Abstract
Biological tissues contain micrometer-scale gaps and pores, including those found within extracellular matrix fiber networks, between tightly packed cells, and between blood vessels or nerve bundles and their associated basement membranes. These spaces restrict cell motion to a single-spatial dimension (1D), a feature that is not captured in traditional in vitro cell migration assays performed on flat, unconfined two-dimensional (2D) substrates. Mechanical confinement can variably influence cell migration behaviors, and it is presently unclear whether the mechanisms used for migration in 2D unconfined environments are relevant in 1D confined environments. Here, we assessed whether a cell migration simulator and associated parameters previously measured for cells on 2D unconfined compliant hydrogels could predict 1D confined cell migration in microfluidic channels. We manufactured microfluidic devices with narrow channels (60-μm2 rectangular cross-sectional area) and tracked human glioma cells that spontaneously migrated within channels. Cell velocities (vexp = 0.51 ± 0.02 μm min−1) were comparable to brain tumor expansion rates measured in the clinic. Using motor-clutch model parameters estimated from cells on unconfined 2D planar hydrogel substrates, simulations predicted similar migration velocities (vsim = 0.37 ± 0.04 μm min−1) and also predicted the effects of drugs targeting the motor-clutch system or cytoskeletal assembly. These results are consistent with glioma cells utilizing a motor-clutch system to migrate in confined environments.
Highlights
Cell migration is involved in numerous physiological functions throughout organismal development and adult life
Each simulated cell contains an ensemble of nmotor myosin II motors, nclutch molecular adhesion clutches, and a total pool of F-actin (Atotal) that form the basis for protrusion modules
Similar confinement can be reliably reproduced in PDMS microchannel assays, and live-celltracking measurements can be compared to biophysical simulations of cell migration mechanics
Summary
Cell migration is involved in numerous physiological functions throughout organismal development and adult life. The physical mechanism of cell migration involves coordinated dynamics of the actin cytoskeleton and adhesion complexes [2,3]. F-actin assembly drives the elongation of cellular protrusions, whereas within protrusions, adhesion receptors (termed ‘‘clutches’’) assemble into complexes and link cells to extracellular matrix (ECM) ligands. Bound clutches cooperatively transmit contractile actin-myosin forces to the ECM, establishing traction forces that drive locomotion. Integrated physical models incorporate mathematical expressions for these molecular processes to successfully predict experimentally measured cell migration behaviors [3,4,5]. Building upon an established motor-clutch model for cell traction [6,7,8], a recently developed computational cell migration simulator (CMS) reproduces the characteristic random motility of glioma cells on compliant
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