Abstract
The nucleus and uropod are the largest and most mechanically distinct structures in migrating amoeboid lymphocytes, including NK, B, and T cells. The biophysical properties of these structures may shape the ability of immune cells to navigate dense tissue microenvironments during immune surveillance. Using bead-spring and agent-based cell models, we explore the biomechanical contributions of the nucleus, uropod, septin-templated cortical rings, actomyosin cytoskeleton, and extracellular matrix obstacles to lymphocyte migration. Our results support a migration model in which, following cell-matrix collisions, septins mediate the formation of cortical rings that hydraulically seal cytoplasmic compartments on each side of the passing nucleus, generating a pressure difference that propels the nucleus forward. This hydraulically driven nuclear piston actively enhances migration through confined spaces. Concurrently, the uropod emerging from the peristaltic collapse of rear compartments stabilizes directional persistence and prevents T cell repolarization. We show that such polarity stabilization boosts immune surveillance efficiency. Together, these models redefine the nucleus as an active component of the migratory engine and the uropod as a locomotion stabilizer. Furthermore, the models offer a predictive framework towards engineering of immune cell motility in complex tissue microenvironments with broad implications for cancer immunotherapy, aging, and regenerative medicine.