eutropha system, was indeed able to bind the cofactor precursor w

eutropha system, was indeed able to bind the cofactor precursor with the cyano- and carbonyl ligands bound to a Fe atom, thus assigning a key role to this protein in the incorporation of the cofactor into hydrogenase [20]. In the same Pevonedistat in vivo system, the existence of HoxL-HoxG and HypC-HoxV complexes was inferred from SDS-PAGE analysis of proteins obtained in co-purification experiments [20]. The data from immunoblot analysis under native conditions and from mass spectrometry analysis presented here provide a direct evidence of the existence of two such complexes

in R. leguminosarum: a major HupL-HupF complex and a much less abundant one involving HupF and HupK. The high recovery of HupL with HupFST points towards a strong interaction between both proteins in the ΔhupD mutant, where the NiFe cofactor is supposed to be inserted into HupL but the protein is still unprocessed. In this situation HupF is firmly attached to unprocessed HupL, and we hypothesize that this immature protein might require the oxygen-protective function of HupF to protect the labile NiFe cluster prior to proteolytic processing, when the protein is still in an open conformation. Following the model described for the R. eutropha system [24] we propose that R. CDK inhibitor leguminosarum proteins in these complexes

interact to transfer the iron-containing hydrogenase cofactor precursor from HupK to HupL, Tariquidar prior to the final HupD-mediated proteolytic step. But HupF protein also Isotretinoin contributes to the stability of hydrogenase large subunit at high oxygen tensions. Data from experiments performed in a ΔhupS background indicate that HupF is not bound to HupL after HupD-mediated proteolytic processing (our unpublished results), indicating that mature HupL is stable enough to not require any additional chaperones, as suggested also by the results on stability of mature enzyme under 21% O2 presented in this paper. This model might not be the only possibility for the biosynthesis of oxygen-tolerant hydrogenases, since recent evidences indicate that hydrogenase-1 from this E. coli is an oxygen-tolerant hydrogen uptake

hydrogenase [37], and neither HupF- nor HupK-like proteins are present in this bacterium. Previous data from our lab and from other laboratories suggest that adaptations to the presence of oxygen also exist for the synthesis of hydrogenase small subunit HupS through the participation of HupGHIJ proteins or their homologues [19, 38]. In the case of endosymbiotic bacteria, such as R. leguminosarum, the synthesis of hydrogenase under the ultra-low oxygen tensions prevalent in symbiotic conditions is less severely dependent on such auxiliary proteins [19]. The low, although significant, levels of hydrogenase activity detected in bacteroids induced by the ΔhupF mutant, but not in vegetative cells, might indicate that for R.

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