Membrane lateral diffusion and capture of CFTR within transient confinement zones

doi:10.1529/biophysj.106.084830

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Membrane lateral diffusion and capture of CFTR within transient confinement zones

Ian R Bates ¹^*, Benedict Hebert ¹, Yishan Luo ¹, Jie Liao ¹, Alexia I Bachir ¹, David L Kolin ¹, Paul W Wiseman ¹ and John W Hanrahan ¹

¹ McGill University

^* To whom correspondence should be addressed. E-mail: ian.bates{at}mcgill.ca.

Submitted on March 10, 2006
Revised on April 20, 2006
Accepted on 8 May 2006

Abstract
The cystic fibrosis transmembrane conductance regulator (CFTR)channel interacts with scaffolding and other proteins that areexpected to restrict its lateral movement, yet previous studieshave reported predominantly free diffusion. We examined thelateral mobility of CFTR channels on live baby hamster kidneycells using three complementary methods. Channels bearing anextracellular biotinylation target sequence were labelled withstreptavidin conjugated with fluorescent dyes (Alexa Fluor 488or 568) or quantum dots (qDot605). Fluorescence recovery afterphotobleaching (FRAP) and image correlation spectroscopy (ICS)of the dye-labelled channels revealed a significant immobilepopulation (~50%), which was confirmed by direct single particletracking (SPT) of qDot605-labelled CFTR. Adding 10 Histidineresidues at the C-terminus of CFTR to mask the PDZ binding motifabolished its association with EBP50/NHERF1, reduced the immobilefraction, and increased mobility. Other interactions that arenot normally detected on this time scale became apparent whenbinding of PDZ domain proteins was disrupted. SPT revealedthat CFTR_His10 channels diffuse randomly, become immobilizedfor periods lasting up to one minute, and in some instancesare recaptured at the same location. The impact of transientconfinement on the measured diffusion using the three fluorescencetechniques were assessed using computer simulations of the biologicalexperiments. Finally, the impact of endosomal CFTR on mobilitymeasurements was assessed by fluorescence correlation spectroscopy(FCS). These results reveal unexpected features of CFTR dynamicswhich may influence its ion channel activity.

Key Words: FRAP, PDZ domains, chloride channel, cystic fibrosis, image correlation spectroscopy, single particle tracking

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