Förster resonance energy transfer: Role of diffusion of fluorophore orientation and separation in observed shifts of FRET efficiency

&

Abstract

Förster resonance energy transfer is a widely used single-molecule technique for measuring nanoscale distances from changes in the non-radiative transfer of energy between donor and acceptor fluorophores. For macromolecules and complexes this observed transfer efficiency is used to infer changes in molecular conformation under differing experimental conditions. However, sometimes shifts are observed in the FRET efficiency even when there is strong experimental evidence that the molecular conformational state is unchanged. We investigate ways in which such discrepancies can arise from kinetic effects. We show that significant shifts can arise from the interplay between excitation kinetics, orientation diffusion of fluorophores, separation diffusion of fluorophores, and non-emitting quenching.

Categories

Add categories

Keywords

Reprint years

Other Versions

No versions found

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 106,716

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

  • Only published works are available at libraries.

My notes

Similar books and articles

Single Pair Förster Resonance Energy Transfer: A Versatile Tool To Investigate Protein Conformational Dynamics.Lena Voith von Voithenberg & Don C. Lamb - 2018 - Bioessays 40 (3):1700078.
Fluorescent proteins for FRET microscopy: Monitoring protein interactions in living cells.Richard N. Day & Michael W. Davidson - 2012 - Bioessays 34 (5):341-350.
Fluorescence resonance energy transfer: FRET studies of ligand binding to cell surface receptors.B. J. Tromberg - unknown
FRET microscopy in the living cell: Different approaches, strengths and weaknesses.Sergi Padilla-Parra & Marc Tramier - 2012 - Bioessays 34 (5):369-376.
Spectroscopic approach for monitoring two-photon excited fluorescence resonance energy transfer from homodimers at the subcellular level.V. J. LaMorte, A. Zoumi & B. J. Tromberg - unknown
Light resonance energy transfer‐based methods in the study of G protein‐coupled receptor oligomerization.Jorge Gandía, Carme Lluís, Sergi Ferré, Rafael Franco & Francisco Ciruela - 2008 - Bioessays 30 (1):82-89.
Superresolution microscopy with novel BODIPY-based fluorophores.Amy M. BIttel, Isaac S. Saldivar, Nick J. Dolman, Xiaolin Nan & Summer L. Gibbs - 2018 - Plos 1 3 (10).
Boundary-conditions for the diffusion equation in radiative-transfer.Haskell Rc, Tromberg Bj, Svaasand Lo, Tsay Tt, Feng Tc & McadaMs ms - unknown
Activation volumes for energy- and electron-transfer quenching of [Cu2+].D. R. Crane & P. C. Ford - unknown
A Model of Isotope Separation in Plants.A. O. Bokunyaeva & A. V. Melkikh - 2017 - Acta Biotheoretica 65 (4):271-284.

Analytics

Added to PP
2017-06-07

Downloads
5 (#1,802,065)

6 months
2 (#1,368,240)

Historical graph of downloads
How can I increase my downloads?

Author's Profile

Brittany Wallace
San Jose State University

Citations of this work

No citations found.

Add more citations

References found in this work

No references found.

Add more references