Bonnie J. Murphy scite author profile

The enterobacterium Escherichia coli synthesizes two H 2 uptake enzymes, Hyd-1 and Hyd-2. We show using precise electrochemical kinetic measurements that the properties of Hyd-1 and Hyd-2 contrast strikingly, and may be individually optimized to function under distinct environmental conditions. Hyd-2 is well suited for fast and efficient catalysis in more reducing environments, to the extent that in vitro it behaves as a bidirectional hydrogenase. In contrast, Hyd-1 is active for H 2 oxidation under more oxidizing conditions and cannot function in reverse. Importantly, Hyd-1 is O 2 tolerant and can oxidize H 2 in the presence of air, whereas Hyd-2 is ineffective for H 2 oxidation under aerobic conditions. The results have direct relevance for physiological roles of Hyd-1 and Hyd-2, which are expressed in different phases of growth. The properties that we report suggest distinct technological applications of these contrasting enzymes.Hydrogenases catalyze the reversible cleavage of H 2 into protons and electrons, and play an important role in the energy metabolism of a broad range of microorganisms (1). Hydrogenases are classified according to their active site metal ion content, and three phylogenetically distinct classes have so far been identified: di-iron [FeFe]-, nickel-iron [NiFe]-, and mono-iron [Fe]-hydrogenases (1). Nickel-iron hydrogenases are the most abundant of the three types (1), and many members of this class are membrane bound, with the membrane-extrinsic domain consisting of a large subunit containing the active site, and a small subunit accommodating one to three electron-transferring iron-sulfur clusters. The active sites of [NiFe]-hydrogenases contain a nickel atom coordinated by four cysteine-S ligands, two of which bridge to an iron atom that is further coordinated by three unusual diatomic ligands, two cyanides and one carbonyl (2).Hydrogenases are inactivated by O 2

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Bacterial formate hydrogenlyase complex

McDowall

Murphy

Haumann

et al. 2014

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

219

238

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Significance The isolation of an active formate hydrogenlyase is a breakthrough in understanding the molecular basis of bacterial hydrogen production. For over 100 years, Escherichia coli has been known to evolve H 2 when cultured under fermentative conditions. Glucose is metabolized to formate, which is then oxidized to CO 2 with the concomitant reduction of protons to H 2 by a single complex called formate hydrogenlyase, which had been genetically, but never biochemically, characterized. In this study, innovative molecular biology and electrochemical experiments reveal a hydrogenase enzyme with the unique ability to sustain H 2 production even under high partial pressures of H 2 . Harnessing bacterial H 2 production offers the prospect of a source of fully renewable H 2 energy, freed from any dependence on fossil fuel.

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Principles of Sustained Enzymatic Hydrogen Oxidation in the Presence of Oxygen – The Crucial Influence of High Potential Fe–S Clusters in the Electron Relay of [NiFe]-Hydrogenases

Evans¹,

Parkin²,

Roessler³

et al. 2013

J. Am. Chem. Soc.

145

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"Hyd-1", produced by Escherichia coli , exemplifies a special class of [NiFe]-hydrogenase that can sustain high catalytic H(2) oxidation activity in the presence of O(2)-an intruder that normally incapacitates the sulfur- and electron-rich active site. The mechanism of "O(2) tolerance" involves a critical role for the Fe-S clusters of the electron relay, which is to ensure the availability-for immediate transfer back to the active site-of all of the electrons required to reduce an attacking O(2) molecule completely to harmless H(2)O. The unique [4Fe-3S] cluster proximal to the active site is crucial because it can rapidly transfer two of the electrons needed. Here we investigate and establish the equally crucial role of the high potential medial [3Fe-4S] cluster, located >20 Å from the active site. A variant, P242C, in which the medial [3Fe-4S] cluster is replaced by a [4Fe-4S] cluster, is unable to sustain steady-state H(2) oxidation activity in 1% O(2). The [3Fe-4S] cluster is essential only for the first stage of complete O(2) reduction, ensuring the supply of all three electrons needed to form the oxidized inactive state "Ni-B" or "Ready" (Ni(III)-OH). Potentiometric titrations show that Ni-B is easily reduced (E(m) ≈ +0.1 V at pH 6.0); this final stage of the O(2)-tolerance mechanism regenerates active enzyme, effectively completing a competitive four-electron oxidase cycle and is fast regardless of alterations at the proximal or medial clusters. As a consequence of all these factors, the enzyme's response to O(2), viewed by its electrocatalytic activity in protein film electrochemistry (PFE) experiments, is merely to exhibit attenuated steady-state H(2) oxidation activity; thus, O(2) behaves like a reversible inhibitor rather than an agent that effectively causes irreversible inactivation. The data consolidate a rich picture of the versatile role of Fe-S clusters in electron relays and suggest that Hyd-1 can function as a proficient hydrogen oxidase.

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Rotary substates of mitochondrial ATP synthase reveal the basis of flexible F ₁ -F _o coupling

Murphy

Klusch

Langer

et al. 2019

Science

179

142

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F1Fo–adenosine triphosphate (ATP) synthases make the energy of the proton-motive force available for energy-consuming processes in the cell. We determined the single-particle cryo–electron microscopy structure of active dimeric ATP synthase from mitochondria of Polytomella sp. at a resolution of 2.7 to 2.8 angstroms. Separation of 13 well-defined rotary substates by three-dimensional classification provides a detailed picture of the molecular motions that accompany c-ring rotation and result in ATP synthesis. Crucially, the F1 head rotates along with the central stalk and c-ring rotor for the first ~30° of each 120° primary rotary step to facilitate flexible coupling of the stoichiometrically mismatched F1 and Fo subcomplexes. Flexibility is mediated primarily by the interdomain hinge of the conserved OSCP subunit. A conserved metal ion in the proton access channel may synchronize c-ring protonation with rotation.

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How Escherichia coli is equipped to oxidize hydrogen under different redox conditions.

Lukey¹,

Parkin²,

Roessler³

et al. 2010

Journal of Biological Chemistry

117

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PAGE 17257:Fig. 2, line 9 should read: F, a projection through a 350 nm thick section of longitudinally sectioned P3H1 null tendon from which the tilt series (supplemental Fig. S1) was collected. ADDITIONS AND CORRECTIONS This paper is available online at www.jbc.orgWe suggest that subscribers photocopy these corrections and insert the photocopies in the original publication at the location of the original article. Authors are urged to introduce these corrections into any reprints they distribute. Secondary (abstract) services are urged to carry notice of these corrections as prominently as they carried the original abstracts.

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Bonnie J. Murphy

How Escherichia coli Is Equipped to Oxidize Hydrogen under Different Redox Conditions

Bacterial formate hydrogenlyase complex

Principles of Sustained Enzymatic Hydrogen Oxidation in the Presence of Oxygen – The Crucial Influence of High Potential Fe–S Clusters in the Electron Relay of [NiFe]-Hydrogenases

Rotary substates of mitochondrial ATP synthase reveal the basis of flexible F ₁ -F _o coupling

How Escherichia coli is equipped to oxidize hydrogen under different redox conditions.

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Bonnie J. Murphy

How Escherichia coli Is Equipped to Oxidize Hydrogen under Different Redox Conditions

Bacterial formate hydrogenlyase complex

Principles of Sustained Enzymatic Hydrogen Oxidation in the Presence of Oxygen – The Crucial Influence of High Potential Fe–S Clusters in the Electron Relay of [NiFe]-Hydrogenases

Rotary substates of mitochondrial ATP synthase reveal the basis of flexible F 1 -F o coupling

How Escherichia coli is equipped to oxidize hydrogen under different redox conditions.

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Rotary substates of mitochondrial ATP synthase reveal the basis of flexible F ₁ -F _o coupling