Precise temporal control of GEVI conformations enables the visualization of charge migration in a fluorescent protein resulting in an improved optical response

Rapid and reproducible optical transitions of a fluorescent protein (FP) can be achieved with a Genetically Encoded Voltage Indicator (GEVI) via manipulation of the membrane potential. These transitions revealed novel effects of internal mutations near the chromophore that would not be detected under steady state conditions. Mutating an internal threonine (T203) affected the speed of the voltage-dependent fluorescence transition suggesting a conformational change inside the protein. These optical transitions also demonstrated interplay between internal and externally oriented sidechains of the {beta}-can structure. Replacing the steric hindrance of a phenylalanine near the chromophore with threonine (F165T) did not alter the resting fluorescence but resulted in a more complex fluorescent transition providing evidence for a flexible chromophore undergoing conformational changes. F165T orientation was influenced by the flanking external amino acids at positions 164 and 166 with 164F/165T/166T exacerbating the complexity of the voltage-dependent transition while 164T/165T/166F reduced the flexibility of the chromophore resembling the transition pattern of the original F165 version. Alphafold predictions reveal a threonine switch with different orientations of the F165T internal side chain depending on the direction of the offset in polarity at external positions 164 and 166. The crystal structures of the pH-sensitive FP, Super Ecliptic pHluorin and two derivatives solved in varying pH conditions also indicate interactions between the external protein surface and the internal environment providing another example of a threonine switch near the chromophore at T203. This ability to orient internal sidechains has led to the development of a novel GEVI that gets brighter upon depolarization of the plasma membrane, works at low light levels, is less susceptible to physiological pH, and provides in vivo signals. These observations affecting fluorescent transitions should also prove valuable to the development of any FP-based biosensor.