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Photophysics-informed two-photon voltage imaging using FRET-opsin voltage indicators

F. Phil Brooks, Daozheng Gong, Hunter C. Davis, Pojeong Park, Yitong Qi, Adam E. Cohen

2025Science Advances13 citationsDOIOpen Access PDF

Abstract

Microbial rhodopsin-derived genetically encoded voltage indicators (GEVIs) are powerful tools for mapping bioelectrical dynamics in cell culture and in live animals. Förster resonance energy transfer (FRET)-opsin GEVIs use voltage-dependent quenching of an attached fluorophore, achieving high brightness, speed, and voltage sensitivity. However, the voltage sensitivity of most FRET-opsin GEVIs has been reported to decrease or vanish under two-photon (2P) excitation. Here, we investigated the photophysics of the FRET-opsin GEVIs Voltron1 and Voltron2. We found that the previously reported negative-going voltage sensitivities of both GEVIs came from photocycle intermediates, not from the opsin ground states. The voltage sensitivities of both GEVIs were nonlinear functions of illumination intensity; for Voltron1, the sensitivity reversed the sign under low-intensity illumination. Using photocycle-optimized 2P illumination protocols, we demonstrate 2P voltage imaging with Voltron2 in the barrel cortex of a live mouse. These results open the door to high-speed 2P voltage imaging of FRET-opsin GEVIs in vivo.

Topics & Concepts

Förster resonance energy transferOpsinTwo-photon excitation microscopyFluorophoreRhodopsinBrightnessSensitivity (control systems)Fluorescence-lifetime imaging microscopyBiophysicsVoltageVoltage-sensitive dyeBiophotonicsFluorescenceMaterials scienceChemistryOpticsOptoelectronicsPhysicsMembrane potentialBiologyBiochemistryRetinalPhotonicsElectronic engineeringEngineeringQuantum mechanicsPhotoreceptor and optogenetics researchNeural dynamics and brain functionNeuroscience and Neural Engineering
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