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)

Malonamidase (MA) E2 was previously purified and characterized from Bradyrhizobium japonicum USDA 110. The gene encoding this enzyme has been cloned, sequenced and expressed in Escherichia coli. The recombinant MAE2 was purified to homogeneity from the transformed E. coli. The biochemical properties of the recombinant enzyme are essentially identical to those from wild-type B. japonicum. A database search showed that the MAE2 protein has a high sequence similarity with the common signature sequences of the amidase family. The only exception is that the aspartic residue in these signature sequences is replaced by a glutamine residue. In order to identify amino acid residues essential for enzyme activity, a series of site-directed mutagenesis studies and steady-state kinetic experiments were performed. Gln(195), Ser(199), Cys(207) and Lys(213) of the common signature sequences were selected for site-directed mutagenesis. Among the mutants, Q195D, Q195E and S199C showed less than 0.02% of the k(cat) value of the wild-type enzyme, and S199A, Q195L and Q195N exhibited no detectable catalytic activities. Mutants (K213L, K213R and K213H) obtained by replacement of the only conserved basic residue, Lys(213), in the signature sequences, also displayed significant reductions (approx. 380-fold) in k(cat) value, whereas C207A kept full activity. These results suggest that MAE2 may catalyse hydrolysis of malonamate by a novel catalytic mechanism, in which Gln(195), Ser(199) and Lys(213) are involved.
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PMID:Identification of active-site residues in Bradyrhizobium japonicum malonamidase E2. 1088 Mar 49

An anionic trypsin from pyloric caeca of chum salmon (Oncorhynchus keta) was purified by ammonium sulfate and acetone fractionation followed by affinity chromatography, gel-filtration, and DEAE-anion exchange chromatography. The apparent molecular mass was about 24 kDa as determined by SDS-PAGE. The anionic chum salmon trypsin was moderately active toward esterase substrates such as tosyl-L-arginine methyl ester and tosyl-L-lysine methyl ester. Its amidase activity for benzoyl-L-arginine p-nitroanilide was comparative to those of bovine and Streptomyces griseus trypsins. Kinetic characteristics of anionic chum salmon, bovine, and Streptomyces griseus trypsins toward inverse substrate (p-amidinophenyl ester) were compared. Inverse substrate behaved as a specific substrate for anionic chum salmon trypsin with specific binding, efficient acylation, and relatively slow deacylation.
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PMID:Anionic trypsin from chum salmon: activity with p-amidinophenyl ester and comparison with bovine and Streptomyces griseus trypsins. 1112 64

In an attempt to investigate the molecular basis of pyrazinamide hydrolysis by the PncA protein from Mycobacterium tuberculosis, we determined the pyrazinamidase activity of nine PncA mutants bearing a single amino acid substitution. Among them, three mutants (D8G, K96T and S104R) had virtually no activity (< or =0.004 unit/mg), five (F13S, T61P, P69L, Y103S and A146V) retained a low level of activity (0.06-0.25 unit/mg) and one (T167L) exhibited a wild-type activity (1.51 units/mg). The possible structural effects of these substitutions were assessed by analysing a three-dimensional model of the PncA protein constructed on the basis of the crystal structure of the N-carbamoylsarcosine amidohydrolase (CSHase) from Arthrobacter sp., an amidohydrolase which was found by hydrophobic cluster analysis to be closely related to PncA. In the PncA model, five of the mutated residues, Asp-8, Phe-13, Lys-96, Tyr-103 and Ser-104, were located within a 6 A sphere around the cysteine residue Cys-138, which could be the counterpart of the active cysteine residue Cys-177 found in the CSHase. Among the remaining mutated residues, Thr-61, Pro-69 and Ala-146 were found to be more distant from Cys-138 but were associated with structural elements contributing to the catalytic centre, whereas Thr-167 was situated in an alpha-helix located far from the putative active site. These data suggest that the decrease in pyrazinamidase activity observed in the PncA mutant proteins is well correlated with the structural modifications the mutations can cause in the environment of the putative active cysteine Cys-138.
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PMID:Study of the structure-activity relationships for the pyrazinamidase (PncA) from Mycobacterium tuberculosis. 1117 Oct 40

The N-carbamoyl-D-amino-acid amidohydrolase (D-NCAase) is used on an industrial scale for the production of D-amino acids. The crystal structure of D-NCAase was solved by multiple isomorphous replacement with anomalous scattering using xenon and gold derivatives, and refined to 1.95 A resolution, to an R-factor of 18.6 %. The crystal structure shows a four-layer alpha/beta fold with two six-stranded beta sheets packed on either side by two alpha helices. One exterior layer faces the solvent, whereas the other one is buried and involved in the tight intersubunit contacts. A long C-terminal fragment extends from a monomer to a site near a dyad axis, and associates with another monomer to form a small and hydrophobic cavity, where a xenon atom can bind. Site-directed mutagenesis of His129, His144 and His215 revealed strict geometric requirements of these conserved residues to maintain a stable conformation of a putative catalytic cleft. A region located within this cleft involving Cys172, Glu47, and Lys127 is proposed for D-NCAase catalysis and is similar to the Cys-Asp-Lys site of N-carbamoylsarcosine amidohydrolase. The homologous active-site framework of these enzymes with distinct structures suggests convergent evolution of a common catalytic mechanism.
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PMID:Crystal structure and site-directed mutagenesis studies of N-carbamoyl-D-amino-acid amidohydrolase from Agrobacterium radiobacter reveals a homotetramer and insight into a catalytic cleft. 1123 98

To clarify the substrate-recognition mechanism of carboxypeptidase Y, Fmoc-(Glu)n Ala-OH (n = 1 to 6), Fmoc-(Glu)n Ala-NH2 (1 to 5), and Fmoc-Lys(Glu)3Ala-NH2 were synthesized, and kinetic parameters for these substrates were measured. Km for Fmoc-peptides significantly decreased as peptide length increased from n = 1 to n = 5 with only slight changes in kcat. Km for Fmoc-(Glu)(5,6)Ala-OH were almost the same as one for protein substrates described previously (Nakase et al., Bull. Chem. Soc. Jpn., 73, 2587-2590). These results show that the enzyme has six subsites (S1' and S1-S5). Each subsite affinity calculated from the Km revealed subsite properties, and from the differences of subsite affinity between pH 6.5 and 5.0, the residues in each subsite were predicted. For Fmoc-peptide amide substrates, the priorities of amidase and carboxamide peptidase activities were dependent on the substrate. It is likely that the interactions between side chains of peptide and subsites compensate for the lack of P1'-S1' interaction, so the amidase activity prevailed for Fmoc-(Glu)(3,5)Ala-NH2. These results suggest that these subsites contribute extensively to substrate recognition rather than a hydrogen bond network.
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PMID:Substrate recognition mechanism of carboxypeptidase Y. 1179 20

The aliphatic amidase from Pseudomonas aeruginosa belongs to the nitrilase superfamily, and Cys(166) is the nucleophile of the catalytic mechanism. A model of amidase was built by comparative modelling using the crystal structure of the worm nitrilase-fragile histidine triad fusion protein (NitFhit; Protein Data Bank accession number 1EMS) as a template. The amidase model predicted a catalytic triad (Cys-Glu-Lys) situated at the bottom of a pocket and identical with the presumptive catalytic triad of NitFhit. Three-dimensional models for other amidases belonging to the nitrilase superfamily also predicted Cys-Glu-Lys catalytic triads. Support for the structure for the P. aeruginosa amidase came from site-direct mutagenesis and from the locations of amino acid residues that altered substrate specificity or binding when mutated.
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PMID:Support for a three-dimensional structure predicting a Cys-Glu-Lys catalytic triad for Pseudomonas aeruginosa amidase comes from site-directed mutagenesis and mutations altering substrate specificity. 1195 82

A large group of hydrolytic enzymes, which contain a conserved stretch of approximately 130 amino acids designated the amidase signature (AS) sequence, constitutes a super family that is distinct from any other known hydrolase family. AS family enzymes are widespread in nature, ranging from bacteria to humans, and exhibit a variety of biological functions. Here we report the first structure of an AS family enzyme provided by the crystal structure of malonamidase E2 from Bradyrhizobium japonicum. The structure, representing a new protein fold, reveals a previously unidentified Ser-cisSer-Lys catalytic machinery that is absolutely conserved throughout the family. This family of enzymes appears to be evolutionarily distinct but has diverged to acquire a wide spectrum of individual substrate specificities, while maintaining a core structure that supports the catalytic function of the unique triad. Based of the structures of the enzyme in two different inhibited states, an unusual action mechanism of the triad is proposed that accounts for the role of the cis conformation in the triad.
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PMID:Structure of malonamidase E2 reveals a novel Ser-cisSer-Lys catalytic triad in a new serine hydrolase fold that is prevalent in nature. 1203 64

To improve the stability of penicillin G acylase(PGA) from Bacillus megaterium, a three-dimensional model of B.megaterium PGA was constructed based on crystal structure of penicillin G acylase from E.coli using PMODELING program. The mutation of Lys at beta427 and 430 to Ala was predicted to enhance the stability of PGA in acidic or organic solvent environment. The results showed that 2 mutant PGA had similar specific activity and Km as the parent PGA. Their optimum pH dropped 0.5 pH units. The stability of Lys430Ala was enhanced obviously at pH 5.2. The half lives of Lys427Ala and Lys430Ala were improved by 60 % and 166 %, respectively, in comparison with the parent PGA.
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PMID:Enhancing Penicillin G Acylase Stability by Site-directed Mutagenesis. 1205 68

The peptide amidase from Stenotrophomonas maltophilia catalyses predominantly the hydrolysis of the C-terminal amide bond in peptide amides. Peptide bonds or amide functions in amino acid side-chains are not hydrolysed. This specificity makes peptide amidase (Pam) interesting for different biotechnological applications. Pam belongs to the amidase signature (AS) family. It is the first protein within this family whose tertiary structure has been solved. The structure of the native Pam has been determined with a resolution of 1.4A and in complex with the competitive inhibitor chymostatin at a resolution of 1.8A. Chymostatin, which forms acyl adducts with many serine proteases, binds non-covalently to this enzyme.Pam folds as a very compact single-domain protein. The AS sequence represents a core domain that is covered by alpha-helices. This AS domain contains the catalytic residues. It is topologically homologous to the phosphoinositol phosphatase domain. The structural data do not support the recently proposed Ser-Lys catalytic dyad mechanism for AS enzymes. Our results are in agreement with the role of Ser226 as the primary nucleophile but differ concerning the roles of Ser202 and Lys123: Ser202, with direct contact both to the substrate molecule and to Ser226, presumably serves as an acid/bases catalyst. Lys123, with direct contact to Ser202 but no contact to Ser226 or the substrate molecule, most likely acts as an acid catalyst.
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PMID:An alternative mechanism for amidase signature enzymes. 1236 28

We have attempted to efficiently obtain catalytic antibodies (catAbs) with amidase/esterase activity in the expanded sequence space of the antibody repertoire. In doing so, we used an autoimmune mouse strain, MRL/lpr, that is known to produce enhanced levels of autoantibodies. We applied different types of haptens, such as, and, that are supposed to mimic the transition state of the substrate in the ester/amide hydrolysis. Among them, hapten (2) could not be used, as it was readily broken down after synthesis. Upon immunization with hapten (1), catAbs preferentially evolved in MRL/lpr mice, but this did not happen upon immunization with haptens (3) and (4). Independently, immunization to MRL/lpr mice with successfully elicited the catAbs with the ability to activate vitamin B(6) prodrugs. The common observation seen in these two cases is that most of the catAbs derived from MRL/lpr mice by hapten (1) and half of them by hapten (5) had a Lys at H95, which is at the junctional N region between the V(H) and J(H) gene segments. Despite the conservation of Lys (H95), analyses of the N-region and utilization of the D gene segment in the heavy chain gene showed that these catAbs were from several independent clones of the same family. Studies of site-directed mutagenesis suggest that, in the catAbs elicited from hapten (1), a Lys (H95) and a His (L91) are involved in the catalytic function. Both residues are known to interact with the phosphonate moiety of hapten (1). Such studies also suggest that, in the catAbs elicited from hapten (5), a Lys (H95) and a His (H35) are involved in the catalytic function. These basic amino acids seem to be important for binding to the phosphonate hapten, as they were not changed even after extensive evolution following multiple mutations. By contrast, in normal BALB/c mice, immunization of hapten (1) resulted in eliciting catAbs in lower yield and the majority were the non-catAbs, whose sequences were quite different from those of the catAbs from MRL/lpr mice. They were clonally related to one another and most of them originated from a single clone. The positions of the interacting key residues in the CDRs that interact with the phosphorus moiety strongly differ between our catAbs and other reported catAbs with esterase/amidase activity, which were elicited by the phosphonate/phosphonamidate haptens from normal mice. Further comparison of antibodies elicited by the phosphorus haptens, such as DNA, RNA, phosphocholine, and phosphotyrosine, indicated that none of them had sequence similarity in the basic amino acids and their positions in the CDRs, except for one example, which is anti-DNA antibody elicited from C3H-lpr mice. Analysis based on the classification of canonical structures of the antibodies again suggested that our catAbs derived from MRL/lpr mice belong to an unusual class that is not listed in the literature. Taken together, the above evidence suggests that the unique catalytic subsets that existed in the initial repertoire in the MRL/lpr mice could effectively be captured by the phosphonate haptens through the interaction with the Lys at H95. In the BALB/c mice, however, another noncatalytic subset with an ability to bind only to a moiety other than the phosphonate moiety alternatively evolved, because of the lowest abundance or elimination of the catalytic subsets.
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PMID:Evolution of catalytic antibody repertoire in autoimmune mice. 1237 63

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