Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:6.3.4.6 (urease)
 7,490 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Uninduced cultures of Saccharomyces cerevisiae exhibit high basal levels of allantoinase, allantoicase, and ureidoglycolate hydrolase, the enzymes responsible for degrading allantoin to urea. As a result, these activities increase only 4- to 8-fold upon induction, whereas the urea-degrading enzymes, urea carboxylase and allophanate hydrolase, have very low basal levels and routinely increase 30-fold on induction. Differences in the inducibility of these five enzymes were somewhat surprising because they are all part of the same pathway and have the same inducer, allophanate. Our current studies reconcile these observations. S. cerevisiae normally contained up to 1 mM allantoin sequestered in a cellular organelle, most likely the vacuole. Separation of the large amounts of allantoin and the enzymes that degrade it provide the cell with an efficient nitrogen reserve. On starvation, sequestered allantoin likely becomes accessible to these degradative enzymes. Because they are already present at high levels, the fact that their inducer is considerably removed from the input allantoin is of little consequence. This suggests that at times metabolite compartmentation may play an equal role with enzyme induction in the regulation of allantoin metabolism. Metabolism of arginine, another sequestered metabolite, must be controlled both by induction of arginase and compartmentation because arginine serves both as a reserve nitrogen source and a precursor of protein synthesis. The latter function precludes the existence of high basal levels of arginase.
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PMID:Metabolite compartmentation in Saccharomyces cerevisiae. 35 30

Cell-free extracts prepared from Pseudomonas aeruginosa cells, cultured in a medium containing allantoin as sole nsource of carbon, nitrogen and energy and harvested in the stationary phase, contain an enzymicly inactive allantoinase-inhibitor complex. Pure inhibitor was isolated by dissociation of this complex followed by gelfiltration. The inhibitor had a molecular weight of about 5500 daltons. Association between inhibitor and allantoinase was demonstrated by gelfiltration and by polyacrylamide gel-electrophoresis. The inhibitor was unstable in the absence of 1 M urea and the inactivation was accompanied by aggregate formation and appearance of urease activity. The inhibitor was also isolated from cells containing urease but no allantoinase. It was concluded that the inhibitor is a subunit of urease. Inhibitors isolated from P. aeruginosa and P. acidovorans cells were active against both allantoinase from P. aeruginosa and allantoinase from P. acidovorans.
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PMID:Inactivation of allantoinase from Pseudomonas aeruginosa by a subunit of urease. 82 28

The break-down of benzamide, acetamide, malonamide and allantoin in M. smegmatis was investigated. It has been stated that the uptake of liberated NH3 into the cells, favoured by the presence of an organic acid, occasionally results in a negative NH3 determination. This difficulty can be overcome by an increase of the substrate concentration from 0.8 up to 4 mM. All antoinase activity in mycobacteria can be demonstrated only by an NH3 determination, when all the enzymes necessary for the complete break-down of allantoin are present. Bacteria containing allantoinase but not urease will be negative in this test. Using high amide concentrations (4 mM) some doubtful results concerning the degradation of acetamide, benzamide, nicotinamide and pyrazinamide can be eliminated as could be demonstrated for different strains of mycobacteria.
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PMID:Biochemical background of some enzymatic tests used for the differentiation of mycobacteria. 96 Feb 26

Seven Bacillus strains including one of the original Bacillus fastidiosus strains of Den Dooren de Jong could grow on urate, allantoin, and, except one, on allantoate. No growth could be detected on adenine, guanine, hypoxanthine, xanthine, and on degradation products of allantoate. Some strains grew very slowly in complex media. The metabolic pathway from urate to glyoxylate involved uricase, S(+)-allantoinase, allantoate amidohydrolase, S(-)-ureidoglycolase, and, in some strains, urease.
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PMID:Uric acid degradation by Bacillus fastidiosus strains. 124 68

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

Five mutants were isolated at the all2 gene on the basis of their inability to utilize hypoxanthine as a sole source of nitrogen. These mutants failed to utilize the purines adenine, hypoxanthine, xanthine, uric acid, allantoin and allantoic acid, although they could utilize urea and ammonium. The all2 mutants appeared to be defective in purine induction of uricase, allantoinase, allantoicase and ureidoglycollase activities but retained wild-type activity of the constitutively synthesized urease. The all2 mutations were recessive.
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PMID:The all2 gene is required for the induction of the purine deamination pathway in Schizosaccharomyces pombe. 402 Mar 41

The wild-type strain of Neurospora crassa Em 5297a can utilize allantoin as a sole nitrogen source. The pathway of allantoin utilization is via its conversion into allantoic acid and urea, followed by the breakdown of urea to ammonia. This is shown by the inability of the urease-less mutant, N. crassa 1229, to grow on allantoin as a sole nitrogen source and by the formation of allantoate and urea by pre-formed mycelia of this mutant. In the wild strain (Em 5297a) thiourea is tenfold more toxic on an allantoin medium than on an inorganic nitrogen medium; allantoin as well as urea counteract thiourea toxicity in the allantoin nitrogen medium. This selective toxicity of thiourea for the mould utilizing allantoin nitrogen does not, however, result in an impairment of allantoin uptake, allantoinase activity or the formation of urea from allantoin. The only process affected by thiourea is the synthesis of urease; urea antagonizes this effect of thiourea in N. crassa.
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PMID:The effect of thiourea on ureide metabolism in Neurospora crassa. 427 57

Saccharomyces cerevisiae can degrade allantoin in five steps to glyoxylate, ammonia, and "CO(2)." We previously demonstrated that synthesis of the urea carboxylase-allophanate hydrolase multienzyme complex is contingent upon the presence of allophanic acid, the product of the urea carboxylase reaction. Since these enzymes catalyze the last two reactions of allantoin degradation, experiments were performed to establish whether or not the presence of allophanic acid was required for synthesis of any other enzymes participating in this degradative pathway. The data presented here indicate that allophanic acid is required for synthesis of all enzymes participating in allantoin degradation. This conclusion is based upon the observation that: (i) wild-type strains produced a large amount of allantoinase upon addition of allantoin, allantoate, ureidoglycolate, or urea to the medium, (ii) no increase in activity was observed unless the added compound could be metabolized to allophanate, (iii) strains lacking allophanate hydrolase contained large amounts of allantoinase even in the absence of added urea, and (iv) the urea analogue, formamide, was capable of inducing allantoinase synthesis in wild-type strains but would not serve this function in a strain lacking urea carboxylase.
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PMID:Induction of the allantoin degradative enzymes in Saccharomyces cerevisiae by the last intermediate of the pathway. 459 22

Hyphomicrobium species are able to use allantoin as a nitrogen source for growth. Allantoin is broken down to glyoxylate and ammonia by the consecutive action of allantoinase, allantoicase, ureidoglycolase and urease.
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PMID:Metabolism of allantoin in Hyphomicrobium species. 733 36

It is generally accepted that all of the allantoin-degrading enzymes (allantoinase, allantoicase, ureidoglycollate lyase and urease), used in purine degradation, were lost during mammalian evolution. However, surprisingly, ureidoglycollate lyase has been found in a mammalian tissue. Ureidoglycollate lyase was purified to homogeneity and characterized from rat-liver mitochondria. The apparent Km (17 mM) of the rat enzyme for ureidoglycollate was much higher than that (0.33 mM) of fish-liver ureidoglycollate lyase. The rat-liver enzyme differed from the fish-liver enzyme in enzymic, physical and immunological properties.
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PMID:Degradation of purines: only ureidoglycollate lyase out of four allantoin-degrading enzymes is present in mammals. 749 31


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