Matrix adherence of endothelial cells attenuates immune reactivity: induction of hyporesponsiveness in allo- and xenogeneic models.

Endothelial integrity regulates vascular tone, luminal patency, and the immune reactivity to tissue grafts. Endothelial dysfunction is the first marker and site of disease initiation and severity. It has long been known that endothelial biochemical function is density dependent, and we have recently shown that endothelial immunobiology is anchorage dependent. Matrix-embedded endothelial cells (EC) establish a controlled anchorage state and are not only immune protected but also induce a system immune protective state. We now define this aspect of vascular and immune biology in detail. The in vitro immune response of allogeneic splenocytes (proliferation, lytic activity, and cytokine expression) on exposure to aortic EC was significantly reduced if EC were embedded within three-dimensional collagen matrices (3D-EC; P<0.005) to an even greater extent than EC that had reached confluence as monolayers on tissue culture plates (EC-TCPS). Splenocyte reactivity was enhanced with repeated exposure to EC-TCPS but minimally if preexposed to 3D-EC (P<0.002). 3D-EC induced significantly greater differentiation of splenocytes into CD4+ CD25+ Foxp3+ regulatory T cells than EC-TCPS (P<0.02). The reduced response to 3D-EC and potential protective effect to subsequent exposure were confirmed in vivo. Repeated exposure of immune-competent mice to injections of xenogeneic EC-TCPS induced vigorous host immunity. In contrast, prior implantation of 3D-EC induced hyporesponsiveness toward subsequent injection of EC-TCPS with reduced humoral response, decreased lytic activity, and lower frequency of effector splenocytes (P<0.001). EC interaction with its matrix determines phenotype, viability, and biosecretory potential. We now show that this microenvironmental interaction also influences endothelial-mediated activation of allo- and xenogeneic immune cells. 3D matrix-embedding limits the ability of EC to initiate adaptive immunity, and initial exposure to 3D-EC confers hyporesponsiveness to subsequent exposure to immunogeneic EC. These effects transcended the traditional control that confluence imposes on EC and reflects perhaps even higher order control. Our findings might offer novel insights to endothelial-mediated diseases and potential cell-based therapies.