Cytoplasmic Regulation of the Movement of E-Cadherin on the Free Cell Surface as Studied by Optical Tweezers and Single Particle Tracking: Corralling and Tethering by the Membrane Skeleton

doi:10.1083/jcb.140.5.1227

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© The Rockefeller University Press, 0021-9525/1998//1227 $5.00
The Journal of Cell Biology, Volume 140, Number 5, , 1998 1227-1240

Article

Cytoplasmic Regulation of the Movement of E-Cadherin on the Free Cell Surface as Studied by Optical Tweezers and Single Particle Tracking: Corralling and Tethering by the Membrane Skeleton

Yasushi Sako^*, Akira Nagafuchi, Shoichiro Tsukita, Masatoshi Takeichi, and Akihiro Kusumi^*

^* Department of Biological Science, Graduate School of Science, Nagoya University, Chikusa-ku, Nagoya 464-8602, Japan; Department of Medical Chemistry, Faculty of Medicine, and Department of Biophysics, Graduate School of Science, Kyoto University, Sakyo-ku, Kyoto 606-8502, Japan

The translational movement of E-cadherin, a calcium-dependentcell–cell adhesion molecule in the plasma membrane inepithelial cells, and the mechanism of its regulation were studiedusing single particle tracking (SPT) and optical tweezers (OT).The wild type (Wild) and three types of artificial cytoplasmic mutants of E-cadherin were expressed in L-cells, and theirmovements were compared. Two mutants were E-cadherins thathad deletions in the COOH terminus and lost the catenin-bindingsite(s) in the COOH terminus, with remaining 116 and 21 aminoacids in the cytoplasmic domain (versus 152 amino acids forWild); these are called Catenin-minus and Short-tailed in this paper, respectively. The third mutant, called Fusion, is afusion protein between E-cadherin without the catenin-bindingsite and ${alpha}$ -catenin without its NH₂-terminal half. These cadherinswere labeled with 40-nm ${varphi}$ colloidal gold or 210-nm ${varphi}$ latex particlesvia a monoclonal antibody to the extracellular domain of E-cadherinfor SPT or OT experiments, respectively. E-cadherin on thedorsal cell surface (outside the cell–cell contact region)was investigated. Catenin-minus and Short-tailed could be draggedan average of 1.1 and 1.8 µm by OT (trapping force of0.8 pN), and exhibited average microscopic diffusion coefficients(D_micro) of 1.2 x 10^–10 and 2.1 x 10^–10 cm²/s,respectively. Approximately 40% of Wild, Catenin-minus, andShort-tailed exhibited confined-type diffusion. The confinementarea was 0.13 µm² for Wild and Catenin-minus, while thatfor Short-tailed was greater by a factor of four. In contrast,Fusion could be dragged an average of only 140 nm by OT. AverageD_micro for Fusion measured by SPT was small (0.2 x 10^–10cm²/s). These results suggest that Fusion was bound to the cytoskeleton.Wild consists of two populations; about half behaves like Catenin-minus, and the other half behaves like Fusion. It is concludedthat the movements of the wild-type E-cadherin in the plasmamembrane are regulated via the cytoplasmic domain by (a) tetheringto actin filaments through catenin(s) (like Fusion) and (b)a corralling effect of the network of the membrane skeleton(like Catenin-minus). The effective spring constants of themembrane skeleton that contribute to the tethering and corralling effects as measured by the dragging experiments were 30 and5 pN/µm, respectively, indicating a difference in theskeletal structures that produce these two effects.

Abbreviations used in this paper: MSD, square displacement averaged over a single particle's trajectory (running average over a single trajectory); OT, optical tweezers; SPT, single particle tracking.

Address all correspondence to Akihiro Kusumi, Department ofBiological Science, Graduate School of Science, Nagoya University,Chikusa-ku, Nagoya 464-8602, Japan. Tel.: 011-81-52-789-2969.Fax: 011-81-52-789-2968. E-mail: akusumi{at}bio.nagoya-u.ac.jp

Y. Sako's present address is First Department of Physiology,Medical School of Osaka University, Yamadaoka, Suita, Osaka565-0871, Japan.

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