Modeling collective cell migration in a heterogeneous environment: Drosophila border cell migration as a model paradigm

Collective cell migration underpins development and disease progression, yet the influence of heterogeneous microenvironments on intercellular forces and migration dynamics remains elusive. Focusing on the chemotactic migration of border cell clusters in Drosophila egg chambers, we present a computational framework that integrates intercellular force dynamics and cell shape changes during large-scale migration, validated with live imaging data. Our model replicates in vivo observations, such as rotations of the cell cluster and its tendency to follow a central path in the egg chamber. Using the model, we discover instantaneous acceleration/deceleration phases as the cell cluster migrates through junctions of other cell types. We also predict how environmental tissue topology and perturbations in chemoattractant gradients and adhesion impact cluster speed and rotation. By addressing the limitations of prior models of border cell migration, our approach offers broad applicability to other migration contexts involving interactions among different cell types in complex environments.