Principles for optimal cooperativity in allosteric materials

Abstract

Allosteric proteins transmit a mechanical signal induced by binding a ligand. However, understanding the nature of the information transmitted and the architectures optimizing such transmission remains a challenge. Here we show using an in-silico evolution scheme and theoretical arguments that architectures optimized to be cooperative, which propagate efficiently energy, qualitatively differ from previously investigated materials optimized to propagate strain. Although we observe a large diversity of functioning cooperative architectures (including shear, hinge and twist designs), they all obey the same principle of displaying a mechanism, i.e. an extended soft mode. We show that its optimal frequency decreases with the spatial extension L of the system as L-d/2, where d is the spatial dimension. For these optimal designs, cooperativity decays logarithmically with L for d=2 and does not decay for d=3. Overall our approach leads to a natural explanation for several observations in allosteric proteins, and indicates an experimental path to test if allosteric proteins lie close to optimality.