Abstract
Mechanical force regulates a broad range of molecular interactions in biology. Three types of counterintuitive mechanical regulation of receptor–ligand dissociation have been described. Catch bonds are strengthened by constant forces, as opposed to slip bonds that are weakened by constant forces. The phenomenon that bonds become stronger with prior application of cyclic forces is termed cyclic mechanical reinforcement (CMR). Slip and catch bonds have respectively been explained by two-state models. However, they assume fast equilibration between internal states and hence are inadequate for CMR. Here we propose a three-state model for CMR where both loading and unloading regulate the transition of bonds among the short-lived, intermediate, and long-lived state. Cyclic forces favor bonds in the long-lived state, hence greatly prolonging their lifetimes. The three-state model explains the force history effect and agrees with the experimental CMR effect of integrin α5β1–fibronectin interaction. This model helps decipher the distinctive ways by which molecular bonds are mechanically strengthened: catch bonds by constant forces and CMR by cyclic forces. The different types of mechanical regulation may enable the cell to fine tune its mechanotransduction via membrane receptors.
Highlights
Mechanical force regulates a broad range of molecular interactions in biology
Catch bonds are strengthened by constant forces, as opposed to slip bonds that are weakened by constant forces
The three-state model explains the force history effect and agrees with the experimental cyclic mechanical reinforcement (CMR) effect of integrin α5β1–fibronectin interaction. This model helps decipher the distinctive ways by which molecular bonds are mechanically strengthened: catch bonds by constant forces and CMR by cyclic forces
Summary
Mechanical force regulates a broad range of molecular interactions in biology. Three types of counterintuitive mechanical regulation of receptor–ligand dissociation have been described. A new type of mechanical regulation has been observed for the interactions of two integrins, α5β1 and αLβ2, with their respective ligands, fibronectin (FN) and intercellular adhesion molecule 1 This phenomenon, termed cyclic mechanical reinforcement (CMR)[26], refers to the observation that a prior cyclic force www.nature.com/scientificreports/. A two-state model was examined for the ability to account for force history effects[29] This model was able to generate single-cycled CMR effect but the multi-cycled CMR was attributed to the pre-matured dissociation of short-lived bonds during loading-unloading cycles prior to lifetime measurement. This possibility was ruled out experimentally in the original CMR study[26]. Bond strengthening by CMR is not distinct from that by catch bonds, yet the biophysical mechanisms underlying these two phenomena may be conceptually different
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