The unusual redox properties of C-type oxidases

Melin, Frédéric; Xie, Hao; Meyer, Thomas; Ahn, Yujin; Gennis, Robert B.; Michel, Hartmut; Hellwig, Petra

doi:10.1016/j.bbabio.2016.09.009

Cited by 28 publications

(36 citation statements)

References 89 publications

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“…In the presence of O 2 , a sigmoidal curve with an onset at +0.05 V and half‐wave potential value of −0.19 V is observed. This behavior has been observed with other heme‐copper oxygen reductases, including cytochrome aa 3 from Paracoccus denitrificans , cytochrome ba 3 oxidase from Thermus thermophilus and cytochrome cbb 3 oxidases from Pseudomonas stutzeri , Rhodobacter sphaeroides and Vibrio cholerae and it is typical for the electrocatalytic reduction of O 2 . The limiting current at −0.4 V increases as a function of the electrode rotation speed, and follows a Koutecky–Levich relationship (see Fig.…”

Section: Resultssupporting

confidence: 56%

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli

et al. 2018

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The coupling of the reaction of a tightly bound ubiquinone with the reduction of O2 in cytochrome bo3 of Escherichia coli was investigated. In the absence of the quinone, a strongly diminished rate of electrocatalytic reduction of oxygen is detected, which can be restored by adding quinones. The correlation of previous EPR data with the electrocatalytic study on mutations in the binding site at positions, Q101, D75, F93, H98, I102 and R71 reveal that the stabilization of the radical is not necessary for the oxygen reaction. The Q101 and F93 variants exhibit both well‐defined catalytic i–V curves, whereas D75H, H98F, I102W and R71H exhibit broad i–V curves with large hysteresis pointing toward a strong alteration in their catalytic activity.

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Section: Resultssupporting

confidence: 56%

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli

et al. 2018

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“…We refer to “apparent” redox potentials because the analysis reflects only the distribution of a single electron after 500 ms in the five-electron system (among five sites). Because interactions between the redox sites are not considered (see 35 , 36 ), the values differ from those obtained in redox titrations, which typically yield a higher midpoint potential for the catalytic site heme (here heme a 3 ) than for the intermediate electron acceptor (here heme a ) 35 , 36 , although in many bacterial oxidases the difference between the midpoint potentials is reversed 37 . Furthermore, because a single electron equilibrates among the five redox sites, the situation differs from a redox titration 38 .…”

Section: Resultsmentioning

confidence: 99%

The electron distribution in the “activated” state of cytochrome c oxidase

Vilhjálmsdóttir

Gennis

Brzezinski

2018

Sci Rep

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Cytochrome c oxidase catalyzes reduction of O2 to H2O at a catalytic site that is composed of a copper ion and heme group. The reaction is linked to translocation of four protons across the membrane for each O2 reduced to water. The free energy associated with electron transfer to the catalytic site is unequal for the four electron-transfer events. Most notably, the free energy associated with reduction of the catalytic site in the oxidized cytochrome c oxidase (state O) is not sufficient for proton pumping across the energized membrane. Yet, this electron transfer is mechanistically linked to proton pumping. To resolve this apparent discrepancy, a high-energy oxidized state (denoted OH) was postulated and suggested to be populated only during catalytic turnover. The difference between states O and OH was suggested to be manifested in an elevated midpoint potential of CuB in the latter. This proposal predicts that one-electron reduction of cytochrome c oxidase after its oxidation would yield re-reduction of essentially only CuB. Here, we investigated this process and found ~5% and ~6% reduction of heme a3 and CuB, respectively, i.e. the apparent redox potentials for heme a3 and CuB are lower than that of heme a.

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“…These results also explain the selective NO reduction cross-reactivity of HCOs: HCOs with low heme E°′ values such as caa 3 oxidase (E°′ = 180 mV), ba 3 oxidase (E°′ = 199 mV) (39) from Thermus thermophilus, bo 3 oxidase from E. coli (E°′ = 160-200 mV) (40), and cbb 3 oxidase (E°′ = −59 mV) from Pseudomonas stutzeri perform NOR reactivity (41). Specifically, the cbb 3 oxidases are C-type HCOs that exhibit unusually low heme redox potential (approximately −50 mV) due to Hbond donation by their proximal His to nearby carboxylate like the Asp-His-Fe triad of peroxidases (42). These C-type HCOs exhibit the highest NO reduction cross-reactivity, consistent with the conclusions of this study that low values of heme E°′ are preferred for NO reduction reactivity.…”

Section: Significancementioning

confidence: 99%

Heme redox potentials hold the key to reactivity differences between nitric oxide reductase and heme-copper oxidase

Bhagi‐Damodaran

Reed

Zhu

et al. 2018

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

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Despite high structural homology between NO reductases (NORs) and heme-copper oxidases (HCOs), factors governing their reaction specificity remain to be understood. Using a myoglobin-based model of NOR (FeMb) and tuning its heme redox potentials (E°') to cover the native NOR range, through manipulating hydrogen bonding to the proximal histidine ligand and replacing heme with monoformyl (MF-) or diformyl (DF-) hemes, we herein demonstrate that the E°' holds the key to reactivity differences between NOR and HCO. Detailed electrochemical, kinetic, and vibrational spectroscopic studies, in tandem with density functional theory calculations, demonstrate a strong influence of heme E°' on NO reduction. Decreasing E°' from +148 to -130 mV significantly impacts electronic properties of the NOR mimics, resulting in 180- and 633-fold enhancements in NO association and heme-nitrosyl decay rates, respectively. Our results indicate that NORs exhibit finely tuned E°' that maximizes their enzymatic efficiency and helps achieve a balance between opposite factors: fast NO binding and decay of dinitrosyl species facilitated by low E°' and fast electron transfer facilitated by high E°'. Only when E°' is optimally tuned in FeMb(MF-heme) for NO binding, heme-nitrosyl decay, and electron transfer does the protein achieve multiple (>35) turnovers, previously not achieved by synthetic or enzyme-based NOR models. This also explains a long-standing question in bioenergetics of selective cross-reactivity in HCOs. Only HCOs with heme E°' in a similar range as NORs (between -59 and 200 mV) exhibit NOR reactivity. Thus, our work demonstrates efficient tuning of E°' in various metalloproteins for their optimal functionality.

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The unusual redox properties of C-type oxidases

Cited by 28 publications

References 89 publications

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli

The electron distribution in the “activated” state of cytochrome c oxidase

Heme redox potentials hold the key to reactivity differences between nitric oxide reductase and heme-copper oxidase

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The unusual redox properties of C-type oxidases

Cited by 28 publications

References 89 publications

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo3 oxidase from Escherichia coli

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo3 oxidase from Escherichia coli

The electron distribution in the “activated” state of cytochrome c oxidase

Heme redox potentials hold the key to reactivity differences between nitric oxide reductase and heme-copper oxidase

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Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli

Role of the tightly bound quinone for the oxygen reaction of cytochrome bo₃ oxidase from Escherichia coli