Thermal fluctuations assist mechanical signal propagation in coiled-coil proteins

Abstract

Recently it has been shown that the long coiled-coil membrane tether protein Early Endosome Antigen 1 (EEA1) switches from a rigid to a flexible conformation upon binding of a signaling protein to its free end. This flexibility switch represents a novel motor-like activity, allowing EEA1 to generate a force that moves vesicles closer to the membrane they will fuse with. To elucidate how binding of a single signaling protein can globally change the stiffness of a 200 nm long chain, we propose a simplified description of the coiled-coil as a one-dimensional Frenkel-Kontorova chain. Using numerical simulations, we find that an initial perturbation of the chain can propagate along its whole length in the presence of thermal fluctuations, changing the configuration of the entire molecule and thereby affecting its stiffness. Our work sheds light onto intramolecular communication and force generation in long coiled-coil proteins.