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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)
Nickel (Ni)-a component of urease and
hydrogenase
-was the latest nutrient to be recognized as an essential element for plants. However, to date there are no records of Ni deficiency for annual species cultivated under field conditions, possibly because of the non-appearance of obvious and distinctive symptoms, i.e., a hidden (or latent) deficiency. Soybean, a crop cultivated on soils poor in extractable Ni, has a high dependence on biological nitrogen fixation (BNF), in which Ni plays a key role. Thus, we hypothesized that Ni fertilization in soybean genotypes results in a better nitrogen physiological function and in higher grain production due to the hidden deficiency of this micronutrient. To verify this hypothesis, two simultaneous experiments were carried out, under greenhouse and field conditions, with Ni supply of 0.0 or 0.5 mg of Ni kg
-1
of soil. For this, we used 15 soybean genotypes and two soybean isogenic lines (urease positive,
Eu3
; urease activity-null,
eu3-a
, formerly
eu3-e1
). Plants were evaluated for yield, Ni and N concentration, photosynthesis, and N metabolism. Nickel fertilization resulted in greater grain yield in some genotypes, indicating the hidden deficiency of Ni in both conditions. Yield gains of up to 2.9 g per plant in greenhouse and up to 1,502 kg ha
-1
in field conditions were associated with a promoted N metabolism, namely, leaf N concentration, ammonia, ureides,
urea
, and urease activity, which separated the genotypes into groups of Ni responsiveness. Nickel supply also positively affected photosynthesis in the genotypes, never causing detrimental effects, except for the
eu3-a
mutant, which due to the absence of ureolytic activity accumulated excess
urea
in leaves and had reduced yield. In summary, the effect of Ni on the plants was positive and the extent of this effect was controlled by genotype-environment interaction. The application of 0.5 mg kg
-1
of Ni resulted in safe levels of this element in grains for human health consumption. Including Ni applications in fertilization programs may provide significant yield benefits in soybean production on low Ni soil. This might also be the case for other annual crops, especially legumes.
...
PMID:Hidden Nickel Deficiency? Nickel Fertilization via Soil Improves Nitrogen Metabolism and Grain Yield in Soybean Genotypes. 2986 70
Using a combination of various types of genetic manipulations (promoter replacement and gene cloning in replicating plasmid expression vector), we have overproduced the complex
hydrogenase
enzyme in the model cyanobacterium Synechocystis PCC6803. This new strain overproduces all twelve following proteins: HoxEFUYH (hydrogen production), HoxW (maturation of the HoxH subunit of
hydrogenase
) and HypABCDEF (assembly of the [NiFe] redox center of HoxHY
hydrogenase
). This strain when grown in the presence of a suitable quantities of nickel and iron used here exhibits a strong (25-fold) increase in
hydrogenase
activity, as compared to the WT strain growing in the standard medium. Hence, this strain can be very useful for future analyses of the cyanobacterial [NiFe]
hydrogenase
to determine its structure and, in turn, improve its tolerance to oxygen with the future goal of increasing hydrogen production. We also report the counterintuitive notion that lowering the activity of the Synechocystis urease can increase the photoproduction of biomass from
urea
-polluted waters, without decreasing
hydrogenase
activity. Such cyanobacterial factories with high
hydrogenase
activity and a healthy growth on
urea
constitute an important step towards the future development of an economical industrial processes coupling H2 production from solar energy and CO2, with wastewater treatment (
urea
depollution).
...
PMID:Overproduction of the cyanobacterial hydrogenase and selection of a mutant thriving on urea, as a possible step towards the future production of hydrogen coupled with water treatment. 2987 9
Freshwater mussel assemblages of the Upper Mississippi River (UMR) sequester tons of ammonia- and
urea
-based biodeposits each day and aerate sediment through burrowing activities, thus creating a unique niche for nitrogen (N) cycling microorganisms. This study explored how mussels impact the abundance of N-cycling species with an emphasis on
Candidatus
Nitrospira inopinata, the first microorganism known to completely oxidize ammonia (comammox) to nitrate. This study used metagenomic shotgun sequencing of genomic DNA to compare nitrogen cycling species in sediment under a well-established mussel assemblage and in nearby sediment without mussels. Metagenomic reads were aligned to the prokaryotic RefSeq non-redundant protein database using BLASTx, taxonomic binning was performed using the weighted lowest common ancestor algorithm, and protein-coding genes were categorized by metabolic function using the SEED subsystem. Linear discriminant analysis (LDA) effect sizes were used to determine which metagenomes and metabolic features explained the most differences between the mussel habitat sediment and sediment without mussels. Of the N-cycling species deemed differentially abundant,
Nitrospira moscoviensis
and "
Candidatus
Nitrospira inopinata" were responsible for creating a distinctive N-cycling microbiome in the mussel habitat sediment. Further investigation revealed that comammox
Nitrospira
had a large metabolic potential to degrade mussel biodeposits, as evidenced the top ten percent of protein-coding genes including the cytochrome c-type biogenesis protein required for hydroxylamine oxidation, ammonia monooxygenase, and
urea
decomposition SEED subsystems. Genetic marker analysis of these two
Nitrospira
taxons suggested that
N. moscoviensis
was most impacted by diverse carbon metabolic processes while "
Candidatus
Nitrospira inopinata" was most distinguished by multidrug efflux proteins (AcrB), NiFe
hydrogenase
(HypF) used in hydrogen oxidation and sulfur reduction coupled reactions, and a heme chaperone (CcmE). Furthermore, our research suggests that comammox and NOB
Nitrospira
likely coexisted by utilizing mixotrophic metabolisms. For example, "
Candidatus
Nitrospira inopinata" had the largest potentials for ammonia oxidation, nitrite reduction with NirK, and hydrogen oxidation, while NOB
Nitrospira
had the greatest potential for nitrite oxidation, and nitrate reduction possibly coupled with formate oxidation. Overall, our results suggest that this mussel habitat sediment harbors a niche for NOB and comammox
Nitrospira
, and ultimately impacts N-cycling in backwaters of the UMR.
...
PMID:The Genomic Potentials of NOB and Comammox
Nitrospira
in River Sediment Are Impacted by Native Freshwater Mussels. 3023 38
Biological nitrogen fixation (BNF) through the enzyme nitrogenase is performed by a unique class of organisms known as diazotrophs. One interesting facet of BNF is that it produces molecular hydrogen (H
2
) as a requisite by-product. In the absence of N
2
substrate, or under conditions that limit access of N
2
to the enzyme through modifications of amino acids near the active site, nitrogenase activity can be redirected toward a role as a dedicated
hydrogenase
. In free-living diazotrophs, nitrogenases are tightly regulated to minimize BNF to meet only the growth requirements of the cell, and are often accompanied by uptake hydrogenases that oxidize the H
2
by-product to recover the electrons from this product. The wild-type strain of Azotobacter vinelandii performs all of the tasks described above to minimize losses of H
2
while also growing as an obligate aerobe. Individual alterations to A. vinelandii have been demonstrated that disrupt key aspects of the N
2
reduction cycle, thereby diverting resources and energy toward the production of H
2
. In this work, we have combined three approaches to override the primary regulation of BNF and redirect metabolism to drive biological H
2
production by nitrogenase in A. vinelandii. The resulting H
2
-producing strain was further utilized as a surrogate to study secondary, post-transcriptional regulation of BNF by several key nitrogen-containing metabolites. The improvement in yields of H
2
that were achieved through various combinations of these three approaches was compared and is presented along with the insights into inhibition of BNF by several nitrogen compounds that are common in various waste streams. The findings indicate that both ammonium and nitrite hinder BNF through this secondary inhibition, but
urea
and nitrate do not. These results provide essential details to inform future biosynthetic approaches to yield nitrogen products that do not inadvertently inhibit BNF.
...
PMID:Efforts toward optimization of aerobic biohydrogen reveal details of secondary regulation of biological nitrogen fixation by nitrogenous compounds in Azotobacter vinelandii. 3025 Sep 77
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