Cadherins are essential cell surface proteins that mediate cell-cell adhesion in all soft tissues. They play critical roles in development and morphogenesis, by directing tissue-specific cell segregation and sorting. A major, unresolved question concerns the molecular basis of cadherin adhesion and binding selectivity. There have been several attempts to elucidate the structural basis of cadherin function from crystal structures, but despite numerous biochemical and structural studies, the identities of the functional adhesive domains and the mechanisms of cadherin binding remain controversial. In this work, we propose to directly address this issue with experimental approaches that directly probe the adhesive function of these proteins. Molecular force probes provide the means to achieve this. Both the surface force apparatus (SFA) and single molecule dynamic force spectroscopy (DFS) provide a powerful, complementary set of tools for uniquely determining the molecular mechanisms of cadherin adhesion and selectivity. By directly measuring the distance-dependent cadherin interaction potentials with the SFA, we will obtain unique information regarding the cadherin docking alignments, and hence, the protein regions that mediate binding. This information, which can't be directly obtained by any other current techniques, will facilitate the identification of the adhesive ectodomain segments, and thereby directly test several key hypotheses concerning the identities of the functional cadherin domains. On the other hand, the proposed DFS measurements will reveal subtle details of single cadherin bonds that may not be evident from the population-averaged, SFA measurements, but may nevertheless control cadherin recognition. These latter measurements will test the hypothesis that differences in the characteristics of cadherin bonds determine cadherin specificity. We will directly test models for cadherin binding and recognition suggested by these force measurements, by determining the impact of cadherin structure variations on both the interprotein potentials and the cadherin bond strengths. The latter will provide a direct link between cadherin architecture and function. Together, these proposed investigations will provide a comprehensive analysis of cadherin function at an unprecedented level of detail, revealing both the underlying adhesive mechanisms and their structural origins.
Maruthamuthu, Venkat; Schulten, Klaus; Leckband, Deborah (2009) Elasticity and rupture of a multi-domain neural cell adhesion molecule complex. Biophys J 96:3005-14 |
Shi, Quanming; Chien, Yuan-Hung; Leckband, Deborah (2008) Biophysical properties of cadherin bonds do not predict cell sorting. J Biol Chem 283:28454-63 |
Chien, Yuan-Hung; Jiang, Ning; Li, Fang et al. (2008) Two stage cadherin kinetics require multiple extracellular domains but not the cytoplasmic region. J Biol Chem 283:1848-56 |
Pierres, Anne; Prakasam, Anil; Touchard, Dominique et al. (2007) Dissecting subsecond cadherin bound states reveals an efficient way for cells to achieve ultrafast probing of their environment. FEBS Lett 581:1841-6 |
Bayas, Marco V; Kearney, Alice; Avramovic, Adam et al. (2007) Impact of salt bridges on the equilibrium binding and adhesion of human CD2 and CD58. J Biol Chem 282:5589-96 |
Li, Fang; Leckband, Deborah (2006) Dynamic strength of molecularly bonded surfaces. J Chem Phys 125:194702 |
Prakasam, A; Chien, Y-H; Maruthamuthu, V et al. (2006) Calcium site mutations in cadherin: impact on adhesion and evidence of cooperativity. Biochemistry 45:6930-9 |
Bayas, Marco V; Leung, Andrew; Evans, Evan et al. (2006) Lifetime measurements reveal kinetic differences between homophilic cadherin bonds. Biophys J 90:1385-95 |
Prakasam, A K; Maruthamuthu, V; Leckband, D E (2006) Similarities between heterophilic and homophilic cadherin adhesion. Proc Natl Acad Sci U S A 103:15434-9 |
Bayas, M V; Schulten, K; Leckband, D (2003) Forced detachment of the CD2-CD58 complex. Biophys J 84:2223-33 |
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