Modulation of ATP/ADP Concentration at the Endothelial Cell Surface by Flow: Effect of Cell Topography

Determining how flow affects the concentration of the adenine nucleotides ATP and ADP at the vascular endothelial cell (EC) surface is essential for understanding flow-induced mobilization of intracellular calcium. Previously, mathematical models were formulated to describe the ATP/ADP concentration at the EC surface; however, all previous models assumed the endothelium to be flat. In the present study we investigate the effect of surface undulations on ATP/ADP concentration at the EC surface. The results demonstrate that under certain geometric and flow conditions, the ATP + ADP concentration at the EC surface is considerably lower for a wavy cell surface than for a flat surface. Because ECs in regions of disturbed arterial flow are expected to have larger undulations than cells in non-disturbed flow zones, our findings suggest that ECs in regions of flow disturbance would exhibit lower ATP + ADP concentrations at their surfaces, which may lead to impaired calcium signaling. If validated experimentally, the present results may contribute to our understanding of endothelial cell dysfunction observed in regions of disturbed flow

Flow-Dependent Mass Transfer May Trigger Endothelial Signaling Cascades

It is well known that fluid mechanical forces directly impact endothelial signaling pathways. But while this general observation is clear, less apparent are the underlying mechanisms that initiate these critical signaling processes. This is because fluid mechanical forces can offer a direct mechanical input to possible mechanotransducers as well as alter critical mass transport characteristics (i.e., concentration gradients) of a host of chemical stimuli present in the blood stream. However, it has recently been accepted that mechanotransduction (direct mechanical force input), and not mass transfer, is the fundamental mechanism for many hemodynamic force-modulated endothelial signaling pathways and their downstream gene products. This conclusion has been largely based, indirectly, on accepted criteria that correlate signaling behavior and shear rate and shear stress, relative to changes in viscosity. However, in this work, we investigate the negative control for these criteria. Here we computationally and experimentally subject mass-transfer limited systems, independent of mechanotransduction, to the purported criteria. The results showed that the negative control (mass-transfer limited system) produced the same trends that have been used to identify mechanotransduction-dominant systems. Thus, the widely used viscosity-related shear stress and shear rate criteria are insufficient in determining mechanotransduction-dominant systems. Thus, research should continue to consider the importance of mass transfer in triggering signaling cascades

Dynamic modeling for shear stress induced ATP release from vascular endothelial cells

10.1007/s10237-007-0088-8Biomechanics and Modeling in Mechanobiology75345-35

Mechanotransduction and Vascular Resistance

International audienceMechanotransduction is the process by which any cell transduces (converts) a mechanical signal into chemical cues. The vessel wall is permanently sheared by the moving blood particles as well as stretched and compressed by the pressure applied by the blood. Multiple types of mechanical stress fields are associated with flow patterns and unsteadiness.Mechanosensing occurs locally at the plasma membrane. It relies on detection of local changes in protein conformation that lead to ion channel opening, protein unfolding, modified enzyme kinetics, and variations in molecular interactions following exposure of buried binding site or, conversely, hiding them.Mechanotransduction initiates several signaling pathways. Multiple mediators include: At the cell surface, G-protein-coupled and protein tyrosine kinase receptors, ion channels, enzymes, adhesion molecules, and specialized plasmalemmal nanodomains At the cell cortex, the cortical actin network that regulates the cell-surface mechanics and signaling adaptors and effectors (e.g., small monomeric guanosine triphosphatases and heterotrimeric guanine nucleotide-binding proteins, kinases, phosphatases, and ubiquitins, among others) In the cytosol, enzymes, scaffolds, carriers such as endosomes, calcium concentration, and transcription factors In the nucleus, nuclear pore carriers, enzymes, and the transcriptional and translational machineryMechanotransduction by vascular cells regulate the contraction–relaxation state of vascular smooth myocytes, thereby regulating locally and quickly the size of the vascular lumen, that is, the local vascular resistance to blood flow. Once experiencing an unusual mechanical stress, vascular smooth myocytes react by contracting or relaxing according to the magnitude of the mechanical stress, the value of which rises above or falls below the range in which it fluctuates in normal conditions. Moreover, they receive chemical and electrochemical signals from endotheliocytes, themselves sensing the wall shear stress at their wetted (luminal) surface.Mechanotransduction thus regulates locally blood flow more rapidly than the endocrine regulation by remote tissues and even than that of the nervous system, which transmits signals very rapidly via afferent nerves and, after processing in the centers of the spinal cord and brain, efferent nerves