Time-Heterogeneity of the F\"orster Radius from Dipole Orientational Dynamics Explains Observed Dynamic Shift

F\"orster resonance energy transfer (FRET) is a quantum mechanical phenomenon involving the non-radiative transfer of energy between coupled electric dipoles. Due to the strong dependence of FRET on the distance between the dipoles, it is frequently used as a ``molecular ruler" in biology, chemistry, and physics. This is done by placing dipolar molecules called dyes on molecules of interest. In time-resolved confocal single-molecule FRET (smFRET) experiments, the joint distribution of the FRET efficiency and the donor fluorescence lifetime can reveal underlying molecular conformational dynamics via deviation from their theoretical F\"orster relationship. This deviation is referred to as a dynamic shift. Quantifying the dynamic shift caused by the motion of the fluorescent dyes is essential to decoupling the dynamics of the studied molecules and the dyes. We develop novel Langevin models for the dye linker dynamics, including rotational dynamics, based on first physics principles and proper dye linker chemistry to match accessible volumes predicted by molecular dynamics simulations. By simulating the dyes' stochastic translational and rotational dynamics, we show that the observed dynamic shift can largely be attributed to the mutual orientational dynamics of the electric dipole moments associated with the dyes, not their accessible volume..

Medienart:	Preprint

Erscheinungsjahr:	2024
Erschienen:	2024

Enthalten in:	arXiv.org - (2024) vom: 15. Apr. Zur Gesamtaufnahme - year:2024

Sprache:	Englisch

Beteiligte Personen:	Frost, David [VerfasserIn] Cook, Keisha [VerfasserIn] Sanabria, Hugo [VerfasserIn]

Links:	Volltext [kostenfrei]

Themen:	510 530 Physics - Biological Physics Physics - Chemical Physics Physics - Computational Physics Physics - Data Analysis; Statistics and Probability Statistics - Computation

Förderinstitution / Projekttitel:

PPN (Katalog-ID):	XAR043275060