Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.5.4.1 (cytosine deaminase)
 747 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Uptake and intracellular transformation of pyrimidines supplying cells of the yeast Rhodotorula glutinis with nitrogen have been studied. The amine nitrogen of cytosine was found to be the easiest to utilize. The presence in the medium of inorganic ammonia along with cytosine had a slight effect on cytosine deaminase (EC 3.5.4.1) activity. The uracil produced entered into the nutrient medium with no fission break of the pyridmidine ring. In the absence of any other source of nitrogen, the cells of the yeast R. glutinis utilized nitrogen of the pyrimidine ring of oxypyrimidines. Catabolism of uracil followed the reductive pattern, with release of carbon dioxide; this was accompanied by synthesis of the key enzyme of pyrimidine catabolism, dihydrouracil dehydrogenase (EC 1.3.1.1), whose activity rose 10-fold. With thymidne as the sole source of nitrogen, the lag-phase growth of the yeast cells was maximum. Catabolism of the pyrimidine ring of thymine was possibly preceded by its transformation into uracil. With no source of nitrogen easily utilized, the uridine 5'-monophosphate content in the generally acid-soluble pool rose. Our discussion of the regulation of catabolism of exogenous pyrimidine bases by the yeast R. glutinis takes into account the fact that transformations of pyrimidine bases are determined by how easily the cells can use a particular base as a source of nitrogen.
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PMID:Utilization of exogenous pyrimidines as a source of nitrogen by cells of the yeast Rhodotorula glutinis. 94 62

Cytosine deaminase, encoded by the codA gene in Escherichia coli catalyzes the deamination of cytosine to uracil and ammonia. Regulation of codA expression was studied by determining the level of cytosine deaminase in E. coli K12 grown in various defined media. Addition of either pyrimidine or purine nucleobases to the growth medium caused repressed enzyme levels, whereas growth on a poor nitrogen source such as proline resulted in derepression of cytosine deaminase synthesis. Derepression of codA expression was induced by starvation for either uracil or cytosine nucleotides. Nitrogen control was found to be mediated by the glnLG gene products, and purine repression required a functional purR gene product. Studies with strains harbouring multiple mutations affecting both pyrimidine, purine and nitrogen control revealed that the overall regulation of cytosine deaminase synthesis by the different metabolites is cumulative.
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PMID:Pyrimidine, purine and nitrogen control of cytosine deaminase synthesis in Escherichia coli K 12. Involvement of the glnLG and purR genes in the regulation of codA expression. 267 19

A novel metabolic pathway for the degradation of creatinine with N-methylhydantoin, N-carbamoylsarcosine and sarcosine as successive intermediates was found to operate in Pseudomonas putida 77 and many other microorganisms. Enzymes involved in this pathway were purified from cells of P. putida 77 and characterized. The first step, deimination of creatinine, is catalyzed by cytosine deaminase/creatinine deiminase. The following two steps, ring-opening of N-methylhydantoin and decarbamoylation of N-carbamoylsarcosine, are catalyzed by new enzymes, N-methylhydantoin amidohydrolase and N-carbamoylsarcosine amidohydrolase, respectively. The former requires ATP, Mg2+, and K+ for the hydrolysis and the reaction proceeds as follows: N-methylhydantoin + ATP + 2 H2O----N-carbamoylsarcosine + ADP + Pi. The latter catalyzes the following reaction; N-carbamoylsarcosine + H2O----sarcosine + NH3 + CO2. Sarcosine dehydrogenase was found to be the responsible enzyme for the oxidation of sarcosine to glycine in P. putida 77, but sarcosine oxidase was also found to be involved in this oxidation in several microorganisms. These enzymes were found to be useful tools for determination of creatinine.
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PMID:Microbial enzymes for creatinine assay: a review. 269 73

The Escherichia coli codBA operon encodes cytosine permease (CodB) and cytosine deaminase (CodA). CodB mediates uptake of exogenously supplied cytosine, and CodA catalyses the hydrolytic deamination of cytosine to uracil and ammonia. The hydropathic profile of CodB indicates that it is an integral cytoplasmic membrane protein possessing several transmembrane-spanning domains. The membrane topology of CodB was investigated by using gene fusions containing varying lengths of the amino-terminus of CodB fused to either alkaline phosphatase (AP) or beta-galactosidase (BG). The AP activities expressed by the CodB-AP fusions are consistent with a topological model in which the amino- and the carboxy-termini of CodB are located in the cytoplasm, and in which CodB possesses 12 membrane-spanning segments. The enzyme activities of most of the CodB-BG fusions support the model. However, the results obtained with some of the CodB-BG fusions illustrate the limitations of using BG as a reporter protein in studies of membrane protein topology.
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PMID:Membrane topology analysis of the Escherichia coli cytosine permease. 853 18

The functional assignment of enzymes that catalyze unknown chemical transformations is a difficult problem. The protein Pa5106 from Pseudomonas aeruginosa has been identified as a member of the amidohydrolase superfamily by a comprehensive amino acid sequence comparison with structurally authenticated members of this superfamily. The function of Pa5106 has been annotated as a probablechlorohydrolase or cytosine deaminase. A close examination of the genomic content of P. aeruginosa reveals that the gene for this protein is in close proximity to genes included in the histidine degradation pathway. The first three steps for the degradation of histidine include the action of HutH, HutU, and HutI to convert L-histidine to N-formimino-L-glutamate. The degradation of N-formimino-L-glutamate to L-glutamate can occur by three different pathways. Three proteins in P. aeruginosa have been identified that catalyze two of the three possible pathways for the degradation of N-formimino-L-glutamate. The protein Pa5106 was shown to catalyze the deimination of N-formimino-L-glutamate to ammonia and N-formyl-L-glutamate, while Pa5091 catalyzed the hydrolysis of N-formyl-L-glutamate to formate and L-glutamate. The protein Pa3175 is dislocated from the hut operon and was shown to catalyze the hydrolysis of N-formimino-L-glutamate to formamide and L-glutamate. The reason for the coexistence of two alternative pathways for the degradation of N-formimino-L-glutamate in P. aeruginosa is unknown.
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PMID:Annotating enzymes of unknown function: N-formimino-L-glutamate deiminase is a member of the amidohydrolase superfamily. 1647 88

Yeast cytosine deaminase (yCD), a zinc metalloenzyme of significant biomedical interest, is investigated by a series of molecular dynamics simulations in its free form and complexed with its reactant (cytosine), product (uracil), several reaction intermediates, and an intermediate analogue. Quantum chemical calculations, used to construct a model for the catalytic Zn ion with its ligands (two cysteines, a histidine, and one water) show, by comparison with crystal structure data, that the cysteines are deprotonated and the histidine is monoprotonated. The simulations suggest that Glu64 plays a critical role in the catalysis by yCD. The rotation of the Glu64 side-chain carboxyl group that can be protonated or deprotonated permits it to act as a proton shuttle between the Zn-bound water and cytosine and subsequent reaction intermediates. Free energy methods are used to obtain the barriers for these rotations, and they are sufficiently small to permit rotation on a nanosecond time scale. In the course of the reaction, cytosine reorients to a geometry to favor nucleophilic attack by a Zn-bound hydroxide. A stable position for a reaction product, ammonia, was located in the active site, and the free energy of exchange with a water molecule was evaluated. The simulations also reveal small motions of the C-terminus and the loop that contains Phe114 that may be important for reactant binding and product release.
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PMID:A molecular dynamics exploration of the catalytic mechanism of yeast cytosine deaminase. 1685 61

Pyrimidine salvage pathways are vital for all bacteria in that they share in the synthesis of RNA with the biosynthetic pathway in pyrimidine prototrophs, while supplying all pyrimidine requirements in pyrimidine auxotrophs. Salvage enzymes that constitute the pyrimidine salvage pathways were studied in 13 members of Pseudomonas and former pseudomonads. Because it has been established that all Pseudomonas lack the enzyme uridine/cytidine kinase (Udk) and all contain uracil phosphoribosyl transferase (Upp), these two enzymes were not included in this experimental work. The enzymes assayed were: cytosine deaminase [Cod: cytosine + H2O --> uracil + NH3], cytidine deaminase [Cdd: cytidine + H2O --> uridine + NH3], uridine phosphorylase [Udp: uridine + Pi <--> uracil + ribose - 1 - P], nucleoside hydrolase [Nuh: purine/pyrimidine nucleoside + H2O --> purine/pyrimidine base + ribose], uridine hydrolase [Udh: uridine/cytidine + H2O --> uracil/cytosine + ribose]. The assay work generated five different Pyrimidine Salvage Groups (PSG) designated PSG1 - PSG5 based on the presence or absence of the five enzymes. These enzymes were assayed using reverse phase high-performance liquid chromatography techniques routinely carried out in our laboratory. Escherichia coli was included as a standard, which contains all seven of the above enzymes.
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PMID:Pathways of pyrimidine salvage in Pseudomonas and former Pseudomonas: detection of recycling enzymes using high-performance liquid chromatography. 1796 97

The reaction mechanism of cytosine deaminase from Escherichia coli is studied using density functional theory. This zinc-dependent enzyme catalyzes the deamination of cytosine to form uracil and ammonia. The calculations give a detailed description of the catalytic mechanism and establish the role of important active-site residues. It is shown that Glu217 is essential for the initial deprotonation of the metal-bound water nucleophile and the subsequent protonation of the substrate. It is also demonstrated that His246 is unlikely to function as a proton shuttle in the nucleophile activation step, as previously proposed. The steps that follow are nucleophilic attack by the metal-bound hydroxide, protonation of the leaving group assisted by Asp313, and C-N bond cleavage. The calculated overall barrier is in good agreement with the experimental findings. Finally, the calculations reproduce the experimentally determined inverse solvent deuterium isotope effect, which further corroborates the suggested reaction mechanism.
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PMID:Reaction mechanism of zinc-dependent cytosine deaminase from Escherichia coli: a quantum-chemical study. 2483 16