Evolution of Molybdenum Nitrogenase during the Transition from Anaerobic to Aerobic Metabolism

Boyd, Eric S.; Costas, Amaya M. Garcia; Hamilton, Trinity L.; Mus, Florence; Peters, John W.

doi:10.1128/jb.02611-14

Cited by 88 publications

(129 citation statements)

References 75 publications

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“…nitrogenases, which notably branch more recently than V-, Fe-, and Mb-Mc Mo-nitrogenases 621 . A subsequently published topology is more similar to the tree 622 presented here, though lacking in Clfx sequences (Boyd, Costas, Hamilton, Mus, & Peters, 2015;623 Boyd & Peters, 2013). It is possible that the larger sequence dataset used here has refined the 624 placement of these uncharacterized clades, which is supported by our analyses with an expanded 625 outgroup that maintains the positions of Clfx and F-Mc sequences (Appendix S2).…”

supporting

confidence: 61%

Reconstructing the Evolutionary History of Nitrogenases: Evidence for Ancestral Molybdenum-Cofactor Utilization

Garcia

McShea

Kolaczkowski

et al. 2019

Preprint

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15The nitrogenase metalloenzyme family, essential for supplying fixed nitrogen to the biosphere, is 16 one of life's key biogeochemical innovations. The three isozymes of nitrogenase differ in their 17 metal dependence, each binding either a FeMo-, FeV-, or FeFe-cofactor for the reduction of 18 nitrogen. The history of nitrogenase metal dependence has been of particular interest due to the 19 possible implication that ancient marine metal availabilities have significantly constrained 20 nitrogenase evolution over geologic time. Here, we combine phylogenetics and ancestral sequence 21 reconstruction -a method by which inferred, historical protein sequence information can be 22 linked to functional molecular properties -to reconstruct the metal dependence of ancient 23 nitrogenases. Inferred ancestral nitrogenase sequences at the deepest nodes of the phylogeny 24

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supporting

confidence: 61%

Reconstructing the Evolutionary History of Nitrogenases: Evidence for Ancestral Molybdenum-Cofactor Utilization

Garcia

McShea

Kolaczkowski

et al. 2019

Preprint

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“…There is growing evidence that bacteria use gene acquisition to adapt to ecological niches. For example, among nitrogen-fixing systems, the acquisition of symbiotic islands was reported for rhizobia (37); analysis of Azospirillum genomes revealed that a large proportion of the genes were acquired to adapt from marine to terrestrial environments (38) and that the evolution of nitrogenase from anoxic to aerobic environments was made possible due to gene acquisition (39).…”

Section: Discussionmentioning

confidence: 99%

The novel regulatory ncRNA, NfiS, optimizes nitrogen fixation via base pairing with the nitrogenase gene nifK mRNA in Pseudomonas stutzeri A1501

Zhan

Yan

Deng

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Unlike most Pseudomonas, the root-associated bacterium Pseudomonas stutzeri A1501 fixes nitrogen after the horizontal acquisition of a nitrogen-fixing (nif) island. A genome-wide search for small noncoding RNAs (ncRNAs) in P. stutzeri A1501 identified the novel P. stutzeri-specific ncRNA NfiS in the core genome, whose synthesis was significantly induced under nitrogen fixation or sorbitol stress conditions. The expression of NfiS was RNA chaperone Hfqdependent and activated by the sigma factor RpoN/global nitrogen activator NtrC/nif-specific activator NifA regulatory cascade. The nfiSdeficient mutant displayed reduced nitrogenase activity, as well as increased sensitivity to multiple stresses, such as osmotic and oxidative stresses. Secondary structure prediction and complementation studies confirmed that a stem-loop structure was essential for NfiS to regulate the nitrogenase gene nifK mRNA synthesis and thus nitrogenase activity. Microscale thermophoresis and physiological analysis showed that NfiS directly pairs with nifK mRNA and ultimately enhances nitrogenase activity by increasing the translation efficiency and the half-life of nifK mRNA. Our data also suggest structural and functional divergence of NfiS evolution in diazotrophic and nondiazotrophic backgrounds. It is proposed that NfiS was recruited by nifK mRNA as a novel regulator to integrate the horizontally acquired nif island into host global networks.nitrogen fixation | Pseudomonas stutzeri | regulatory ncRNA | NfiS | nifK mRNA

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“…This is an important thought with regard to both, the oxygen development in Earth history, and the predicted loss of oxygen in today's Oceans in a warming world (Keeling, Kortzinger, and Gruber 2010;Schmidtko, Stramma, and Visbeck 2017;Stramma et al 2008). The question of the evolutionary development of those three nitrogenases is still hotly debated, however, the general conclusion is that they have a common origin (Boyd et al 2011;Boyd et al 2015;Boyd and Peters 2013;Raymond et al 2004), which is supported, e.g. by the structural similarity of at least parts of their operons.…”

Section: Introductionmentioning

confidence: 99%

Facets of diazotrophy in the OMZ off Peru revisited- what we couldn’t see from a single marker gene approach

Christiansen

Löscher

2019

Preprint

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Correspondence to cloescher@biology.sdu.dk Significance statementThis study addresses the important process of N 2 fixation, based on a whole-metagenome and -transcriptome screening, reports an increased diversity of N 2 fixing microbes in the sulfidic shelf water off Peru, as compared to previous target-gene based studies from the same waters. In addition to a generally higher diversity, genes encoding for alternative nitrogenases, which were previously not subject of any study on N 2 fixation in oxygen minimum zones, were detected. The ecological meaning and evolutionary history of those alternative nitrogenases is subject of ongoing debates, however, their presence in OMZ waters would allow for N 2 fixation at extreme anoxia, which may become important in a future ocean challenged by progressive deoxygenation. AbstractBiological dinitrogen (N 2 ) fixation is the pathway making the large pool of atmospheric N 2 available to marine life. Besides direct rate measurements, a common approach to explore the potential for N 2 fixation in the ocean is a mining based on molecular genetic methods targeting the key functional gene nifH, coding for a subunit of the nitrogenase reductase. As novel sequencing and single cell techniques improved, our knowledge on the diversity of marine N 2 fixers grew exponentially. However, to date one aspect of N 2 fixation in the ocean is commonly left aside. This is the existence of two alternative types of nitrogenases, which are besides the Mo-Fe nitrogenase Nif, the Fe-Fe nitrogenase Anf, and the V-Fe nitrogenase Vnf, which differ with regard to their metal co-enzymes, as well as regarding their operon structure and composition. nifH-based studies may thus be biased, and alternative nitrogenases could not be recovered. Here, we screened a set of 6 metagenomes and -transcriptomes from a sulfidic water patch from the oxygen minimum zone off Peru for genes involved in N 2 fixation. We identified genes related to all three nitrogenases, and generally increased diversity as compared to our previous nifH-based study from the same waters. While we could not confirm gene expression of the alternative nitrogenases from our transcriptomes, we detected additional diazotrophs involved in N 2 fixation. We suggest that alternative nitrogenases may not be used under conditions present in those waters, however, depending on trace metal limitation in the future they may become active.

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Evolution of Molybdenum Nitrogenase during the Transition from Anaerobic to Aerobic Metabolism

Cited by 88 publications

References 75 publications

Reconstructing the Evolutionary History of Nitrogenases: Evidence for Ancestral Molybdenum-Cofactor Utilization

Reconstructing the Evolutionary History of Nitrogenases: Evidence for Ancestral Molybdenum-Cofactor Utilization

The novel regulatory ncRNA, NfiS, optimizes nitrogen fixation via base pairing with the nitrogenase gene nifK mRNA in Pseudomonas stutzeri A1501

Facets of diazotrophy in the OMZ off Peru revisited- what we couldn’t see from a single marker gene approach

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