Abstract 14765: Exosome Shuttled VEGFR Promotes Angiogenesis in Peripheral Vascular Disease

Abstract

Introduction: Counteracting the pandemic of peripheral vascular disease necessitates development of proangiogenic treatments. As stem cell benefit has increasingly been associated with paracrine influence on diseased tissue, a purified extracellular vesicle population (PEP) was established to promote tissue regeneration and neovascularization. The mechanistic basis for PEP-induced proangiogenic effects was here probed and validated in two separate in vivo models of vascular ischemia. Hypothesis: PEP drives pro-angiogenic effects though donation of VEGFR. Methods: Nanosight and immunoblotting were utilized to characterize PEP purity and identity. OMICs profiling identified VEGFR as highly prioritized, with downstream signaling was tested in human umbilical vascular endothelial cells using Matrigel assay, qPCR and immunoblotting. In vivo, blood perfusion (Fluorescent imaging - SPY) was quantified in a rodent model of hind-limb ischemia and in a rabbit model of critical ischemic ear, each treated with sham or PEP. Rabbit tissues were next examined by whole transcriptome analysis to assess PEP-induced proangiogenic signaling. Immunohistochemical staining with smooth muscle actin and von Willebrand factor probed de novo blood vessel formation. Results: PEP was characterized by size (mean: 128.6 +/-1 nm) and VEGFR expression. VEGFR knock-down diminished endothelial cell angiogenic activity in vitro, rescued with PEP (5.3x1010+/-109 vesicles/ml) was sufficient enhance total and phosphor-VEGFR expression, along with amplification of downstream VEGFR targets (MAPK, AKT, CXCL8, NOTCH4, MMP9) and enhanced tube formation. In both hind-limb (n=5) and critical ear (n=4) ischemia models, local delivery of PEP to ischemic tissue resulted in restoration of blood perfusion and prioritized proangiogenic signaling in tissue transcriptome pathway analysis, further confirmed by immunohistochemistry. Conclusions: Taken together, our study establishes a new regenerative paradigm documenting exosome-based delivery of VEGFR as a key driver for angiogenesis. This PEP-based platform broadens potential options available for treatment of peripheral vascular disease and may have therapeutic implications in restoration of microvasculature.