Chromophore Twisting in the Excited State of a Photoswitchable Fluorescent Protein Captured by Time-resolved Serial Femtosecond Crystallography

Overview

Journal Nat Chem

Specialty Chemistry

Date 2017 Dec 20

PMID 29256511

Citations 74

Authors

Nicolas Coquelle

Michel Sliwa

Joyce Woodhouse

Giorgio Schiro

Virgile Adam

Andrew Aquila

Thomas R M Barends

Sebastien Boutet

Martin Byrdin

Sergio Carbajo

Eugenio De La Mora

R Bruce Doak

Mikolaj Feliks

Franck Fieschi

Lutz Foucar

Virginia Guillon

Mario Hilpert

Mark S Hunter

Stefan Jakobs

Jason E Koglin

Gabriela Kovacsova

Thomas J Lane

Bernard Levy

Mengning Liang

Karol Nass

Jacqueline Ridard

Joseph S Robinson

Christopher M Roome

Cyril Ruckebusch

Matthew Seaberg

Michel Thepaut

Marco Cammarata

Isabelle Demachy

Martin Field

Robert L Shoeman

Dominique Bourgeois

Jacques-Philippe Colletier

Ilme Schlichting

Martin Weik

Affiliations

Soon will be listed here.

Abstract

Chromophores absorb light in photosensitive proteins and thereby initiate fundamental biological processes such as photosynthesis, vision and biofluorescence. An important goal in their understanding is the provision of detailed structural descriptions of the ultrafast photochemical events that they undergo, in particular of the excited states that connect chemistry to biological function. Here we report on the structures of two excited states in the reversibly photoswitchable fluorescent protein rsEGFP2. We populated the states through femtosecond illumination of rsEGFP2 in its non-fluorescent off state and observed their build-up (within less than one picosecond) and decay (on the several picosecond timescale). Using an X-ray free-electron laser, we performed picosecond time-resolved crystallography and show that the hydroxybenzylidene imidazolinone chromophore in one of the excited states assumes a near-canonical twisted configuration halfway between the trans and cis isomers. This is in line with excited-state quantum mechanics/molecular mechanics and classical molecular dynamics simulations. Our new understanding of the structure around the twisted chromophore enabled the design of a mutant that displays a twofold increase in its off-to-on photoswitching quantum yield.

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