Conformational triggering in voltammetry and single-molecule conductivity of two-centre redox metalloproteins: Cytochrome c4 and copper nitrite reductase

Henrik Bohr; Irene Shim; Jens Ulstrup; Xinxin Xiao

doi:10.1016/j.coelec.2022.101137

Conformational triggering in voltammetry and single-molecule conductivity of two-centre redox metalloproteins: Cytochrome c4 and copper nitrite reductase

Henrik Bohr, Irene Shim, Jens Ulstrup^*, Xinxin Xiao

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

2 Citations (Scopus)

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Abstract

Blue copper enzymes often show no voltammetry themselves, whereas substrate binding triggers strong electrocatalytic signals. Similarly, electrochemical STM only gives strong contrasts when substrate (O2, NO2-) is present. AFM shows that CuNIR on Au(111)-electrodes modified by self-assembled cysteamine monolayers (SAMs) maintains constant height throughout the electrocatalytic range, while NO2- triggers substantial enzyme ‘swelling’. ‘Swelling’ does not accord with the crystalline state, which, however, is not the relevant catalytic environment.

With a view on understanding these patterns, we present ab initio quantum chemical studies of CuNIR/OH2 and CuNIR/NO2- 740-atom fragments including the type I and type II Cu-centres. Replacing water at the type II centre by nitrite triggers 2-Å Cu–Cu distance increase, according with enzyme ‘swelling’. 2 Å Cu–Cu increase would close intramolecular ET entirely, but is compensated by efficient superexchange alignment of closely interacting LUMOs and HOMOs. In the water-bound enzyme these orbitals are separated by unfavourable through-space tunneling regions.

Original language	English
Article number	101137
Journal	Current Opinion in Electrochemistry
Volume	36
DOIs	https://doi.org/10.1016/j.coelec.2022.101137
Publication status	Published - Dec 2022

Keywords

DFT and Ab initio calculations
Single-molecule in situ AFM
Single-molecule in situ STM
Substrate-triggered single-molecule enzyme swelling
Two-centre redox metalloproteins
Voltammetry

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@article{050f889255ed4a05a79ff07767fa85c0,

title = "Conformational triggering in voltammetry and single-molecule conductivity of two-centre redox metalloproteins: Cytochrome c4 and copper nitrite reductase",

abstract = "Blue copper enzymes often show no voltammetry themselves, whereas substrate binding triggers strong electrocatalytic signals. Similarly, electrochemical STM only gives strong contrasts when substrate (O2, NO2-) is present. AFM shows that CuNIR on Au(111)-electrodes modified by self-assembled cysteamine monolayers (SAMs) maintains constant height throughout the electrocatalytic range, while NO2- triggers substantial enzyme {\textquoteleft}swelling{\textquoteright}. {\textquoteleft}Swelling{\textquoteright} does not accord with the crystalline state, which, however, is not the relevant catalytic environment.With a view on understanding these patterns, we present ab initio quantum chemical studies of CuNIR/OH2 and CuNIR/NO2- 740-atom fragments including the type I and type II Cu-centres. Replacing water at the type II centre by nitrite triggers 2-{\AA} Cu–Cu distance increase, according with enzyme {\textquoteleft}swelling{\textquoteright}. 2 {\AA} Cu–Cu increase would close intramolecular ET entirely, but is compensated by efficient superexchange alignment of closely interacting LUMOs and HOMOs. In the water-bound enzyme these orbitals are separated by unfavourable through-space tunneling regions.",

keywords = "DFT and Ab initio calculations, Single-molecule in situ AFM, Single-molecule in situ STM, Substrate-triggered single-molecule enzyme swelling, Two-centre redox metalloproteins, Voltammetry",

author = "Henrik Bohr and Irene Shim and Jens Ulstrup and Xinxin Xiao",

year = "2022",

month = dec,

doi = "10.1016/j.coelec.2022.101137",

language = "English",

volume = "36",

journal = "Current Opinion in Electrochemistry",

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T1 - Conformational triggering in voltammetry and single-molecule conductivity of two-centre redox metalloproteins: Cytochrome c4 and copper nitrite reductase

AU - Bohr, Henrik

AU - Shim, Irene

AU - Ulstrup, Jens

AU - Xiao, Xinxin

PY - 2022/12

Y1 - 2022/12

N2 - Blue copper enzymes often show no voltammetry themselves, whereas substrate binding triggers strong electrocatalytic signals. Similarly, electrochemical STM only gives strong contrasts when substrate (O2, NO2-) is present. AFM shows that CuNIR on Au(111)-electrodes modified by self-assembled cysteamine monolayers (SAMs) maintains constant height throughout the electrocatalytic range, while NO2- triggers substantial enzyme ‘swelling’. ‘Swelling’ does not accord with the crystalline state, which, however, is not the relevant catalytic environment.With a view on understanding these patterns, we present ab initio quantum chemical studies of CuNIR/OH2 and CuNIR/NO2- 740-atom fragments including the type I and type II Cu-centres. Replacing water at the type II centre by nitrite triggers 2-Å Cu–Cu distance increase, according with enzyme ‘swelling’. 2 Å Cu–Cu increase would close intramolecular ET entirely, but is compensated by efficient superexchange alignment of closely interacting LUMOs and HOMOs. In the water-bound enzyme these orbitals are separated by unfavourable through-space tunneling regions.

AB - Blue copper enzymes often show no voltammetry themselves, whereas substrate binding triggers strong electrocatalytic signals. Similarly, electrochemical STM only gives strong contrasts when substrate (O2, NO2-) is present. AFM shows that CuNIR on Au(111)-electrodes modified by self-assembled cysteamine monolayers (SAMs) maintains constant height throughout the electrocatalytic range, while NO2- triggers substantial enzyme ‘swelling’. ‘Swelling’ does not accord with the crystalline state, which, however, is not the relevant catalytic environment.With a view on understanding these patterns, we present ab initio quantum chemical studies of CuNIR/OH2 and CuNIR/NO2- 740-atom fragments including the type I and type II Cu-centres. Replacing water at the type II centre by nitrite triggers 2-Å Cu–Cu distance increase, according with enzyme ‘swelling’. 2 Å Cu–Cu increase would close intramolecular ET entirely, but is compensated by efficient superexchange alignment of closely interacting LUMOs and HOMOs. In the water-bound enzyme these orbitals are separated by unfavourable through-space tunneling regions.

KW - DFT and Ab initio calculations

KW - Single-molecule in situ AFM

KW - Single-molecule in situ STM

KW - Substrate-triggered single-molecule enzyme swelling

KW - Two-centre redox metalloproteins

KW - Voltammetry

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U2 - 10.1016/j.coelec.2022.101137

DO - 10.1016/j.coelec.2022.101137

M3 - Review article

VL - 36

JO - Current Opinion in Electrochemistry

JF - Current Opinion in Electrochemistry

M1 - 101137

ER -

Conformational triggering in voltammetry and single-molecule conductivity of two-centre redox metalloproteins: Cytochrome c4 and copper nitrite reductase

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