Tropomyosin Isoform Expression Regulates the Transition of Adhesions To Determine Cell Speed and Direction

The balance of transition between distinct adhesion types contributes to the regulation of mesenchymal cell migration, and the characteristic association of adhesions with actin filaments led us to question the role of actin filament-associating proteins in the transition between adhesive states. Tropomyosin isoform association with actin filaments imparts distinct filament structures, and we have thus investigated the role for tropomyosins in determining the formation of distinct adhesion structures. Using combinations of overexpression, knockdown, and knockout approaches, we establish that Tm5NM1 preferentially stabilizes focal adhesions and drives the transition to fibrillar adhesions via stabilization of actin filaments. Moreover, our data suggest that the expression of Tm5NM1 is a critical determinant of paxillin phosphorylation, a signaling event that is necessary for focal adhesion disassembly. Thus, we propose that Tm5NM1 can regulate the feedback loop between focal adhesion disassembly and focal complex formation at the leading edge that is required for productive and directed cell movement.Among the different modes of migration that cells adopt, mesenchymal cell migration is dependent on integrin-based adhesion to the extracellular matrix (14), and the cellular mechanisms regulating integrin adhesion formation and turnover (adhesion dynamics) are integral to this process. The fate of integrin adhesions is intimately linked with filaments of polymerized actin (4). At the molecular level, actin filaments are highly dynamic, and this aspect of actin polymer biology provides an important control mechanism by which cells can organize filaments into structures with distinct properties. Tropomyosins are a multi-isoform family of actin-associating proteins that confer isoform-specific regulation of diverse actin filaments (3, 16, 34, 35). The interdependence of integrin adhesions and actin filaments suggests that expression of actin-associated proteins such as the tropomyosins may represent a mechanism for the regulation of adhesion dynamics that determine cell migration.In migrating cells small integrin-based focal complexes form at the periphery of lamellipodial extensions (32). These complexes are characterized by their subcellular distribution, dot-like shape, dependence on Rac activity, phosphorylated paxillin, and association with the network of short, branched actin filaments at the leading edge. The focal complexes are short lived (43) but provide strong traction forces at the leading edge (2) and most likely regulate directional migration (19). Subsets of focal complexes mature into focal adhesions, structures characterized by: Rho GTPase and Rho kinase dependence, dash-like shape, high levels of paxillin and phosphorylated paxillin, and low levels of the actin-binding molecule tensin (43, 44). The focal adhesions play an important role in anchoring bundles of polymerized actin stress fibers, providing the contractile force necessary for the translocation of the cell body during migration. There are at least three distinct classes of stress fibers observed in migrating cells (20, 27). Dorsal stress fibers are inserted into focal adhesions at the ventral surface of the cell. The distal end of the dorsal fibers can associate with a second type of actin fiber, the transverse arcs that run parallel to the leading edge and are not directly connected to focal adhesions. Ventral stress fibers have focal adhesions at either end and can be established following the contraction of two dorsal stress fibers and the associated transverse arc to form one actin bundle (20).Increased ventral stress fibers and focal adhesions are characteristic of nonmotile cells, in contrast, cell migration depends on focal adhesion turnover at the leading edge, allowing the formation of newly protruding regions of membrane and focal complex formation (28, 39). While the precise mechanism of focal adhesion turnover is incompletely understood, activation and phosphorylation of Src kinase, p130Cas, and paxillin (13, 39, 45) have all been implicated in focal adhesion turnover. A biphasic relationship between cell adhesion and cell speed suggests that conditions that alter the turnover rate of focal adhesions (either too much or too little) can reduce cell speed (18, 22).In cells with a fibroblastic phenotype, increased levels of acto-myosin contractility promote focal adhesion transition to fibrillar adhesions (also known as ECM contacts) (6, 7): elongated, thin, central arrays of dots or elongated fibrils that characteristically contain tensin but low levels of phosphorylated paxillin (29, 44, 45) and bind fibrils of fibronectin parallel to actin bundles (23, 29). These adhesions are formed by ligand-occupied fibronectin integrin receptor translocation from focal adhesions along bundles of actin filaments toward the cell center, and the process is dependent on an intact actin cytoskeleton and myosin activity (29). Receptor translocation stimulates matrix reorganization by transmitting cytoskeleton-generated tension through the integrin receptors onto the surrounding matrix (25, 29). The rate of receptor translocation is apparently independent from the rate of cell migration (29). However, the cytoskeletal tension that causes the fibrillar adhesion formation is also reported to decrease paxillin phosphorylation (45). Since phosphorylated paxillin is required for the generation of new focal complexes (45), conditions which switch the balance of adhesion in favor of fibrillar adhesion should presumably result in significantly reduced paxillin phosphorylation, leading to reduced focal adhesion turnover and correspondingly decreased cell migration.The cytoskeletal tropomyosin Tm5NM1 is a broadly distributed isoform (37) that alters cell shape (34), localizes to and promotes stress fibers that are resistant to actin depolymerizing drugs (9), enhances myosin IIA activation and recruitment to stress fibers, and inhibits cell migration (3). Therefore, we hypothesized that Tm5NM1 expression might determine cell migration by coordinating actin-dependent transition toward a predominance of focal adhesions and fibrillar adhesions. Using overexpression, knockdown, and genetic knockout models, we demonstrate that Tm5NM1 inhibits cell migration by promoting selective stabilization of focal adhesions and transition to fibrillar adhesions via the regulation of paxillin phosphorylation.