Abstract
Motile cells often face microenvironmental constraints and obstacles that force them to extend multiple protrusions. However, the analysis of shape dynamics during directional decision-making has been restricted to single junctions. Here, we combined live-cell imaging and a coarse-grained model to study the migratory behavior of highly branched cells while simultaneously facing several junctions. The theoretical model predicts that the choice of a new direction is determined by the competition between the cellular protrusions in the form of seesaw oscillations. We found that macrophages and endothelial cells display different regimes moving on hexagonal networks, despite sharing a mesenchymal (i.e., adhesion-dependent) migratory strategy. The model describes the motility of both cell types and reveals a trade-off between branching and speed: Having many protrusions allows local microenvironmental exploration for directional cues, but long-range migration efficiency improves with fewer protrusions. Collectively, our data highlight the relevance and provide insights for the regulation of shape dynamics during cell navigation in complex geometries.