Endothelial cell stiffness and type drive the formation of biomechanically-induced transcellular pores.
Formation of transcellular pores facilitates the transport of materials across endothelial barriers. In Schlemm's canal (SC) endothelium, impaired pore formation is associated with glaucoma. However, our understanding of the cellular processes responsible for pore formation is limited by lack of in vitro assays. Here, we present a novel platform for studying transcellular pore formation in human endothelial cells. We induced pores in SC cells by seeding them atop micron-sized magnetic beads followed by application of a magnetic field to subject cells to a basal to apical force, mimicking in vivo biomechanical forces. The pore formation process was dynamic, with pores opening and closing. Glaucomatous cells exhibited impaired pore formation that correlated with their increased stiffness. We further discovered that application of forces from the apical to basal direction did not induce pores in SC cells but resulted in formation of pores in other types of endothelial cells. Our studies reveal the central role of cell mechanics in formation of transcellular pores in endothelial cells, and provide a new approach for investigating their associated underlying mechanism/s.
