Molecular-scale, nonlinear actomyosin binding dynamics drive population-scale adaptation and evolutionary convergence

Abstract

Biological actuators -- from myosin motors to muscles -- follow Hill's model where a dimensionless parameter α captures the nonlinear coupling between contraction rate and force generation. Our prior work identified a characteristic α* = 3.85 2.32 across natural muscles and showed that α* optimizes a power-efficiency tradeoff, potentially explaining its prevalence in nature. However, those results reflected short-term actuation tasks whereas phenotypic distributions in α emerge over evolutionary timescales. Here, we use numerical simulations of self-propelled agents to explore how nonlinear actomyosin actuation (parameterized by α) shapes population dynamics. Agents of different α compete for resources and reproduce with slight mutations. Without mutations, resource availability drives populations in α toward distinct behaviors: under abundance or scarcity, specialized α survive. However, with mutations and selection, populations evolve toward distributions centered around the characteristic α* observed in nature. Further, we show that the mutation rate δ governs a balance between adaptability and robustness: large δ generates instability and extinction, small δ prevents feedback, while intermediate δ enables long-term adaptability while remaining robust to short-term noise. Our results suggest that nonlinear actuation provides a general understanding of energy management in actomyosin systems across a wide range of timescales, ranging from the task-specific to evolutionary. These insights may guide the rational design of active materials with adaptive properties.

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