Geometry-sensitive protrusion growth directs confined cell migration

TL;DR

This paper presents a biophysical model explaining how cell protrusions and nuclei coordinate in response to geometric cues, guiding confined cell migration and decision-making between different microchannel sizes.

Contribution

It introduces a novel geometry-dependent coupling mechanism that predicts cell migration behaviors and decision-making, validated by experimental results.

Findings

Cell migration is directed by geometry-sensitive protrusion-nucleus coupling.

The model predicts complex decision-making based on channel widths.

Experimental validation confirms the model's predictions.

Abstract

The migratory dynamics of cells can be influenced by the complex micro-environment through which they move. It remains unclear how the motility machinery of confined cells responds and adapts to their micro-environment. Here, we propose a biophysical mechanism for a geometry-dependent coupling between cellular protrusions and the nucleus that leads to directed migration. We apply our model to geometry-guided cell migration to obtain insights into the origin of directed migration on asymmetric adhesive micro-patterns and the polarization enhancement of cells observed under strong confinement. Remarkably, for cells that can choose between channels of different size, our model predicts an intricate dependence for cellular decision making as a function of the two channel widths, which we confirm experimentally.