X-ray crystallographic and computational studies of the O
            <sub>2</sub>
            -tolerant [NiFe]-hydrogenase 1 from
            <i>Escherichia coli</i>

Volbeda, Anne; Amara, Patricia; Darnault, Claudine; Mouesca, Jean‐Marie; Parkin, Alison; Roessler, Maxie M.; Armstrong, Fräser A.; Fontecilla‐Camps, Juan C.

doi:10.1073/pnas.1119806109

Cited by 192 publications

(298 citation statements)

References 44 publications

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“…In the T18D variant, the H-bond between Glu-25 L and the 18-position residue is lost. Thr-18 S was proposed to be a relay of PT, next to Glu-25 L (11,13,15). Alcoholic residues have frequently been shown, including in [FeFe]-hydrogenases, to act as proton relays or to influence the reactivity of neighboring relay residues (44, 45), but we cannot confirm this function, at least for the Df enzyme.…”

Section: Discussioncontrasting

confidence: 45%

“…We used the nonredox HDE assay to show that changing the residue at this position may moderately affect the rate of gas diffusion in the tunnel (Table 2, for example, the rate constant for H 2 release from the active site in the T18D variant is approximatively 5-fold lower than that in the WT enzyme). Because the H 2 oxidation/production rates and the rates of H/D exchange (k) are affected to the same extent in the T18V, T18Q, and T18D variants, it may have been tempting to assume that S is involved in a step that is involved in the three reactions, namely active site chemistry or proton transfer, as suggested by calculations and crystallographic studies (13)(14)(15)(16). However, a crucial observation is that the T18G variant is almost inactive for H 2 oxidation or production and yet catalyzes HDE at a high rate.…”

Section: Discussionmentioning

confidence: 99%

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A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

Abou‐Hamdan

Ceccaldi

Lebrette

et al. 2015

Journal of Biological Chemistry

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Background:A conserved threonine in [NiFe]-hydrogenases is a putative proton transfer relay. Results: Poorly active variants have modified spectroscopic signatures associated with changes in local protein structure. Conclusion: This threonine is not necessarily a proton transfer relay but, rather, stabilizes reaction intermediates. Significance: Combined kinetic, spectroscopic, and structural characterizations of several variants are necessary to assess the role of a residue in [NiFe]-hydrogenase.

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Section: Discussioncontrasting

confidence: 45%

Section: Discussionmentioning

confidence: 99%

A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

Abou‐Hamdan

Ceccaldi

Lebrette

et al. 2015

Journal of Biological Chemistry

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“…[106] This shows that Ni-B reactivates faster in O 2 -tolerant than in O 2 -sensitive Hases. [118,119] Thanks to the resolution of the crystallographic structures of three O 2 -tolerant Hases, [120][121][122] and to genetic engineering both on O 2 -tolerant and O 2 -sensitive Hases, a general scheme is nowadays proposed that may account for O 2 tolerance.…”

Section: Chemelectrochem Reviews Wwwchemelectrochemorgmentioning

confidence: 99%

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective

et al. 2014

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Among sustainable alternatives to fossil fuel, proton exchange membrane fuel cells are promising devices that deliver electricity from hydrogen and oxygen, producing only water. The transformation of the fuel and oxidant however relies on rare‐metal catalysts. H2/O2 enzymatic biofuel cells thus emerge as sustainable biotechnological devices in which chemical catalysts are replaced by hydrogenases at the anode and multicopper oxidases at the cathode. This review discusses the recent breakthroughs and the limitations in all the components of H2/O2 biofuel cells: 1) Catalytic mechanisms involved in multicopper oxidases and hydrogenases, in addition to the new potential of enzymes from the biodiversity pool, which exhibit outstanding properties. 2) The molecular basis for oriented enzyme immobilization on the electrochemical interfaces as a prerequisite for a fast direct electron‐transfer rate. 3) The requirement for 3D networks to enhance current densities. 4) The production of H2 from biomass. 5) The history of H2/O2 biofuel cells and recent devices, which also highlights the remaining issues that will allow the use of such devices in low‐power applications.

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“…As illustrated in Fig. 2B, the unusual structure allows it to undergo two consecutive one-electron transfers at similar potentialsthe rapid removal of the second electron (in a proton-coupled reaction) yielding a Fe-N(peptide) bond in a reaction that is (locally at least) electroneutral (1,2,10,(12)(13)(14)(15). The [3Fe-4S] cluster occupying the medial position in respiratory membrane bound [NiFe]-hydrogenases also has a higher reduction potential in O 2 -tolerant hydrogenases (e.g., 190 ± 30 mV at pH 6 in E. coli Hyd-1) (15) than in standard hydrogenases (e.g., −70 mV at pH 7 in Desulfovibrio gigas hydrogenase) (16).…”

mentioning

confidence: 99%

“…Fig. 2A shows the structure of an O 2 -tolerant [NiFe]-hydrogenase known as hydrogenase-1 (Hyd-1), which is produced in Escherichia coli (10). Like other respiratory membrane-bound [NiFe]-hydrogenases, it contains a buried [NiFe] catalytic center and FeS clusters that are located in separate α and β subunits.…”

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confidence: 99%

How oxygen reacts with oxygen-tolerant respiratory [NiFe]-hydrogenases

Wulff

Day

Sargent

et al. 2014

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

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An oxygen-tolerant respiratory [NiFe]-hydrogenase is proven to be a four-electron hydrogen/oxygen oxidoreductase, catalyzing the reaction 2 H 2 + O 2 = 2 H 2 O, equivalent to hydrogen combustion, over a sustained period without inactivating. At least 86% of the H 2 O produced by Escherichia coli hydrogenase-1 exposed to a mixture of 90% H 2 and 10% O 2 is accounted for by a direct four-electron pathway, whereas up to 14% arises from slower side reactions proceeding via superoxide and hydrogen peroxide. The direct pathway is assigned to O 2 reduction at the [NiFe] active site, whereas the side reactions are an unavoidable consequence of the presence of low-potential relay centers that release electrons derived from H 2 oxidation. The oxidase activity is too slow to be useful in removing O 2 from the bacterial periplasm; instead, the four-electron reduction of molecular oxygen to harmless water ensures that the active site survives to catalyze sustained hydrogen oxidation.hydrogen | mass spectrometry | Fe-S cluster H ydrogenases are enzymes that catalyze the interconversion of H 2 and H + with great efficiency. Containing Fe or Fe and Ni as active metals, they are not only important in biohydrogen production (by fermentative and photosynthetic means) but also provide inspiration for detailed understanding and development of optimal molecular electrocatalysts. The minimal active site motif, common to all hydrogenases, is a low-spin Fe atom coordinated by CO, CN − , and thiolate ligands, a combination expected to be unstable under aerobic conditions. Indeed, most hydrogenases suffer long-term or permanent inactivation when exposed to even traces of O 2 . It is therefore of special interest that certain [NiFe]-hydrogenases have evolved to sustain H 2 oxidation in the continued presence of O 2 , without inactivation: these enzymes are known as O 2 -tolerant [NiFe]-hydrogenases.Most of our current insight into the mechanism of O 2 tolerance stems from studies on respiratory membrane-bound [NiFe]-hydrogenases that couple H 2 oxidation to reduction of quinones (1-3). These enzymes are localized at the cytoplasmic membrane and project into the periplasmic space. A model proposed for the O 2 -tolerance mechanism of these [NiFe]-hydrogenases ( Fig. 1) is based on the following evidence. Oxygen reacts with O 2 -tolerant membrane-bound [NiFe]-hydrogenases to form, exclusively, an inactive state known as Ni-B or "ready," formulated as a Ni(III)-OH species, which is rapidly reactivated by one-electron transfer to rejoin the catalytic cycle of H 2 oxidation. Provided Ni-B is the sole product of O 2 attack, the presence of O 2 merely attenuates the steady-state rate of H 2 oxidation. In contrast, standard (O 2 sensitive) [NiFe]-hydrogenases react with O 2 to give a mixture of states, including ones variously known as "unready" or Ni-A, in which O 2 is either only partially reduced (possibly trapped as a peroxide) or has oxygenated atoms of the active site (3-7). The unready states are only reactivated very slowly; consequently, t...

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X-ray crystallographic and computational studies of the O ₂ -tolerant [NiFe]-hydrogenase 1 from Escherichia coli

Cited by 192 publications

References 44 publications

A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective

How oxygen reacts with oxygen-tolerant respiratory [NiFe]-hydrogenases

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X-ray crystallographic and computational studies of the O 2 -tolerant [NiFe]-hydrogenase 1 from Escherichia coli

Cited by 192 publications

References 44 publications

A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

A Threonine Stabilizes the NiC and NiR Catalytic Intermediates of [NiFe]-hydrogenase

Biohydrogen for a New Generation of H2/O2 Biofuel Cells: A Sustainable Energy Perspective

How oxygen reacts with oxygen-tolerant respiratory [NiFe]-hydrogenases

Contact Info

Product

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X-ray crystallographic and computational studies of the O ₂ -tolerant [NiFe]-hydrogenase 1 from Escherichia coli

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective