How Cells Integrate Complex Stimuli: The Effect of Feedback from Phosphoinositides and Cell Shape on Cell Polarization and Motility

Athanasius F M Marée,Verônica A Grieneisen,Leah Edelstein-Keshet,Andrew D Mcculloch

doi:10.1371/journal.pcbi.1002402

Athanasius F M Marée, Verônica A Grieneisen + Show 2 more

Open Access

https://doi.org/10.1371/journal.pcbi.1002402

Copy DOI

Abstract

To regulate shape changes, motility and chemotaxis in eukaryotic cells, signal transduction pathways channel extracellular stimuli to the reorganization of the actin cytoskeleton. The complexity of such networks makes it difficult to understand the roles of individual components, let alone their interactions and multiple feedbacks within a given layer and between layers of signalling. Even more challenging is the question of if and how the shape of the cell affects and is affected by this internal spatiotemporal reorganization. Here we build on our previous 2D cell motility model where signalling from the Rho family GTPases (Cdc42, Rac, and Rho) was shown to organize the cell polarization, actin reorganization, shape change, and motility in simple gradients. We extend this work in two ways: First, we investigate the effects of the feedback between the phosphoinositides (PIs) , and Rho family GTPases. We show how that feedback increases heights and breadths of zones of Cdc42 activity, facilitating global communication between competing cell “fronts”. This hastens the commitment to a single lamellipodium initiated in response to multiple, complex, or rapidly changing stimuli. Second, we show how cell shape feeds back on internal distribution of GTPases. Constraints on chemical isocline curvature imposed by boundary conditions results in the fact that dynamic cell shape leads to faster biochemical redistribution when the cell is repolarized. Cells with frozen cytoskeleton, and static shapes, consequently respond more slowly to reorienting stimuli than cells with dynamic shape changes, the degree of the shape-induced effects being proportional to the extent of cell deformation. We explain these concepts in the context of several in silico experiments using our 2D computational cell model.

Highlights

Reorganization of the actin cytoskeleton is essential in eukaryotic cell motility
Through in silico experiments using a computational model of a moving cell, the interactions of an important class of such proteins (Rho GTPases) and lipids, their spatial redistribution, and how they affect and are affected by cell shape
Active Cdc42 and Rac, as well as PIP2 and PIP3, are enriched at one end, whereas active Rho and PIP are most prevalent at the opposite end

Summary

Introduction

Reorganization of the actin cytoskeleton is essential in eukaryotic cell motility. Signalling modules that regulate this reorganization include the Rho GTPases (Cdc, Rac, Rho) and membrane lipids (PIP2 and PIP3). In zones of high Rho activity, actomyosin contraction is enhanced [5,6,7] These combined effects lead to protrusion at the cell front and retraction at the rear. Such effects change the cell’s shape, and orchestrate directed motion and chemotaxis. Recent work on visualizing cell motility in vivo, e.g. Yoo et al [8], points to the importance of understanding the role of feedback (e.g. between PIP3 and Rac). This paper addresses such questions in the context of a computational model for cell motility

Objectives

Methods

Results

Conclusion