EC:1.12.7.2 - FACTA Search

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Query: EC:1.12.7.2 (hydrogenase)
3,522 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Methanol:5-hydroxybenzimidazolylcobamide methyltransferase from Methanosarcina barkeri has been purified to approximately 90% homogeneity by ion-exchange chromatography on DEAE-cellulose and QAE-A50 Sephadex columns. The molecular weight, estimated by gel electrophoresis, was found to be 122,000, and the enzyme contained two different subunits with molecular weights of 34,000 and 53,000, which indicates an alpha 2 beta structure. The enzyme contains three or four molecules of 5-hydroxybenzimidazolylcobamide, which could be removed by treatment of the enzyme with 2-mercaptoethanol or sodium dodecyl sulfate. In both cases the enzyme dissociated into its subunits. For stability, the enzyme required the presence of divalent cations such as Mg2+, Mn2+, Sr2+, Ca2+, or Ba2+. ATP, GTP, or CTP was needed in a reductive activation process of the enzyme. This activation was brought about by a mixture of H2, ferredoxin, and hydrogenase, but also by CO, which is thought to reduce the corrinoid chemically. The CO dehydrogenase-like activity of the methyltransferase is discussed.
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PMID:Purification and properties of methanol:5-hydroxybenzimidazolylcobamide methyltransferase from Methanosarcina barkeri. 643 59

The product of the hypB gene, which is required for the maturation of the three [NiFe]hydrogenases of Escherichia coli, is a member of the GTPase family and exhibits a low intrinsic GTPase activity. It was studied whether or not GTP hydrolysis by HypB is coupled to nickel insertion into hydrogenases and to maturation of hydrogenases. Mutations were introduced into the hypB gene at sites expected to code for amino acids involved in guanine-nucleotide binding. Lys117 of G-motif 1, as well as Asp241 of G-motif 4 were substituted by asparagine residues. The purified mutant HypB proteins showed strongly reduced, but still significant, GTPase activity. In the case of [D241N]HypB, the kcat/Km value was lowered by a factor of 85 and the specificity of the enzyme for GTP was apparently lost, with other nucleoside triphosphates including XTP becoming compatible substrates. The decrease in GTPase activity was even more pronounced for [K117N]HypB. To assess the functionality of these HypB proteins in vivo, the wild-type hypB gene in the chromosome of E. coli was replaced by the mutant alleles. The resulting mutant strains BKN117 and BDN241 were affected in hydrogen metabolism under fermentative conditions. BKN117 did not display hydrogenase activity due to a loss of nickel incorporation into the large subunit. BDN241 exhibited a reduction of hydrogenase activity by 44% and only a portion of the hydrogenase 3 large subunit was in the mature nickel-containing form. From these results, it is concluded that GTP hydrolysis catalysed by HypB is an integral process in nickel incorporation into hydrogenases.
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PMID:GTP hydrolysis by HypB is essential for nickel insertion into hydrogenases of Escherichia coli. 760 Oct 92

Four microbial enzymes are known to require nickel: hydrogenase, methyl coenzyme M reductase, carbon monoxide dehydrogenase, and urease. Recent biochemical and molecular biological experiments have provided clear evidence for the existence of multiple auxiliary genes that facilitate nickel incorporation into urease and hydrogenase. Similarly, accessory factors are also likely to be required for the other two enzymes. One of the urease-related genes (ureE) encodes a cytoplasmic protein that has been purified and shown to bind nickel reversibly. We propose that the UreE protein serves as a nickel donor to urease apoprotein. A second urease-related auxiliary gene (ureG) possesses a sequence motif that is found in ATP- and GTP-binding proteins. We have shown that nickel incorporation into urease requires energy and speculate that the UreG protein may serve as an energy transducer, coupling the energy of NTP hydrolysis to metallocenter incorporation. The UreG protein is related in sequence to HypB, a protein that has been proposed to function in nickel processing in hydrogenases. Hence, the mechanisms for metallocenter biosynthesis in these two dissimilar enzymes may have evolved from a common nickel incorporation system.
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PMID:Nickel enzymes in microbes. 802 91

H2 oxidation in Azotobacter vinelandii is catalyzed by a membrane-bound, alpha beta dimeric [NiFe] hydrogenase. Maturation of the enzyme involves cleavage of a putative N-terminal signal sequence in the beta subunit and removal of 15 amino acids from the C terminus of the alpha subunit. Cells limited for nickel exhibited low hydrogenase activities and contained an apparently large form of the alpha subunit. Addition of nickel to such cells increased hydrogenase activities fivefold over 2 h. The increase in the first hour did not require transcription and translation and correlated with processing of the large form of the alpha subunit (pre-alpha) to the small form (alpha) resembling the alpha subunit from the purified enzyme. In vivo, pre-alpha appeared soluble whereas the majority of alpha was membrane bound. Processing of pre-alpha to alpha was reproduced in vitro in membrane-depleted extracts of nickel-limited cells. Processing specifically required the addition of Ni2+, whereas Co2+, Cu2+, Ca2+, Fe2+, Mn2+, and Zn2+ were ineffective. However, Zn2+, Co2+, and Cu2+ inhibited nickel-dependent processing. Mg-ATP and Mg-GTP stimulated processing, whereas anaerobic conditions and/or the addition of dithiothreitol and sodium dithionite was unnecessary. Processing was not inhibited by the protease inhibitors phenylmethylsulfonyl fluoride, E64, and pepstatin.
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PMID:In vivo and in vitro nickel-dependent processing of the [NiFe] hydrogenase in Azotobacter vinelandii. 828 21

Sequencing of a 1359-bp (NruI-AccI) DNA fragment located approximately 5.2 kb downstream from the end of the hydrogenase structural genes of Bradyrhizobium japonicum revealed two open reading frames designated hypA and hypB, encoding polypeptides with predicted molecular masses of 12.3 and 32.8 kDa, respectively. Both hypA and hypB showed strong homology with other genes in hydrogenase-containing bacteria. Two 'C-X-X-C' motifs were contained in the deduced amino acid sequence of hypA, a motif that is present in all known products homologous to HypA. The deduced product of hypB contains an area remarkably rich in histidine residues at the N-terminus (24 histidines within a 39 amino acid stretch). The deduced HypB also contains GTP-binding domains. We postulate that the product of hypB is involved in nickel binding and accumulation, and may utilize energy (GTP) to mobilize nickel for its subsequent incorporation into hydrogenase.
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PMID:Nucleotide sequences of two hydrogenase-related genes (hypA and hypB) from Bradyrhizobium japonicum, one of which (hypB) encodes an extremely histidine-rich region and guanine nucleotide-binding domains. 830 50

The products of the hyp operon genes are essential for the formation of catalytically active hydrogenases in Escherichia coli. At least one of these auxiliary proteins, HYPB, appears to be involved in nickel liganding to the hydrogenase apoprotein, since mutations in hypB can be phenotypically suppressed by high nickel concentrations in the medium (R. Waugh and D. H. Boxer, Biochimie 68:157-166, 1986). To approach the identification of the specific function of HYPB, we overexpressed the hypB gene and purified and characterized the gene product. HYPB is a homodimer of 31.6-kDa subunits, and it binds guanine nucleotides, with a Kd for GDP of 1.2 microM. The protein displays a low level of GTPase activity, with a kcat of 0.17 min-1. The apparent Km for GTP, as measured in the GTP hydrolysis reaction, was determined to be 4 microM. A chromatography system was established to measure nickel insertion into hydrogenase 3 from E. coli and to determine the effects of lesions in hypB. Nickel appears to be associated only with the processed large subunit of hydrogenase 3 in the wild type, and hypB mutants accumulate the precursor form of this subunit, which is devoid of nickel. The results are discussed in terms of a model in which HYPB is involved in nickel donation to the hydrogenase apoprotein and in which GTP hydrolysis is thought to reverse the interaction between either HYPB or another nickel-binding protein and the hydrogenase apoprotein after the nickel has been released.
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PMID:The product of the hypB gene, which is required for nickel incorporation into hydrogenases, is a novel guanine nucleotide-binding protein. 842 37

The high degree of similarity that exists between all the [NiFe] hydrogenase operons and the near universality of hydrogen metabolism among microorganisms suggest that the microbial ability to metabolize hydrogen is of great importance and ancient origin. The large number of genes present in these operons, which are mostly involved in the maturation of the structural subunit, is indicative of the complexity of the hydrogenase molecular structure. Two main groups of maturation genes can be differentiated based on the resulting phenotypes when mutated: the 'cis-genes', encoding narrow specificity proteins, are mainly located on the same transcription unit as the structural genes, and the 'trans-genes', encoding broad specificity proteins, are located on a different operon. The maturation of the large subunit starts with the formation of a complex with the chaperone HypC, which remains bound to the amino terminus throughout processing. The ligands CN and CO, which are derived from carbamoylphosphate, are then inserted via HypF and probably other accessory proteins. HypB is responsible for nickel atom delivery in a GTP-hydrolysis-dependent reaction. The last identified step in the large subunit maturation process is proteolytic cleavage at the carboxyl terminus. The possible roles of the other maturation proteins are also discussed.
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PMID:Maturation of the [NiFe] hydrogenases. 1133 40

Previous studies demonstrated that two accessory proteins, HypA and HypB, play a role in nickel-dependent maturation of both hydrogenase and urease in Helicobacter pylori. Here, the two proteins were purified and characterized. HypA bound two Ni(2+) ions per dimer with positive cooperativity (Hill coefficient, approximately 2.0). The dissociation constants K(1) and K(2) for Ni(2+) were 58 and 1.3 microM, respectively. Studies on purified site-directed mutant proteins in each of the five histidine residues within HypA, revealed that only one histidine residue (His2) is vital for nickel binding. Nuclear magnetic resonance analysis showed that this purified mutant version (H2A) was similar in structure to that of the wild-type HypA protein. A chromosomal site-directed mutant of hypA (in the codon for His2) lacked hydrogenase activity and possessed only 2% of the wild-type urease activity. Purified HypB had a GTPase activity of 5 nmol of GTP hydrolyzed per nmol of HypB per min. Site-directed mutagenesis within the lysine residue in the conserved GTP-binding motif of HypB (Lys59) nearly abolished the GTPase activity of the mutant protein (K59A). In native solution, both HypA and HypB exist as homodimers with molecular masses of 25.8 and 52.4 kDa, respectively. However, a 1:1 molar mixture of HypA plus HypB gave rise to a 43.6-kDa species composed of both proteins. A 43-kDa heterodimeric HypA-HypB complex was also detected by cross-linking. The cross-linked adduct was still observed in the presence of 0.5 mM GTP or 1 microM nickel or when the mutant version of HypA (altered in His2) and HypB (altered in Lys59) were tested. Individually, HypA and HypB formed homodimeric cross-linked adducts. An interaction between HypA and the Hp0868 protein (encoded by the gene downstream of hypA) could not be detected via cross-linking, although such an interaction was predicted by yeast two-hybrid studies. In addition, the phenotype of an insertional mutation within the Hp0868 gene indicated that its presence is not critical for either the urease or the hydrogenase activity.
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PMID:Characterization of Helicobacter pylori nickel metabolism accessory proteins needed for maturation of both urease and hydrogenase. 1253 48

Helicobacter pylori synthesizes two nickel-containing enzymes (urease and hydrogenase), both of which are important pathogenesis factors. Among the many accessory proteins needed for maturation of these Ni-enzymes, are two proteins, HypB and UreG, each of which contain a conserved nucleotide-binding domain (GSGKT). To address the role of this domain in the maturation process, site-directed mutations were introduced in both hypB and ureG. The hypB site-directed mutant strain (Lys59 to Ala59) lacked hydrogenase activity and had less than 1% of the parental urease activity. Hydrogenase activity was partially, and urease activity was fully restored in the hypB mutant strain when grown on nickel supplemented media. The hydrogenase activity of the ureG site-directed mutant strain (Lys14 to Ala14) was comparable to that of the parental strain. However, the ureG mutant strain lacked urease activity, and this deficiency could not be suppressed even when the strain was grown on nickel supplemented media. The expression of immunologically detectable HypB and UreG in the mutants was similar to the parental strain. Expression of the UreA and UreB subunits of urease in both the mutants was also normal. Purified UreG parental and mutant (Lys14 to Ala14) proteins had molecular masses of 27 kDa, but possessed negligible GTP hydrolyzing activity.
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PMID:Roles of conserved nucleotide-binding domains in accessory proteins, HypB and UreG, in the maturation of nickel-enzymes required for efficient Helicobacter pylori colonization. 1452 81

The biosynthesis of the active metal-bound form of the nickel-dependent enzyme urease involves the formation of a lysine-carbamate functional group concomitantly with the delivery of two Ni(2+) ions into the precast active site of the apoenzyme and with GTP hydrolysis. In the urease system, this role is performed by UreG, an accessory protein belonging to the group of homologous P-loop GTPases, often required to complete the biosynthesis of nickel-enzymes. This study is focused on UreG from Helicobacter pylori (HpUreG), a bacterium responsible for gastric ulcers and cancer, infecting large part of the human population, and for which urease is a fundamental virulence factor. The soluble HpUreG was expressed in E. coli and purified to homogeneity. On-line size exclusion chromatography and light scattering indicated that apo-HpUreG exists as a monomer in solution. Circular dichroism, which demonstrated the presence of a well-defined secondary structure, and NMR spectroscopy, which revealed a large number of residues that appear structured on the basis of their backbone amide proton chemical shift dispersion, indicated that, at variance with other UreG proteins so far characterized, this protein is significantly folded in solution. The amino acid sequence of HpUreG is 29% identical to that of HypB from Methanocaldococcus jannaschii, a dimeric zinc-binding GTPase involved in the in vivo assembly of [Ni,Fe]-hydrogenase. A homology-based molecular model of HpUreG was calculated, which allowed us to identify structural and functional features of the protein. Isothermal titration microcalorimetry demonstrated that HpUreG specifically binds 0.5 equivalents of Zn(2+) per monomer (K(d) = 0.33 +/- 0.03 microM), whereas it has 20-fold lower affinity for Ni(2+) (K(d) = 10 +/- 1 microM). Zinc ion binding (but not Ni(2+) binding) causes protein dimerization, as confirmed using light scattering measurements. The structural rearrangement occurring upon Zn(2+)-binding and consequent dimerization was evaluated using circular dichroism and fluorescence spectroscopy. Fully conserved histidine and cysteine residues were identified and their role in zinc binding was verified by site-directed mutagenesis and microcalorimetry. The results are analyzed and discussed with respect to analogous examples of GTPases in nickel metabolism.
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PMID:Zn2+-linked dimerization of UreG from Helicobacter pylori, a chaperone involved in nickel trafficking and urease activation. 1876 50

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