RT Journal Article
SR Electronic
T1 Getting in shape and swimming: the role of cortical forces and membrane heterogeneity in eukaryotic cells
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 198523
DO 10.1101/198523
A1 Hao Wu
A1 Marco Avila Ponce de León
A1 Hans G. Othmer
YR 2017
UL http://biorxiv.org/content/early/2017/10/26/198523.abstract
AB Recent research has shown that motile cells can adapt their mode of propulsion to the mechanical properties of the environment in which they find themselves – crawling in some environments while swimming in others. The latter can involve movement by blebbing or other cyclic shape changes, and both highly-simplified and more realistic models of these modes have been studied previously. Herein we study swimming that is driven by membrane tension gradients that arise from flows in the actin cortex underlying the membrane, and does not involve imposed cyclic shape changes. Such gradients can lead to a number of different characteristic cell shapes, and our first objective is to understand how different distributions of membrane tension influence the shape of cells in a quiescent fluid. We then analyze the effects of spatial variation in other membrane properties, and how they interact with tension gradients to determine the shape. We also study the effect of fluid-cell interactions and show how tension leads to cell movement, how the balance between tension gradients and a variable bending modulus determine the shape and direction of movement, and how the efficiency of movement depends on the properties of the fluid and the distribution of tension and bending modulus in the membrane.Dedicated to the memory of Karl P. Hadeler, a pioneer in the field of Mathematical Biology and a friend and mentor to many.