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.     

Reduced mRNA abundance of the main enzymes involved in methionine metabolism in human liver cirrhosis and hepatocellular carcinoma

BACKGROUND/AIMS: It has been known for at least 50 years that alterations in methionine metabolism occur in human liver cirrhosis. However, the molecular basis of this alteration is not completely understood. In order to gain more insight into the mechanisms behind this condition, mRNA levels of methionine adenosyltransferase (MAT1A), glycine methyltransferase (GNMT), methionine synthase (MS), betaine homocysteine methyltransferase (BHMT) and cystathionine beta-synthase (CBS) were examined in 26 cirrhotic livers, five hepatocellular carcinoma (HCC) tissues and ten control livers. METHODS: The expression of the above-mentioned genes was determined by quantitative RT-PCR analysis. Methylation of MAT1A promoter was assessed by methylation-sensitive restriction enzyme digestion of genomic DNA. RESULTS: When compared to normal livers MAT1A, GNMT, BHMT, CBS and MS mRNA contents were significantly reduced in liver cirrhosis. Interestingly, MAT1A promoter was hypermethylated in the cirrhotic liver. HCC tissues also showed decreased mRNA levels of these enzymes. CONCLUSIONS: These findings establish that the abundance of the mRNA of the main genes involved in methionine metabolism is markedly reduced in human cirrhosis and HCC. Hypermethylation of MAT1A promoter could participate in its reduced expression in cirrhosis. These observations help to explain the hypermethioninemia, hyperhomocysteinemia and reduced hepatic glutathione content observed in cirrhosis.     

Effects of betaine supplementation on hepatic metabolism of sulfur-containing amino acids in mice

BACKGROUND/AIMS: We previously reported that acute betaine treatment induced significant changes in the hepatic glutathione and cysteine levels in mice and rats. The present study was aimed to determine the effects of dietary betaine on the metabolism of sulfur-containing amino acids. METHODS/RESULTS: Male mice were supplemented with betaine (1%) in drinking water for up to 3 weeks. Changes in hepatic levels of major sulfur amino acid metabolites and products were stabilized after 2 weeks of betaine supplementation. Betaine intake increased methionine, S-adenosylmethionine, and S-adenosylhomocysteine levels significantly, but homocysteine and cystathionine were reduced. Methionine adenosyltransferase activity was elevated to three-fold of control. Cysteine catabolism to taurine was inhibited as evidenced by a decrease in cysteine dioxygenase activity and taurine levels in liver and plasma. Despite the significant changes in the transsulfuration reactions, neither hepatic cysteine nor glutathione was altered. Betaine supplementation decreased the hepatotoxicity induced by chloroform (0.5 ml/kg, ip) significantly. CONCLUSIONS: Betaine supplementation enhances recycling of homocysteine for the generation of methionine and S-adenosylmethionine while reducing its utilization for the synthesis of cystathionine and cysteine. However, the hepatic levels of cysteine or glutathione are not affected, most probably due to the depression of taurine generation from cysteine.     

Increased gene and protein expression of the novel eNOS regulatory protein NOSTRIN and a variant in alcoholic hepatitis

BACKGROUND & AIMS: Increased intrahepatic resistance in cirrhosis is associated with reduced endothelial NO synthase (eNOS) activity and exacerbated by superimposed inflammation. NOSTRIN induces intracellular translocation of eNOS and reduces NO generation. Our aims were to quantify and compare hepatic expression of eNOS, NOSTRIN, NOSIP, and caveolin-1 in alcoholic cirrhosis with or without superimposed alcoholic hepatitis and in normal livers. METHODS: Biopsy specimens from 20 decompensated alcoholic cirrhotic patients with portal hypertension (10 with alcoholic hepatitis) and 6 normal livers were analyzed: real-time polymerase chain reaction for quantification of messenger RNA; Western blotting; and enzyme assays of eNOS in normal and diseased liver were performed. Localization and interaction of eNOS and NOSTRIN in liver was assessed by immunohistochemistry and co-immunoprecipitation. RESULTS: eNOS mRNA was significantly increased and eNOS activity decreased in alcoholic hepatitis patients, despite no differences in eNOS protein expression among the patients. Patients with alcoholic hepatitis had significantly higher hepatic levels of NOSTRIN and caveolin-1 mRNA compared with cirrhosis alone or normal biopsy specimens. A NOSTRIN splice variant, not present in normal tissue, was detected on mRNA and protein levels in all alcoholic patients. Coimmunoprecipitation demonstrated association among NOSTRIN, eNOS, and caveolin-1. CONCLUSIONS: An increase in mRNA and protein of NOSTRIN and its shortened variant in alcoholic hepatitis may partly account for the paradox of increased mRNA levels and normal protein expression but decreased enzymatic activity of eNOS in diseased liver. Such intracellular regulators of NO production may be important in the development of increased intrahepatic resistance in alcoholic hepatitis patients.     

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.     

Long-term histologic follow-up study of alcoholic liver disease.

Forty Japanese patients with alcoholic liver disease (nonspecific change, 9; fatty liver, 5; hepatic fibrosis, 4; chronic hepatitis, 12; alcoholic hepatitis, 5; liver cirrhosis, 5) were followed for 3-17 yr (average 8 yr) with repeated liver biopsies (2-5 times; average 2.5 times) at intervals of more than 3 yr. All of the patients continued to consume alcohol during this observation period. Five out of 12 patients with chronic hepatitis and 2 of 5 patients with alcoholic hepatitis eventually progressed to cirrhosis, while none of the 4 patients with hepatic fibrosis became cirrhotic. Anti-hepatitis C virus antibody was positive in 2 patients with liver cirrhosis among 12 patients whose sera were available. Two patients with cirrhosis died of hepatic failure and one patient died of hepatocellular carcinoma. These data suggest that the long-term prognosis of alcoholic liver disease is not necessarily poor, but patients with chronic hepatitis or alcoholic hepatitis can be at risk of progression to cirrhosis.     

Elevated carboxy terminal cross linked telopeptide of type I collagen in alcoholic cirrhosis: relation to liver and kidney function and bone metabolism

BACKGROUND: The carboxy terminal cross linked telopeptide of type I collagen (ICTP) has been put forward as a marker of bone resorption. Patients with alcoholic liver disease may have osteodystrophy. AIMS: To assess circulating and regional concentrations of ICTP in relation to liver dysfunction, bone metabolism, and fibrosis. METHODS: In 15 patients with alcoholic cirrhosis and 20 controls, hepatic venous, renal venous, and femoral arterial concentrations of ICTP, and bone mass and metabolism were measured. RESULTS: Circulating ICTP was higher in patients with cirrhosis than in controls. No overall significant hepatic disposal or production was found in the patient or control groups but slightly increased production was found in a subset of patients with advanced disease. Significant renal extraction was observed in the controls, whereas only a borderline significant extraction was observed in the patients. Measurements of bone mass and metabolism indicated only a mild degree of osteodystrophy in the patients with cirrhosis. ICTP correlated significantly in the cirrhotic patients with hepatic and renal dysfunction and fibrosis, but not with measurements of bone mass or metabolism. CONCLUSIONS: ICTP is highly elevated in patients with cirrhosis, with no detectable hepatic net production or disposal. No relation between ICTP and markers of bone metabolism was identified, but there was a relation to indicators of liver dysfunction and fibrosis. As the cirrhotic patients conceivably only had mild osteopenia, the elevated ICTP in cirrhosis may therefore primarily reflect liver failure and hepatic fibrosis.     

Reduced hepatic glycogen stores in patients with liver cirrhosis

Abstract: Background: Patients with alcoholic liver cirrhosis have reduced hepatic glycogen stores but the mechanisms leading to this finding are not clear. Methods: We therefore determined the hepatic glycogen content in patients with alcoholic (n = 9) or biliary cirrhosis (n = 8), and in control patients undergoing liver surgery (n = 14). All patients were in the postabsorptive state. In addition, we performed a morphometric analysis of the livers, and measured activities and mRNA expression of several enzymes involved in glycogen metabolism. Cirrhotic and control patients were similar regarding age and body weight. Results: Cirrhotic patients had a reduced glycogen content per gram liver wet weight (17 ± 11 versus 45 ± 17 mg/g, P < 0.05), per milliliter hepatocytes (28 ± 16 versus 52 ± 21 mg/ml, P < 0.05) and per liver (28 ± 17 versus 64 ± 22 g, P < 0.05), the reduction being observed in both patients with alcoholic or biliary cirrhosis. Liver histology confirmed these findings and revealed that the decrease in liver glycogen in cirrhotic patients was not homogenous across cirrhotic lobules. Activities of glycogen synthase and phosphorylase (total activity and active form) were not different between cirrhotic and control patients, whereas hepatic mRNA expression was decreased in cirrhotics by approximately 50%. The activity of glucokinase was decreased in cirrhotic as compared in control patients (0.06 ± 0.30 versus 0.42 ± 0.21 U/ml hepatocytes, P < 0.05), the reduction being observed in both patients with alcoholic or biliary cirrhosis. Conclusions: We conclude that patients with alcoholic or biliary cirrhosis have decreased hepatic glycogen stores per volume of hepatocytes and per liver. Decreased activity of glucokinase may represent an important mechanism leading to this finding.     

Elevated nitric oxide and 3′,5′ cyclic guanosine monophosphate levels in patients with alcoholic cirrhosis

AIM： To evaluate whether serum levels of nitric oxide （NO^.） and plasma levels of cyclic guanosine monophosphate （cGMP） and total glutathione （GSH） are altered in patients with alcoholic cirrhosis and to examine their correlation with the severity of liver disease.
METHODS： Twenty-six patients with alcoholic liver cirrhosis were studied. Serum levels of NO^. and plasma levels of cGMP and GSH were measured in 7 patients with compensated alcoholic cirrhosis （Child-Pugh A） and 19 patients with advanced cirrhosis （Child-Pugh B and C）. The model for end-stage liver disease （MELD） score was evaluated. Sixteen healthy volunteers served as controls. Liver enzymes and creatinine levels were also tested.
RESULTS： NO^. and cGMP levels were higher in patients with Child-Pugh B and C cirrhosis than in Child-Pugh A cirrhosis or controls （NO^.： 21.70 ± 8.07 vs 11.70 ± 2.74; 21.70± 8.07 vs 7.26 ± 2.47 μmol/L, respectively; P 〈 0.001） and （cGMP： 20.12 ± 6.62 vs 10.14 ± 2.78; 20.12 ± 6.62 vs 4.95 ± 1.21 pmol/L, respectively; P 〈 0.001）. Total glutathione levels were lower in patients with Child-Pugh B and C cirrhosis than in patients with Child-Pugh A cirrhosis or controls （16.04 ± 6.06 vs 23.01 ± 4.38 or 16.04 ± 6.06 vs 66.57 ±26.23 μmol/L, respectively; P 〈 0.001）. There was a significant correlation between NO^. and cGMP levels in all patients with alcoholic cirrhosis. A significant negative correlation between reduced glutathione/glutathione disulfide and the MELD score was found in all cirrhotic patients.
CONCLUSION： Our results suggest a role for oxidative stress in alcoholic liver cirrhosis, which is more significant in decompensated patients with higher levels of NO^. and cGMP and lower GSH levels than in compensated and control patients. Altered mediator levels in decompensated patients may influence the hemodynamic changes in and progression of liver disease.     

Increasing dimethylarginine levels are associated with adverse clinical outcome in severe alcoholic hepatitis

Previous studies suggest reduced hepatic endothelial nitric oxide synthase activity contributes to increased intrahepatic resistance. Asymmetric dimethylarginine (ADMA), an endogenous nitric oxide synthase inhibitor, undergoes hepatic metabolism via dimethylarginine-dimethylamino-hydrolase, and is derived by the action of protein-arginine-methyltransferases. Our study assessed whether ADMA, and its stereo-isomer symmetric dimethylarginine (SDMA), are increased in alcoholic hepatitis patients, and determined any relationship with severity of portal hypertension (hepatic venous pressure gradient measurement) and outcome. Fifty-two patients with decompensated alcoholic cirrhosis were studied, 27 with acute alcoholic hepatitis and cirrhosis, in whom hepatic venous pressure gradient was higher (P = 0.001) than cirrhosis alone, and correlated with ADMA measurement. Plasma ADMA and SDMA were significantly higher in alcoholic hepatitis patients and in nonsurvivors. Dimethylarginine-dimethylamino-hydrolase protein expression was reduced and protein-arginine-methyltransferase-1 increased in alcoholic hepatitis livers. ADMA, SDMA and their combined sum, which we termed a dimethylarginine score, were better predictors of outcome compared with Pugh score, MELD and Maddrey's discriminant-function. CONCLUSION: Alcoholic hepatitis patients have higher portal pressures associated with increased ADMA, which may result from both decreased breakdown (decreased hepatic dimethylarginine-dimethylamino-hydrolase) and/or increased production. Elevated dimethylarginines may serve as important biological markers of deleterious outcome in alcoholic hepatitis.     

Synthesis of glutathione in response to methionine load in control subjects and in patients with cirrhosis

The fasting plasma level of reduced glutathione (GSH), a methionine-derived tripeptide, is reduced in cirrhosis. There is evidence that a reduced activity of S-adenosyl-L-methionine synthetase limiting the flux of methionine along the transmethylation/transsulfuration pathway may contribute to decrease GSH levels. No studies have analyzed plasma GSH in response to a methionine load. In 6 control subjects and in 10 patients with cirrhosis, plasma sulfur amino acid and plasma and erythrocyte GSH levels were measured in response to a L-methionine load (0.1 g/kg). Blood samples were obtained throughout the day after the oral load. Urine was collected for measurement of sulfur excretion. During the study period, all subjects consumed a standard diet of 1,683 kcal containing 2% protein and virtually no methionine. Plasma methionine increased in both groups to a peak level exceeding 20 times the basal value 90 minutes after the load, and declined thereafter. Methionine clearance, calculated on the descending part of the methionine-time curve, was reduced by 50% in cirrhosis (P = .0001). Fasting GSH was higher in controls (mean +/- SD, 3.9 +/- 1.3 v 1.6 +/- 0.7 micromol/L, P = .0004). In response to a methionine load, it peaked at 10.2 +/- 7.2 and 3.2 +/- 1.3 micromol/L, respectively (P = .009). Thereafter, plasma GSH progressively declined, and after 24 hours, it returned to the fasting preinfusion values in both groups. Plasma cysteine and taurine concentrations, as well as the erythrocyte GSH time course, paralleled plasma GSH levels, with less significant differences between groups. Sulfate excretion was delayed. GSH synthesis is stimulated by a methionine load. The reduced flux of methionine along the transmethylation/transsulfuration pathway reduces GSH synthesis in cirrhosis. Defective methionine metabolism also may be responsible for reduced fasting GSH.     

Cobalamin deficiency with and without neurologic abnormalities: differences in homocysteine and methionine metabolism

The unknown biochemical basis for neurologic dysfunction in cobalamin deficiency and the frequent divergence between neurologic and hematologic manifestations led us to study homocysteine metabolism in 22 patients with pernicious anemia. Serum levels of total homocysteine (tHcy), methionine, S-adenosylmethionine (AdoMet), cysteine, cysteinylglycine (cys-gly), and glutathione (GSH) were measured. Only levels of tHcy and cysteine were increased and only GSH was decreased in cobalamin deficiency as a whole, compared with 17 control subjects. AdoMet correlated only with methionine levels (P =.015) and cysteine only with cys-gly (P =.007) in healthy subjects, but in cobalamin-deficient patients AdoMet correlated instead with cysteine, cys-gly, and folate levels only (P =.008, P =.03, and P =.03, respectively). Significant differences appeared in clinically subgrouped cobalamin-deficient patients. The 11 patients with neurologic defects had higher mean levels of folate (27.9 versus 15.4 nM), AdoMet (117.2 versus 78.6 nM), cysteine (462 versus 325 microM), and cys-gly (85.0 versus 54.7 microM) than the 11 neurologically unaffected patients. Cobalamin therapy restored all metabolic changes to normal. The results indicate that changes in several metabolic pathways differ in patients with and without neurologic dysfunction. Cysteine levels were the most significant predictors of neurologic dysfunction, but it is unclear if they are direct or indirect indicators of neurotoxicity. The higher AdoMet levels in neurologically affected patients may result from inhibition of glycine N-methyltransferase by those patients' higher folate levels. The origin of the folate differences is unclear and possibly varied. Low AdoMet and GSH levels were independent predictors of anemia.     

New concepts of the pathogenesis of alcoholic liver disease lead to novel treatments

Activation of methionine to S-adenosylmethionine is depressed in alcoholics. Its repletion opposes alcoholic liver cirrhosis in baboons, decreases mortality in cirrhotic patients, and opposes oxidative stress resulting from cytochrome P4502E1 (CYP2E1) induction by alcohol, ketones, and fatty acids. Their excess causes alcoholic and nonalcoholic steatohepatitis. CYP2E1 is also induced in Kupffer cells, promoting their activation and release of inflammatory cytokines, including tumor necrosis factor (TNF)-α. The TNF-α inhibitor pentoxifylline decreased mortality from alcoholic hepatitis. Polyenylphosphatidylcholine (PPC), an antioxidant phosphatidylcholine mixture extracted from soybeans, 50% of which consists of the highly bioavailable dilinoleoylphosphatidylcholine, restores phospholipids of the damaged membranes and reactivates their enzymes, including phosphatidylethanolamine methyltransferase, needed for phospholipid regeneration. In baboons, PPC prevented cirrhosis by stimulating collagenase and by opposing lipid peroxidation, which produces the fibrogenic hydroxynonenal. PPC was beneficial in patients with alcoholic hepatitis, and it opposed fibrosis in heavy drinkers and decreased aminotransferases in patients with hepatitis C. The antioxidant silymarin also successfully opposed alcoholic cirrhosis in baboons and in some but not all clinical trials; this effect also pertains to α-tocopherol. The anti-inflammatory corticosteroids and colchicine yielded mixed results. Finally, replacing long-chain with medium-chain triglycerides opposed the fatty liver experimentally and clinically.     

酒精性肝病患者血浆白细胞介素-21水平及重组IL-21对LX-2肝星状细胞增殖和活化的影响

目的：分析酒精性肝病患者血浆白细胞介素-21（IL-21）水平及重组IL-21体外对LX-2肝星状细胞增殖和活化的影响。方法采用ELISA法检测17例酒精性肝炎、51例酒精性肝硬化患者和20例健康人血浆IL-21水平;体外培养LX-2肝星状细胞,以IL-21（1ng/ml或10ng/ml）处理24 h或48 h,检测LX-2细胞增殖及α-平滑肌肌动蛋白表达。结果与健康对照人群比,酒精性肝炎和酒精性肝硬化患者血浆IL-21水平均显著升高（P＆lt;0.05）,但酒精性肝炎和肝硬化患者之间无显著性差异,不同Child分级的肝硬化患者之间也无显著性差异;在IL-21作用24～48 h后,LX-2细胞增殖水平与对照组比无显著性差异,但α-平滑肌肌动蛋白表达均较对照组显著升高。结论血浆IL-21可能通过促进肝星状细胞活化参与了酒精性肝病患者肝纤维化的发生和发展。     

Clinicopathological Study of Alcoholic Fibrosis

Among 112 patients with alcoholic liver injury, 45 had alcoholic fibrosis. The incidence of alcoholic fibrosis was 40.2% which was the highest among various types of alcoholic liver injury (fatty liver: 3.6%, alcoholic hepatitis; 2.7% and liver cirrhosis: 31.3%). Clinical features of alcoholic fibrosis were milder than those of liver cirrhosis and more severe than those of fatty liver. The mean laboratory values in alcoholic fibrosis were significantly different from those in fatty liver and liver cirrhosis. The laboratory data were well correlated with the presence of pericellular fibrosis and thickening of the terminal hepatic venule, but only partially with hepatic cell necrosis and not with fatty metamorphosis. Two patients with alcoholic fibrosis who developed cirrhosis without any clinical and histological features of hepatitis were observed during 5-yr follow-up. These results indicate that alcoholic fibrosis is the most common type of alcoholic liver injury in Japan and is an independent clinicopathological entity distinct from the classical types of alcoholic liver injury. Pericellular fibrosis and thickening of the terminal hepatic venule which are the main histological features of alcoholic fibrosis may play an important role in its transition to liver cirrhosis.     

Hepatic venous pressure gradient determination in patients with hepatitis C virus-related and alcoholic cirrhosis

OBJECTIVES: Few data exist regarding the degree of portal hypertension in hepatitis C virus (HCV)-related cirrhosis, as the majority of studies have included mainly patients with alcoholic cirrhosis. This study was aimed at comparing the severity of portal hypertension in patients with HCV-related or alcoholic cirrhosis. METHODS: In total, 59 cirrhotic patients with portal hypertension (HCV-related in 34 cases and alcoholic in 25) underwent main right hepatic vein catheterization, with determination of the wedged and free hepatic venous pressures, and of hepatic venous pressure gradient (HVPG). RESULTS: HVPG values did not differ between the two groups of patients (19.4 +/- 6.0 mmHg vs 18.5 +/- 3.5 mmHg; P = 0.51). The prevalence and degree of oesophageal and gastric varices and portal hypertensive gastropathy did not correlate with the aetiology. Patients with viral cirrhosis had a lower prevalence of previous bleeding than those with alcoholic cirrhosis, despite a similar proportion of large varices in the two groups and similar HVPG levels. In both groups of patients, HVPG did not differ between patients with previous bleeds and those without. CONCLUSIONS: The degree of portal hypertension in cirrhotic patients does not correlate with the cause of the disease. Thus, current statements on the management of portal hypertension, although based upon studies including mainly patients with alcoholic cirrhosis, can be applied also to patients with viral-related cirrhosis.     

Impaired metabolism of methionine in severe liver diseases. I. Clinical and pathophysiological significance of elevated serum methionine levels

Serum methionine levels increased to a greater extent in patients with severe liver diseases such as fulminant hepatitis and liver cirrhosis with and without hepatic encephalopathy. However, the concentrations remained unchanged in non-encephalopathic cirrhotic cases associated with hepatocellular carcinoma, and their serum methionine levels increased only moderately even at the time of encephalopathy. At least two different mechanisms of serum methionine elevations, possibly due to release from injured hepatocytes or diminished catabolisms of this amino acid in the damaged liver, could be differentiated; the former would be involved mainly in fulminant hepatitis and the latter in liver cirrhosis. A methionine-loading test performed in cirrhotic patients supported the validity of these considerations. No significant increase of serum methionine levels in cirrhotic patients with hepatocellular carcinoma was observed, possibly by remarkable consumption of this amino acid in hepatoma tissues. During the clinical course of several patients, serial determinations of serum methionine concentrations indicated that the levels varied depending upon alterations in the pathophysiological state of the damaged liver; much higher levels were observed concomitantly with decompensated signs such as ascites, jaundice and hepatic encephalopathy. These results suggest that monitoring of serum methionine levels would be very valuable, especially for judging prognosis and predicting hepatic encephalopathy in severe liver disease.     

Progastrin and its products from patients with chronic viral hepatitis and liver cirrhosis

BACKGROUND: Gastrin and its precursor, progastrin, are synthesized in the stomach, particularly when infected with Helicobacter pylori, and they are metabolized, at least in part, in the liver. However, little is known about their levels in various hepatic diseases. METHODS: This study was carried out on 147 patients including chronic hepatitis B (n = 35), hepatitis C (n = 52) and liver cirrhosis (n = 60) of class A (n = 38), class B (n = 15) and class C (n = 7) (Child-Pugh classification) and age- and sex-matched healthy controls (n = 65). The diagnosis of chronic hepatitis was confirmed by liver biopsy in all patients, whereas the diagnosis of liver cirrhosis was based on clinical and laboratory findings. Liver biopsy was done in 38 out of 60 patients. Blood samples were collected under basal conditions and separated plasma samples were kept frozen at -70 degrees C until radioimmunoassay of progastrin and its products, including bioactive amidated gastrins. RESULTS: Median (range) plasma concentrations of total progastrin product and amidated gastrin in control subjects were 147.5 (73-345) pM and 33 (15-65), respectively. These concentrations in hepatitis B and C were not significantly different from those in controls. In cirrhosis (classes A, B and C), the concentrations of the progastrin and of gastrin were significantly (P < 0.05) higher than in controls reaching, respectively, 253.5 (135-683 pM) and 47.5 (17-385) pM. Both progastrin and gastrin levels were significantly higher in H. pylori-positive than in negative cirrhotic patients. Antibodies against H. pylori were present in about 50% of controls, 68% of hepatitis B, 57% of hepatitis C and in 83% in cirrhosis patients. The difference in H. pylori prevalence between cirrhosis and controls was statistically significant. CONCLUSIONS: Plasma levels of progastrin and gastrin are significantly increased in cirrhotic patients and this could be attributed to reduced metabolism of these peptides in liver cirrhosis and to their increased release due to H. pylori infection rate in this disease.