Forced-rupture of Cell-Adhesion Complexes Reveals abrupt switch between two Brittle States

TL;DR

This study uses simulations to reveal an abrupt switch between two brittle states in cell adhesion complexes during forced rupture, showing a novel behavior not seen in other protein complexes and elucidating the underlying free energy landscape.

Contribution

The paper uncovers a new mechanism of force-induced brittle state switching in cell adhesion complexes through detailed simulation and free energy analysis.

Findings

Two distinct linear regimes in rupture force vs. log loading rate.

Abrupt transition of transition state positions at a critical force.

Identification of a collective reaction coordinate involving charged residues and a metal ion.

Abstract

Cell adhesion complexes (CACs), which are activated by ligand binding, play key roles in many cellular functions ranging from cell cycle regulation to mediation of cell extracellular matrix adhesion. Inspired by single molecule pulling experiments on leukocyte function-associated antigen-1 (LFA-1), expressed in T-cells, bound to intercellular adhesion molecules (ICAM), we performed constant loading rate ($r_f$) and constant force ($F$) simulations using the Self-Organized Polymer (SOP) model to describe the mechanism of ligand rupture from CACs. The simulations reproduce the major experimental finding on the kinetics of the rupture process, namely, the dependence of the most probable rupture forces ($f^*$s) on $\ln r_f$ ($r_f$ is the loading rate) exhibits two distinct linear regimes. The first, at low $r_f$, has a shallow slope whereas the slope at high $r_f$ is much larger, especially for LFA-1/ICAM-1 complex with the transition between the two occurring over a narrow $r_f$ range. Locations of the two transition states (TSs), extracted from the simulations show an abrupt change from a high value at low $r_f$ or $F$ to a low value at high $r_f$ or $F$. The unusual behavior in which the CACs switch from one brittle (TS position is a constant over a range of forces) state to another brittle state is not found in forced-rupture in other protein complexes. We explain this novel behavior by constructing the free energy profiles, $F(\Lambda)$s, as a function of a collective reaction coordinate ($\Lambda$), involving many key charged residues and a critical metal ion. The TS positions in F($\Lambda) change abruptly at a critical force, demonstrating that it, rather than the molecular extension is a good reaction coordinate. We reveal a new mechanism for the two loading regimes observed in the rupture kinetics in CACs.