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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)
The photosynthetic bacterium Rhodobacter capsulatus contains two [NiFe]hydrogenases: an energy-generating
hydrogenase
, HupSL, and a regulatory
hydrogenase
, HupUV. The synthesis of HupSL is specifically activated by H(2) through a signal transduction cascade comprising three proteins: the H(2)-sensing HupUV protein, the histidine kinase HupT, and the transcriptional regulator HupR. Whereas a phosphotransfer between HupT and HupR was previously demonstrated, interaction between HupUV and HupT was only hypothesized based on in vivo analyses of mutant phenotypes. To visualize the in vitro interaction between HupUV and HupT proteins, a six-His (His(6))-HupU fusion protein and the HupV protein were coproduced by using a homologous expression system. The two proteins copurified as a His(6)-HupUHupV complex present in dimeric and tetrameric forms, both of which had H(2) uptake activity. We demonstrated that HupT and HupUV interact and form stable complexes that could be separated on a native gel. Interaction was also monitored with surface plasmon resonance technology and was shown to be insensitive to salt concentration and pH changes, suggesting that the interactions involve hydrophobic residues. As expected, H(2) affects the interaction between HupUV and HupT, leading to a weakening of the interaction, which is independent of the phosphate status of HupT. Several forms of HupT were tested for their ability to interact with HupUV and to complement hupT mutants. Strong interaction with HupUV was obtained with the isolated
PAS
domain of HupT and with inactive HupT mutated in the phosphorylable histidine residue, but only the wild-type HupT protein was able to restore normal H(2) regulation.
...
PMID:Interaction between the H2 sensor HupUV and the histidine kinase HupT controls HupSL hydrogenase synthesis in Rhodobacter capsulatus. 1464 70
Two [NiFe] hydrogenases enable the proteobacterium Ralstonia eutropha H16 to grow on molecular hydrogen as the sole energy source. A third [NiFe]
hydrogenase
(RH) acts as an H2 sensor in a multiple component signal transduction chain that controls
hydrogenase
gene transcription. The RH forms a dimeric heterodimer (HoxBC)2 in which HoxC contains the H2-sensing active site and HoxB the electron-transferring components including an organic, not yet identified redox cofactor. This oligomer forms a tight complex with the histidine protein kinase HoxJ. Both the sensor and the kinase were analysed by mutagenesis for functional domains that are instrumental in H2 signal transmission. A mutant deleted for a C-terminal peptide of 55 amino acids in HoxB lost its H2-sensing ability but still catalysed H2 oxidation. The mutant protein failed to form the dimeric heterodimer and a complex with HoxJ. The organic redox cofactor was no longer detectable in the truncated sensor. H2 sensing was also abolished by deletion of the
PAS
domain of HoxJ, indicating that this domain is involved in signal transduction. A truncated version of HoxJ consisting of only the input domain of the kinase was still capable of forming a complex with the RH. Mass determination of the purified HoxJ protein revealed that the kinase forms a homotetramer. The unique oligomeric structure of the H2-sensing complex with respect to its regulatory function is discussed.
...
PMID:The H2-sensing complex of Ralstonia eutropha: interaction between a regulatory [NiFe] hydrogenase and a histidine protein kinase. 1500 94
Transcription of the hupSL genes, which encode the uptake [NiFe]
hydrogenase
of Rhodobacter capsulatus, is specifically activated by H(2). Three proteins are involved, namely the H(2)-sensor HupUV, the histidine kinase HupT and the transcriptional activator HupR. hupT and hupUV mutants have the same phenotype, i.e. an increased level of hupSL expression (assayed by phupS::lacZ fusion) in the absence of H(2); they negatively control hupSL gene expression. HupT can autophosphorylate its conserved His(217), and in vitro phosphotransfer to Asp(54) of its cognate response regulator, HupR, was demonstrated. The non-phosphorylated form of HupR binds to an enhancer site (5'-TTG-N(5)-CAA) of phupS localized at -162/-152 nt and requires integration host factor to activate fully hupSL transcription. HupUV is an O(2)-insensitive [NiFe]
hydrogenase
, which interacts with HupT to regulate the phosphorylation state of HupT in response to H(2) availability. The N-terminal domain of HupT, encompassing the
PAS
domain, is required for interaction with HupUV. This interaction with HupT, leading to the formation of a (HupT)(2)-(HupUV)(2) complex, is weakened in the presence of H(2), but incubation of HupUV with H(2) has no effect on the stability of the heterodimer/tetramer, HupUV-(HupUV)(2), equilibrium. HupSL biosynthesis is also under the control of the global two-component regulatory system RegB/RegA, which controls gene expression in response to redox. RegA binds to a site close to the -35 promoter recognition site and to a site overlapping the integration host factor DNA-binding site (5'-TCACACACCATTG, centred at -87 nt) and acts as a repressor.
...
PMID:Transcriptional regulation of the uptake [NiFe]hydrogenase genes in Rhodobacter capsulatus. 1566 56
Three putative
hydrogenase
enzyme systems in Thermoanaerobacterium saccharolyticum were investigated at the genetic, mRNA, enzymatic, and phenotypic levels. A four-gene operon containing two [FeFe]-
hydrogenase
genes, provisionally termed hfs (
hydrogenase
-Fe-S), was found to be the main enzymatic catalyst of hydrogen production. hfsB, perhaps the most interesting gene of the operon, contains an [FeFe]-
hydrogenase
and a
PAS
sensory domain and has several conserved homologues among clostridial saccharolytic, cellulolytic, and pathogenic bacteria. A second
hydrogenase
gene cluster, hyd, exhibited methyl viologen-linked
hydrogenase
enzymatic activity, but hyd gene knockouts did not influence the hydrogen yield of cultures grown in closed-system batch fermentations. This result, combined with the observation that hydB contains NAD(P)+ and FMN binding sites, suggests that the hyd genes are specific to the transfer of electrons from NAD(P)H to hydrogen ions. A third gene cluster, a putative [NiFe]-
hydrogenase
with homology to the ech genes, did not exhibit
hydrogenase
activity under any of the conditions tested. Deletion of the hfs and hydA genes resulted in a loss of detectable methyl viologen-linked
hydrogenase
activity. Strains with a deletion of the hfs genes exhibited a 95% reduction in hydrogen and acetic acid production. A strain with hfs and ldh deletions exhibited an increased ethanol yield from consumed carbohydrates and represents a new strategy for engineering increased ethanol yields in T. saccharolyticum.
...
PMID:Identification of the [FeFe]-hydrogenase responsible for hydrogen generation in Thermoanaerobacterium saccharolyticum and demonstration of increased ethanol yield via hydrogenase knockout. 1964 38
Computational approaches based on Molecular Dynamics simulations, Quantum Mechanical methods and 3D Quantitative Structure-Activity Relationships were employed by computational chemistry groups at the University of Milano-Bicocca to study biological processes at the molecular level. The paper reports the methodologies adopted and the results obtained on Aryl hydrocarbon Receptor and homologous
PAS
proteins mechanisms, the properties of prion protein peptides, the reaction pathway of
hydrogenase
and peroxidase enzymes and the defibrillogenic activity of tetracyclines.
...
PMID:Computational approaches to shed light on molecular mechanisms in biological processes. 2141 34
Ruminococcus albus 7 has played a key role in the development of the concept of interspecies hydrogen transfer. The rumen bacterium ferments glucose to 1.3 acetate, 0.7 ethanol, 2 CO2, and 2.6 H2 when growing in batch culture and to 2 acetate, 2 CO2, and 4 H2 when growing in continuous culture in syntrophic association with H2-consuming microorganisms that keep the H2 partial pressure low. The organism uses NAD(+) and ferredoxin for glucose oxidation to acetyl coenzyme A (acetyl-CoA) and CO2, NADH for the reduction of acetyl-CoA to ethanol, and NADH and reduced ferredoxin for the reduction of protons to H2. Of all the enzymes involved, only the enzyme catalyzing the formation of H2 from NADH remained unknown. Here, we report that R. albus 7 grown in batch culture on glucose contained, besides a ferredoxin-dependent [FeFe]-
hydrogenase
(HydA2), a ferredoxin- and NAD-dependent electron-bifurcating [FeFe]-
hydrogenase
(HydABC) that couples the endergonic formation of H2 from NADH to the exergonic formation of H2 from reduced ferredoxin. Interestingly, hydA2 is adjacent to the hydS gene, which is predicted to encode an [FeFe]-
hydrogenase
with a C-terminal
PAS
domain. We showed that hydS and hydA2 are part of a larger transcriptional unit also harboring putative genes for a bifunctional acetaldehyde/ethanol dehydrogenase (Aad), serine/threonine protein kinase, serine/threonine protein phosphatase, and a redox-sensing transcriptional repressor. Since HydA2 and Aad are required only when R. albus grows at high H2 partial pressures, HydS could be a H2-sensing [FeFe]-
hydrogenase
involved in the regulation of their biosynthesis.
...
PMID:Hydrogen formation and its regulation in Ruminococcus albus: involvement of an electron-bifurcating [FeFe]-hydrogenase, of a non-electron-bifurcating [FeFe]-hydrogenase, and of a putative hydrogen-sensing [FeFe]-hydrogenase. 2515 86
