Oscillation death by mechanochemical feedback

Many cellular proteins, such as ERK, undergo oscillation death when cells are compressed, initiating many developmental processes in organisms. Whether such a transition arises from these proteins' specific biochemistry or generic dynamical features remains unclear. In this paper, we show that coupling mechanics to the chemistry of Hopf oscillators, such as ERK, through mechanochemical feedback (MCF) can generically drive oscillation death upon compression. We demonstrate this result using an active solid, a 1D ring of Brusselators coupled through damped springs, which we term Harmonic Brusselator Ring (HBR). Because of MCF, HBR's dynamics is non-Hermitian and breaks $\mathcal{PT}$-symmetry in a scale-dependent manner, generating a rich array of patterns, including traveling pulses, chimera states, intermittent fluctuations, and collective oscillation death. Furthermore, MCF engenders three dynamic phase transitions that separate the observed patterns into four phases. The underlying symmetry of HBR implies that the observed patterns and phases may generically arise in many natural and synthetic systems.