Holtz, A. M.; Vorpahl, M.; Ahmed, M. J.; Austin, E. D.; Bawa, P. S.; Villacorta-Martin, C.; Yoder, M. C.; Kotton, D. N.

Advances in tissue biology have revealed remarkable transcriptomic heterogeneity of endothelial cells between and within organ systems. This necessitates more precise models of organ-specific endothelium to understand the pathogenesis of genetic vascular disorders, such as pulmonary hypertension (PH), where gene-disease associations have implicated endothelial cell dysfunction as a key driver of disease pathogenesis. Towards this end, human induced pluripotent stem cells (hiPSCs) hold immense promise for PH disease modeling where hiPSCs are generated from an affected individual and undergo gene correction to generate syngeneic controls that can be differentiated to endothelial cells (hiEndos), providing a limitless source of material for downstream studies; however, the ability to generate lung-specific hiEndos to model pulmonary vascular disease has been limited. To overcome this challenge, we developed a chimeric human-mouse lung vascular model wherein hiEndos are first patterned via BMP9-induced signaling towards a lung-like molecular phenotype in vitro and are then intravenously transplanted into the mouse lung vasculature in vivo to generate orthotopic lung-specific endothelium for downstream studies. Transplanted pre-patterned hiEndos form functional connections to the native mouse lung vasculature and upregulate differentiated lung-specific molecular cell subtype profiles that include capillary- and arterial-like cell populations. To apply this approach for disease modeling, we generated new hiPSC lines by reprogramming fibroblasts from individuals of the 2001 landmark cohort of BMPR2 gene variant-associated PH and developed a novel in vivo competitive lung endothelial reconstitution assay to quantify functional and molecular differences between human BMPR2-variant vs syngeneic gene-corrected/edited hiEndos. Our approach revealed novel insights into PH disease pathogenesis, not previously evident with prior models, including BMPR2 variant-induced in vivo defects in human lung capillary gene expression, elevated lncRNA H19 expression, increased AHR signaling, and diminished functional capacity to repopulate the pulmonary vascular endothelium.