Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.1.1.1 (alcohol dehydrogenase)
 9,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The metabolism of ethanol to acetaldehyde proceeds in the liver via alcohol dehydrogenase (ADH) and the microsomal ethanol oxidizing system (MEOS), whereas catalase plays no significant role. ADH is localized in the cytosol, required required NAD+ as cofactor and exhibits a pH optimum in the alkaline range and a Km of less than 2 mM for ethanol. Conversely, the MEOS resides in the endoplasmic reticulum, requires NADPH and O2, is inhibited by CO, and exhibits a Km of about 10 mM for ethanol. The microsomal system also metabolizes higher aliphatic alcohols such as butanol which is not a substrate for catalase. Moreover, it could be separated from ADH and catalase by column chromatography. The MEOS exhibits a variety of properties similar to those of other microsomal drug metabolizing enzymes and is characterized by inducibility of its activity following chronic alcohol consumption, which suggests the involvement of the microsomal system in the adaptive enhancement of ethanol clearance commonly observed in alcoholics.
 ...
PMID:[Biochemical and pathophysiological aspects of alcohol metabolism (author's transl)]. 3 9

Rat liver microsomes oxidized ethanol two to three times faster than propanol when incubated with either an NADPH- or an H2O2-generating system. In addition, solubilized, purified microsomal subfractions were found to contain protein with an electrophoretic mobility identical to rat liver catalase on SDS polyacrylamide gels, suggesting that the separation of catalase from cytochrome P-450 and other microsomal components may not be feasible. These data support the postulate that catalase is responsible for NADPH-dependent microsomal ethanol oxidation. Direct read-out techniques for pyridine nucleotides, the catalase-H2O2 complex, and cytochrome P-450 were utilized to evaluate the specificity of inhibitors of alcohol dehydrogenase (4-methylpyrazole; 4 mM) and catalase (aminotriazole; 1.0 g/kg) qualitatively in perfused rat livers. 4-Methylpyrazole and aminotriazole are specific inhibitors for alcohol dehydrogenase and catalase, respectively, under these conditions. Neither inhibitor nor a combination of them altered the mixed function oxygen of p-nitroanisole to p-nitrophenol as observed by oxygen uptake and product formation. When ethanol utilization was measured over the concentration range 20-80 mM in perfused liver, a concentration dependence was observed. At low concentrations of ethanol, ethanol oxidation was almost totally abolished by 4-methylpyrazole; however, the contribution of 4-methylpyrazole-insensitive ethanol uptake increased as a function of ethanol concentration. At 80 mM ethanol, ethanol utilization was nearly 50% methylpyrazole-insensitive. This portion of ethanol oxidation, however, was abolished by aminotriazole. The data indicate that alcohol dehydrogenase and catalase-H2O2 are responsible for hepatic ethanol oxidation. At low ethanol concentrations (less than 20 mM), alcohol dehydrogenase is predominant; however, at higher ethanol concentrations (up to 80 mM), the contribution of catalase-H2O2 to overall ethanol utilization is significant. No evidence that the endoplasmic reticulum is involved in ethanol metabolism in the perfused liver emerged from these studies.
 ...
PMID:Significant pathways of hepatic ethanol metabolism. 24 Jul 43

Hepatic metabolism of ethanol to acetaldehyde by the alcohol dehydrogenase (ADH) pathway is associated with the generation of reducing equivalents as NADH. Conversely, reducing equivalents are consumed when ethanol oxidation is catalyzed by the NADPH dependent microsomal ethanol oxidizing system (MEOS). Since the major fraction of ethanol metabolism proceeds via ADH and since the oxidation of acetaldehyde also generates NADH, an excess of reducing equivalents is produced. This explains a variety of effects following acute ethanol administration, including hyperlactacidemia, hyperuricemia, enhanced lipogenesis and depressed lipid oxidation. To the extent that ethanol is oxidized by the alternate MEOS pathway, it slows the metabolism of other microsomal substrates. Following chronic ethanol consumption, adaptive microsomal changes prevail, which include enhanced ethanol and drug metabolism, and increased lipoprotein production. Eventually, injury develops with alterations of the rough endoplasmic reticulum and structural and functional abnormalities of the mitochondria.
 ...
PMID:Effect of chronic alcohol consumption on ethanol and acetaldehyde metabolism. 24 Dec 14

The object of the study was the liver of newborn rats. Specimens were taken from the 2nd to the 8th hour after birth. Tissue material was obtained from control animals and the newborns whose mothers had been ethanol fed throughout gestation period. 40% ethanol was administered in doses of 8.0 g/kg weight, by gastric tube. In the newborn liver ethanol ingestion had led to significant accumulation of lipids, a strong acid phosphatase reaction and to a drop in succinic dehydrogenase activity. Histochemically, the intensity of alcohol dehydrogenase activity did not show any difference when the ethanol treated newborn liver was compared with controls. Ultrastructurally, the changes in the liver cells were expressed by a disappearance of the rough endoplasmic reticulum elements. Mitochondria were often swollen and distorted.
 ...
PMID:Ethanol toxic effect on the newborn rat liver.--Histochemical and electronmicroscopical investigations. 74 9

The mechanisms by which ethanol inhibits testicular testosterone synthesis in rats were studied in vitro using isolated rat Leydig cells. The ethanol-induced inhibition was reversed by 4-methylpyrazole, an alcohol dehydrogenase inhibitor, suggesting that ethanol metabolism was responsible for this inhibition. L-glutamate and pyruvate, when added to the Krebs-Ringer incubation medium, reversed the inhibition by ethanol. The membrane glutamate receptor agonists kainic acid and quisqualic acid had no effects, indicating metabolic mechanisms for the L-glutamate action. This was verified also by observations that the metabolic transaminase inhibitors aminooxyacetate and cycloserine inhibited testosterone synthesis. In the amino acid supplemented Krebs-Ringer, pyruvate could not fully prevent inhibition by ethanol alone, but addition of L-glutamate to this medium abolished ethanol-induced inhibition. Experiments performed using a new inhibitor of testosterone biosynthesis in intact Leydig cells, triethylcitrate, indicated that active citrate metabolism, and/or efflux from mitochondria, was essential for the steroidogenic pathway from pregnenolone to testosterone in the smooth endoplasmic reticulum. The early steps of hCG stimulation before pregnenolone formation were most sensitive to its effect. Our results indicate that the inhibition of steroidogenesis by ethanol results from decreased availability of the metabolites involved in the substrate shuttles maintaining the NAD(P)H redox states between the mitochondrial and the smooth endoplasmic reticulum compartments, and that the inhibition can be overcome by a proper selection of exogenous sources for these metabolites.
 ...
PMID:Ethanol-induced inhibition of testosterone biosynthesis in rat Leydig cells: role of mitochondrial substrate shuttles and citrate. 198 8

Exposure of early third instar larvae of Drosophila melanogaster to a nonlethal dose of ethanol was detrimental to larvae lacking alcohol dehydrogenase (ADH) but beneficial to wild-type larvae in terms of surviving a later ethanol tolerance test, indicating that one of the important functions of the ADH system is to supply derivatives of ethanol to larvae that in turn promote ethanol tolerance. High intracellular concentrations of ethanol in ADH-deficient (Adhn2) larvae fed ethanol were accompanied by a decrease in the cell membrane infoldings of fat body cells, suggesting that the capacities to absorb and release molecules were reduced. Marked effects of ethanol on the endoplasmic reticulum and mitochondria of ADH-deficient larvae were also evident. The absence of similar changes in wild-type larvae that were fed moderate levels of ethanol showed that the ADH system kept the intracellular level of ethanol at a concentration low enough to avoid cell damage. A cytometric analysis of electron micrographs showed that there were ethanol-induced reductions in glycogen, lipid, and protein stores in the fat body cells of ADH-deficient larvae fed 1.25% ethanol (v/v) compared with null larvae fed an ethanol-free diet. This finding implied that the capacities to synthesize or store these compounds may be limited by high intracellular concentrations of ethanol. The cytometric analysis also revealed that the consumption of diets containing 2.5% and 4.5% ethanol by Canton-S wild-type larvae for 3 days after 4 days of feeding on an ethanol-free diet resulted in decreases in glycogen and protein deposits in fat body cells, but increased the amount of lipid deposits compared to larvae fed an ethanol-free diet. This observation, coupled with the greater weight of wild-type adults that were fed a growth-limiting concentration of ethanol compared with control adults, suggested that a metabolic defense mechanism in larvae is to convert toxic ethanol to nontoxic storage products. Dietary ethanol alone and in combination with isopropanol stimulated an increase in the size of the NAD-pool in larvae, a condition that may favor the activity of ADH. A low dietary level of isopropanol (1%) completely blocked glycogen deposition in wild-type larvae, whereas ethanol did not. Thus ethanol and isopropanol exert some different toxic effects on larval fat bodies.
 ...
PMID:Alcohol dehydrogenase and ethanol tolerance at the cellular level in Drosophila melanogaster. 249 60

A ketone reducing enzyme was purified to homogeneity from female mouse liver microsomes, using the diagnostic cytochrome P-450 inhibitor metyrapone as a substrate. In contrast to the usually employed indirect spectrophotometric recording of pyridine nucleotide oxidation at 340 nm, a HPLC method was applied for direct alcohol metabolite determination. Purification of the carbonyl reductase resulted in a 360-fold increase in specific activity together with a single band in the 34 kD region after SDS-polyacrylamide gel electrophoresis. Phenobarbital, indomethacin, dicoumarol and 5 alpha-dihydrotestosterone inhibited the enzyme, whereas quercitrin did not affect the enzyme activity. Thus, by inhibitor classification of carbonyl reductases the ketone metyrapone is reduced by an aldehyde reductase, rather than by a ketone reductase. Dihydrotestosterone, the strongest inhibitor, is supposed to be the physiological substrate for the purified enzyme. It was demonstrated that during the steps of purification both NADPH and NADH can supply the required reducing equivalents, although the activity with NADH is weaker. The highest activity was obtained using an NADPH-regenerating system. Ethanol and the nonionic detergent Emulgen 913 led to an increased specific activity, indicating that the enzyme is bound to the membranes of the endoplasmic reticulum in a latent state. From these results it is concluded that the microsomal metyrapone-reducing enzyme belongs to the family of carbonyl reductases, but differs from the common patterns of their classification with regard to cofactor requirement and inhibitor susceptibility.
 ...
PMID:Purification and properties of a metyrapone-reducing enzyme from mouse liver microsomes--this ketone is reduced by an aldehyde reductase. 267 47

Hepatocytes from 12-day-old rats, pre- and post-natally exposed to alcohol, together with those from pair-fed controls, were isolated and subfractionated in six cell subpopulations on Percoll density gradients. These cells were characterized using a combination of biochemical and stereological methods. The low density cells (F2) mainly showed biochemical and stereological features of perivenous hepatocytes, whereas the heavier cells (F6) were primarily periportal hepatocytes. The alcohol-metabolizing enzymes, alcohol dehydrogenase and aldehyde dehydrogenase (high and low Km) showed more activity in the F2 fraction. Alcohol-altered mitochondria and Golgi apparatus occurred mainly in F2 cells, whereas the endoplasmic reticulum and lysosomes appeared to be more altered in the F6 hepatocytes. Alcohol also induced the appearance of some small hepatocytes, with a well-developed rough endoplasmic reticulum and an increased number of mitochondria. Biochemical data indicated that glutamate dehydrogenase and alanine aminotransferase were more affected in F2 cells from alcohol-treated rats, and that the activity of the ethanol-metabolizing enzymes was alos reduced in these hepatocytes. Our results indicate that alcohol exposure during zonal development in the liver could have a selective effect on specific cell components depending on the acinar zone, and that the perivenous hepatocytes appear to be more damaged under these conditions.
 ...
PMID:A biochemical and stereological study of neonatal rat hepatocyte subpopulations. Effect of pre- and postnatal exposure to ethanol. 289 91

The metabolism of ethanol to acetaldehyde in the liver proceeds via alcohol dehydrogenase (ADH) and the microsomal ethanol-oxidizing system (MOS), whereas catalase plays no significant role. ADH is an enzyme of the cytosol, requires NAD+ as cofactor and exhibits a pH optimum in the alkaline range. The Km of ADH is about 2 mM for ethanol (equivalent to 0.1%). Thus, the enzyme is already saturated at low ethanol concentrations. Conversely, MEOS resides in the endoplasmic reticulum, requires NADPH and O2, is inhibited by CO and exhibits a km of about 10 mM corresponding to 0.5% ethanol. This enzyme system is therefore primarily the pathway of ethanol metabolism at intermediate to high ethanol concentrations. MEOS has many properties in common with other drug metabolizing enzymes and is characterized by inducibility following chronic ethanol consumption, which suggests the involvement of the microsomal system in the adaptive enhancement of ethanol clearance commonly observed in alcoholics. The product of ethanol oxidation by ADH, MEOS and catalase is acetaldehyde. Acetaldehyde is oxidized in the liver to acetate by NAD dependent aldehyde dehydrogenase. Four isozymes have been identified. Lack of isozyme I is responsible for the "flush-syndrome" commonly observed in asian people following alcohol intake. Ethanol metabolism is affected by the aging process and is decreased with advancing age.
 ...
PMID:[The biochemistry of alcohol metabolism]. 306 40

Maternal ethanol consumption produces a reduction in postnatal growth. We have studied especially changes of liver and brain. This reduction is more marked if the alcoholic offspring are maintained with their biological mothers than if they are kept with surrogate mothers. Rats exposed prenatally to alcohol show a marked accumulation of fat in the liver and a significant proliferation of liver endoplasmic reticulum. No change in the postnatal development of liver alcohol (ADH) and acetaldehyde dehydrogenases (ALDH) (high and low Km) is observed in offspring from alcoholic mothers, with the exception of slightly higher ALDH (low Km) for the offspring that remain with alcoholic mothers. The postnatal development of the liver (Na+-K+) ATPase is also similar in control and alcoholic groups. However, in the case of the enzyme from the brain, a lower ATPase activity is observed in the group derived from alcoholic mothers. Interestingly, at 20 days of postnatal period, an induction of the ATPase (from liver and brain) was observed when the group of offspring from alcoholic mothers were kept on an alcohol diet.
 ...
PMID:Effects of prenatal and postnatal exposure of rats to alcohol: changes in (Na+-K+) ATPase. 629 87


1 2 3 4 Next >>