Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Methanococcus thermolithotrophicus can use either H2 or formate as the electron donor for methanogenesis from CO2. Resuspended-cell experiments revealed that the ability to use H2 as the source of electrons for methanogenesis was constitutive; cells grown on formate or H2-CO2 were equally capable of H2-CO2 methanogenesis. The ability to metabolize formate at high rates was observed only in cells previously grown on formate. Two such strains were distinguished: strain F and strain HF. Strain F was repeatedly grown exclusively on formate for over 3 years; this strain showed a constitutive capacity to metabolize formate to methane, even after subsequent repeated transfers to medium containing only H2-CO2. Strain HF could only metabolize formate to methane when grown in the presence of formate with no H2 present; this strain was recently derived from another strain (H) that had been exclusively grown on H2-CO2 and which upon initial transfer to formate medium could only metabolize formate to methane at a very slow rate. Initial adaptation of strain H to growth on formate was preceded by a long lag. The specific activities of hydrogenase and formate dehydrogenase in cell extracts derived from these different strains confirmed these findings. Similar levels of hydrogenase were observed in all strains, independent of the presence of H2 in the growth medium medium. High levels of formate dehydrogenase were also constitutive in strain F. Only low formate dehydrogenase activities were observed in strain H. High levels of formate dehydrogenase were observed in strain HF only when these cells were grown with formate in the absence of H2. In all strains the two- to threefold fluctuations of both hydrogenase and formate dehydrogenase cell-free activities were observed during growth, with peak activities reached in the middle of the exponential phase.
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PMID:Regulation of formate dehydrogenase activity in Methanococcus thermolithotrophicus. 210 11

A new gene whose product is required for the production of formate hydrogenlyase (FHL) has been identified in Escherichia coli. This gene, termed fhlB, maps between the frdA (94.4 min) and argI (96.6 min) genes on the E. coli chromosome and is transcribed in a clockwise direction toward argI. Biochemical analysis of an FhlB- mutant, strain SE-2011 [phi(fhlB-lacZ+)], revealed that the mutant lacks formate dehydrogenase activity associated with FHL (FDH-H) and hydrogenase activity. As a result of these defects, fermentative hydrogen production and hydrogen uptake reactions were undetectable in strain SE-2011. Fumarate reductase activity of this mutant was also reduced to about 15% of the levels of the parent (strain MC4100), and strain SE-2011 did not produce succinate as a fermentation end product. Regulation of expression of the fhlB gene, studied as production of beta-galactosidase activity by strain SE-2011, revealed that the operon is expressed at low levels under aerobic conditions. Under anaerobic growth conditions, this activity increased by two- to threefold. Addition of formate enhanced the differential rate of synthesis of the fhlB gene product to as high as 130 U of beta-galactosidase specific activity per microgram of cell protein, but only under anaerobic conditions. Formate-dependent expression of phi(fhlB-lacZ+) required the sigma 54 subunit of RNA polymerase and the fhlA gene product. The concentration of formate required for maximum expression of the fhlB gene was about 15 mM; this value decreased to about 3 mM in the presence of plasmid pSE-133, which carries the fhlA gene in a multicopy plasmid. DNA sequence analysis of the fhlA gene showed that the FhlA protein is 686 amino acids long and has an anhydrous molecular weight of 78,086. On the basis of sequence homology with other transcriptional activators such as NtrC, HydG, and Klebsiella pneumoniae NifA proteins, the FhlA protein was deduced to be a transcriptional activator controlling the production of FHL. It is proposed that formate interacts with the FhlA protein and that this active complex initiates transcription of the fhlB gene. The FhlA and FhlB proteins act as a cascade in regulating the production of FDH-H and the FHL-linked hydrogenase and ultimately the production of FHL and fermentative hydrogen.
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PMID:Genetic regulation of formate hydrogenlyase of Escherichia coli: role of the fhlA gene product as a transcriptional activator for a new regulatory gene, fhlB. 211 3

A mutation in a new gene, molR, prevented the synthesis in Escherichia coli of molybdoenzymes, including the two formate dehydrogenase isoenzymes, nitrate reductase and trimethylamine-N-oxide reductase. This phenotype was suppressed by supplementing the media with molybdate. Thus, the molR mutant was phenotypically similar to previously described chlD mutants, thought to be defective in molybdate transport. The molR gene is located at 65.3 min in the E. coli chromosome, in contrast to the chlD gene, which maps at 17 min and thus can be readily distinguished. The molR gene is also cotransducible with a hitherto unidentified gene essential for the production of 2-oxoglutarate from isocitrate, designated icdB (located at 66 min). The molR mutant strain SE1100 also failed to produce the hydrogenase component of formate hydrogenlyase (HYD3) in molybdate-unsupplemented media. The amount of molybdate required by strain SE1100 for the production of parental levels of formate hydrogenlyase activity was dependent on the growth medium. In Luria-Bertani medium, this value was about 100 microM, and in glucose-minimal medium, 1.0 microM was sufficient. In low-sulfur medium, this value decreased to about 50 nM. The addition of sulfate or selenite increased the amount of molybdate needed for the production of formate hydrogenlyase activity. These data suggest that in the absence of the high-affinity molybdate transport system, E. coli utilizes sulfate and selenite transport systems for transporting molybdate, preferring sulfate transport over the selenite transport system.
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PMID:Identification of a new gene, molR, essential for utilization of molybdate by Escherichia coli. 215 10

The formate-hydrogen lyase complex of Escherichia coli decomposes formic acid to hydrogen and carbon dioxide under anaerobic conditions in the absence of exogenous electron acceptors. The complex consists of two separable enzymatic activities: a formate dehydrogenase and a hydrogenase. The formate dehydrogenase component (FDHH) of the formate-hydrogen lyase complex was purified to near homogeneity in two column chromatographic steps. The purified enzyme was composed of a single polypeptide of molecular weight 80,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Metal analysis showed each mole of enzyme contained 3.3 g atoms of iron. Denaturation of FDHH released a compound which, when oxidized, displayed a fluorescence spectrum similar to that of the molybdopterin cofactor found in certain other enzymes. The enzyme contained selenium in the form of selenocysteine as determined by radioactive labeling of the enzyme with 75Se and amino acid analysis. FDHH activity was maximal between pH 7.5 and 8.5; however, the enzyme was maximally stable at pH 5.3-6.4 and highly unstable above pH 7.5. Nitrate and nitrite salts caused a drastic reduction in activity. Although azide inhibited FDHH activity, it also protected the enzyme from inactivation by oxygen.
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PMID:Escherichia coli formate-hydrogen lyase. Purification and properties of the selenium-dependent formate dehydrogenase component. 221 98

Through complementation of a trans-acting regulatory mutation a gene has been cloned whose product is required for the formate induction of the anaerobic expression of the formate hydrogenlyase structural genes. By restriction analysis, and from the size of the encoded protein, the gene could be identified as being equivalent to fhlA described by Sankar et al. (1988). The nucleotide sequence of the fhlA gene was determined and it was shown to code for a protein with a calculated Mr of 78,467. Analysis of the derived amino acid sequence showed that the carboxy-terminal domain of FHLA shares considerable sequence similarity with NIFA and NTRC, which are the 'regulators' of two-component regulatory systems. Carboxy-terminal truncation of, and introduction of amino-terminal deletions in, the fhlA gene delivered inactive gene products. When overexpressed, FHLA mediates activation of expression of the formate dehydrogenase and hydrogenase structural genes in the presence of formate also under aerobic growth conditions. FHLA appears to bind to the upstream regulatory sequence (URS) in the 5' flanking region of the fdhF gene since activation of fdhF expression was dependent on the presence of the URS.
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PMID:Identification and sequence analysis of the gene encoding the transcriptional activator of the formate hydrogenlyase system of Escherichia coli. 228 Jun 86

The regulatory elements involved in expression of the gene (fdhF) for the selenopolypeptide of formate dehydrogenase and of a gene (or transcriptional unit) (hyd) specifically responsible for the formation of the gas-evolving hydrogenase (hydrogenase 3) in Escherichia coli were investigated. Formate (or a product of it) is required for expression of both systems since in a pyruvate-formate-lyase deficient mutant induction occurs only when formate is supplemented externally. Under this condition, formate can partially overcome repression by nitrate. The transcription of both the fdhF gene and the hydrogenase-3-encoding systems is independent of the presence of a wild-type fnr gene when formate is present, supporting the view that the Fnr effect on the formation of the formate-hydrogen-lyase pathway is indirect. Mutations blocking the synthesis of a functional molybdenum cofactor also had no major affect on fdhF and hyd expression. The nucleotide sequence of the 5' flanking region of the fdhF gene was determined and the transcription start point of the fdhF gene was localized by nuclease S1 mapping. Nuclease Bal31 generated deletion clones were constructed and the regulation of their expression was studied. Anaerobic expression and induction by formate depended on the presence of a stretch of approximately 185 nucleotides upstream of the translation start. Elements mediating formate induction and oxygen or nitrate repression could not be separated physically. The regulatory features of the fdhF upstream region bear striking resemblance to systems whose expression are dependent upon upstream activating elements.
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PMID:Factors affecting transcriptional regulation of the formate-hydrogen-lyase pathway of Escherichia coli. 244

In contrast to the widespread ability of bacteria, plants, and animals to incorporate selenium nonspecifically into proteins in the form of selenomethionine residues, the selenoamino acid selenocysteine occurs as a highly specific component of a few selenium-dependent enzymes. Selenocysteine has been identified in glycine reductase, formate dehydrogenase, and hydrogenase of bacterial origin and glutathione peroxidase from mammalian and avian sources. In these enzymes there is evidence that the selenol group, which is largely ionized at physiological pH, functions as a redox center. It now seems clear, from studies with both prokaryotes and eukaryotes, that the UGA opal stop codon is used to specify the cotranslational insertion of selenocysteine into proteins. The factors that allow this unusual use of the stop codon are, however, unknown. The occurrence of selenium as a normal constituent of several bacterial tRNA species has been established. The presence of a selenonucleoside, 5-methylaminomethyl-2-selenouridine, in the first or wobble position of the anticodons of certain glutamate and lysine iso-acceptor species influences codon-anticodon interaction and thus may serve to regulate translational processes. The biosynthesis of the selenonucleoside appears to involve the ATP-dependent activation of the sulfur in a preformed 5-methylaminomethyl-2-thiouridine residue in tRNA and replacement of the sulfur with selenium.
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PMID:Specific occurrence of selenium in enzymes and amino acid tRNAs. 244 14

Systematic screening of 6.10(4) independent Tn5 insertion mutants of Escherichia coli yielded one new hydrogenase locus, hydF, mapping near 64.8 min, i.e., close to the hydL locus (K. Stoker, L.F. Oltmann, and A.H. Stouthamer, J. Bacteriol. 170:1220-1226, 1988). It regulated specifically the activity of the hydrogenase isoenzymes, formate dehydrogenase and lyase activities being unaffected. In hydF mutants, hydrogenase 1 and 2 activities were reduced to 1% of the parental level, whereas the electrophoretically labile part was present at about 20% of the parental level. H2 uptake was also reduced to about 20%, which suggested a relationship between these two activities. Experiments with 63Ni indicated that hydrogenase isoenzymes 1 and 2 might be present in these strains but in an inactive form. The hydF product might therefore be a posttranslational activator. At least three other mutant classes were isolated. Additional data were obtained on coisolated, nickel-restorable hydC mutants (L.F. Wu and M.-A. Mandrand-Berthelot, Biochimie 68:167-179, 1986). These strains were found to suffer a general impairment of nickel uptake. Restoration of hydrogenase activities was specific for NiCl2 and inhibited by chloramphenicol, which indicated an effect either on the transcription of hydrogenase(-associated) genes or by cotranslational incorporation in nickel-containing enzymes (e.g., in hydrogenases). The hydC mutation could not be complemented in trans, evidence that the hydC product is not a nickel transport protein but rather a cis-acting regulatory gene. Parent HB101, hydF mutants, and the other mutants were further analyzed by monitoring the induction of hydrogenase and hydrogenase-associated activities upon transition of cells from aerobic to anaerobic growth. These experiments also revealed a correlation between the early-induced H2 uptake route and labile hydrogenase activity. The formate hydrogenlyase induction patterns followed quite well the slower induction patterns of hydrogenases 1 and 2.
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PMID:Randomly induced Escherichia coli K-12 Tn5 insertion mutants defective in hydrogenase activity. 253 83

Formate hydrogenlyase activity in a cell extract of Methanobacterium formicicum was abolished by removal of coenzyme F420; addition of purified coenzyme F420 restored activity. Formate hydrogenlyase activity was reconstituted with three purified components from M. formicicum: coenzyme F420-reducing hydrogenase, coenzyme F420-reducing formate dehydrogenase, and coenzyme F420. The reconstituted system required added flavin adenine dinucleotide (FAD) for maximal activity. Without FAD, the formate dehydrogenase and hydrogenase rapidly lost coenzyme F420-dependent activity relative to methyl viologen-dependent activity. Immunoadsorption of formate dehydrogenase or coenzyme F420-reducing hydrogenase from the cell extract greatly reduced formate hydrogenlyase activity; addition of the purified enzymes restored activity. The formate hydrogenlyase activity was reversible, since both the cell extract and the reconstituted system produced formate from H2 plus CO2 and HCO3-.
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PMID:Reconstitution and properties of a coenzyme F420-mediated formate hydrogenlyase system in Methanobacterium formicicum. 266 36

An operon fusion was constructed in which the chloramphenicol acetyltransferase gene (cat) is under the transcriptional control of the anaerobically-activated formate dehydrogenase (fdhF) gene promoter. It was used as a screening system for mutations in trans which prevent the formate-dependent anaerobic induction of fdhF gene expression. Five classes of mutants were identified. The defect in class I mutants was complemented by a plasmid (pBA11) or subclones thereof, which harbor genes of the Escherichia coli 58 min hyd (hydrogenase) gene cluster. They may comprise regulatory gene mutants. The phenotype of class II mutants was reversed by supplementing the medium with 100 microM MoO4(2-); WO4(2-) could substitute for MoO4(2-) in restoring anaerobic induction by formate. Similarly, class III mutants were phenotypically suppressed by inclusion of 500 microM Ni2+ in the medium; these mutants were shown to carry a defective fnr gene. The mutant of class IV had a defect in a formate dehydrogenase structural gene and that of class V was unable to grow under fermentative conditions while maintaining the capability to grow anaerobically in the presence of electron acceptors.
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PMID:Mutations in trans which affect the anaerobic expression of a formate dehydrogenase (fdhF) structural gene. 266 74


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