Accurate quantification of diffusion and binding kinetics of non-integral membrane proteins by FRAP

Ronen Berkovich, Haguy Wolfenson, Sharon Eisenberg, Marcelo Ehrlich, Matthias Weiss, Joseph Klafter, Yoav I. Henis*, Michael Urbakh

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

24 Scopus citations

Abstract

Non-integral membrane proteins frequently act as transduction hubs in vital signaling pathways initiated at the plasma membrane (PM). Their biological activity depends on dynamic interactions with the PM, which are governed by their lateral and cytoplasmic diffusion and membrane binding/unbinding kinetics. Accurate quantification of the multiple kinetic parameters characterizing their membrane interaction dynamics has been challenging. Despite a fair number of approximate fitting functions for analyzing fluorescence recovery after photobleaching (FRAP) data, no approach was able to cope with the full diffusion-exchange problem. Here, we present an exact solution and matlab fitting programs for FRAP with a stationary Gaussian laser beam, allowing simultaneous determination of the membrane (un)binding rates and the diffusion coefficients. To reduce the number of fitting parameters, the cytoplasmic diffusion coefficient is determined separately. Notably, our equations include the dependence of the exchange kinetics on the distribution of the measured protein between the PM and the cytoplasm, enabling the derivation of both k on and k off without prior assumptions. After validating the fitting function by computer simulations, we confirm the applicability of our approach to live-cell data by monitoring the dynamics of GFP-N-Ras mutants under conditions with different contributions of lateral diffusion and exchange to the FRAP kinetics.

Original languageEnglish
Pages (from-to)1648-1657
Number of pages10
JournalTraffic
Volume12
Issue number11
DOIs
StatePublished - Nov 2011

Keywords

  • Binding kinetics
  • Diffusion analysis
  • FRAP
  • Membrane interactions
  • Simulations

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