Flow-Induced Changes in Endothelial Cell Micro-Mechanical Properties

Studying mechanical properties of cells is becoming increasingly important in understanding how they behave, and interact with their environment. Endothelial cells (ECs) have the capability of sensing and distinguishing between low and high fluid shear stress (FSS) conditions in the vasculature (mechanosensing), leading to preferential localization of atherosclerotic lesions in regions of arterial curvatures where blood flow changes direction and the FSS is physiologically lower. In this book, the oscillating optical tweezers (OOT) methodology was developed as a tool to study micro-mechanical properties of ECs, and used to examine mechanical changes in the vicinity of two mechanosensors, integrin and PECAM, as a response to FSS. FSS-induced structural changes in the vicinity of these mechanosensors were also visualized using confocal microscopy, where actin filament association with integrin and PECAM mechanosensors was examined using the DuolinkTM Proximity Ligation Assay. These studies provided an insight on FSS-induced mechanical and structural changes in the vicinity of integrin and PECAM mechanosensors that could lead to a better understanding of mechanosensing events in ECs.

Autorentext

Meron Mengistu obtained her Ph.D. in Molecular Biology from Lehigh University in Bethlehem, Pennsylvania. Her research interests encompass the understanding of structural and mechanical changes in cells, and the signaling events that control these changes in diseases such as atherosclerosis, HIV/AIDS, and cancer.