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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)
Production of H2 by Azospirillum brasilense under N2-fixing conditions was studied in continuous and batch cultures.
Net
H2 production was consistently observed only when the gas phase contained CO. Nitrogenase activity (C2H2 reduction) and H2 evolution (in the presence of 5% CO) showed a similar response to O2 and were highest at 0.75% dissolved O2. Uptake
hydrogenase
activity, ranging from 0.3 to 2.5 mumol H2/mg protein per hour was observed in batch cultures under N2. Such rates were more than sufficient to recycle nitrogenase-produced H2. Tritium-exchange assay showed that H2 uptake was higher under Ar than under N2. Uptake
hydrogenase
was strongly inhibited by CO and C2H2. Cyclic GMP inhibited both nitrogenase and uptake
hydrogenase
activities.
...
PMID:Hydrogen metabolism of Azospirillum brasilense in nitrogen-free medium. 625 62
Assembly of active Fe-
hydrogenase
in the chloroplasts of the green alga Chlamydomonas reinhardtii requires auxiliary maturases, the S-adenosylmethionine-dependent enzymes HydG and HydE and the GTPase HydF. Genes encoding homologous maturases had been found in the genomes of all eubacteria that contain Fe-
hydrogenase
genes but not yet in any other eukaryote. By means of proteomic analysis, we identified a homologue of HydG in the hydrogenosomes, mitochondrion-related organelles that produce hydrogen under anaerobiosis by the activity of Fe-
hydrogenase
, in the pathogenic protist Trichomonas vaginalis. Genes encoding two other components of the Hyd system, HydE and HydF, were found in the T. vaginalis genome database. Overexpression of HydG, HydE, and HydF in trichomonads showed that all three proteins are specifically targeted to the hydrogenosomes, the site of Fe-
hydrogenase
maturation. The results of Neighbor-
Net
analyses of sequence similarities are consistent with a common eubacterial ancestor of HydG, HydE, and HydF in T. vaginalis and C. reinhardtii, supporting a monophyletic origin of Fe-
hydrogenase
maturases in the two eukaryotes. Although Fe-hydrogenases exist in only a few eukaryotes, related Narf proteins with different cellular functions are widely distributed. Thus, we propose that the acquisition of Fe-hydrogenases, together with Hyd maturases, occurred once in eukaryotic evolution, followed by the appearance of Narf through gene duplication of the Fe-
hydrogenase
gene and subsequent loss of the Hyd proteins in eukaryotes in which Fe-
hydrogenase
function was lost.
...
PMID:Fe-hydrogenase maturases in the hydrogenosomes of Trichomonas vaginalis. 1652 12
Shoot/root grafting studies showed organ and host cultivar effects on net H(2) evolution from Pisum sativum L. root nodules.
Net
H(2) evolution from those nodules represents the sum of H(2) formed by Rhizobium nitrogenase and H(2) oxidized by any uptake
hydrogenase
present in the bacteria. Grafts between pea cultivars ;JI1205' or ;Alaska' and ;Feltham First' in symbioses with R. leguminosarum 128C53 showed that shoots of both JI1205 and Alaska increased H(2) uptake significantly (P </= 0.05) in Feltham First root nodules. The same plants also had less net H(2) evolution at similar rates of C(2)H(2) reduction than plants formed by grafting Feltham First shoots on Feltham First roots. Although JI1205 and Alaska shoots increased H(2)-uptake activity of Feltham First root nodules 28 days after the graft was made, intermediate to high levels of H(2) uptake activity were still present in nodules on roots of both JI1205 and Alaska grafted to Feltham First shoots. These results indicate the presence of a transmissible shoot factor(s) which can increase uptake
hydrogenase
activity in a Rhizobium symbiont and show that root genotype also can influence that parameter.Parallel grafting experiments using the same pea cultivars in symbioses with R. leguminosarum strain 300, which lacks uptake
hydrogenase
activity, suggested that a transmissible shoot factor(s) altered H(2) formation from nitrogenase by changing the electron allocation coefficient of that enzyme complex.The root and shoot factor(s) detected in this study had no permanent effect on strain 128C53. Bacterial cells isolated from Feltham First nodules with low H(2) uptake activity formed root nodules on JI1205 and Alaska with high H(2) uptake activity. Bacteroids isolated from nodules on intact JI1205, Alaska, or Feltham First plants with high, medium, or low H(2) uptake activity, respectively, maintained those phenotypes during in vitro assays.
...
PMID:A transmissible plant shoot factor promotes uptake hydrogenase activity in Rhizobium symbionts. 1666 77
Hydrogen (H(2)) release from photosynthetic microbial mats has contributed to the chemical evolution of Earth and could potentially be a source of renewable H(2) in the future. However, the taxonomy of H(2)-producing microorganisms (hydrogenogens) in these mats has not been previously determined. With combined biogeochemical and molecular studies of microbial mats collected from Elkhorn Slough, Monterey Bay, California, we characterized the mechanisms of H(2) production and identified a dominant hydrogenogen.
Net
production of H(2) was observed within the upper photosynthetic layer (0-2 mm) of the mats under dark and anoxic conditions. Pyrosequencing of rRNA gene libraries generated from this layer demonstrated the presence of 64 phyla, with Bacteriodetes, Cyanobacteria and Proteobacteria dominating the sequences. Sequencing of rRNA transcripts obtained from this layer demonstrated that Cyanobacteria dominated rRNA transcript pyrotag libraries. An OTU affiliated to Microcoleus spp. was the most abundant OTU in both rRNA gene and transcript libraries. Depriving mats of sunlight resulted in an order of magnitude decrease in subsequent nighttime H(2) production, suggesting that newly fixed carbon is critical to H(2) production. Suppression of nitrogen (N(2))-fixation in the mats did not suppress H(2) production, which indicates that co-metabolic production of H(2) during N(2)-fixation is not an important contributor to H(2) production. Concomitant production of organic acids is consistent with fermentation of recently produced photosynthate as the dominant mode of H(2) production. Analysis of rRNA % transcript:% gene ratios and H(2)-evolving bidirectional [NiFe]
hydrogenase
% transcript:% gene ratios indicated that Microcoelus spp. are dominant hydrogenogens in the Elkhorn Slough mats.
...
PMID:Hydrogen production in photosynthetic microbial mats in the Elkhorn Slough estuary, Monterey Bay. 2201 21
N
2
-fixing cyanobacteria mediate H
2
fluxes through the opposing processes of H
2
evolution, which is a by-product of the N
2
fixation reaction, and H
2
uptake, which is driven by uptake hydrogenases. Here, we used microelectrodes to characterize H
2
and O
2
dynamics in single natural colonies of the globally important N
2
fixer
Trichodesmium
collected from the Gulf of Eilat. We observed gradually changing H
2
dynamics over the course of the day, including both net H
2
evolution and net H
2
uptake, as well as large differences in H
2
fluxes between individual colonies.
Net
H
2
uptake was observed in colonies amended with H
2
in both light and dark.
Net
H
2
evolution was recorded in the light only, reflecting light-dependent N
2
fixation coupled to H
2
evolution. Both net H
2
evolution and H
2
uptake rates were higher before 2 pm than later in the day. These pronounced H
2
dynamics in the morning coincided with strong net O
2
uptake and the previously reported diel peak in N
2
fixation. Later in the afternoon, when photosynthesis rates determined by O
2
measurements were highest, and N
2
fixation rates decrease according to previous studies, the H
2
dynamics were also less pronounced. Thus, the observed diel variations in H
2
dynamics reflect diel changes in the rates of O
2
consumption and N
2
fixation. Remarkably, the presence of H
2
strongly stimulated the uptake of mineral iron by natural colonies. The magnitude of this effect was dependent on the time of day, with the strongest response in incubations that started before 2 pm, i.e., the period that covered the time of highest uptake
hydrogenase
activity. Based on these findings, we propose that by providing an electron source for mineral iron reduction in N
2
-fixing cells, H
2
may contribute to iron uptake in
Trichodesmium
colonies.
...
PMID:Hydrogen Dynamics in
Trichodesmium
Colonies and Their Potential Role in Mineral Iron Acquisition. 3135 65
