Microscopic Control of Cortical Flows in Polarized C. elegans Zygotes

Cell polarization, migration, and cytokinesis rely on flows of the cell cortex, a network of actin filaments, cross-linkers, and motors beneath the plasma membrane of animal cells. While actin network architecture, assembly dynamics, and motor activity are known to be important for cortical flows, how their modulation tunes macroscopic flow dynamics remains poorly quantified in vivo . Here, we use quantitative microscopy to constrain agent-based simulations that account for filament assembly, crosslinking, and motor activity. We calibrate the model to reproduce steady-state flows in polarized C. elegans zygotes and then challenge it to predict the results of RNA interference (RNAi) experiments. Our model predicts, and experiments largely confirm, a biphasic dependence of flow speed on microscopic rates of actin filament assembly and crosslinking. This biphasic dependence reflects a competition between the tendencies of perturbations to disrupt both transmission of and resistance to cortical forces. Our results provide new insights into how variations in microscopic features shape the emergent dynamics of the cell cortex. By establishing a well-calibrated model of cortical flow in a highly tractable model cell, we also provide a foundation for future studies of microscopic origins and biological control of cortical contractility and flow in vivo .