Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0030305 (pancreatitis)
 16,014 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The trypsin-inhibiting activity of human serum is lowered upon addition of formaldehyde or acetaldehyde thereto. Acetaldehyde reacts with alpha-1-proteinase inhibitor (alpha 1-PI) to decrease its trypsin-inhibiting ability. Acetaldehyde has only a slight effect on the tryptic hydrolysis of benzoyl-DL-arginine-p-nitroanilide. It did not decrease the inhibitory activity of the Kunitz inhibitor (Aprotinin) or soybean trypsin inhibitor. Since aldehydes form covalent products with primary amines, primary amides, arginine, tyrosine, and tryptophan in protein, as well as methylene bridges thereby crosslinking functional groups, it is proposed that one or more such interactions affect alpha 1-PI activity. It is further suggested that chronically high levels of acetaldehyde, as a metabolic produce of ethanol, may be a contributory factor to the generation of pancreatitis in alcoholics by possibly lowering the effective alpha 1-PI level which is a natural protective element from proteolysis by trypsin.
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PMID:Acetaldehyde decreases the antitryptic activity of alpha 1-proteinase inhibitor. 131 22

Acetaldehyde (AA), the first product of ethanol metabolism, has been suggested as an important mediator in alcoholic pancreatitis, but experimental evidence has not been convincing. Prior work using the isolated perfused canine pancreas preparation has suggested that toxic oxygen metabolites generated by xanthine oxidase (XO) may mediate the early injury in pancreatitis. Xanthine oxidase is capable of oxidizing AA, and during this oxidation free radicals are released. The hypothesis that acute alcoholic pancreatitis may be initiated by AA in the presence of active XO (converted from xanthine dehydrogenase [XD]) was tested in the authors' experimental preparation by converting XD to XO by a period of ischemia, and infusing AA. Control preparations remained normal throughout the 4-hour perfusion (weight gain, 7 +/- 4 g; amylase activity, 1162 +/- 202 U/dL). One hour of ischemia or infusion of AA at 25 mg/hr or at 50 mg/hr without ischemia did not induce changes in the preparation. Acetaldehyde at 250 mg/hr induced minimal edema and weight gain (16 +/- 4 g; p less than 0.05), but not significant hyperamylasemia. Changes also were not observed when 1-hour ischemia was followed by a bolus of ethanol (1.5 g) or sodium acetate (3.0 g), or by infusion of 25 mg/hr of AA. One hour of ischemia followed by infusion of AA at 50 mg/hr or at 250 mg/hr induced edema, hemorrhage, weight gain (22 +/- 7 g [p less than 0.05] and 26 +/- 17 g [p less than 0.05]) and hyperamylasemia (2249 +/- 1034 U/dL [p less than 0.05] and 2602 +/- 1412 U/dL [p less than 0.05]). Moreover infusion of AA at 250 mg/hr after 2 hours of ischemia potentiated the weight gain (62 +/- 20 g versus 30 +/- 14 g [p less than 0.05]), but not the hyperamylasemia (3404 +/- 589 U/dL versus 2862 +/- 1525 U/dL) as compared with 2 hours of ischemia alone. Pancreatitis induced by 1 hour of ischemia followed by AA at 50 mg/hr could be inhibited by pretreatment with the free radical scavengers superoxide dismutase and catalase and ameliorated with the XO inhibitor allopurinol. The authors conclude that AA, in the presence of active XO, can initiate acute pancreatitis in the isolated canine pancreas preparation and may be important in the initiation of acute alcoholic pancreatitis in man. Toxic oxygen metabolites appear to play an important intermediary role.
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PMID:The role of acetaldehyde in the pathogenesis of acute alcoholic pancreatitis. 172 Jun 11

Alcoholic liver disease includes steatosis, alcoholic hepatitis and cirrhosis. Other liver diseases of genetic origin, but with a curious association with alcohol intake, are hemochromatosis and porphyria cutanea tarda. The attribution of chronic hepatitis to alcohol intake remains speculative, and the association may reflect hepatitis C infection. Hepatic injury attributed to alcohol includes the changes reported in the fetal alcohol syndrome. Steatosis, the characteristic consequence of excess alcohol intake, is usually macrovesicular and rarely microvesicular. Acute intrahepatic cholestasis, which in rare instances accompanies steatosis, must be distinguished from other causes of intrahepatic cholestasis (e.g., drug-induced) and from mechanical obstruction of the intrahepatic bile ducts (e.g., pancreatitis, choledocholithiasis) before being accepted. Alcoholic hepatitis (steatonecrosis) is characterized by a constellation of lesions: steatosis, Mallory bodies (with or without a neutrophilic inflammatory response), megamitochondria, occlusive lesions of terminal hepatic venules, and a lattice-like pattern of pericellular fibrosis. All these lesions mainly affect zone 3 of the hepatic acinus. Other changes, observed at the ultrastructural level, are of importance in progression of the disease. They include widespread cytoplasmic shedding, and capillarization and defenestration of sinusoids. Progressive fibrosis complicating alcoholic hepatitis eventually leads to cirrhosis that is typically micronodular but can evolve to a mixed or macronodular pattern. Hepatocellular carcinoma occurs in 5 to 15% of patients with alcoholic liver disease. The clinical syndrome of alcoholic liver disease is the result of three factors--parenchymal insufficiency, portal hypertension and the clinical consequences of extrahepatic damage produced by alcohol. At the several phases of the life history of alcoholic liver disease, the individual factors play a different role. The clinical manifestations of alcoholic steatosis are mainly extrahepatic in origin. Those of alcoholic hepatitis reflect mainly parenchymal insufficiency and those of cirrhosis are mainly those of portal hypertension. Alcoholic liver injury appears to be generated by the effects of ethanol metabolism and the toxic effects of acetaldehyde, perhaps the immune responses to alcohol- or acetaldehyde-altered proteins, and questionably enhanced by viral hepatitis. Alcoholic hepatitis may be mimicked histologically, and to a varying degree clinically, by a number of conditions (obesity, diabetes, several drug-induced injuries, jejunoileal bypass, and related "shortcircuiting" of the bowel). Perhaps the most important facet of the hepatotoxicity of alcohol is its enhancement of the effects of a number of other hepatotoxic agents, among which acetaminophen is the prime example.
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PMID:Alcoholic liver disease: pathologic, pathogenetic and clinical aspects. 205 45

This study investigates the effect of ethanol on enzyme synthesis and secretion in rat pancreatic lobules. Ethanol caused a dose-dependent inhibition of 3H-leucine incorporation into total protein. Examination of the time dependence showed that ethanol inhibited protein synthesis at each time point. Removal of ethanol partially reversed this inhibition. An autoradiograph of the newly synthesized proteins separated on SDS-PAGE showed that ethanol inhibited synthesis of all proteins. 14C-cycloleucine uptake was not altered by ethanol, excluding inhibition of amino acid uptake as the mechanism for the decreased protein synthesis induced by ethanol. Electron microscopy revealed no ultrastructural damage. Ethanol had no effect on the stimulated release of (i) amylase from zymogen granules nor (ii) newly synthesized pulse labelled enzymes. Acetaldehyde had no inhibitory effect on enzyme synthesis or secretion indicating that ethanol per se and not its metabolite is inhibitory. The decreased synthesis after acute exposure to ethanol with preservation of exocytosis would limit the autodigestive potential of pancreatic tissue. This may explain why isolated toxic doses of ethanol are rarely if ever associated with pancreatitis.
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PMID:The effect of ethanol on enzyme synthesis and secretion in isolated rat pancreatic lobules. 244 46

The aim of this study was to evaluate the adverse effects on the exocrine pancreas of ethanol and ethanol with congeners which coexist in alcoholic beverages most commonly consumed by the Portuguese population. Eighteen male Wistar rats were divided into three groups and submitted to a daily intraperitoneal injection of a hydroalcoholic solution of ethanol (SHAE) and a hydroalcoholic solution of ethanol, acetaldehyde, methanol and higher alcohols (SHAF); the third group served as a control and received an equivalent volume of an isocaloric solution of dextrose. All the animals were sacrificed at the end of the 9th week of the experiment. The following histological lesions were considered: acinar cell necrosis and steatosis, ductal dilatation, intraluminal plugs, parenchymal inflammation, fibrosis, peripancreatic fat necrosis and inflammation. Their severity was graded by means of a scoring system. The histopathologic changes which characterize pancreatitis (acinar cell necrosis, parenchymal inflammation, fibrosis and peripancreatic fat necrosis and inflammation) were found in the majority of animals of both study groups, but in none of the control group. The lesions tend to be more frequent and severe in the group treated with ethanol and its congeners (SHAF) than in the SHAE group; these differences are statistically significant when necrosis, ductal dilatation and overall severity of lesions are considered. The results of this study suggest that in the pancreas the toxicity of ethanol is enhanced by interaction with other components of alcoholic beverages.
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PMID:[The effect of combined toxicity on the development of alcoholic pancreatic lesions. A long-term experimental trial]. 748 40

Free radical-mediated injury is believed to play a key role in the pathogenesis of acute pancreatitis (AP). Therefore, oxidative damage of proteins may be an important event in the development of AP. The present study was performed to investigate oxidative protein modification, quantified as 2,4-dinitrophenylhydrazine-reactive protein-carbonyls, during the time course of taurocholate-induced pancreatitis of the rat and to analyze oxidatively modified proteins by Western blotting. Protein modification in pancreatic homogenates was found as early as 30 min after induction of severe AP with 3% taurocholate preceding the elevation of serum amylase activity and the increase of malondialdehyde in the tissue. A correlation of protein-carbonyl contents to a score of pancreatic macroscopic alterations (r = .69) and to the wet weight/dry weight ratio (r = .65) was found. Infusion of 5% taurocholate resulted in fulminant AP with high lethality during the 24 h of the experiment. However, rats surviving showed significantly lower level of protein-carbonyls than animals that died between 20-24 h after AP induction. The quantitative data were confirmed by the intensity of immunostained protein-carbonyls. The present data show a rather uniform increase in the staining pattern not revealing single, selectively damaged proteins. The aldehydic product of lipid peroxidation 4-hydroxynonenal (HNE) is known for its reactivity towards proteins. Interestingly, an antibody raised against protein-bound HNE did not indicate an increased protein modification by this aldehyde. In conclusion, experimental AP is characterized by an early oxidative protein modification, possibly contributing to functional impairment of the pancreas. This protein alteration may not be mediated by HNE.
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PMID:Occurrence of oxidatively modified proteins: an early event in experimental acute pancreatitis. 943 51

Oxidative stress is considered to be a pathogenic factor for multisystem organ failure during acute pancreatitis. Infusion of 3% and 5% sodium taurocholate into the pancreatic duct of rats resulted in a 24-hr lethality of 8% and 82%, respectively. Kidney tissue showed a long-lasting significant elevation of malondialdehyde (lipid peroxidation). Only small amounts of this aldehyde were formed in the liver. In the lung malondialdehyde was increased during the first 6 hr after pancreatitis induction. Malondialdehyde levels were not different for pancreatitis initiated by 3% or 5% taurocholate. Protein-bound carbonyls (protein oxidation) in the tissues were not significantly changed at any time point. However, after infusion of 5% taurocholate, lung proteins were oxidatively modified by the product of lipid peroxidation, 4-hydroxynonenal. Another parameter characteristic for pancreatitis with high lethality was the high number of neutrophils in the lungs. We conclude that oxidative stress is important for the injury of extrapancreatic tissues during pancreatitis, but survival is determined by the degree of systemic inflammation.
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PMID:Differential oxidative injury in extrapancreatic tissues during experimental pancreatitis: modification of lung proteins by 4-hydroxynonenal. 1133 Apr 37

Exogenous acetaldehyde infusion can induce pancreatitis-like injury of the pancreas in some isolated pancreas models, whereas in vivo such treatment has failed to induce pancreatitis. In vivo exogenous acetaldehyde may not be effective because it is rapidly metabolized. The aim of this study was to investigate whether endogenous acetaldehyde accumulates in the pancreas after ethanol feeding when acetaldehyde metabolism is blocked by disulfiram, and whether this treatment can induce pancreatitis-like injury in the rat. The liver was studied for comparison. In part I of the experiment, adult male Wistar rats were given water (n = 24), ethanol (n = 24), disulfiram (n = 24), and ethanol plus disulfiram for 1 week (n = 24) or 3 weeks (n = 24) and for 3 weeks with (n = 6) and without (n = 6) hypovolemia. In part II of the experiment, rats were given water (n = 6), ethanol (n = 6), and high-dose disulfiram (n = 6) and ethanol plus high-dose disulfiram (n = 6). Ethanol and acetaldehyde concentrations in blood, liver, and pancreas were measured. Animal behavior was monitored, and weight changes, plasma amylase activity, water content, and histomorphology of the pancreas and liver were studied without knowing the group. No increases in plasma amylase activity and no histomorphologic changes in the pancreas were observed under light or electron microscopy in part I of the experiment. In part II, treatment with ethanol induced acetaldehyde accumulation in the liver (33.6 +/- 2.6 micromol/L), but to a lesser degree in the blood (9.6 +/- micromol/L) and pancreas (5.0 +/-.2 micromol/L). Ethanol plus disulfiram induced marked accumulation of acetaldehyde in the liver (83.2 +/- 15.9 micromol/L), blood (280.0 +/- 47.4 micromol/L), and pancreas (43.6 +/- 4.7 micromol/L). When tissue acetaldehyde levels reached 30 to 40 micromol/L, we found a decrease in zymogen granules along with formation of small intracytoplasmic vacuolizations in the acinar cells and accumulation of lipid droplets in the hepatocytes, whereas physiologic signs of pancreatitis (hyperamylasemia, edema) or increases in liver enzymes did not develop. High levels of acetaldehyde accumulate in the liver and pancreas with the treatment described. Although this was accompanied by lipid degeneration of the hepatocytes and some subcellular changes in the acinar cells, physiologic signs of pancreatitis did not develop. Thus acetaldehyde accumulation alone, or in combination with hypovolemia, is not responsible for the induction of acute pancreatitis.
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PMID:Effects on endogenous acetaldehyde production by disulfiram and ethanol feeding on rat pancreas. 1198 5

Long-term, heavy alcohol consumption is associated with both acute and chronic pancreatitis. Progression of pancreatitis may lead to multiple comorbidities including maldigestion, diabetes, and pancreatic cancer. Understanding the underlying molecular, biochemical, and cellular mechanisms by which alcohol ingestion leads to the development of pancreatitis may help to develop strategies for the treatment and prevention of the disease. The National Institute on Alcohol Abuse and Alcoholism and the Office of Rare Diseases of National Institutes of Health sponsored a satellite symposium on "Mechanisms of Alcoholic Pancreatitis" at the annual meeting of the American Pancreatic Association, Chicago, IL, November 2002. For this symposium, 8 speakers were invited to address the following issues: (1) epidemiology of alcoholic pancreatitis; (2) pathophysiology of alcoholic pancreatitis; (3) animal models of alcoholic pancreatitis--roles of cholecystokinin (CCK) and viral infections; (4) alcohol and zymogen activation in the pancreatic acinar cell; (5) role of alcohol metabolism in alcoholic pancreatitis; (6) pancreatic stellate cell activation in alcoholic pancreatitis; and (7) genetic predisposition to alcoholic chronic pancreatitis. It was concluded that alcohol abuse is a major contributory factor to the development of both acute and chronic pancreatitis. The injurious effects of ethanol on the pancreas may be mediated through (1) sensitization of acinar cells to CCK-induced premature activation of zymogens; (2) potentiation of the effect of CCK on the activation of transcription factors, nuclear factor kappaB (NF-kappaB) and activating protein-1 (AP-1); (3) generation of toxic metabolites such as acetaldehyde and fatty acid ethyl esters; (4) sensitization of the pancreas to the toxic effects of coxsackievirus B3; and (5) activation of pancreatic stellate cells by acetaldehyde and oxidative stress and subsequent increased production of collagen and other matrix proteins.
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PMID:Mechanisms of alcoholic pancreatitis. Proceedings of a conference. Chicago, Illinois, USA, November 2002. 1457 87

The pathogenesis of pancreatic fibrosis, a characteristic feature of alcohol-induced chronic pancreatitis, has received increasing attention over the past few years, largely due to the identification and characterization of stellate cells in the pancreas. These cells are morphologically similar to hepatic stellate cells, the principal effector cells in liver fibrosis. The role of pancreatic stellate cells (PSCs) in alcoholic pancreatic fibrosis has been studied using 2 approaches: (i) in vivo studies using pancreatic tissue from patients with alcohol-induced chronic pancreatitis and from animal models of experimental pancreatitis and (ii) in vitro studies using cultured PSCs. These studies indicate that PSCs are activated early in the course of pancreatic injury and are the predominant source of collagen in the fibrotic pancreas. Several factors that may be responsible for mediating PSC activation during chronic alcohol exposure have also been identified. From the findings to date, it may be speculated that the pathogenesis of alcoholic pancreatic fibrosis may involve 2 pathways: (i) a necroinflammatory pathway involving cytokine release and PSC activation and (ii) a nonnecroinflammatory pathway involving direct activation of PSCs by ethanol via its metabolism to acetaldehyde and the generation of oxidant stress.
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PMID:Stellate cell activation in alcoholic pancreatitis. 1457 94


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