EC:3.5.1.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.5.1.4 (deaminase)
5,113 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Marked activity of cobalt-activated acylase was found in the sera of 33 of 37 patients with acute toxic hepatitis due to poisoning with either amanita mushrooms or chemicals. The activity of the enzyme showed a positive correlation with that of serum transaminases, reached the highest levels on the patient's admission to hospital and within a few days fell rapidly to undetectable levels. Slight acylase activity was observed in the majority of patients intoxicated with drugs or carbon monoxide but was not seen in sera of those poisoned with non-amanita mushrooms who showed no signs of liver injury. Unlike acylase, the serum activity of gamma-glutamyl transpeptidase remained unchanged over the first days of acute toxic hepatitis. The determination of serum cobalt-activated acylase might be of value in the diagnosis of acute liver injury.
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PMID:Serum cobalt-activated acylase and gamma-glutamyl transpeptidase activities in toxic hepatitis. 24 82

Iproniazid (1-isonicotinoyl-2-isopropylhydrazine), an antidepressant drug removed from clinical use because of hepatic injury, and isopropylhydrazine, a metabolite of iproniazid, were found to be potent hepatotoxins in rats. This animal model was used in studies in vivo and in vitro to define better the biochemical and chemical mechanism(s) by which iproniazid and isopropylhydrazine mediate hepatotoxicity. Phenobarbital, an inducer of a class of hepatic microsomal cytochrome P-450 enzymes, greatly potentiated the necrosis, whereas inhibitors of these microsomal enzymes such as cobalt chloride, piperonyl butoxide and alpha-naphthylisothiocyanate, prevented the necrosis. Bis-para-nitrophenyl phosphate, an inhibitor of esterase and amidase enzymes, prevented the necrosis caused by iproniazid but had no effect on the necrosis caused by isopropylhydrazine. Iproniazid and isopropylhydrazine labeled with tritium or carbon-14 in the isopropyl group were found to bind covalently to hepatic tissue macromolecules, and those pretreatments that increased hepatic necrosis significantly increased covalent binding, whereas those pretreatments which prevented necrosis significantly decreased covalent binding. Iproniazid labeled with tritium in the pyridine ring or carbon-14 in the carbonyl group did not bind significantly to hepatic tissue. Rats that were given iproniazid or isopropylhydrazine, labeled specifically with tritium and carbon-14 on the c-2 methine position of the isopropyl group, expired acetone and carbon dioxide labeled with carbon-14. More importantly, propane was expired and contained a ratio of 3H/14C that was identical to that in the administered iproniazid or isopropylhydrazine and also identical to the 3H/14C ratio of the metabolite that was covalently bound to hepatic tissue macromolecules. Experiments carried out with rat liver microsomes and isopropylhydrazine specifically labeled with deuterium, tritium and carbon-14 support the view that isopropylhydrazine is the metabolite of iproniazid that is oxidized by a microsomal P-450 enzyme to a species that alkylates tissue macromolecules. Some of the urinary metabolites excreted by rats that were administered hepatotoxic doses of iproniazid and isopropylhydrazine have been identified by cochromatography and isotope dilution with synthetic standards and by comparative mass spectra. Compounds excreted into the urine of rats dosed with iproniazid include iproniazid, iproniazid-1-oxide, isonicotinic acid, isonicotinoyl glycine, acetylisoniazid, isopropylhydrazine, 1-acetyl-2-isopropylhydrazine and acetone. Isopropylhydrazine, 1-acetyl-2-isopropylhydrazine, and acetone have been found in the urine of animals administered toxic doses of isopropylhydrazine.
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PMID:Hepatotoxicity and metabolism of iproniazid and isopropylhydrazine. 70 22

Pseudomonas fluorescens UK-1 has been incubated in basal mineral medium which was 0.5mM in pterine or pterine-6-carboxylic acid. During incubation the test organism splits the pteridine ring by liberating carbon dioxide from position 2. Glucose added to the medium greatly enhances both the growth of the organism and the carbon dioxide formation. Despite the structural similarities between pterine and pterine-6-carboxylic acid, only the degradation products derived from pterine are fluorescent in UV-light. Among the degradation products lumazine, pyrazine-2-carboxylic acid, and pyrazine-2-carboxamide have been identified. Also the activities of pterine deaminase and a carbon dioxide-liberating enzyme have been determined.
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PMID:Studies on the degradation of pterine and pterine-6-carboxylic acid by Pseudomonas fluorescens UK-1. 81 Oct 29

The phenylurea herbicide linuron is hydrolyzed by Bacillus sphaericus ATCC 12123 quantitatively forming 3,4-dichloroaniline, CO2, and N,O-dimethylhydroxylamine. The inducible enzyme responsible for this hydrolysis was purified to homogeneity as judged by polyacrylamide gel electrophoresis. Its molecular weight was 75 000 +/- 10%. Studies on its substrate specificity showed that either whole cells as the linuron-induced enzyme hydrolyze a large number of herbicidal and fungicidal acylanilides, the methoxysubstituted phenylureas and the phenylcarbamate propham at the carbonyl-aniline bond. This would classify the enzyme as an aryl acylamidase (E.C. 3.5.1). Hydrolysis of phenylamides by whole cells and by the enzyme is inhibited by different methylcarbamate and organophosphorus insecticides. Inhibition of hydrolysis of linuron by the aryl acylamidase by methylcarbamates is a competitive one.
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PMID:[Hydrolysis of methoxysubstituted phenylureas, acylanilides and phenylcarbamates by a microbial aryl acylamidase (author's transl)]. 99 41

Ureidoglycolate is an intermediate of allantoin catabolism in ureide-transporting legumes. This report describes the first purification of ureidoglycolate degrading activity (UGDA) from plant tissue in which the enzyme has been separated from urease. The enzyme from developing fruits of Phaseolus vulgaris has been purified 48-fold to give a preparation free of allantoinase and urease activity. UGDA was inhibited by EDTA while the Vmax was increased in the presence of Mn2+. The Km values for ureidoglycolate in the presence and the absence of Mn2+ were 2.0 and 5.4 mM, respectively. In the absence of Mn2+ UGDA was heat labile at 40 degrees C, but in the presence of Mn2+ the activity was stable up to temperatures of 60 degrees C. The Mr of UGDA was determined to be 300,000 by gel filtration chromatography and the pH optimum ranged from pH 7.0 to 8.5. Ammonia was determined to be the nitrogen-containing product of UGDA by a microdiffusion assay. This enzyme should therefore be described as ureidoglycolate amidohydrolase. The activity was shown to be associated with peroxisomes by fractionation of a crude extract on a sucrose density gradient. The products of ureidoglycolate degradation are glyoxylate, ammonia, and presumably carbon dioxide, which can be readily utilized by pathways of metabolism that are known to be present in this organelle.
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PMID:Ureidoglycolate amidohydrolase from developing French bean fruits (Phaseolus vulgaris [L.].). 191 Feb 98

The detrimental effects of excessive Ni on plant growth have been well known for many years. More recent evidence indicates that Ni is required in small amounts for normal plant growth and development. Ni is an essential component of urease in plants and microorganisms. A deficiency of Ni in plants is reported to result in necrotic lesions in leaves in response to toxic accumulations of urea. Urease plays an essential role in mobilization of nitrogenous compounds in plants, a process that is especially important during seed germination and fruit formation when protein reserves are degraded into amino acids. Arginine, an abundant amino acid in plants, when degraded produces urea as a product and urease is needed for urea utilization. Theories of urea formation during allantoin degradation in Glycine max have been recently refuted. In G. max ureides apparently are metabolized via an amidohydrolase reaction with subsequent degradation of ureidoglycine, yielding glyoxylate, NH+4 and CO2. No evidence is available for the formation of urea in this pathway. Nitrogen-fixing symbionts, such as Rhizobium and Bradyrhizobium, contain two known Ni enzymes: urease and hydrogenase. Optimum growth of nodulated legumes and actinorhizal plants may depend on an adequate supply of Ni to meet the requirements of the Ni-requiring enzymes in host plants and endophytes. The seeds of severely Ni-deficient Hordeum are completely inviable, thus providing conclusive evidence for the essentiality of Ni for this species. The evidence indicates that Ni must be added to the list of micronutrient elements generally required by plants.
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PMID:Nickel as a micronutrient element for plants. 307 27

N-Carbamoylsarcosine amidohydrolase, a novel enzyme involved in the microbial degradation of creatinine in Pseudomonas putida 77, was purified 27-fold to homogeneity with a 63% overall recovery through simple purification procedures including successive ammonium sulfate fractionation, DEAE-cellulose chromatography, and crystallization. The relative molecular mass of the native enzyme estimated by the ultracentrifugal equilibrium method is 102,000 +/- 5000, and the subunit Mr is 27,000. The Km and Vm values for N-carbamoylsarcosine are 3.2 mM and 1.75 units/mg protein, respectively. Ammonia, carbon dioxide, and sarcosine were formed stoichiometrically from N-carbamoylsarcosine through the action of the purified enzyme preparation. N-Carbamoyl amino acids with a methyl group or hydrogen atom on the amino-N atom and possessing glycine, D-alanine, or one of their derivatives as an amino acid moiety served well as substrates for N-carbamoylsarcosine amidohydrolase. N-Carbamoylsarcosine, N-methyl-N-carbamoyl-D-alanine, N-carbamoylglycine, and N-carbamoyl-D-alanine were hydrolyzed at relative rates of 100, 12.8, 9.8, and 7.3, respectively, by the enzyme. N-Carbamoyl derivatives of D-tryptophan, D-phenylalanine, and those of some other amino acids including D-phenylglycine and p-hydroxy-D-phenylglycine were also hydrolyzed by the enzyme. For the L-isomers of all N-carbamoyl amino acids tested there was no production of ammonia, carbon dioxide, or the corresponding amino acids due to the action of the enzyme. Cupric, mercuric, and silver ions inhibited the enzyme strongly, and some thiol reagents were also found to be inhibitory.
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PMID:Purification and characterization of a novel enzyme, N-carbamoylsarcosine amidohydrolase, from Pseudomonas putida 77. 374 68

The effects of an induced malignant hyperthermia (MH) crisis have been studied in the intact pig. Both physiological and biochemical changes in skeletal muscle were studied. MH was induced with 3% halothane plus a bolus injection of succinylcholine. In the prechallenge period a significant difference was observed in the concentration of certain muscle metabolites, comparing the MH-susceptible (MH+) with the non-susceptible (MH-) pigs. A lower level was measured for phosphocreatine (PCr), inosine monophosphate (IMP) and an increased level of lactate and creatine (Cr) in the susceptible pigs (MH+). The challenge caused a significant reduction of the level of PCr and adenosine in MH+ pigs, compared to the prechallenge period. After administration of dantrolene sodium, a significant decrease was measured in the level of lactate, compared to the prechallenge period as well as during the challenge. In contrast, in the control pigs no significant changes were observed in muscle metabolites, either after induction of MH or after the administration of dantrolene sodium. Enzyme activity determinations of muscle adenylate kinase and adenosine monophosphate (AMP)-deaminase did not show any difference in activity either before or during the MH crisis or after treatment with dantrolene sodium. The earliest physiological change during an induced MH crisis in our study was the rapid increase of the end-tidal CO2. Within 5 min after MH induction, end-tidal CO2 was doubled. It is concluded that the monitoring of the end-tidal CO2 is essential to diagnose MH at a very early stage.
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PMID:In vivo induced malignant hyperthermia in pigs. I. Physiological and biochemical changes and the influence of dantrolene sodium. 671 Dec 53

N-Carbamoyl-D-amino acid amidohydrolase was purified 119-fold, with 36% overall recovery from a cell-free extract of Comamonas sp. E222c. The purified enzyme was homogeneous as judged by SDS/PAGE. The relative molecular mass of the native enzyme was 120,000 and that of the subunit was 40,000. The purified enzyme hydrolyzed various N-carbamoyl-D-amino acids to D-amino acids, ammonia and carbon dioxide. N-Carbamoyl-D-amino acids having hydrophobic groups served as good substrates for the enzyme. The Km and Vmax values for N-carbamoyl-D-phenylalanine were 19.7 mM and 13.1 units/mg, respectively, and those for N-carbamoyl-D-p-hydroxyphenylglycine were 13.1 mM and 0.56 units/mg, respectively. The enzyme strictly recognized the configuration of the substrate and only the D-enantiomer of the N-carbamoyl amino acid was hydrolyzed. The enzyme activity was not significantly affected by N-carbamoyl-L-amino acids and ammonia. The enzyme was sensitive to thiol reagents and did not require metal ions for its activity. The enzyme did not hydrolyze N-carbamoyl-beta-alanine or N-carbamoyl-DL-aspartate suggesting that the enzyme is different from the N-carbamoylamide-hydrolyzing enzymes involved in the pyrimidine degradation pathway. The enzyme did not hydrolyze allantoin and allantoic acid, which are intermediates in purine degradation, N-carbamoylsarcosine and citrulline, suggesting that it is a novel N-carbamoylamide amidohydrolase.
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PMID:N-carbamoyl-D-amino acid amidohydrolase from Comamonas sp. E222c purification and characterization. 846 43

Pesticides based on the s-triazine ring structure are widely used in cultivation of food crops. Cleavage of the s-triazine ring is an important step in the mineralization of s-triazine compounds and hence in their complete removal from the environment. Cyanuric acid amidohydrolase cleaves cyanuric acid (2,4,6-trihydroxy-s-triazine), which yields carbon dioxide and biuret; the biuret is subject to further metabolism, which yields CO(2) and ammonia. The trzD gene encoding cyanuric acid amidohydrolase was cloned into pMMB277 from Pseudomonas sp. strain NRRLB-12227, a strain that is capable of utilizing s-triazines as nitrogen sources. Hydrolysis of cyanuric acid was detected in crude extracts of Escherichia coli containing the cloned gene by monitoring the disappearance of cyanuric acid and the appearance of biuret by high-performance liquid chromatography (HPLC). DEAE and hydrophobic interaction HPLC were used to purify cyanuric acid amidohydrolase to homogeneity, and a spectrophotometric assay for the purified enzyme was developed. The purified enzyme had an apparent K(m) of 0.05 mM for cyanuric acid at pH 8.0. The enzyme did not cleave any other s-triazine or hydroxypyrimidine compound, although barbituric acid (2,4, 6-trihydroxypyrimidine) was found to be a strong competitive inhibitor. Neither the nucleotide sequence of trzD nor the amino acid sequence of the gene product exhibited a significant level of similarity to any known gene or protein.
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PMID:Gene sequence and properties of an s-triazine ring-cleavage enzyme from Pseudomonas sp. strain NRRLB-12227. 1042 42

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