Engineering a photoenzyme to use red light

Jose M. Carceller; Bhumika Jayee; Claire G. Page; Daniel G. Oblinsky; Gustavo Mondragón-Solórzano; Nithin Chintala; Jingzhe Cao; Zayed Alassad; Zheyu Zhang; Nathaniel White; Danny J. Diaz; Andrew D. Ellington; Gregory D. Scholes; Sijia S. Dong; Todd K. Hyster

doi:10.1016/j.chempr.2024.09.017

Engineering a photoenzyme to use red light

Jose M. Carceller, Bhumika Jayee, Claire G. Page, Daniel G. Oblinsky, Gustavo Mondragón-Solórzano, Nithin Chintala, Jingzhe Cao, Zayed Alassad, Zheyu Zhang, Nathaniel White, Danny J. Diaz, Andrew D. Ellington, Gregory D. Scholes, Sijia S. Dong, Todd K. Hyster

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Photoenzymatic reactions involving flavin-dependent “ene”-reductases (EREDs) rely on protein-templated charge transfer (CT) complexes between the cofactor and substrate for radical initiation. These complexes typically absorb in the blue region of the electromagnetic spectrum. Here, we engineered an ERED to form CT complexes that absorb red light. Mechanistic studies indicate that red-light activity is due to the growth of a red-absorbing shoulder off the previously identified cyan absorption feature. Molecular dynamics simulations, docking, and excited-state calculations suggest that the cyan feature involves a π→π∗ transition on flavin, whereas the red-light absorption is a π→π∗ transition between flavin and the substrate. Differences in the electronic transition are due to changes in the substrate-binding conformation and allosteric tuning of the electronic structure of the cofactor-substrate complex. Microenvironment tuning of the CT complex for red-light activity is observed with other engineered photoenzymatic reactions, highlighting this effect's generality.

Original language	English
Journal	Chem
DOIs	https://doi.org/10.1016/j.chempr.2024.09.017
State	Accepted/In press - 1 Jan 2024
Externally published	Yes

Keywords

SDG9: Industry, innovation, and infrastructure
biocatalysis
density functional theory
photochemistry
photoenzyme
protein engineering
red light
ultrafast spectroscopy

ASJC Scopus subject areas

General Chemistry
Biochemistry
Environmental Chemistry
General Chemical Engineering
Biochemistry, medical
Materials Chemistry

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.chempr.2024.09.017

Cite this

@article{0f438f9f4a674573a765ee72787d4bf8,

title = "Engineering a photoenzyme to use red light",

abstract = "Photoenzymatic reactions involving flavin-dependent “ene”-reductases (EREDs) rely on protein-templated charge transfer (CT) complexes between the cofactor and substrate for radical initiation. These complexes typically absorb in the blue region of the electromagnetic spectrum. Here, we engineered an ERED to form CT complexes that absorb red light. Mechanistic studies indicate that red-light activity is due to the growth of a red-absorbing shoulder off the previously identified cyan absorption feature. Molecular dynamics simulations, docking, and excited-state calculations suggest that the cyan feature involves a π→π∗ transition on flavin, whereas the red-light absorption is a π→π∗ transition between flavin and the substrate. Differences in the electronic transition are due to changes in the substrate-binding conformation and allosteric tuning of the electronic structure of the cofactor-substrate complex. Microenvironment tuning of the CT complex for red-light activity is observed with other engineered photoenzymatic reactions, highlighting this effect's generality.",

keywords = "SDG9: Industry, innovation, and infrastructure, biocatalysis, density functional theory, photochemistry, photoenzyme, protein engineering, red light, ultrafast spectroscopy",

author = "Carceller, {Jose M.} and Bhumika Jayee and Page, {Claire G.} and Oblinsky, {Daniel G.} and Gustavo Mondrag{\'o}n-Sol{\'o}rzano and Nithin Chintala and Jingzhe Cao and Zayed Alassad and Zheyu Zhang and Nathaniel White and Diaz, {Danny J.} and Ellington, {Andrew D.} and Scholes, {Gregory D.} and Dong, {Sijia S.} and Hyster, {Todd K.}",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Inc.",

year = "2024",

month = jan,

day = "1",

doi = "10.1016/j.chempr.2024.09.017",

language = "English",

journal = "Chem",

issn = "2451-9308",

publisher = "Elsevier Inc.",

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TY - JOUR

T1 - Engineering a photoenzyme to use red light

AU - Carceller, Jose M.

AU - Jayee, Bhumika

AU - Page, Claire G.

AU - Oblinsky, Daniel G.

AU - Mondragón-Solórzano, Gustavo

AU - Chintala, Nithin

AU - Cao, Jingzhe

AU - Alassad, Zayed

AU - Zhang, Zheyu

AU - White, Nathaniel

AU - Diaz, Danny J.

AU - Ellington, Andrew D.

AU - Scholes, Gregory D.

AU - Dong, Sijia S.

AU - Hyster, Todd K.

PY - 2024/1/1

Y1 - 2024/1/1

N2 - Photoenzymatic reactions involving flavin-dependent “ene”-reductases (EREDs) rely on protein-templated charge transfer (CT) complexes between the cofactor and substrate for radical initiation. These complexes typically absorb in the blue region of the electromagnetic spectrum. Here, we engineered an ERED to form CT complexes that absorb red light. Mechanistic studies indicate that red-light activity is due to the growth of a red-absorbing shoulder off the previously identified cyan absorption feature. Molecular dynamics simulations, docking, and excited-state calculations suggest that the cyan feature involves a π→π∗ transition on flavin, whereas the red-light absorption is a π→π∗ transition between flavin and the substrate. Differences in the electronic transition are due to changes in the substrate-binding conformation and allosteric tuning of the electronic structure of the cofactor-substrate complex. Microenvironment tuning of the CT complex for red-light activity is observed with other engineered photoenzymatic reactions, highlighting this effect's generality.

AB - Photoenzymatic reactions involving flavin-dependent “ene”-reductases (EREDs) rely on protein-templated charge transfer (CT) complexes between the cofactor and substrate for radical initiation. These complexes typically absorb in the blue region of the electromagnetic spectrum. Here, we engineered an ERED to form CT complexes that absorb red light. Mechanistic studies indicate that red-light activity is due to the growth of a red-absorbing shoulder off the previously identified cyan absorption feature. Molecular dynamics simulations, docking, and excited-state calculations suggest that the cyan feature involves a π→π∗ transition on flavin, whereas the red-light absorption is a π→π∗ transition between flavin and the substrate. Differences in the electronic transition are due to changes in the substrate-binding conformation and allosteric tuning of the electronic structure of the cofactor-substrate complex. Microenvironment tuning of the CT complex for red-light activity is observed with other engineered photoenzymatic reactions, highlighting this effect's generality.

KW - SDG9: Industry, innovation, and infrastructure

KW - biocatalysis

KW - density functional theory

KW - photochemistry

KW - photoenzyme

KW - protein engineering

KW - red light

KW - ultrafast spectroscopy

UR - http://www.scopus.com/inward/record.url?scp=85207761645&partnerID=8YFLogxK

U2 - 10.1016/j.chempr.2024.09.017

DO - 10.1016/j.chempr.2024.09.017

M3 - Article

AN - SCOPUS:85207761645

SN - 2451-9308

JO - Chem

JF - Chem

ER -

Engineering a photoenzyme to use red light

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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