DOCK8 regulates a mechanosensitive actin redistribution that maintains immune cell cohesion and protects the nucleus during migration

Abstract

AbstractImmune cells navigate through complex 3-dimensional tissue architectures, utilizing an amoeboid mode of migration, characterized by extensive cellular deformation, low adhesion, and high cell velocities. In the absence of expression ofDedicator of Cytokinesis 8 (Dock8), a gene identified with loss-of-function mutations in immunodeficiency, cells become entangled during migration through dense, confined environments and consequently undergo catastrophic cell rupturing, while migration on 2D surfaces remains entirely intact. Here we investigated the specific cytoskeletal defect ofDock8-deficient activated T cells, showing that even prior to entanglement they display a striking difference in F-actin distribution compared to wild type (WT) cells. We describe a central pool of F-actin in WT murine and human T cells which is absent inDock8KO T cells, and determine that the relocalization of F-actin is a mechanoresponsive circuit, emerging only when cells are very confined. Our works shows that the central actin pool is nucleo-protective, reducing nuclear deformation and DNA damage during confined migration. We identify the Hippo-pathway kinase Mst1 as a co-mediator of this mechanosensitive pathway in conjunction with Dock8, allowing for cell cohesion and survival during migration through complex environments.