Extracellular Matrix Contributions to Early Vascular Development and Pericyte Precursor Dynamics

The vasculature is a highly intricate system of "highways" that shuttles blood from the heart to every tissue and organ in the human body. These vessels are responsible for carrying oxygen, trafficking hormones, delivering nutrients, and removing waste products from the body. The formation of a functioning vascular system depends on the close coordination of many cell types and, on the capillary level, specifically endothelial cells and pericytes as well as the surrounding protein microenvironment, known as the extracellular matrix (ECM). Impaired coordination amongst the cellular and protein constituents results in the improper functioning of the vascular network and can eventually contribute to the failure of organ systems. This dissertation research focuses on how improper ECM deposition affects vascular assembly. We utilized several approaches to affect ECM composition, specifically: 1) hypoxia exposure and 2) reducing ECM pharmacologically and utilizing lentiviral-mediated silencing of Type IV Collagen (Col-IV, gene Col4a1) expression. In these experimental settings, we observed downstream changes in the coordination between endothelial cells and pericytes while forming vascular networks. In short, this dissertation work suggests that excess ECM deposition, and particularly that of Col-IV, has unique deleterious effects on the developing vasculature as compared to reduced ECM deposition. The findings from this work suggest mechanisms underlying how the vasculature may be destabilized in hypoxia-associated pathologies, such as preeclampsia.