Nickel Metalloregulators and Chaperones

Higgins, Khadine A.

doi:10.3390/inorganics7080104

Cited by 11 publications

(3 citation statements)

References 167 publications

(597 reference statements)

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“…The role of HypA and HypB during [NiFe]-hydrogenase maturation is well studied and first involves the metal-dependent (Ni 2+ ) dimerization of HypB with one equivalent of nickel per dimer ( 79 , 80 ). Second, the hydrolysis of GTP facilitates the transfer of Ni 2+ from HypB to HypA by weakening the binding affinity of Ni 2+ to HypB and promoting the formation of the HypAB heterodimer ( 81 ) or, in some organisms such as Thermococcus kodakarensis , a heterotetramer HypAABB ( 82 ). After the Ni 2+ is transferred to HypA, HypA dissociates from the complex and delivers the cofactor to the large subunit of the hydrogenase ( 50 , 83 ).…”

Section: Discussionmentioning

confidence: 99%

Evidence for a Putative Isoprene Reductase in Acetobacterium wieringae

et al. 2023

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Section: Discussionmentioning

confidence: 99%

Evidence for a Putative Isoprene Reductase in Acetobacterium wieringae

et al. 2023

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“…Nickel is required for the synthesis of hydrogenase in prokaryotes, which catalyzes the oxidation of hydrogen liberated by nitrogenase during the dinitrogen reduction process [ 15 ]. Nickelin (HypB), an accessory protein responsible for Ni supply in rhizobia, has a dual role in Ni mobilization into hydrogenase and Ni storage [ 16 ]. Metals have been shown to negatively affect microorganism growth, morphology, and activity, including symbiotic nitrogen fixation [ 17 ].…”

Section: Introductionmentioning

confidence: 99%

Synergistic Interaction between Symbiotic N2 Fixing Bacteria and Bacillus strains to Improve Growth, Physiological Parameters, Antioxidant Enzymes and Ni Accumulation in Faba Bean Plants (Vicia faba) under Nickel Stress

Elbagory

El-Nahrawy

Omara

2022

Plants

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Several activities in the agriculture sector lead to the accumulation of Nickel (Ni) in soil. Therefore, effective and economical ways to reduce soil bioavailability of Ni must be identified. Five isolates of Rhizobium leguminosarum biovar Viceae (ICARDA 441, ICARDA 36, ICARDA 39, TAL–1148, and ARC–207) and three bacterial strains (Bacillus subtilis, B. circulance, and B. coagulans) were evaluated for tolerance and biosorption of different levels of Ni (0, 20, 40, 60, and 80 mg L−1). Pot experiments were conducted during the 2019/2020 and 2020/2021 seasons using four inoculation treatments (inoculation with the most tolerant Rhizobium (TAL–1148), inoculation with the most tolerant Rhizobium (TAL–1148) + B. subtilis, inoculation with the most tolerant Rhizobium (TAL–1148) + B. circulance, and inoculation with the most tolerant Rhizobium (TAL–1148) + B. coagulans) under different levels of Ni (0, 200, 400, and 600 mg kg−1), and their effects on growth, physiological characteristics, antioxidant enzymes, and Ni accumulation in faba bean plants (Vicia faba C.V. Nobaria 1) were determined. The results showed that Rhizobium (TAL–1148) and B. subtilis were the most tolerant of Ni. In pot trials, inoculation with the most tolerant Rhizobium TAL–1148 + B. subtilis treatment was shown to be more effective in terms of growth parameters (dry weight of plant, plant height, number of nodules, and N2 content), and this was reflected in physiological characteristics and antioxidant enzymes under 600 mg kg−1 Ni compared to the other treatments in the 2019/2020 season. In the second season, 2020/2021, a similar pattern was observed. Additionally, lower concentrations of Ni were found in faba bean plants (roots and shoots). Therefore, a combination of the most tolerant Rhizobium (TAL–1148) + B. subtilis treatment might be used to reduce Ni toxicity.

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“…The knowledge of proteins involved in cellular nickel trafficking (metalloregulators and metallochaperones) is summarized by Higgins in a review [5], which is complemented by a second monographic article by Nim and Wong [6], that focuses more specifically on the maturation of the nickel enzyme urease as a paradigmatic example of how cells balance nickel essentiality and toxicity. These two reviews are augmented by two original research papers on this aspect of the nickel bioinorganic chemistry field: the paper by Alfano et al [7] is focused on CooJ, an accessory protein necessary for the maturation of the nickel-dependent enzyme carbon monoxide dehydrogenase, while the paper by Barchi and Musiani [8] describes the structure-function relationships in InrS, a nickel-dependent transcription factor from cyanobacteria.…”

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confidence: 99%