αvß3 integrins negatively regulate cellular forces by phosphorylation of its distal NPXY site.

BACKGROUND INFORMATION: Integrins are key receptors that allow cells to sense and respond to their mechanical environment. Although they bind the same ligand, ß1 and ß3 integrins have distinct and cooperative roles in mechanotransduction. RESULTS: Using traction force microscopy on unconstrained cells, we show that deleting ß3 causes traction forces to increase, whereas the deletion of ß1 integrin results in a strong decrease of contractile forces. Consistently, loss of ß3 integrin also induces an increase in ß1 integrin activation. Using a genetic approach, we identified the phosphorylation of the distal NPXY domain as an essential process for ß3 integrin to be able to modulate traction forces. Loss of ß3 integrins also impacted cell shape and the spatial distribution of traction forces, by causing forces to be generated closer to the cell edge, and the cell shape. CONCLUSIONS: Our results emphasize the role of ß3 integrin in spatial distribution of cellular forces. We speculate that, by modulating its affinity with kindlin, ß3 integrins may be able to locate near the cell edge where it can control ß1 integrin activation and clustering. SIGNIFICANCE: Tensional homeostasis at the single cell level is performed by the ability of ß3 adhesions to negatively regulate the activation degree and spatial localization of ß1 integrins. By combining genetic approaches and new tools to analyze traction distribution and cell morphology on a population of cells we were able to identify the molecular partners involved in cellular forces regulation.

Desmin Mutation in the C-Terminal Domain Impairs Traction Force Generation in Myoblasts.

The cytoskeleton plays a key role in the ability of cells to both resist mechanical stress and generate force, but the precise involvement of intermediate filaments in these processes remains unclear. We focus here on desmin, a type III intermediate filament, which is specifically expressed in muscle cells and serves as a skeletal muscle differentiation marker. By using several complementary experimental techniques, we have investigated the impact of overexpressing desmin and expressing a mutant desmin on the passive and active mechanical properties of C2C12 myoblasts. We first show that the overexpression of wild-type-desmin increases the overall rigidity of the cells, whereas the expression of a mutated E413K desmin does not. This mutation in the desmin gene is one of those leading to desminopathies, a subgroup of myopathies associated with progressive muscular weakness that are characterized by the presence of desmin aggregates and a disorganization of sarcomeres. We show that the expression of this mutant desmin in C2C12 myoblasts induces desmin network disorganization, desmin aggregate formation, and a small decrease in the number and total length of stress fibers. We finally demonstrate that expression of the E413K mutant desmin also alters the traction forces generation of single myoblasts lacking organized sarcomeres.

AmotL2 links VE-cadherin to contractile actin fibres necessary for aortic lumen expansion.

The assembly of individual endothelial cells into multicellular tubes is a complex morphogenetic event in vascular development. Extracellular matrix cues and cell-cell junctional communication are fundamental to tube formation. Together they determine the shape of endothelial cells and the tubular structures that they ultimately form. Little is known regarding how mechanical signals are transmitted between cells to control cell shape changes during morphogenesis. Here we provide evidence that the scaffold protein amotL2 is needed for aortic vessel lumen expansion. Using gene inactivation strategies in zebrafish, mouse and endothelial cell culture systems, we show that amotL2 associates to the VE-cadherin adhesion complex where it couples adherens junctions to contractile actin fibres. Inactivation of amotL2 dissociates VE-cadherin from cytoskeletal tensile forces that affect endothelial cell shape. We propose that the VE-cadherin/amotL2 complex is responsible for transmitting mechanical force between endothelial cells for the coordination of cellular morphogenesis consistent with aortic lumen expansion and function.