Abstract
RATIONALE: Direct reprogramming of fibroblasts into endothelial cells (rECs) using ETV2 shows promise for vascular regeneration. However, current approaches using integrating viral vectors pose clinical translation barriers, and poor long-term cell survival limits therapeutic efficacy. OBJECTIVE: To develop a clinically compatible method for generating rECs using non-integrating adenoviral ETV2 (Ad-ETV2) and enhance their engraftment and therapeutic efficacy through peptide amphiphile (PA) nanomatrix encapsulation. METHODS AND RESULTS: Human dermal fibroblasts were reprogrammed using Ad-ETV2 and characterized by flow cytometry, RNA sequencing, and functional assays. Therapeutic efficacy was evaluated in murine hindlimb ischemia with or without PA-RGDS encapsulation over 12 months. Ad-ETV2 induced robust endothelial gene expression (CDH5, KDR, PECAM1) within 6 days, with 40-50% reprogramming efficiency. KDR+ Ad-rECs demonstrated functional endothelial properties including Ac-LDL uptake, tube formation, and exceptional proangiogenic factor secretion (200-fold higher HGF than HUVECs). RNA sequencing revealed rapid transcriptional reprogramming with fibroblast gene suppression and endothelial/angiogenic gene activation. In hindlimb ischemia, Ad-rECs significantly enhanced blood flow recovery and capillary density versus controls. Long-term analysis revealed sustained vascular contribution through three mechanisms: direct incorporation, perivascular support, and vessel guidance, persisting throughout 12 months-the longest reported follow-up for reprogrammed cells. PA-RGDS encapsulation markedly improved cell retention; while 75% of cells were lost by 3 months, retention stabilized thereafter with minimal additional loss through 12 months. CONCLUSIONS: Adenoviral ETV2 delivery enables efficient generation of clinically compatible rECs without genomic integration. These cells demonstrate potent and sustained therapeutic efficacy through multiple vascular regeneration mechanisms. PA-RGDS encapsulation significantly enhances long-term engraftment, establishing this combined approach as a promising platform for treating ischemic cardiovascular diseases.