Monitoring GPCR Conformation with GFP-Inspired Dyes

Abstract

AbstractSolvatochromic compounds have emerged as valuable environment-sensitive probes for biological research, with the chromophore of the green fluorescent protein (GFP) being a well-studied example. In this study, we demonstrate that synthetic analogues of the GFP chromophore can be used to investigate ligand-induced conformational changes in proteins. We synthesized thiol-reactive derivatives of four analogues of the GFP chromophore that exhibit notable solvatochromism. We used these derivatives to label two proteins: the soluble calcium sensor recoverin (Rec) and the transmembrane G protein-coupled A2Aadenosine receptor (A2AAR), via cysteines located or introduced in the regions that undergo structural changes upon ligand binding. Two of these dyes showed Ca2+-induced fluorescence changes when attached to Rec. Notably, our best-performing dye, DyeC, when attached to A2AAR, revealed agonist-induced changes in both fluorescence intensity and shape of the emission spectrum. Molecular dynamics (MD) simulations provided mechanistic insights into these changes showing the activation of A2AAR transfers DyeC to a more confined and more hydrophilic environment. Additionally, an allosteric modulator, HMA, induces changes in DyeC fluorescence spectra, indicating a distinct receptor conformation from apo, antagonist, or agonist-bound receptors. Our study demonstrates that GFP-inspired dyes are effective for detecting structural changes in GPCR (G protein-coupled receptors), with advantages such as the ability to perform both intensity-based and ratiometric tracking, red-shifted fluorescence spectra, high extinction coefficient, and sensitivity to allosteric modulation. These dyes expand the toolbox for tracking ligand-induced changes and facilitate new insights into conformational changes induced by allosteric modulators in GPCRs.