Mo-, V-, and Fe-Nitrogenases Use a Universal Eight-Electron Reductive-Elimination Mechanism To Achieve N<sub>2</sub> Reduction

Harris, Derek F.; Lukoyanov, Dmitriy; Kallas, Hayden; Trncik, Christian; Yang, Zhi Yong; Compton, Philip D.; Kelleher, Neil L.; Einsle, Oliver; Dean, Dennis R.; Hoffman, Brian M.; Seefeldt, Lance C.

doi:10.1021/acs.biochem.9b00468

Cited by 116 publications

(184 citation statements)

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“…Previous in vitro studies have shown that electron availability, which can be manipulated by varying the dinitrogenase reductase versus dinitrogenase protein ratio, can influence the efficiency of Nase, including the specific N 2 reduction rate and the H 2 :N 2 ratio (Eady, ; Harris et al ., ). For R .…”

Section: Resultsmentioning

confidence: 97%

“…Our direct measurements of N 2 reduction and H 2 production indicate that the V‐Nase H 2 :N 2 ratio can be as low as ~1.5, half of the canonical 3:1 ratio (Table ). In fact, recent evidence has confirmed that all three forms of Nase use an analogous catalytic mechanism with the same minimum 1 H 2 : 1 N 2 stoichiometry for N 2 binding to the active site (Lukoyanov et al ., , ; Harris et al ., ; Harris et al ., ). Many of the measurements that led to the canonical 3:1 ratio for V‐Nase were conducted at 30°C (Bishop et al ., ; Dilworth et al ., ) but there are hints that the H 2 :N 2 ratio may be temperature dependent and that it is lower at 19°C, the temperature where our growth experiments were performed (Table S2; Miller and Eady, ).…”

Section: Resultsmentioning

confidence: 97%

“…Diazotrophic growth on succinate and acetate are differentiated by electron availability Previous in vitro studies have shown that electron availability, which can be manipulated by varying the dinitrogenase reductase versus dinitrogenase protein ratio, can influence the efficiency of Nase, including the specific N 2 reduction rate and the H 2 :N 2 ratio (Eady, 1996;Harris et al, 2019). For R. palustris, the key determinants of whether it is limited by electron acceptors or donors are (i) the oxidation state of the substrate relative to the biomass (Table 1) Fig.…”

Section: Mo-nase Strain Grows Slowly Compared With the Wild Type Strainmentioning

confidence: 99%

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Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Luxem

Kraepiel

Zhang

et al. 2020

Environmental Microbiology

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Summary Biological nitrogen fixation is catalyzed by the molybdenum (Mo), vanadium (V) and iron (Fe)‐only nitrogenase metalloenzymes. Studies with purified enzymes have found that the ‘alternative’ V‐ and Fe‐nitrogenases generally reduce N2 more slowly and produce more byproduct H2 than the Mo‐nitrogenase, leading to an assumption that their usage results in slower growth. Here we show that, in the metabolically versatile photoheterotroph Rhodopseudomonas palustris, the type of carbon substrate influences the relative rates of diazotrophic growth based on different nitrogenase isoforms. The V‐nitrogenase supports growth as fast as the Mo‐nitrogenase on acetate but not on the more oxidized substrate succinate. Our data suggest that this is due to insufficient electron flux to the V‐nitrogenase isoform on succinate compared with acetate. Despite slightly faster growth based on the V‐nitrogenase on acetate, the wild‐type strain uses exclusively the Mo‐nitrogenase on both carbon substrates. Notably, the differences in H2:N2 stoichiometry by alternative nitrogenases (~1.5 for V‐nitrogenase, ~4–7 for Fe‐nitrogenase) and Mo‐nitrogenase (~1) measured here are lower than prior in vitro estimates. These results indicate that the metabolic costs of V‐based nitrogen fixation could be less significant for growth than previously assumed, helping explain why alternative nitrogenase genes persist in diverse diazotroph lineages and are broadly distributed in the environment.

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 97%

Section: Mo-nase Strain Grows Slowly Compared With the Wild Type Strainmentioning

confidence: 99%

See 1 more Smart Citation

Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Luxem

Kraepiel

Zhang

et al. 2020

Environmental Microbiology

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“…Instead, it is possible that, lacking nifEN , an alternative and/or simplified pathway for FeMo‐ or similar cofactor synthesis may have acted as a transition state between such an Mo‐independent stage (i.e., binding a cluster resembling the NifB‐cofactor; Boyd & Peters, ; Mus et al, ) and the development of the canonical FeMo‐cofactor biosynthetic pathway. It is thus reasonable to speculate that this transition to Mo‐usage may be exhibited by AncC–D ancestors. Mo‐nitrogenases are far more efficient at reducing nitrogen than V‐ or Fe‐nitrogenases (Eady, ; Harris et al, ; Harris, Yang, et al, ), and the majority of all extant nitrogenases are Mo‐dependent across both anoxic and oxic environments (Boyd et al, ; Mus et al, ; Raymond et al, ). Even those organisms that have additional V‐ or Fe‐nitrogenases still retain and preferentially express Mo‐nitrogenases (Boyd, Anbar, et al, ; Boyd, Hamilton, et al, ; Dos Santos et al, ; Hamilton et al, ; Raymond et al, ).…”

Section: Discussionmentioning

confidence: 99%

Reconstructing the evolutionary history of nitrogenases: Evidence for ancestral molybdenum‐cofactor utilization

et al. 2020

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The nitrogenase metalloenzyme family, essential for supplying fixed nitrogen to the biosphere, is one of life's key biogeochemical innovations. The three forms of nitrogenase differ in their metal dependence, each binding either a FeMo-, FeV-, or FeFecofactor where the reduction of dinitrogen takes place. The history of nitrogenase metal dependence has been of particular interest due to the possible implication that ancient marine metal availabilities have significantly constrained nitrogenase evolution over geologic time. Here, we reconstructed the evolutionary history of nitrogenases, and combined phylogenetic reconstruction, ancestral sequence inference, and structural homology modeling to evaluate the potential metal dependence of ancient nitrogenases. We find that active-site sequence features can reliably distinguish extant Mo-nitrogenases from V-and Fe-nitrogenases and that inferred ancestral sequences at the deepest nodes of the phylogeny suggest these ancient proteins most resemble modern Mo-nitrogenases. Taxa representing early-branching nitrogenase lineages lack one or more biosynthetic nifE and nifN genes that both contribute to the assembly of the FeMo-cofactor in studied organisms, suggesting that early Monitrogenases may have utilized an alternate and/or simplified pathway for cofactor biosynthesis. Our results underscore the profound impacts that protein-level innovations likely had on shaping global biogeochemical cycles throughout the Precambrian, in contrast to organism-level innovations that characterize the Phanerozoic Eon. K E Y W O R D Sancestral sequence reconstruction, metal cofactor, metalloenzyme, nitrogen fixation, nitrogenase This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…Molecular hydrogen (H2) is an obligatory product of nitrogen fixation and, in our experiments, is generated simultaneously with the production of methane from carbon dioxide (53,54). We explored whether the buildup and isotopic composition of H2 influence methane isotope fractionation by nitrogenase, as has been observed for mcr-based methanogenesis (2,43,48,(55)(56)(57)(58)(59)(60)(61)(62)(63)(64).…”

Section: Hydrogen Concentration Does Not Influence Methane Isotope Frmentioning

confidence: 96%

Large Hydrogen Isotope Fractionation Distinguishes Nitrogenase-Derived Methane from Other Methane Sources

Luxem

Leavitt

Zhang

2020

Appl Environ Microbiol

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Biological nitrogen fixation is catalyzed by the enzyme nitrogenase. Two forms of this metalloenzyme, the vanadium (V) and iron (Fe)-only nitrogenases, were recently found to reduce small amounts of carbon dioxide (CO2) into the potent greenhouse gas methane (CH4). Here we report carbon (13C/12C) and hydrogen (2H/1H) stable isotopic compositions and fractionations of methane generated by V- and Fe-only nitrogenases in the metabolically versatile nitrogen fixer Rhodopseudomonas palustris. The stable carbon isotope fractionation imparted by both forms of alternative nitrogenase are within the range observed for hydrogenotrophic methanogenesis (13αCO2/CH4 = 1.051 ± 0.002 for V-nitrogenase and 1.055 ± 0.001 for Fe-only nitrogenase, mean ± SE). In contrast, the hydrogen isotope fractionations (2αH2O/CH4 = 2.071 ± 0.014 for V-nitrogenase and 2.078 ± 0.018 for Fe-only nitrogenase) are the largest of any known biogenic or geogenic pathway. The large 2αH2O/CH4 shows that the reaction pathway nitrogenases use to form methane strongly discriminates against 2H, and that 2αH2O/CH4 distinguishes nitrogenase-derived methane from all other known biotic and abiotic sources. These findings on nitrogenase-derived methane will help constrain carbon and nitrogen flows in microbial communities and the role of the alternative nitrogenases in global biogeochemical cycles. Importance All forms of life require nitrogen for growth. Many different kinds of microbes living in diverse environments make inert nitrogen gas from the atmosphere bioavailable using a special enzyme, nitrogenase. Nitrogenase has a wide substrate range, and in addition to producing bioavailable nitrogen, some forms of nitrogenase also produce small amounts of the greenhouse gas methane. This is different from other microbes that produce methane to generate energy. Until now, there was no good way to determine when microbes with nitrogenases are making methane in nature. Here, we present an isotopic fingerprint that allows scientists to distinguish methane from microbes making it for energy versus those making it as a byproduct of nitrogen acquisition. With this new fingerprint, it will be possible to improve our understanding of the relationship between methane production and nitrogen acquisition in nature.

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Mo-, V-, and Fe-Nitrogenases Use a Universal Eight-Electron Reductive-Elimination Mechanism To Achieve N₂ Reduction

Cited by 116 publications

References 56 publications

Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Reconstructing the evolutionary history of nitrogenases: Evidence for ancestral molybdenum‐cofactor utilization

Large Hydrogen Isotope Fractionation Distinguishes Nitrogenase-Derived Methane from Other Methane Sources

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Mo-, V-, and Fe-Nitrogenases Use a Universal Eight-Electron Reductive-Elimination Mechanism To Achieve N2 Reduction

Cited by 116 publications

References 56 publications

Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Carbon substrate re‐orders relative growth of a bacterium using Mo‐, V‐, or Fe‐nitrogenase for nitrogen fixation

Reconstructing the evolutionary history of nitrogenases: Evidence for ancestral molybdenum‐cofactor utilization

Large Hydrogen Isotope Fractionation Distinguishes Nitrogenase-Derived Methane from Other Methane Sources

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Mo-, V-, and Fe-Nitrogenases Use a Universal Eight-Electron Reductive-Elimination Mechanism To Achieve N₂ Reduction