Vascular endothelial cells derived from transgene-free pig induced pluripotent stem cells for vascular tissue engineering.

Induced pluripotent stem cells (iPSCs) hold great promise for the treatment of cardiovascular diseases through cell-based therapies, but these therapies require extensive preclinical testing that is best done in species-in-species experiments. Pigs are a good large animal model for these tests due to the similarity of their cardiovascular system to humans. However, a lack of adequate pig iPSCs (piPSCs) that are analogous to human iPSCs has greatly limited the potential usefulness of this model system. Herein, transgene-free piPSCs with true pluripotency were generated by using reprogramming factors in an optimized pig pluripotency medium. Using an effective differentiation protocol, piPSCs were used to derive endothelial cells (ECs) which displayed EC markers and functionality comparable to native pig ECs. Further, piPSC-ECs demonstrated suitability for vascular tissue engineering, producing a tissue engineered vascular conduit (TEVC) that displayed the upregulation of flow responding markers. In an in vivo functional study, these piPSC-EC-TEVCs maintained the expression of endothelial markers and prevented thrombosis as interposition inferior vena cava grafts in immunodeficient rats. The piPSCs described in this study open up the possibility of unique preclinical species-in-species large animal modeling for the furtherance of modeling of cell-based cardiovascular tissue engineering therapies. STATEMENT OF SIGNIFICANCE: While there has been significant progress in the development of cellularized cardiovascular tissue engineered therapeutics using stem cells, few of them have moved into clinical trials. This is due to the lack of a robust preclinical large animal model to address the high safety and efficacy standards for transplanted therapeutics. In this study, pig stem cells that are analagous to human's were created to address this bottleneck. They demonstrated the ability to differentiate into functional endothelial cells and were able to create a tissue engineered therapeutic that is analogous to a human therapy. With these cells, future experiments testing the safety and efficacy of tissue engineered constructs are possible, bringing these crucial therapeutics closer to the patients that need them.