Fibrillar adhesions are the primary integrin complexes shaped by matrix topography

Mechanisms of matrix topography recognition are poorly understood. Here, we show that α5β1-integrin mediated fibrillar adhesions serve this function. While on planar substrates, their formation requires fibronectin secretion, tensins, and actomyosin contractility, these requirements are bypassed on nanotopographical features. While focal adhesions avoid these features, fibrillar adhesions rapidly align along pre-existing fibrous cell-derived matrix or electrospun nanofibers where they can then template fibronectin fibrils. Topography-induced fibrillar adhesions depend primarily on α5β1-integrin clustering and disassemble upon cortical stiffening driven by myosin-II overactivation or increased membrane tension. We propose a generic theoretical model where the adhesion receptor favours the membrane and substrate planes to be tilted relative to each other. This model matches experimental observations of preferential α5β1-integrin clustering along nanofibers and concave edges of large negative curvature along micro-ridges. These findings establish fibrillar adhesions as primary adhesion complexes that form independently of focal adhesions in response to matrix topography.