Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.5.4.4 (adenosine deaminase)
5,136 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Deoxycytidylate (dCMP) deaminase, a hexameric allosteric enzyme induced on infection of Escherichia coli by bacteriophage T4, was shown to contain two atoms of zinc per subunit by atomic absorption spectroscopy. One zinc appears to be involved in catalysis, as described for adenosine deaminase (Sharaff, A. J., Wilson, D. K., Chang, Z., and Quiocho, F. A. (1992) J. Mol. Biol. 226, 917-921) and cytidine deaminase (Yang, C., Carlow, D., Wolfenden, R., and Short, S. A. (1992) Biochemistry 31, 4168-4174). This thesis is supported by the finding that the enzyme loses about 80% of its activity in the presence of o-phenanthroline. It has also been found that zinc is released when the enzyme is denatured in the presence of the metallochromic indicator, 4-(2-pyridylazo)resorcinol. Renaturation of the deaminase to an active form occurred in the presence but not in the absence of zinc. The second atom of zinc is proposed to be located in a region of T4-dCMP deaminase that resembles a zinc finger. This region, which has the sequence His-X3-Cys-X14-His-X3-His, would represent a zinc-binding motif that has not been described previously.
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PMID:T4-phage deoxycytidylate deaminase is a metalloprotein containing two zinc atoms per subunit. 842 2

Adenosine deaminase has been reported to bind the product inosine (the substrate for the reverse reaction) as inosine 1,6-hydrate considered similar in structure to the transition state for adenosine deamination (Wilson & Quiocho, 1994) Accumulation on the enzyme of inosine 1,6-hydrate would be surprising, because this compound is an actual intermediate, probably approaching the transition state, in oxygen exchange between water and the C==O group of inosine, a reaction previously shown to be catalyzed by adenosine deaminase (Wolfenden & Kirsch, 1968). The equilibrium constant for conversion of ES to ES*, in the oxygen exchange reaction, is less than 10-12. To investigate the structure of enzyme-bound inosine in a different way, we labeled deoxyinosine with 13C, excepting an upfield shift of 70-110 ppm if significant rehybridization to sp3 had occurred at the carbonyl group. Instead, the results show a very small shift (1.3 ppm), indicating that C-6 of 2'-deoxyinosine retains its sp2 hybridization after binding by calf intestinal adenosine deaminase. In a separate series of experiments, [4,5-13C]-2'-deoxyuridine was synthesized and found to retain its sp2 hybridization at C-4, after binding by Escherichia coli cytidine deaminase, an enzyme that catalyzes 18O exchange from water into uridine. These findings are consistent with the general expectation, based on the unfavorable equilibrium of activation of enzyme-bound substrates, that enzymes should not accumulate appreciable concentrations of intermediates whose free energies approach that of the transition state in substrate transformation.
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PMID:Enzyme-substrate complexes of adenosine and cytidine deaminases: absence of accumulation of water adducts. 866 59

Crystal structures of the cytidine deaminase-uridine product complex prepared either by cocrystallizing enzyme with uridine or by diffusing cytidine into ligand-free crystals show that the product binds as a 4-ketopyrimidine. They reveal four additional features of the catalytic process. (1) A water molecule bound to a site previously observed to bind the incoming 4-NH2 group represents the site for the leaving ammonia molecule. The conserved Pro 128 accommodates both moieties by orienting the carbonyl group of the previous residue. (2) The Glu 104 carboxylate group rotates from its hydrogen bond to the O4 hydroxyl group in transition-state analog complexes, forming a new hydrogen bond to the leaving group moiety. Thus, after stabilizing the hydroxyl group in the transition state, Glu 104 transfers a proton from that group to the leaving amino group, promoting enol-to-keto isomerization of the product. (3) Difference Fourier comparisons with transition-state complexes indicate that the pyrimidine ring rotates toward the zinc by approximately 10 degrees. The active site thus "pulls" the ring and 4-NH2 group in opposite directions during catalysis. To preserve coplanarity of the 4-keto group with the pyrimidine ring, the N1-C1' glycosidic bond bends by approximately 19 degrees out of the ring plane. This distortion may "spring-load" the product complex and promote dissociation. Failure to recognize a similar distortion could explain an earlier crystallographic interpretation of the adenosine deaminase-inosine complex [Wilson, D. K., & Quiocho, F. A. (1994) Nat. Struct. Biol. 1, 691-694]. (4) The Zn-Sgamma132 bond, which lengthens in transition-state complexes, shortens as the O4 atom returns to a state of lower negative charge in the planar product, consistent with our previous proposal that this bond buffers the zinc bond valence, compensating buildup of negative charge on the oxygen nucleophile during catalysis.
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PMID:The structure of the cytidine deaminase-product complex provides evidence for efficient proton transfer and ground-state destabilization. 912 97

Several transfer RNAs (tRNAs) contain inosine (I) at the first position of their anticodon (position 34); this modification is thought to enlarge the codon recognition capacity during protein synthesis. The tRNA-specific adenosine deaminase of Saccharomyces cerevisiae that forms I(34) in tRNAs is described. The heterodimeric enzyme consists of two sequence-related subunits (Tad2p/ADAT2 and Tad3p/ADAT3), both of which contain cytidine deaminase (CDA) motifs. Each subunit is encoded by an essential gene (TAD2 and TAD3), indicating that I(34) is an indispensable base modification in elongating tRNAs. These results provide an evolutionary link between the CDA superfamily and RNA-dependent adenosine deaminases (ADARs/ADATs).
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PMID:An adenosine deaminase that generates inosine at the wobble position of tRNAs. 1055 50

Cytosine deaminase (CD) catalyzes the deamination of cytosine, producing uracil. This enzyme is present in prokaryotes and fungi (but not multicellular eukaryotes) and is an important member of the pyrimidine salvage pathway in those organisms. The same enzyme also catalyzes the conversion of 5-fluorocytosine to 5-fluorouracil; this activity allows the formation of a cytotoxic chemotherapeutic agent from a non-cytotoxic precursor. The enzyme is of widespread interest both for antimicrobial drug design and for gene therapy applications against tumors. The structure of Escherichia coli CD has been determined in the presence and absence of a bound mechanism-based inhibitor. The enzyme forms an (alphabeta)(8) barrel structure with structural similarity to adenosine deaminase, a relationship that is undetectable at the sequence level, and no similarity to bacterial cytidine deaminase. The enzyme is packed into a hexameric assembly stabilized by a unique domain-swapping interaction between enzyme subunits. The active site is located in the mouth of the enzyme barrel and contains a bound iron ion that coordinates a hydroxyl nucleophile. Substrate binding involves a significant conformational change that sequesters the reaction complex from solvent.
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PMID:The structure of Escherichia coli cytosine deaminase. 1181 40

We evaluated serum total adenosine deaminase, its isoenzymes adenosine deaminase-1 and adenosine deaminase-2, and cytidine deaminase activities in 24 patients with active systemic lupus erythematosus, and in 26 healthy control subjects, and found the means +/- SD values to be 21.38 +/- 5.96 IU/l, 3.74 +/- 2.12 IU/l, 17.72 +/- 5.02 IU/l and 17.89 +/- 4.62 IU/l, respectively in the patients, and 14.97+/- 4.71 IU/l, 4.01 +/- 1.35 IU/l, 10.91 +/- 3.91 IU/l and 7.39 +/- 3.97 IU/l, respectively in the control subjects. When compared to the healthy controls, serum total adenosine deaminase, adenosine deaminase-2 and cytidine deaminase levels were significantly higher (p<0.001) in systemic lupus erythematosus patients, but the decrease of adenosine deaminase-1 level was not statistically significant (p>0.05). The increased adenosine deaminase-2 may be of macrophage origin. It closely correlated with clinical signs of active systemic lupus erythematosus. The membranes of polymorphonuclear neutrophils may be damaged, and cytidine deaminase may be released into serum. In conclusion, serum total adenosine deaminase, adenosine deaminase-2 and cytidine deaminase activities may serve as useful indicators for evaluating disease activity in patients with active systemic lupus erythematosus.
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PMID:Serum adenosine deaminase and cytidine deaminase activities in patients with systemic lupus erythematosus. 1211 94

Cytosine deaminase (CD) catalyzes the deamination of cytosine and is only present in prokaryotes and fungi, where it is a member of the pyrimidine salvage pathway. The enzyme is of interest both for antimicrobial drug design and gene therapy applications against tumors. The structure of Saccharomyces cerevisiae CD has been determined in the presence and absence of a mechanism-based inhibitor, at 1.14 and 1.43 A resolution, respectively. The enzyme forms an alpha/beta fold similar to bacterial cytidine deaminase, but with no similarity to the alpha/beta barrel fold used by bacterial cytosine deaminase or mammalian adenosine deaminase. The structures observed for bacterial, fungal, and mammalian nucleic acid deaminases represent an example of the parallel evolution of two unique protein folds to carry out the same reaction on a diverse array of substrates.
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PMID:The 1.14 A crystal structure of yeast cytosine deaminase: evolution of nucleotide salvage enzymes and implications for genetic chemotherapy. 1290 27

Of the human salvage enzymes that deaminate ribonucleosides, two--cytidine deaminase and adenosine deaminase--have been found particularly useful for diagnostic purposes. In humans, no enzymes are present that can directly deaminate the bases of these ribonucleosides. Indeed, the only enzyme present that can directly deaminate a base is guanine deaminase, and the diagnostic usefulness of this enzyme has been well documented. The aim of this study is to identify the origin of the ammonia formed when human sera and tissue extracts are incubated with buffered guanosine, and to clarify whether the ammonia comes from the deamination of guanosine by guanosine deaminase or is produced as a result of deamination of guanine formed as a breakdown product of guanosine by purine nucleoside phosphorylase (PNP). Apparent deamination of guanosine by guanosine deaminase in human sera and tissue extracts was found to be due to two enzymes acting in tandem when the products of the reaction were examined by HPLC. The ribose was first removed from guanosine by PNP to form guanine, which was then deaminated to xanthine by guanine deaminase.
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PMID:Guanosine deaminase in human serum and tissue extracts--a reappraisal of the products. 1472 35

Numerous studies have investigated the reproduction mechanisms in mollusc species at a biochemical and physiological level; few have described these mechanisms at a molecular level, despite great commercial interest in several mollusc species. We investigated genes involved in gonad maturation of the marine scallop Argopecten purpuratus. A cDNA library was made from gonad tissue. After sequence analysis, 418 unique genes were characterized, of these, about 80% were of unknown function. Among the identified sequences, we analyzed the mRNA expression by real-time PCR of 7 genes involved in reproduction mechanisms, either directly: testis-specific serine/threonine-protein kinase (TSSK), vitellogenin (Vg), and spermatogenesis and centriole associated 1 (SCA) or indirectly: calcineurin A (CNA), centrin, RNA-specific adenosine deaminase (ADAR), and cytidine deaminase (CDA). The real-time PCR analyses were conducted on different tissues of mature and immature scallops (testis, ovary, immature gonad, gill, digestive gland and mantle). The genes studied, presented (1) a strong tissue-dependent expression pattern (higher expression in gonad tissues than in all other tissues) and (2) a sex- and maturation-specific expression pattern (except centrin). This is the first time that the expression of specific genes involved in reproduction mechanisms in a marine mollusc has been described at the molecular level.
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PMID:Characterization of reproduction-specific genes in a marine bivalve mollusc: influence of maturation stage and sex on mRNA expression. 1797 28

Bacterial tRNA-specific adenosine deaminase (TadA) catalyzes the essential deamination of adenosine to inosine at the wobble position of tRNAs and is necessary to permit a single tRNA species to recognize multiple codons. The transition state structure of Escherichia coli TadA was characterized by kinetic isotope effects (KIEs) and quantum chemical calculations. A stem loop of E. coli tRNA(Arg2) was used as a minimized TadA substrate, and its adenylate editing site was isotopically labeled as [1'-(3)H], [5'-(3)H2], [1'-(14)C], [6-(13)C], [6-(15)N], [6-(13)C, 6-(15)N] and [1-(15)N]. The intrinsic KIEs of 1.014, 1.022, 0.994, 1.014 and 0.963 were obtained for [6-(13)C]-, [6-(15)N]-, [1-(15)N]-, [1'-(3)H]-, [5'-(3)H2]-labeled substrates, respectively. The suite of KIEs are consistent with a late SNAr transition state with a complete, pro-S-face hydroxyl attack and nearly complete N1 protonation. A significant N6-C6 dissociation at the transition state of TadA is indicated by the large [6-(15)N] KIE of 1.022 and corresponds to an N6-C6 distance of 2.0 A in the transition state structure. Another remarkable feature of the E. coli TadA transition state structure is the Glu70-mediated, partial proton transfer from the hydroxyl nucleophile to the N6 leaving group. KIEs correspond to H-O and H-N distances of 2.02 and 1.60 A, respectively. The large inverse [5'-(3)H] KIE of -3.7% and modest normal [1'-(3)H] KIE of 1.4% indicate that significant ribosyl 5'-reconfiguration and purine rotation occur on the path to the transition state. The late SNAr transition-state established here for E. coli TadA is similar to the late transition state reported for cytidine deaminase. It differs from the early SNAr transition states described recently for the adenosine deaminases from human, bovine, and Plasmodium falciparum sources. The ecTadA transition state structure reveals the detailed architecture for enzymatic catalysis. This approach should be readily transferable for transition state characterization of other RNA editing enzymes.
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PMID:Transition state structure of E. coli tRNA-specific adenosine deaminase. 1825 77


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