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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)

High-affinity nickel transport in Alcaligenes eutrophus H16 is mediated by a function designated hoxN. hoxN lies within the hydrogenase gene cluster of megaplasmid pHG1. An insertional mutation at the hoxN locus led to an increased nickel requirement. In this mutant (strain HF260) both autotrophic growth on hydrogen and wild-type level of urease, a nickel-containing enzyme, were dependent on high concentration of nickel in the medium. Studies with a heterologous in vivo expression system revealed that the hoxN locus encodes two proteins with Mr = 30,000 and 28,000. Only the larger polypeptide was essential for nickel transport. The hoxN locus was cloned on a 2.2-kilobase pair fragment. Nucleotide sequence analysis of the hoxN locus revealed an open reading frame with a coding capacity for a protein of 33.1 kDa. The insertion leading to the Nic- phenotype of strain HF260 maps within this open reading frame indicating that it does in fact have coding function. The deduced amino acid sequence of the hoxN gene has several features typical of a hydrophobic integral membrane protein. Alkaline phosphatase fusion proteins produced by insertion of the transposon TnphoA into hoxN gave significant levels of alkaline phosphatase activity indicating that protein HoxN contains periplasmic domains. Taken together, our results suggest that gene hoxN encodes the high-affinity nickel transporter of A. eutrophus.
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PMID:Cloning, nucleotide sequence, and heterologous expression of a high-affinity nickel transport gene from Alcaligenes eutrophus. 184 42

A mixed culture of ruminal microorganisms was used to demonstrate that nickel (Ni) is incorporated into factor F430 and to determine the effects of monensin and formate on incorporation of Ni into factor F430. Ruminal microorganisms obtained from a semicontinuous culture were grown for 24 h in the presence of 63Ni and a 2 x 2 factorial arrangement of monensin (0 to 5 micrograms/ml) and formate (0 to 20 mM) treatments. Factor F430 was isolated and purified from the cultures by QAE-Sephadex A-25 column chromatography. The purified preparation contained 63Ni and exhibited a peak in absorbance at 430 nm. Methane production was decreased (P less than .01) 45% by monensin but was increased (P less than .01) 1.8-fold by formate. However, incorporation of 63Ni into factor F430, which is ubiquitous in methanogens and not found in other bacteria, did not parallel changes in methane production. Incorporation of 63Ni into factor F430 was decreased (P less than .01) 55% by monensin but was not affected (P greater than .05) by formate. In addition to its use for synthesis of urease and hydrogenase, Ni is involved in ruminal fermentation as a component of factor430.
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PMID:Incorporation of nickel into ruminal factor F430 as affected by monensin and formate. 236 52

Nickel-deficient (Nic-) mutants of Alcaligenes eutrophus requiring high levels of nickel ions for autotrophic growth with hydrogen were characterized. The Nic- mutants carried defined deletions in the hydrogenase gene cluster of the indigenous pHG megaplasmid. Nickel deficiency correlated with a low level of the nickel-containing hydrogenase activity, a slow rate of nickel transport, and reduced activity of urease. The Nic+ phenotype was restored by a cloned DNA sequence (hoxN) of a megaplasmid pHG1 DNA library of A. eutrophus H16. hoxN is part of the hydrogenase gene cluster. The nickel requirement of Nic- mutants was enhanced by increasing the concentration of magnesium. This suggests that the Nic- mutants are impaired in the nickel-specific transport system and thus depend on the second transport activity which normally mediates the uptake of magnesium.
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PMID:Genetic determinants of a nickel-specific transport system are part of the plasmid-encoded hydrogenase gene cluster in Alcaligenes eutrophus. 264 80

The detrimental effects of excessive Ni on plant growth have been well known for many years. More recent evidence indicates that Ni is required in small amounts for normal plant growth and development. Ni is an essential component of urease in plants and microorganisms. A deficiency of Ni in plants is reported to result in necrotic lesions in leaves in response to toxic accumulations of urea. Urease plays an essential role in mobilization of nitrogenous compounds in plants, a process that is especially important during seed germination and fruit formation when protein reserves are degraded into amino acids. Arginine, an abundant amino acid in plants, when degraded produces urea as a product and urease is needed for urea utilization. Theories of urea formation during allantoin degradation in Glycine max have been recently refuted. In G. max ureides apparently are metabolized via an amidohydrolase reaction with subsequent degradation of ureidoglycine, yielding glyoxylate, NH+4 and CO2. No evidence is available for the formation of urea in this pathway. Nitrogen-fixing symbionts, such as Rhizobium and Bradyrhizobium, contain two known Ni enzymes: urease and hydrogenase. Optimum growth of nodulated legumes and actinorhizal plants may depend on an adequate supply of Ni to meet the requirements of the Ni-requiring enzymes in host plants and endophytes. The seeds of severely Ni-deficient Hordeum are completely inviable, thus providing conclusive evidence for the essentiality of Ni for this species. The evidence indicates that Ni must be added to the list of micronutrient elements generally required by plants.
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PMID:Nickel as a micronutrient element for plants. 307 27

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

The products of cooCTJ are involved in normal in vivo Ni insertion into the carbon monoxide dehydrogenase (CODH) of Rhodospirillum rubrum. Located on a 1.5-kb DNA segment immediately downstream of the CODH structural gene (cooS), two of the genes encode proteins that bear motifs reminiscent of other (urease and hydrogenase) Ni-insertion systems: a nucleoside triphosphate-binding motif near the N terminus of CooC and a run of 15 histidine residues regularly spaced over the last 30 amino acids of the C terminus of CooJ. A Gm(r)omega-linker cassette was developed to create both polar and nonpolar (60 bp) insertions in the cooCTJ region, and these, along with several deletions, were introduced into R. rubrum by homologous recombination. Analysis of the exogenous Ni levels required to sustain CO-dependent growth of the R. rubrum mutants demonstrated different phenotypes: whereas the wild-type strain and a mutant bearing a partial cooJ deletion (of the region encoding the histidine-rich segment) grew at 0.5 microM Ni supplementation, strains bearing Gm(r)omega-linker cassettes in cooT and cooJ required approximately 50-fold-higher Ni levels and all cooC insertion strains, bearing polar or nonpolar insertions, grew optimally at 550 microM Ni.
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PMID:In vivo nickel insertion into the carbon monoxide dehydrogenase of Rhodospirillum rubrum: molecular and physiological characterization of cooCTJ. 907 11

Complex metalloenzymes (e.g., nitrogenase, hydrogenase, urease) are synthesized starting from the apoprotein via several intermediates by the action of accessory proteins. The isolation and biochemical characterization of such intermediates is hampered by their low abundance and their lability. Here we describe a technique for efficient single-step purification of a hydrogenase precursor under mild conditions using a N-terminal Strep-tag II affinity peptide and a novel StrepTactin Sepharose matrix. The tag was fused to the large subunit of [NiFe] hydrogenase 3 (HycE) of Escherichia coli. No significant influence of the affinity peptide on maturation or activity of the protein was observed when the modified gene was integrated into the chromosome by homologous recombination. A tagged nickel-free precursor form of HycE bound quantitatively to a recombinant StrepTactin Sepharose column. More than 90% pure subunit could be obtained after elution with desthiobiotin. The procedure was shown to be more efficient than purification by immobilized metal affinity chromatography using a N-terminal His-tag. General advantages of the novel Strep-tag II affinity purification especially for applications with metalloenzymes are discussed.
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PMID:Strep-tag II affinity purification: an approach to study intermediates of metalloenzyme biosynthesis. 960 45

Since 1995, crystal structures have been determined for many transition-metal enzymes, in particular those containing the rarely used transition metals vanadium, molybdenum, tungsten, manganese, cobalt and nickel. Accordingly, our understanding of how an enzyme uses the unique properties of a specific transition metal has been substantially increased in the past few years. The different functions of nickel in catalysis are highlighted by describing the active sites of six nickel enzymes - methyl-coenyzme M reductase, urease, hydrogenase, superoxide dismutase, carbon monoxide dehydrogenase and acetyl-coenzyme A synthase.
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PMID:Active sites of transition-metal enzymes with a focus on nickel. 991 55

The nickel-containing enzymes hydrogenase and urease require accessory proteins in order to incorporate properly the nickel atom(s) into the active sites. The Helicobacter pylori genome contains the full complement of both urease and hydrogenase accessory proteins. Two of these, the hydrogenase accessory proteins HypA (encoded by hypA) and HypB (encoded by hypB), are required for the full activity of both the hydrogenase and the urease enzymes in H. pylori. Under normal growth conditions, hydrogenase activity is abolished in strains in which either hypA (HypA:kan) or hypB (HypB:kan) have been interrupted by a kanamycin resistance cassette. Urease activity in these strains is 40 (HypA:kan)- and 200 (HypB:kan)-fold lower than for the wild-type (wt) strain 43504. Nickel supplementation in the growth media restored urease activity to almost wt levels. Hydrogenase activity was restored to a lesser extent, as has been observed for hyp mutants in other (H(2)-oxidizing) bacteria. Expression levels of UreB (the urease large subunit) were not affected by inactivation of either hypA or hypB, as determined by immunoblotting. Urease activity was not affected by lesions in the genes for either the hydrogenase accessory proteins HypD or HypF or the hydrogenase large subunit structural gene, indicating that the urease deficiency was not caused by lack of hydrogenase activity. When crude extracts of wt, HypA:kan and HypB:kan were separated by anion exchange chromatography, the urease-containing fractions of the mutant strains contained about four (HypA:kan)- and five (HypB:kan)-fold less nickel than did the urease from wt, indicating that the lack of urease activity in these strains results from a nickel deficiency in the urease enzyme.
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PMID:Requirement of nickel metabolism proteins HypA and HypB for full activity of both hydrogenase and urease in Helicobacter pylori. 1112 99

Analysis of a Brucella suis 1330 gene fused to a gfp reporter, and identified as being induced in J774 murine macrophage-like cells, allowed the isolation of a gene homologous to nikA, the first gene of the Escherichia coli operon encoding the specific transport system for nickel. DNA sequence analysis of the corresponding B. suis nik locus showed that it was highly similar to that of E. coli except for localization of the nikR regulatory gene, which lies upstream from the structural nikABCDE genes and in the opposite orientation. Protein sequence comparisons suggested that the deduced nikABCDE gene products belong to a periplasmic binding protein-dependent transport system. The nikA promoter-gfp fusion was activated in vitro by low oxygen tension and metal ion deficiency and was repressed by NiCl(2) excess. Insertional inactivation of nikA strongly reduced the activity of the nickel metalloenzyme urease, which was restored by addition of a nickel excess. Moreover, the nikA mutant of B. suis was functionally complemented with the E. coli nik gene cluster, leading to the recovery of urease activity. Reciprocally, an E. coli strain harboring a deleted nik operon recovered hydrogenase activity by heterologous complementation with the B. suis nik locus. Taking into account these results, we propose that the nik locus of B. suis encodes a nickel transport system. The results further suggest that nickel could enter B. suis via other transport systems. Intracellular growth rates of the B. suis wild-type and nikA mutant strains in human monocytes were similar, indicating that nikA was not essential for this step of infection. We discuss a possible role of nickel transport in maintaining enzymatic activities which could be crucial for survival of the bacteria under the environmental conditions encountered within the host.
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PMID:Identification of the nik gene cluster of Brucella suis: regulation and contribution to urease activity. 1113 34


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