and transport efficiencies among tissues, the present studies suggest that chronic ethanol exposure decreases the intestinal absorption of folic acid by altering the expression of RFC and consequently its transport kinetics in JBB. These findings provide a mechanism for the clinical finding of reduced folic acid absorption in chronic alcoholics.
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Hepatology, 1995
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Hepatology, 1993
We established a new animal model of alcoholic liver disease in the micropig, a species that cons... more We established a new animal model of alcoholic liver disease in the micropig, a species that consumes ethanol voluntarily in the diet. Ten micropigs were pair-fed diets containing 40% of calories as ethanol or cornstarch with identical amounts of fat, protein and micronutrients for 12 mo. Liver histopathology in the ethanol-fed pigs included steatonecrosis in all five and interstitial and perivenous fibrosis in three. Electron microscopy showed Ito-cell transformation with perisinusoidal collagen accumulation. Acetaldehyde adducts were found by immunofluorescence in the centrilobular region and were focused in perivenous zone 3 of all ethanol-fed animals. Protein and triglyceride levels were increased, whereas vitamin A and iron levels were decreased in liver homogenates from ethanol-fed animals. Thus, in this new animal model of alcoholism, ethanol feeding produced the features of alcoholic liver disease concurrent with hepatic deficiency of selected nutrients. Histological and immunofluorescent studies provide in vivo evidence that perivenous collagen deposition is linked to ethanol metabolism and acetaldehyde production. (HEPATOLOGY 1993;18:954-960).
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Alcohol, 2002
Methionine metabolism is regulated by folate, and both folate deficiency and abnormal hepatic met... more Methionine metabolism is regulated by folate, and both folate deficiency and abnormal hepatic methionine metabolism are recognized features of alcoholic liver disease (ALD). Previously, histological features of ALD were induced in castrated male micropigs fed diets containing ethanol at 40% of kilocalories for 12 months, whereas in male micropigs fed the same diets for 12 months abnormal methionine metabolism and hepatocellular apoptosis developed. Folate deficiency may promote the development of ALD by accentuating abnormal methionine metabolism. Intact male micropigs received eucaloric diets that were folate sufficient, folate deficient, or each containing 40% of kilocalories as ethanol for 14 weeks. Folate deficiency alone reduced hepatic folates by one half, and ethanol feeding alone reduced methionine synthase, S-adenosylmethionine (SAM), and glutathione (GSH) levels and elevated plasma malondialdehyde (MDA) levels. The combined regimen elevated plasma homocysteine, hepatic S-adenosylhomocysteine (SAH), urinary 8-hydroxy-2-deoxyguanosine (oxy(8)dG), an index of DNA oxidation, and serum aspartate aminotransferase (AST) levels. Terminal hepatic histopathologic characteristics included typical features of steatonecrosis and focal inflammation in pigs fed the combined diet, with no changes in the other groups. Hepatic SAM levels correlated with those of GSH, whereas urinary oxy(8)dG and plasma MDA levels correlated with the SAM:SAH ratio and to hepatic GSH. The results demonstrate the linkage of abnormal methionine metabolism to products of DNA and lipid oxidation and to liver injury. The finding of steatonecrosis and focal inflammation only in the combined diet group supports the suggestion that folate deficiency promotes and folate sufficiency protects against the early onset of methionine cycle-mediated ALD.
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Metabolism-clinical and Experimental, 1993
Our previous research with miniature pigs has shown that long-term ethanol feeding with a low-fat... more Our previous research with miniature pigs has shown that long-term ethanol feeding with a low-fat diet decreases arachidonic acid (20:4 omega 6) levels in multiple tissues, but we did not find significant liver pathology. In this study, we investigated the effect of ethanol feeding with high dietary linoleic acid (18:2 omega 6) on tissue fatty acid (FA) profiles and body composition. Five Yucatan micropigs were fed 370 kJ (89 kcal)/kg body weight of a diet containing ethanol and fat as 40% and 34% of energy, respectively; five control pigs were pair-fed corn starch in place of ethanol. Corn oil, 61% 18:2 omega 6, supplied most of the dietary fat. Liver biopsies were performed at baseline (n = 2 per group) and at three other time points (n = 5 per group). Phospholipid (PL) FA levels were measured by thin-layer and gas chromatography. Body composition was analyzed by underwater weighing of carcasses. Body composition analysis demonstrated a marked reduction of carcass fat in the ethanol group, but no significant reduction of carcass lean weight after 12 months. In liver PLs, the ethanol group showed decreased 20:4 omega 6 and docosahexaenoic acid (22:6 omega 3) after 1 month. While the decreased 20:4 omega 6 remained constant after 1 month, 22:6 omega 3 showed a progressive decrease up to 12-months, resulting in a continuous decrease of the omega 3/omega 6 FA ratio. This slowly progressive decrease in the omega 3/omega 6 ratio in liver PLs with ethanol feeding may have enhanced the inflammatory response in the liver, contributing to liver pathology. Body composition results indicate marked wasting of energy in the ethanol group.
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Alcoholism-clinical and Experimental Research, 2007
Background: To demonstrate a causative role of abnormal methionine metabolism in the pathogenesis... more Background: To demonstrate a causative role of abnormal methionine metabolism in the pathogenesis of alcoholic steatosis, we measured the effects on hepatic lipid synthesis of supplementing ethanol and folate-deficient diets with S-adenosylmethionine (SAM), a metabolite that regulates methionine metabolism.Methods: Yucatan micropigs were fed folate-deficient diets as control, with ethanol at 40% of kcal, and with ethanol supplemented with SAM at 0.4 g/1,000 kcal for 14 weeks. Histopathology, triglyceride levels and transcripts, and protein levels of the regulatory signals of hepatic lipid synthesis were measured in terminal omental adipose and liver samples.Results: Feeding ethanol at 40% of kcal with folate-deficient diets for 14 weeks increased and supplemental SAM maintained control levels of liver and plasma triglyceride. Serum adiponectin, liver transcripts of adiponectin receptor-1 (AdipoR1), and phosphorylated adenosine monophosphate kinase-β (p-AMPKβ) were each reduced by ethanol feeding and were sustained at normal levels by SAM supplementation of the ethanol diets. Ethanol feeding activated and SAM supplementation maintained control levels of ER stress-induced transcription factor sterol regulatory element-binding protein-1c (SREBP-1c) and its targeted transcripts of lipid synthesizing enzymes acetyl-CoA carboxylase (ACC), fatty acid synthase (FAS), and glycerol-3-phosphate acyltransferase (GPAT).Conclusions: Ethanol feeding with a folate-deficient diet stimulates hepatic lipid synthesis by down-regulating adiponectin-mediated pathways of p-AMPK to increase the expression of nSREBP-1c and its targeted lipogenic enzymes. Preventing abnormal hepatic methionine metabolism by supplementing ethanol diets with SAM reduces liver triglyceride levels by up-regulation of adiponectin-mediated pathways to decrease fatty acid and triglyceride synthesis. This study demonstrates that ethanol-induced hepatic lipid synthesis is mediated in part by abnormal methionine metabolism, and strengthens the concept that altered methionine metabolism plays an integral role in the pathogenesis of steatosis.
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Hepatology, 1991
In the miniature pig, ethanol consumption has been reported to induce alterations in hepatic anti... more In the miniature pig, ethanol consumption has been reported to induce alterations in hepatic antioxidant defense capacity, which could result in increased risk of peroxidative damage. However, ethanol may also induce changes in membrane fatty acid composition, which could reduce the risk of peroxidative damage. This study examined lipid peroxidation, antioxidant defense and fatty acid composition in livers from miniature pigs fed ethanol in diets containing 12% of their calories as fat for 20 mo. After 12 and 20 mo of feeding, ethanol-fed pigs had higher hepatic manganese–superoxide dismutase activity, lower hepatic copper concentrations and low hepatic copperzinc–superoxide dismutase and glutathione peroxidase activities compared with controls. Lipid peroxidation as assessed by thiobarbituric acid reacting substance assay was lower in liver homogenate and mitochondrial and microsomal fractions from ethanol-fed pigs than in controls. The percentage contribution of highly unsaturated fatty acids to total fatty acids in liver homogenates (after 12 mo of feeding) and microsome fractions (after 20 mo of feeding) was lower in the ethanol-fed pigs than in the controls, resulting in a lower peroxidizability index. Ethanol-fed pigs had minimal or no hepatic damage as assessed by histological methods. We suggest that the relative resistance of microsomes to lipid peroxidation is due to the lower peroxidizability index in the ethanol-fed pigs and may account in part for the absence of significant histopathological findings after 20 mo of ethanol feeding. (HEPATOLOGY 1991;13:1185–1192.)
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Alcoholism-clinical and Experimental Research, 2007
Background: To demonstrate a causative role for abnormal methionine metabolism in the pathogenes... more Background: To demonstrate a causative role for abnormal methionine metabolism in the pathogenesis of alcoholic steatohepatitis (ASH), we measured the preventive effects of supplementing folate deficient and ethanol containing diets in the micropig with S-adenosylmethionine (SAM), a metabolite that regulates methionine metabolism.Methods: Yucatan micropigs were fed folate-deficient diets as control, with ethanol at 40% of kcal, or with ethanol supplemented with SAM at 0.4 g/1000 kcal for 14 weeks. Histopathology, markers of liver injury, and regulatory enzymes were measured in terminal liver samples.Results: Among the ethanol group, livers showed hepatocellular necrosis together with increased levels of S-adenosylhomocysteine (SAH) and reduced levels of SAM and its ratio to SAH and glutathione (GSH), together with increased malondialdehyde plus hydroxynonenol (MDA + HNE) and nitrotyrosine (NT), transcripts and protein levels of cytochrome P4502E1 (CYP2E1), activity of NADPH oxidase, and activity and protein levels of inducible nitric oxide (iNOS). These findings were attenuated partially or completely to control levels by SAM supplementation of the ethanol diet.Conclusions: The present results indicate that SAM supplementation attenuates ethanol induced liver injury through its effects on the expressions and activities of oxidative stress pathways, and are consistent with the concept that the pathogenesis of oxidative liver injury is regulated in part through altered hepatic methionine metabolism.
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Hepatology, 1999
To assess possible links between ethanol-induced oxidant stress, expression of hepatic cytochrome... more 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.
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Alcoholism-clinical and Experimental Research, 2006
Background: Alcoholic liver disease is associated with abnormalities of methionine metabolic enzy... more Background: Alcoholic liver disease is associated with abnormalities of methionine metabolic enzymes that may contribute to glutathione depletion. Previously, we found that feeding micropigs a combination of ethanol with a folate-deficient diet resulted in the greatest decreases in S-adenosylmethionine and glutathione and increases in liver S-adenosylhomocysteine and oxidized disulfide glutathione.Methods: To study the mechanisms of glutathione depletion, we analyzed the transcripts and activities of enzymes involved in its synthesis and metabolism in liver and plasma specimens that were available from the same micropigs that receive folate-sufficient or folate-depleted diets with or without 40% of energy as ethanol for 14 weeks.Results: Ethanol feeding, folate deficiency, or their combination decreased liver and plasma glutathione and the activities of hepatic copper-zinc superoxide dismutase and glutathione peroxidase and increased the activity of manganese superoxide dismutase and glutathione reductase. Hepatic levels of cysteine and taurine were unchanged while plasma cysteine was increased in the combined diet group. Cystathionine β-synthase transcripts and activity were unaffected by ethanol feeding, while the activities of other transsulfuration enzymes involved in glutathione synthesis were increased. Glutathione transferase transcripts were increased 4-fold and its mean activity was increased by 34% in the combined ethanol and folate-deficient diet group, similar in magnitude to the observed 36% reduction in hepatic glutathione.Conclusions: Chronic ethanol feeding and folate deficiency acted individually or synergistically to affect methionine metabolism in the micropig by depleting glutathione pools and altering transcript expressions and activities of enzymes involved in its synthesis, utilization, and regeneration. The data suggest that the observed decrease in hepatic glutathione during ethanol feeding reflects its increased utilization to meet increased antioxidant demands, rather than reduction in its synthesis.
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Hepatology, 2004
Alcoholic liver disease is associated with abnormal hepatic methionine metabolism, including incr... more Alcoholic liver disease is associated with abnormal hepatic methionine metabolism, including increased levels of homocysteine and S-adenosylhomocysteine (SAH) and reduced levels of S-adenosylmethionine (SAM) and glutathione (GSH). The concept that abnormal methionine metabolism is involved in the pathogenesis of alcoholic liver disease was strengthened by our previous findings in a micropig model where combining dietary folate deficiency with chronic ethanol feeding produced maximal changes in these metabolites together with early onset of microscopic steatohepatitis and an eightfold increase in plasma aspartate aminotransferase. The goal of the present study was to determine potential mechanisms for abnormal levels of these methionine metabolites by analyzing the transcripts and activities of transmethylation enzymes in the livers of the same micropigs. Ethanol feeding or folate deficiency, separately or in combination, decreased transcript levels of methylenetetrahydrofolate reductase (MTHFR), methionine adenosyltransferase (MAT1A), glycine-N-methyltransferase (GNMT) and S-adenosylhomocysteine hydrolase (SAHH). Ethanol feeding alone reduced the activities of methionine synthase (MS) and MATIII and increased the activity of GNMT. Each diet, separately or in combination, decreased the activities of MTHFR and SAHH. In conclusion, the observed abnormal levels of methionine metabolites in this animal model of accelerated alcoholic liver injury can be ascribed to specific effects of ethanol with or without folate deficiency on the expressions and activities of hepatic enzymes that regulate transmethylation reactions. These novel effects on transmethylation reactions may be implicated in the pathogenesis of alcoholic liver disease. (HEPATOLOGY 2004;39:1303–1310.)
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