Geometry-induced patterns through mechanochemical coupling

TL;DR

This paper investigates how dynamic cell membrane shapes influence protein pattern formation through a mathematical model, revealing that shape changes can induce, suppress, or shift patterns, leading to complex behaviors like oscillations and waves.

Contribution

It introduces a geometric reaction-diffusion model on evolving manifolds, providing a simple criterion for shape-induced pattern instabilities and expanding understanding of cell polarity mechanisms.

Findings

Shape changes can induce local pattern-forming instabilities.

Membrane deformations can suppress or shift existing patterns.

Complex patterns like oscillations and waves emerge from shape-dynamics feedback.

Abstract

Intracellular protein patterns regulate a variety of vital cellular processes such as cell division and motility, which often involve dynamic changes of cell shape. These changes in cell shape may in turn affect the dynamics of pattern-forming proteins, hence leading to an intricate feedback loop between cell shape and chemical dynamics. While several computational studies have examined the resulting rich dynamics, the underlying mechanisms are not yet fully understood. To elucidate some of these mechanisms, we explore a conceptual model for cell polarity on a dynamic one-dimensional manifold. Using concepts from differential geometry, we derive the equations governing mass-conserving reaction-diffusion systems on time-evolving manifolds. Analyzing these equations mathematically, we show that dynamic shape changes of the membrane can induce pattern-forming instabilities in parts of the membrane, which we refer to as regional instabilities. Deformations of the local membrane geometry can also (regionally) suppress pattern formation and spatially shift already existing patterns. We explain our findings by applying and generalizing the local equilibria theory of mass-conserving reaction-diffusion systems. This allows us to determine a simple onset criterion for geometry-induced pattern-forming instabilities, which is linked to the phase-space structure of the reaction-diffusion system. The feedback loop between membrane shape deformations and reaction-diffusion dynamics then leads to a surprisingly rich phenomenology of patterns, including oscillations, traveling waves, and standing waves that do not occur in systems with a fixed membrane shape. Our work reveals that the local conformation of the membrane geometry acts as an important dynamical control parameter for pattern formation in mass-conserving reaction-diffusion systems.