Actomyosin Dynamics in 3D Traction Force Generation

Abstract

The generation and coordination of cellular traction forces plays important roles in cell adhesion, cell migration, and extracellular matrix (ECM) remodeling, and hence in the development and repair of biological tissues. Historically, models for how cells generate and sense mechanical force have been derived from observations of cells grown on hard, two-dimensional (2D) surfaces. However, the cytoskeletal geometry of cells embedded in porous, 3D environments is inherently different than those found in 2D. Here we seek to understand the spatio-temporal regulation of cellular traction forces in a 3D environment. We embed primary human fibroblasts in a fluorescently labeled fibrin matrix, and use multicolor, time-lapse confocal microscopy to simultaneously image matrix deformation induced by cellular traction and the dynamics of the acto-myosin cytoskeleton and paxillin-rich cell-matrix adhesions. We observe significant traction forces transduced to the matrix through dynamic actomyosin-rich protrusions. Flux analysis of myosin concentrations in the protrusions reveals recruitment of myosin towards the protrusion tip during extension, and localization of myosin farther from the tip during retraction. Moreover, we observe both retrograde and anterograde movement of F-actin and myosin during cell traction generation, as well as similar bi-directional dynamics for paxillin-rich adhesions. Our data suggests a model of force generation and mechanotransduction different from the canonical continuous lamellipodial retrograde flow implicated in 2D cell migration. Ongoing work examines the role of signal transduction pathways in regulating cellular force generation, with the end goal of understanding how cells couple force generation and mechanotransduction in fully 3D environments.