English

Multicellular sensing at a feedback-induced critical point

Biological Physics 2020-12-04 v2 Molecular Networks

Abstract

Feedback in sensory biochemical networks can give rise to bifurcations in cells' behavioral response. These bifurcations share many properties with thermodynamic critical points. Evidence suggests that biological systems may operate near these critical points, but the functional benefit of doing so remains poorly understood. Here we investigate a simple biochemical model with nonlinear feedback and multicellular communication to determine if criticality provides a functional benefit in terms of the ability to gain information about a stochastic chemical signal. We find that when signal fluctuations are slow, the mutual information between the signal and the intracellular readout is maximized at criticality, because the benefit of high signal susceptibility outweighs the detriment of high readout noise. When cells communicate, criticality gives rise to long-range correlations in readout molecule number among cells. Consequently, we find that communication increases the information between a given cell's readout and the spatial average of the signal across the population. Finally, we find that both with and without communication, the sensory benefits of criticality compete with critical slowing down, such that the information rate, as opposed to the information itself, is minimized at the critical point. Our results reveal the costs and benefits of feedback-induced criticality for multicellular sensing.

Keywords

Cite

@article{arxiv.2005.07010,
  title  = {Multicellular sensing at a feedback-induced critical point},
  author = {Michael Vennettilli and Amir Erez and Andrew Mugler},
  journal= {arXiv preprint arXiv:2005.07010},
  year   = {2020}
}

Comments

15 pages, 5 figures

R2 v1 2026-06-23T15:32:56.414Z