Pseudomonas putida mutants defective in the metabolism of the products of meta fission of catechol and its methyl analogues.
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A selection procedure is described which was used to isolate mutants of Pseudomonas putida strain U in the following enzymes of the meta-fission pathway of phenol and cresols: hydrolase, tautomerase, and decarboxylase. Strains deficient in the hydrolase are unable to use either o- or m-cresol as a sole carbon source and were shown to accumulate 2-hydroxy-6-keto-2,4-heptadienoate when incubated in the presence of o- or m-cresol. When 2-hydroxymuconic semialdehyde (plus nicotinamide adenine dinucleotide, oxidized form) was metabolized by phenol-induced extracts of tautomerase-deficient strains, the enol tautomer of 4-oxalocrotonate accumulated and was then converted slowly to the keto tautomer by a nonenzymatic reaction. Phenol-induced extracts of decarboxylase-deficient strains accumulated the keto tautomer of 4-oxalocrotonate from 2-hydroxymuconic semialdehyde (plus nicotinamide adenine dinucleotide, oxidized form). Strains with an inactive decarboxylase are unable to completely metabolize either phenol or p-cresol. Tautomerase-defective strains are unable to grow with p-cresol as the sole carbon source and grow only very slowly on phenol. (+info)
Cross specificity in some vertebrate and insect glutathione-transferases with methyl parathion (dimethyl p-nitrophenyl phosphorothionate), 1-chloro-2,4-dinitro-benzene and s-crotonyl-N-acetylcysteamine as substrates.
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1. Enzymes catalysing the reaction between GSH and methylparathion (dimethyl p-nitrophenyl phosphorothionate), 1-chloro-2,4-dinitrobenzene and S-crotonyl-N-acetylcysteamine were separated by (NH(4))(2)SO(4) precipitation from homogenates of sheep, rat and mouse livers and from homogenates of cockroaches, houseflies and grass grubs. 2. Electrofocusing of the preparations from each of these species separated a number of zones, each of which catalysed the reaction of GSH with all three substrates. 3. Ion-exchange chromatography on CM-cellulose also separated a number of fractions in which activity towards the three substrates coincided. 4. In both separation methods patterns of the activities were consistent with the presence in all species of several GSH transferases each having a degree of cross specificity towards the three substrates. (+info)
Treatment of a neonate with propionic acidaemia and severe hyperammonaemia by peritoneal dialysis.
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A moribund newborn infant with propionic acidaemia and severe hyperammonaemia was successfully treated by peritoneal dialysis. The removal of ammonia and possibly additional toxic metabolites by peritoneal dialysis may be life-saving in newborn infants with propionic acidaemia or other hyperammonaemic syndromes. (+info)
Evidence for isofunctional enzymes in the degradation of phenol, m- and p-toluate, and p-cresol via catechol meta-cleavage pathways in Alcaligenes eutrophus.
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A study of the degradation of phenol, p-cresol, and m- and p-toluate by Alcaligenes eutrophus 345 has provided evidence that these compounds are metabolized via separate catechol meta-cleavage pathways. Analysis of the enzymes synthesized by wild-type and mutant strains and by strains cured of the plasmid pRA1000, which encodes m- and p-toluate degradation, indicated that two or more isofunctional enzymes mediated several steps in the pathway. The formation of three catechol 2,3-oxygenases and two 2-hydroxymuconic semialdehyde hydrolases was indicated from an examination of the ratio of the specific activities of these enzymes against various substrates. Evidence for two 2-hydroxymuconic semialdehyde dehydrogenases, two 4-oxalocrotonate isomerases and decarboxylases, and three 2-ketopent-4-enoate hydratases was derived from the induction of these enzymes under different growth conditions. Each activity was detected when the wild type was grown in the presence of m-toluate, but not when grown with phenol (except for a hydratase) or p-cresol, whereas in strains cured of pRA1000, growth with phenol or p-cresol, but not with m-toluate, induced these enzymes. Hydroxylation of phenol and p-cresol appears to be mediated by the same enzyme. (+info)
Catabolism of 2,4,5-trimethyoxybenzoic acid and 3-methoxycrotonic acid.
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4-Methoxygentisic acid was an intermediate formed when Arthrobacter degraded, 2,4,5-trimethoxybenzoic acid. Isolates of Pseudomonas and Arthrobacter from soil grew at the expense of 3-methoxycrotonic acid. Evidence is presented that enzymatic hydration, with elimination of methanol, accounted for replacement of the methoxyl group of 3-methoxycrotonic acid and also of one methoxyl group of 2,4,5-trimethoxybenzoic acid. (+info)
Mutant holocarboxylase synthetase: evidence for the enzyme defect in early infantile biotin-responsive multiple carboxylase deficiency.
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Biotin-responsive multiple carboxylase deficiency is an inherited disorder of organic acid metabolism in man in which there are deficiencies of propionyl-coenzyme A (CoA), 3-methylcrotonyl-CoA, and pyruvate carboxylases that can be corrected with large doses of biotin. It has been proposed that the basic defect in patients with the early infantile form of the disease is in holocarboxylase synthetase, the enzyme that covalently attaches biotin to the inactive apocarboxylases to form active holocarboxylases. We have developed an assay for holocarboxylase synthetase in extracts of human fibroblasts using as substrate apopropionyl-CoA carboxylase partially purified from livers of biotin-deficient rats. Fibroblasts from the initial patient with the infantile form of biotin-responsive multiple carboxylase deficiency were shown to have abnormal holocarboxylase synthetase activity with a maximum velocity about 30-40% of normal, a Km for ATP of 0.3 mM similar to the normal Km of 0.2 mM, and a highly elevated Km for biotin of 126 ng/ml, about 60 times the normal Km of 2 ng/ml. These results show that the primary defect in this patient is a mutation affecting holocarboxylase synthetase activity, and thus a genetic defect of the metabolism of biotin. (+info)
Phosphorylation of adenosine monophosphate in the mitochondrial matrix.
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The origin of the GTP needed for th phosphorylation of AMP in the mitochondrial matrix was investigated. When short-chain fatty acids are metabolized by hepatocytes, AMP is readily formed within the matrix by the butyryl-CoA ligase (AMP-forming) reaction (EC 6.2.1.2). The rate of matrix AMP formation in rat hepatocytes was calculated from the rate of ketone-body formation. The rate of the reconversion of matrix AMP into ADP by GTP-AMP transphosphorylase is limited by the rate of supply of GTP. GTP can be formed either by succinic thiokinase (EC 6.2.1.4) or by nucleoside diphosphokinase (EC 2.7.4.6). The rate of the succinic thiokinase reaction was calculated from turnover of the tricarboxylic acid cycle and this was calculated from the rate of O2 consumption and ketone-body formation. The results show that nucleoside diphosphokinase can make a major contribution (up to 80%) to the supply of GTP under the test conditions. (+info)
Fatty acid synthase, purified from lactating bovine mammary gland, utilizes coenzyme A esters of acetoacetic, 3-hydroxybutyric, and crotonic acids as substrates for its partial reactions at micromolar concentrations. The NADPH:acetoacetyl-CoA reductase had a Km of 5 microM acetoacetyl-CoA and a Vmax of about 4 mumol of NADPH oxidized min-1 mg-1. In contrast, the Km for the model compound, acetoacetyl pantetheine was 820 microM and that of S-acetoacetyl-N-acetylcysteamine was over 40 mM. The reduction of acetoacetyl-CoA was observed with the enzyme from rat tissues also but not with those from avian tissues or yeast. With the bovine mammary enzyme, the reaction was found to oxidize 2 mol of NADPH for every mol of acetoacetyl-CoA consumed. Butyrate was the major product of reduction. The reductase activity was susceptible to inhibition by several sulfhydryl reagents; it was lost when the synthase was dissociated into one-half molecular weight subunits or when the incubation mixture was depleted of CoA. It was competitively inhibited by acetyl-CoA, butyryl-CoA, methylmalonyl-CoA, and 2-methylcrotonyl-CoA. These results as well as its use as a primer in fatty acid synthesis by the enzyme suggest that the acetoacetyl group from acetoacetyl-CoA is transferred to the enzyme, presumably to its 4'-phosphopantheine prosthetic group. The acyl group is then expected to remain attached to the enzyme while it is reduced, dehydrated, and reduced again to form a butyryl group which can either undergo chain elongation, if malonyl-CoA is present, or be released from the enzyme by hydrolysis or transfer to free CoA. (+info)