Physiological Modeling of the Vascularized Human Lung Organoid.

Studies using human lung organoids (hLO) have focused on differentiation of lung epithelial subtypes into distal alveolar unit. A major question has been whether introducing endothelial cells (EC) and resultant vascularization alter development of hLO. We describe herein a method for vessel infiltration of hLO in which we determined differences of these hLOs with standard avascular hLOs. hLO are generated by combining hiPSC-derived lung progenitor cells (LP) with EC at different LP:EC ratios. This results in vascularization of hLO and enables comparisons with hLO generated without EC. We observe red blood-filled vessels in hLOs generated post-implantation into the kidney capsule of NOD/SCID mice. Both human and mouse EC conjoin in the capsule to form chimeric vessels in hLOs. Vessel-infiltrating hLOs show robust generation of alveolar type II epithelial cells (ATII) and alveolar type I cells (ATI), although there was no difference in the observed 1:1 ATII/ATI cell ratio. Electron microscopy revealed better-developed surfactant production apparatus in ATII of vascularized hLOs compared to avascular hLOs. We observed prominent primitive airway sacs with alveolar epithelial cells lining lumen in vascularized vs. avascular hLOs. The vessel-infiltrating hLOs also mounted a robust inflammatory response characterized by mouse PMN influx after challenging host mice with lipopolysaccharide. Thus, interaction of EC with LP generated vascularized hLOs and drive ATII and ATI differentiation and hLOs also mount a robust inflammatory response upon LPS challenge of hLO-transplanted recipient mice. Our results show usefulness of generating hLOs in studying human lung development and mechanisms underlying inflammatory lung injury.