Litcius/Paper detail

Retinal chromophore charge delocalization and confinement explain the extreme photophysics of Neorhodopsin

Riccardo Palombo, Leonardo Barneschi, Laura Pedraza‐González, Daniele Padula, Igor Schapiro, Massimo Olivucci

2022Nature Communications43 citationsDOIOpen Access PDF

Abstract

The understanding of how the rhodopsin sequence can be modified to exactly modulate the spectroscopic properties of its retinal chromophore, is a prerequisite for the rational design of more effective optogenetic tools. One key problem is that of establishing the rules to be satisfied for achieving highly fluorescent rhodopsins with a near infrared absorption. In the present paper we use multi-configurational quantum chemistry to construct a computer model of a recently discovered natural rhodopsin, Neorhodopsin, displaying exactly such properties. We show that the model, that successfully replicates the relevant experimental observables, unveils a geometrical and electronic structure of the chromophore featuring a highly diffuse charge distribution along its conjugated chain. The same model reveals that a charge confinement process occurring along the chromophore excited state isomerization coordinate, is the primary cause of the observed fluorescence enhancement.

Topics & Concepts

ChromophoreDelocalized electronIsomerizationRhodopsinRetinalExcited stateOptogeneticsCharge (physics)QuantumChemical physicsFluorescenceChemistryRational designPhotochemistryMaterials sciencePhysicsNanotechnologyAtomic physicsQuantum mechanicsBiologyNeuroscienceCatalysisOrganic chemistryBiochemistryPhotoreceptor and optogenetics researchNeural dynamics and brain functionNeuroscience and Neuropharmacology Research