Observation of
Cation Chromophore Photoisomerization
of a Fluorescent Protein Using Millisecond Synchrotron Serial Crystallography
and Infrared Vibrational and Visible Spectroscopy
posted on 2022-11-03, 12:05authored byJames
M. Baxter, Christopher D.
M. Hutchison, Karim Maghlaoui, Violeta Cordon-Preciado, R. Marc L. Morgan, Pierre Aller, Agata Butryn, Danny Axford, Sam Horrell, Robin L. Owen, Selina L. S. Storm, Nicholas E. Devenish, Jasper J. van Thor
The chromophores
of reversibly switchable fluorescent proteins
(rsFPs) undergo photoisomerization of both the trans and cis forms.
Concurrent with cis/trans photoisomerisation, rsFPs typically become
protonated on the phenolic oxygen resulting in a blue shift of the
absorption. A synthetic rsFP referred to as rsEospa, derived from
EosFP family, displays the same spectroscopic behavior as the GFP-like
rsFP Dronpa at pH 8.4 and involves the photoconversion between nonfluorescent
neutral and fluorescent anionic chromophore states. Millisecond time-resolved
synchrotron serial crystallography of rsEospa at pH 8.4 shows that
photoisomerization is accompanied by rearrangements of the same three
residues as seen in Dronpa. However, at pH 5.5 we observe that the
OFF state is identified as the cationic chromophore with additional
protonation of the imidazolinone nitrogen which is concurrent with
a newly formed hydrogen bond with the Glu212 carboxylate side chain.
FTIR spectroscopy resolves the characteristic up-shifted carbonyl
stretching frequency at 1713 cm–1 for the cationic
species. Electronic spectroscopy furthermore distinguishes the cationic
absorption band at 397 nm from the neutral species at pH 8.4 seen
at 387 nm. The observation of photoisomerization of the cationic chromophore
state demonstrates the conical intersection for the electronic configuration,
where previously fluorescence was proposed to be the main decay route
for states containing imidazolinone nitrogen protonation. We present
the full time-resolved room-temperature X-ray crystallographic, FTIR,
and UV/vis assignment and photoconversion modeling of rsEospa.