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)

By recording the incubation time needed for initial appearance of the red and blue formazans the reliability of the histochemical method for 3beta-HSD was investigated: 1. Prefixation of small tissue blocks with 1% W/V methanol-free formaldehyde (pH=7.2) for up to 30 min preserved morphological integrity as well as maximal enzyme activity. Moreover, the substantivity of formazans and lipids was enhanced. 2. Commercial available glutaraldehyde (pH=7.2) induced SH groups in the tissue (even at 0.1% W/V for 5 min) thereby enhancing the Nothing dehydrogenase reaction. 3. Preextraction of lipids with acetone for 20 min at -30 degree C caused no loss of activity and was an inevitable step if a reliable activity pattern had to be achieved (e.g. in interstitial cells). 4. No diffusion of enzyme was noticed within 30 min of preincubation in phosphate buffer (0.2 M, pH=7.2) at 20 degree C. 5. By using the double-section incubation method no diffusion of 3beta-HSD or rediffusion of NADH or PMSH could be noticed withn 45 min of incubation, provided that low concentrations of NAD (0.1 mg/ml) and PMS (0.003 mg/ml) were balanced against the concentration of Nitro BT (0.5 mg/ml) or Tetranitro BT (1.0mg/ml). 6. The utlity of different inhibitors of alkaline phosphomonoesterase was tested and discussed. 7. By inhibiting alkaline phosphomonoesterase with 0.1 mM of L-p-bromotetramisole or 16 mM of beta-glycerophosphate, 3beta-HSD was shown to be exclusively NAD-linked. 8. Levamisole was a potent inhibitor of NADH-tetrazolium reductase as well as 3 beta-HSD, but not of NADPH-tetrazolium reductase. 9. 3beta-HSD possess SH groups requisite for the activity as this enzyme was totally inhibited by N-ethyl maleimide. 10. Whether alcohol dehydrogenases may use steroids as substrate is discussed; It is concluded that preextraction (by acetone) and/or the use of an inhibitor of alcohol dehydrogenase (1,10-phenanthroline) has to be performed. 11. Propylene glycol was a poor solvent for all substrates and was itself an excellent substrate for alcohol dehydrogenase. 12. Specifications for the ideal solvent of steroid substrates in the histochemical practice are proposed. DMSO showed to be promising as a steroid solvent (e.g. extraction of formazans was considerably lower as compared to DMF). 13. The utilization of substrates was descending in the following order (using 1 mM and 0.1 ml/ml of either DMF or DMSO): epiandrosterone, methandriol, dehydroepiandrosterone and pregnenolone. 14. If DMSO was used as solvent for pregnenolone (but not for the other substrates tested) an evident increase of activity was recorded as compared to DMF.
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PMID:Histochemistry of 3beta-hydroxysteroid dehydrogenase in rat ovary. I. Amethodological study. 55 64

The gene that encodes 1,2-propanediol oxidoreductase (fucO) from Escherichia coli was sequenced. The reading frame specified a protein of 383 amino acids (including the N-terminal methionine), with an aggregate molecular weight of 40,642. The induction of fucO transcription, which occurred in the presence of fucose, was confirmed by Northern blot analysis. In E. coli, the primary fucO transcript was approximately 2.1 kilobases in length. The 5' end of the transcript began more than 0.7 kilobase upstream of the fucO start codon within or beyond the fucA gene. Propanediol oxidoreductase exhibited 41.7% identity with the iron-containing alcohol dehydrogenase II from Zymomonas mobilis and 39.5% identity with ADH4 from Saccharomyces cerevisiae. These three proteins did not share homology with either short-chain or long-chain zinc-containing alcohol dehydrogenase enzymes. We propose that these three unusual alcohol dehydrogenases define a new family of enzymes.
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PMID:Similarity of Escherichia coli propanediol oxidoreductase (fucO product) and an unusual alcohol dehydrogenase from Zymomonas mobilis and Saccharomyces cerevisiae. 266 35

Eight dogs with ethylene glycol intoxication were treated with 4-methylpyrazole, an alcohol dehydrogenase inhibitor. Dogs had clinical signs referable to ethylene glycol ingestion including ataxia, depression, vomiting, polyuria, and dehydration. Metabolic abnormalities included high anion gap metabolic acidosis, serum hyperosmolality, isosthenuria, and monohydrate and dihydrate calcium oxalate crystalluria. Serum and urine ethylene glycol concentrations were determined to confirm ingestion of ethylene glycol. A 50-mg/ml solution of 4-methylpyrazole in propylene glycol was administered iv as follows: initial treatment, 20 mg/kg of body weight; at 17 hours after admission, 15 mg/kg; at 25 hours after admission, 5 mg/kg. By 24 hours after admission, all dogs had clinical and metabolic improvement. Of the 8 dogs, 7 were released within 3 days of admission. Four of the 8 dogs returned for follow-up evaluation, at which time biochemical or hematologic abnormalities were not observed.
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PMID:4-Methylpyrazole as treatment for naturally acquired ethylene glycol intoxication in dogs. 258 8

Intraperitoneal injection of 5 mumol of acetone/g, body weight, into 3 rats previously fed 1% acetone (v/v) in their drinking water resulted in the appearance in blood serum of 16 +/- 2 nmol of 1,2-propanediol/ml and 8 +/- 1 nmol of 2,3-butanediol/ml. No detectable 1,2-propanediol or 2,3-butanediol was found in the serum of animals after acetone or saline injection without prior addition of acetone to drinking water or in the serum of animals injected with saline after having been maintained on drinking water containing 1% acetone. These data suggest that acetone both acts to induce a critical enzyme or enzymes and serves as a precursor for the production of 1,2-propanediol. It is also clear from these data that chronic acetone feeding plays a role in 2,3-butanediol production in the rat. Microsomes isolated from the liver of animals maintained on drinking water supplemented with 1% acetone contained two previously unreported enzymatic activities, acetone monooxygenase which converts acetone to acetol and acetol monooxygenase which converts acetol to methylglyoxal. Both activities require O2 and NADPH. Prior treatment with acetone increased serum D-lactate from 9 nmol/ml +/- 9 nmol/ml in control animals to 77 +/- 36 nmol/ml in acetone-fed animals after injection with 5 mumol of acetone/g, body weight. This is consistent with methylglyoxal being a by-product of acetone metabolism. Two pathways for the conversion of acetone to glucose are proposed, the methylglyoxal and the propanediol pathways. The methylglyoxal pathway is responsible for the conversion of acetone to acetol, acetol to methylglyoxal, and the subsequent conversion of methylglyoxal to glucose. The propanediol pathway involves the conversion of acetol to L-1,2-propanediol by an as yet unknown process. L-1,2-Propanediol is converted to L-lactaldehyde by alcohol dehydrogenase, and L-lactaldehyde is converted to L-lactic acid by aldehyde dehydrogenase. Expression of these metabolic pathways in rat appears to be dependent on the induction of acetone monooxygenase and acetol monooxygenase by acetone.
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PMID:The metabolism of acetone in rat. 670 32

We used phase fluorometry to investigate the wavelength dependence of the fluorescence lifetimes of N-acetyl-L-tryptophanamide (NATA) in solvents of varying viscosity and the lifetimes of tryptophan in human serum albumin, melittin, and liver alcohol dehydrogenase. In highly fluid solvents, and in completely vitrified solvents, the lifetime of NATA was constant across its emission spectrum. In viscous solvents, such as propylene glycol at -9 degrees C, the lifetimes of NATA increased across its emission spectrum, with the values being 3.3, 5.5, and 8.1 ns at 317, 344, and 400 nm, respectively. These wavelength-dependent lifetimes appear to be a result of reorientations of solvent dipoles around the excited state dipole moment of the indole moiety. For the three proteins investigated, the fluorescence lifetimes of tryptophan increased with increasing wavelength in a manner comparable to that observed for NATA in propylene glycol. These observations indicate that these protein matrices can reorientation around their tryptophan residues on the nanosecond timescale, and illustrate the potential of phase fluorometry for quantifying the details of these dipolar relaxation processes.
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PMID:Dipolar relaxation in proteins on the nanosecond timescale observed by wavelength-resolved phase fluorometry of tryptophan fluorescence. 735 62

1,2-Propanediol (1,2-PD) is a major commodity chemical currently derived from propylene. Previously, we have demonstrated the production of enantiomerically pure (R)-1,2-propanediol from glucose by an engineered E. coli expressing genes for NADH-linked glycerol dehydrogenase and methylglyoxal synthase. In this work, we investigate three methods to improve 1,2-PD in E. coli. First, we investigated improving the host by eliminating production of a byproduct, lactate. To do this, we constructed strains with mutations in two enzymes involved in lactate production, lactate dehydrogenase and glyoxalase I. (Surprisingly, when mutations were made in its ability to produce lactate, one strain of E. coli [MM294], produced a small amount of 1,2-PD without any added genes.) Second, we constructed a complete pathway to 1,2-PD from the glycolytic intermediate, dihydroxyacetone phosphate. Our previous 1, 2-PD producing strains relied on at least one endogenous E. coli activity and only produced 0.7 g/L of 1,2-PD. The complete pathway involved the coexpression of methylglyoxal synthase (mgs), glycerol dehydrogenase (gldA), and either yeast alcohol dehydrogenase (adhI) or E. coli 1,2-propanediol oxidoreductase (fucO). Third, we investigated bioprocessing improvements by carrying out a fed-batch fermentation with the best engineered strain (expressing mgs, gldA, and fucO). A final titer of 4.5 g/L of (R)-1,2-PD was produced, with a final yield of 0.19 g of 1,2-PD per gram of glucose consumed. This work provides a basis for further strain and process improvement.
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PMID:Enhanced production of (R)-1,2-propanediol by metabolically engineered Escherichia coli. 1110 19

Laboratory-reared males of the cactophilic Drosophila pachea exhibit a spontaneous and sex-specific suppression of alcohol dehydrogenase (ADH) activity within 4 days after eclosion. A lack of ADH activity also is usually seen in wild-caught males, although relatively high activity is always seen in female flies. In the present study we examined the effectiveness of different alcohols and related compounds, including several found naturally in necroses of the host cactus, to induce suppressed ADH activity in wild males of D. pachea and to serve as enzyme substrates. The primary alcohols (methanol, ethanol, 1-propanol, 1-butanol, and 1-pentanol), and the secondary alcohols (2-propanol and 2-butanol), each induced activity after 24 h exposure, although to different degrees. 1,2-Propanediol was usually effective as an inducer, but 2,3-butanediol usually was ineffective. Little or no induction was seen with 1-octanol, 2-pentanol, 3-methyl-1-butanol, 3-hydroxy-2-butanone, or acetaldehyde. Although the compounds tested varied in their ability to function as ADH substrates, methanol was the only alcohol that showed no activity staining. Ethanol induction of ADH activity was apparent after 3-6 h exposure and induced activity decreased dramatically within 1 week of flies being placed in an alcohol-free environment. Ethanol exposure did not induce ADH in adult female D. pachea, or in adult males and females of D. acutilabella in which control males show reduced ADH activity compared to females. The implications of the loss of ADH activity in adult males of D. pachea, as they relate to feeding ecology and fitness, are discussed.
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PMID:Induction of suppressed ADH activity in Drosophila pachea exposed to different alcohols. 1499 29

The National Toxicology Program (NTP) Center for the Evaluation of Risks to Human Reproduction (CERHR) conducted an evaluation of the potential for propylene glycol (PG) to cause adverse effects on reproduction and development in humans. PG was selected for evaluation because of the potential for widespread human exposure through its use in food, tobacco, pharmaceutical products, cosmetics, various paints and coatings and as an antifreeze and de-icing solution. PG is a small, hydroxy-substituted hydrocarbon used as a chemical intermediate in the production of unsaturated polyester resins and in the production of plasticizers. The results of this evaluation on PG are published in an NTP-CERHR monograph which includes: 1) the NTP Brief, 2) the Expert Panel Report on the Reproductive and Developmental Toxicity of Propylene Glycol, and 3) public comments received on the Expert Panel Report. As stated in the NTP Brief, the NTP reached the following conclusions regarding the possible effects of exposure to PG on human development and reproduction. There is negligible concern for adverse developmental and reproductive effects in humans at current, proposed, or estimated exposure levels. There is no direct evidence that exposure of people to PG adversely affects reproduction or development. Studies in pregnant laboratory animals at oral doses of PG greater than 1,200 mg/kg body weight/ day and up to 10,400 mg/kg body weight/day in mice, did not produce developmental toxicity in offspring. In a continuous breeding study, no effects on fertility were observed in male or female mice at doses up to 10,100 mg/kg body weight/day in drinking water. The pharmacokinetics of PG indicates that the lack of adverse effects observed in laboratory animals is relevant to humans. The rate-limiting step in PG metabolism is conversion to the more toxic lactaldehyde product by alcohol dehydrogenase. Studies indicate that this enzyme saturates in humans at doses 8-10- fold lower than in rats and rabbits, thus affording less toxicity in humans. It is estimated that the average daily intake of PG from food products in the US is 34 mg/kg body weight/day for a 70 kg person, which is over 300 -fold lower than the highest dose tested in laboratory animals. NTP-CERHR monographs are transmitted to federal and state agencies, interested parties, and the public and are available in electronic PDF format on the CERHR web site (http://cerhr.niehs.nih.gov) and in printed text or CD-ROM from the CERHR (National Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-32, Research Triangle Park, NC; fax: 919-316-4511).
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PMID:NTP-CERHR Monograph on the Potential Human Reproductive and Developmental Effects of Propylene Glycol (PG). 1599 35

Two bacterial consortia growing on a random copolymer of ethylene glycol and propylene glycol units were obtained by enrichment cultures from various microbial samples. Six major strains included in both consortia were purified and identified as Sphingomonads, Pseudomonas sp. and Stenotrophomonas maltophilia. Three of them (Sphingobium sp. strain EK-1, Sphingopyxis macrogoltabida strain EY-1, and Pseudomonas sp. strain PE-2) utilized both PEG and polypropylene glycol (PPG) as a sole carbon source. Four PEG-utilizing bacteria had PEG dehydrogenase (PEG-DH) activity, which was induced by PEG. PCR products from DNA of these bacteria generated with primers designed from a PEG-DH gene (AB196775 for S. macrogoltabida strain 103) indicated the presence of a sequence that is the homologous to the PEG-DH gene (99% identity). On the other hand, five PPG-utilizing bacteria had PPG dehydrogenase (PPG-DH) activity, but the activity was constitutive. PCR of a PPG-DH gene was performed using primers designed from a polyvinyl alcohol dehydrogenase (PVA-DH) gene (AB190288 for Sphingomonas sp. strain 113P3) because a PPG-DH gene has not been cloned yet, but both PPG-DH and PVA-DH were active toward PPG and PVA (Mamoto et al. 2006). PCR products of the five strains did not have similarity to each other or to oxidoreductases including PVA-DH.
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PMID:Isolation of bacteria able to grow on both polyethylene glycol (PEG) and polypropylene glycol (PPG) and their PEG/PPG dehydrogenases. 1704 22

Alcohol-related intoxications, including methanol, ethylene glycol, diethylene glycol, and propylene glycol, and alcoholic ketoacidosis can present with a high anion gap metabolic acidosis and increased serum osmolal gap, whereas isopropanol intoxication presents with hyperosmolality alone. The effects of these substances, except for isopropanol and possibly alcoholic ketoacidosis, are due to their metabolites, which can cause metabolic acidosis and cellular dysfunction. Accumulation of the alcohols in the blood can cause an increment in the osmolality, and accumulation of their metabolites can cause an increase in the anion gap and a decrease in serum bicarbonate concentration. The presence of both laboratory abnormalities concurrently is an important diagnostic clue, although either can be absent, depending on the time after exposure when blood is sampled. In addition to metabolic acidosis, acute renal failure and neurologic disease can occur in some of the intoxications. Dialysis to remove the unmetabolized alcohol and possibly the organic acid anion can be helpful in treatment of several of the alcohol-related intoxications. Administration of fomepizole or ethanol to inhibit alcohol dehydrogenase, a critical enzyme in metabolism of the alcohols, is beneficial in treatment of ethylene glycol and methanol intoxication and possibly diethylene glycol and propylene glycol intoxication. Given the potentially high morbidity and mortality of these intoxications, it is important for the clinician to have a high degree of suspicion for these disorders in cases of high anion gap metabolic acidosis, acute renal failure, or unexplained neurologic disease so that treatment can be initiated early.
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PMID:Toxic alcohol ingestions: clinical features, diagnosis, and management. 1804 60


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