Summary Background Mechanical forces regulate cell behavior and function during development, differentiation, and tissue morphogenesis. In the vascular system, forces produced by blood flow are critical determinants not only of morphogenesis and function, but also pathological states such as atherosclerosis. Endothelial cells (ECs) have numerous mechanotransducers, including platelet endothelial cell adhesion molecule-1 (PECAM-1) at cell-cell junctions and integrins at cell-matrix adhesions. However, the processes by which forces are transduced to biochemical signals and subsequently translated into downstream effects are poorly understood. Results Here, we examine mechanochemical signaling in response to direct force application on PECAM-1. We demonstrate that localized tensional forces on PECAM-1 result in, surprisingly, global signaling responses. Specifically, force-dependent activation of phosphatidylinositol 3-kinase (PI3K) downstream of PECAM-1 promotes cell-wide activation of integrins and the small GTPase RhoA. These signaling events facilitate changes in cytoskeletal architecture, including growth of focal adhesions and adaptive cytoskeletal stiffening. Conclusions Taken together, our work provides the first evidence of a global signaling event in response to a localized mechanical stress. In addition, these data provide a possible mechanism for the differential stiffness of vessels exposed to distinct hemodynamic force patterns in vivo.
Coordinated movement of large groups of cells is required for many biological processes, such as gastrulation and wound healing. During collective cell migration, cell-cell and cell-extracellular matrix (ECM) adhesions must be integrated so that cells maintain strong interactions with neighboring cells and the underlying substratum. Initiation and maintenance of cadherin adhesions at cell-cell junctions and integrin-based cell-ECM adhesions require integration of mechanical cues, dynamic regulation of the actin cytoskeleton, and input from specific signaling cascades, including Rho family GTPases. Here, we summarize recent advances made in understanding the interplay between these pathways at cadherin- and integrin-based adhesions during collective cell migration and highlight outstanding questions that remain in the field.
Endothelial cell (ECs) lining blood vessels express many mechanosensors, including platelet endothelial cell adhesion molecule-1 (PECAM-1), that convert mechanical force to biochemical signals. While it is accepted that mechanical stresses and the mechanical properties of ECs regulate vessel health, the relationship between force and biological response remains elusive. Here we show that ECs integrate mechanical forces and extracellular matrix (ECM) cues to modulate their own mechanical properties. We demonstrate that the ECM influences EC response to tension on PECAM-1. ECs adherent on collagen display divergent stiffening and focal adhesion growth compared to ECs on fibronectin. This is due to PKA-dependent serine phosphorylation and inactivation of RhoA. PKA signaling regulates focal adhesion dynamics and EC compliance in response to shear stress in vitro and in vivo. Our study identifies a ECM-specific, mechanosensitive signaling pathway that regulates EC compliance and may serve as an atheroprotective mechanism maintains blood vessel integrity in vivo.
Estimating ultrafine particle number concentrations (PNC) near highways for exposure assessment in chronic health studies requires models capable of capturing PNC spatial and temporal variations over the course of a full year. The objectives of this work were to describe the relationship between near-highway PNC and potential predictors, and to build and validate hourly log-linear regression models. PNC was measured near Interstate 93 (I-93) in Somerville, MA (USA) using a mobile monitoring platform driven for 234 hours on 43 days between August 2009 and September 2010. Compared to urban background, PNC levels were consistently elevated within 100–200 m of I-93, with gradients impacted by meteorological and traffic conditions. Temporal and spatial variables including wind speed and direction, temperature, highway traffic, and distance to I-93 and major roads contributed significantly to the full regression model. Cross-validated model R2 values ranged from 0.38–0.47, with higher values achieved (0.43–0.53) when short-duration PNC spikes were removed. The model predicts highest PNC near major roads and on cold days with low wind speeds. The model allows estimation of hourly ambient PNC at 20-m resolution in a near-highway neighborhood.
The GEF Tiam1 acts as a novel molecular link to the VE-cadherin–p67phox–Par3 polarity complex, leading to localized activation of Rac1 and NADPH oxidase in response to fluid flow.
Mechanical cues are sensed and transduced by cell adhesion complexes to regulate diverse cell behaviors. Extracellular matrix (ECM) rigidity sensing by integrin adhesions has been well studied, but rigidity sensing by cadherins during cell adhesion is largely unexplored. Using mechanically tunable polyacrylamide (PA) gels functionalized with the extracellular domain of E-cadherin (Ecad-Fc), we showed that E-cadherin-dependent epithelial cell adhesion was sensitive to changes in PA gel elastic modulus that produced striking differences in cell morphology, actin organization, and membrane dynamics. Traction force microscopy (TFM) revealed that cells produced the greatest tractions at the cell periphery, where distinct types of actin-based membrane protrusions formed. Cells responded to substrate rigidity by reorganizing the distribution and size of hightraction-stress regions at the cell periphery. Differences in adhesion and protrusion dynamics were mediated by balancing the activities of specific signaling molecules. Cell adhesion to a 30-kPa Ecad-Fc PA gel required Cdc42-and formin-dependent filopodia formation, whereas adhesion to a 60-kPa Ecad-Fc PA gel induced Arp2/3-dependent lamellipodial protrusions. A quantitative 3D cell-cell adhesion assay and live cell imaging of cell-cell contact formation revealed that inhibition of Cdc42, formin, and Arp2/3 activities blocked the initiation, but not the maintenance of established cell-cell adhesions. These results indicate that the same signaling molecules activated by E-cadherin rigidity sensing on PA gels contribute to actin organization and membrane dynamics during cell-cell adhesion. We hypothesize that a transition in the stiffness of E-cadherin homotypic interactions regulates actin and membrane dynamics during initial stages of cellcell adhesion.C ell adhesion is essential for tissue structure and function. Cells use specialized types of adhesions to interact with the surrounding environment, including integrin-based focal adhesions at cell-extracellular matrix (cell-ECM) contacts and cadherin-based adhesions at cell-cell contacts (1). Integrins bind to the ECM and intracellular proteins that link to the actin cytoskeleton and important signaling pathways (2). Similarly, cadherins regulate cellcell recognition and adhesion (3) and, through cytoplasmic adaptor proteins (catenins, vinculin) (4, 5), also link to the actin cytoskeleton and other proteins with signaling and scaffolding functions (6).Initiation of cell-cell adhesion requires significant reorganization of the actin cytoskeleton and is tightly controlled by the activities of actin nucleating proteins and Rho GTPases. Adhesion is initiated when filopodia from opposing cells come into contact with one another (7,8), and this process is regulated by Cdc42 activity (9, 10) and formin-dependent actin polymerization (11)(12)(13)(14). Intermediate stages of cell-cell contact formation involve lateral expansion of the contact by Rac1-induced and Arp2/3-dependent lamellipodial activity (15, 16). Finally, com...
Elmo–Dock complexes are involved not just in integrin-based adhesions but also in the initial formation of strong cadherin-based adhesions through the regulation of local Rho GTPase activity and actin remodeling.
Aging is a key risk factor associated with the associated onset of cardiovascular disease. Notably, vascular aging and cardiovascular disease are both with endothelial dysfunction, or a marked decrease in production and bioavailability the vasodilator of nitric oxide (NO). As a result of decreased nitric oxide availability, aging vessels often exhibit endothelial cell senescence and increased oxidative stress. One of the most potent activators of NO production is fluid shear stress produced by blood flow. Interestingly, age-related decrease in NO production partially results from endothelial insensitivity to shear stress. While the endothelial cell response to fluid shear stress has been well characterized in recent years, the exact mechanisms of how the mechanical force of fluid shear stress is converted into intracellular biochemical signals are relatively unknown. Therefore, gaining a better knowledge of mechanosignaling events in endothelial cells may prove to be beneficial for developing potential therapies for cardiovascular diseases. Vascular Aging and Endothelial DysfunctionAging is associated with a progressive decline in numerous physiologic processes, leading to an increased risk of health complications and diseases. Notably, aging is a key risk factor involved in the development of cardiovascular diseases, such as atherosclerosis, hypertension, and stroke. These cardiovascular diseases occur in the aging population even in the absence of other well-established risk factors, such as high plasma lipid levels, diabetes, smoking, or sedentary lifestyle. In addition, aging is associated with a progressive decline in cardiovascular function, further increasing the risk of cardiovascular disease. Importantly, both vascular aging and the onset of cardiovascular diseases are associated with endothelial cell (EC) dysfunction. ECs are continually exposed to circulating blood and must function to regulate and meet the oxygen and nutrient needs of the underlying tissue. Additionally, ECs are essential for cardiovascular homeostasis and maintaining vascular tone. Therefore, endothelial dysfunction markedly affects the overall integrity and function of the cardiovascular system. Endothelial dysfunction is largely to due decreased production and bioavailability of the potent vasodilator nitric oxide (NO), resulting in impaired arterial vasodilation. Reduction of NO availability greatly influences the vessel as a whole, impacting the ability of the vessel to dilate, but also specifically affects the function and structure of the vessel on a cellular level, mediating numerous changes in EC structure and function.
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