Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0015695 (fatty liver)
 13,941 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Two patients presenting with acute fatty liver of pregnancy were studied. Because of similarities between acute fatty liver of pregnancy and Reye's syndrome, we investigated hepatic ultrastructure, urea-cycle enzyme activities, and plasma amino acids. Initial liver biopsies obtained 12 and 21 days after the onset of illness demonstrated microvesicular fat deposition and mitochondrial ultrastructural changes, including pleomorphism and abundant crystalline inclusions. In both biopsies, activity of the mitochondrial urea-cycle enzyme OTC was markedly below normal limits. Activity of the other mitochondrial urea-cycle enzyme, CPS, was low in one patient. Abnormalities of these enzymes persisted in second biopsies obtained at 9 and 28 weeks, respectively. By 44 weeks all urea-cycle enzyme activities had returned to normal in one patient. However, in the other patient OTC activity was still reduced at 52 weeks, although it had doubled in comparison to previous biopsies. Morphological changes of the mitochondria generally improved in parallel with the urea-cycle enzymes. Plasma amino acids, obtained at the time of the initial biopsies, demonstrated a generalized hypoaminoacidemia with the exception of glutamate. Serial observations in patients with this rare disease indicate that there are similarities with Reye's syndrome, in particular, reduced activity of the mitochondrial urea-cycle enzymes. But there are important differences. (1) Enzymatic and ultrastructural abnormalities of mitochondria persist for a longer period of time than in Reye's syndrome. (2) Mitochondrial ultrastructure is different. (3) Plasma amino acid profiles are different.
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PMID:Abnormalities of hepatic mitochondrial urea-cycle enzyme activities and hepatic ultrastructure in acute fatty liver of pregnancy. 46 76

Previous studies in our laboratories have revealed that juvenile visceral steatosis mice show suppressed transcription of urea cycle enzyme genes during development and are systemically deficient in carnitine. It has not yet been explained, however, how this carnitine deficiency relates to the abnormal gene expression. We investigated the effect of carnitine on abnormal gene expression, growth retardation, and fatty liver. Carnitine administration relieved the suppression of the developmental induction of two urea cycle enzymes examined, carbamoyl-phosphate synthetase and argininosuccinate synthase, and kept the activities of enzymes normal. However, carnitine did not reduce accumulated lipid in the liver to the normal level. These results suggest that carnitine deficiency plays an important role in the abnormal expression of urea cycle enzyme genes and that the abnormal expression of the genes is not directly caused by lipid accumulation in the liver.
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PMID:Carnitine administration to juvenile visceral steatosis mice corrects the suppressed expression of urea cycle enzymes by normalizing their transcription. 154 87

High fructose consumption is associated with the development of fatty liver and dyslipidemia with poorly understood mechanisms. We used a matrix-assisted laser desorption/ionization-based proteomics approach to define the molecular events that link high fructose consumption to fatty liver in hamsters. Hamsters fed high-fructose diet for 8 weeks, as opposed to regular-chow-fed controls, developed hyperinsulinemia and hyperlipidemia. High-fructose-fed hamsters exhibited fat accumulation in liver. Hamsters were killed, and liver tissues were subjected to matrix-assisted laser desorption/ionization-based proteomics. This approach identified a number of proteins whose expression levels were altered by >2-fold in response to high fructose feeding. These proteins fall into 5 different categories including (1) functions in fatty acid metabolism such as fatty acid binding protein and carbamoyl-phosphate synthase; (2) proteins in cholesterol and triglyceride metabolism such as apolipoprotein A-1 and protein disulfide isomerase; (3) molecular chaperones such as GroEL, peroxiredoxin 2, and heat shock protein 70, whose functions are important for protein folding and antioxidation; (4) enzymes in fructose catabolism such as fructose-1,6-bisphosphatase and glycerol kinase; and (5) proteins with housekeeping functions such as albumin. These data provide insight into the molecular basis linking fructose-induced metabolic shift to the development of metabolic syndrome characterized by hepatic steatosis and dyslipidemia.
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PMID:Proteomic analysis of fructose-induced fatty liver in hamsters. 1864 Mar 90