Abstract
Cells can move through extracellular environments with varying geometries and adhesive properties. Adaptation to these differences is achieved by switching between different modes of motility, including lamellipod-driven and blebbing motility. Further, cells can modulate their level of adhesion to the extracellular matrix (ECM) depending on both the level of force applied to the adhesions and cell intrinsic biochemical properties. We have constructed a computational model of cell motility to investigate how motile cells transition between extracellular environments with varying surface continuity, confinement and adhesion. Changes in migration strategy are an emergent property of cells as the ECM geometry and adhesion changes. The transition into confined environments with discontinuous ECM fibres is sufficient to induce shifts from lamellipod-based to blebbing motility, while changes in confinement alone within a continuous geometry are not. The geometry of the ECM facilitates plasticity, by inducing shifts where the cell has high marginal gain from a mode change, and conserving persistency where the cell can continue movement regardless of the motility mode. This regulation of cell motility is independent of global changes in cytoskeletal properties, but requires locally higher linkage between the actin network and the plasma membrane at the cell rear, and changes in internal cell pressure. In addition to matrix geometry, we consider how cells might transition between ECM of different adhesiveness. We find that this requires positive feedback between the forces cells apply on the adhesion points, and the strength of the cell–ECM adhesions on those sites. This positive feedback leads to the emergence of a small number of highly adhesive cores, similar to focal adhesions. While the range of ECM adhesion levels the cell can invade is expanded with this feedback mechanism; the velocities are lowered for conditions where the positive feedback is not vital. Thus, plasticity of cell motility sacrifices the benefits of specialization, for robustness.
Highlights
Motile cells are required to navigate through a variety of extracellular conditions, both in terms of the geometry and adhesiveness of the extracellular matrix (ECM)
We propose that a regulatory mechanism for the cell–ECM adhesion in response to applied forces is a good candidate to increase the plasticity of cell motility
In our previous work, using a unified model that incorporates lamellipodia, blebbing and cell–ECM interactions, we identified different ECM geometries will have different cellular requirements and efficacy of invasion through a given matrix geometry will strongly depend on the motility mode [2]
Summary
Motile cells are required to navigate through a variety of extracellular conditions, both in terms of the geometry and adhesiveness of the extracellular matrix (ECM). These changing environments have different motility requirements [1]. Other geometries favour migration dominated by high actomyosin contractility and hydrostatic pressure pushing the plasma membrane forward. The plasticity of cell motility can be exploited in pathological contexts such as the spread of cancer cells through the body It is unclear what regulatory mechanisms confer this adaptability and if this plasticity comes at the cost of the benefits of specialization.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
