Human lungs experience dynamic oxygen tension during development. Here, we show that hypoxia directly regulates human lung epithelial cell identity using tissue-derived organoids. Fetal multipotent lung epithelial progenitors remain undifferentiated in a self-renewing culture condition under normoxia but spontaneously differentiate toward multiple airway cell types and inhibit alveolar differentiation under hypoxia. Using chemical and genetic tools, we demonstrate that hypoxia-induced airway differentiation depends on hypoxia-inducible factor (HIF) activity, with HIF1α and HIF2α differentially regulating progenitor fate decisions. KLF4 and KLF5 are direct HIF targets that promote basal and secretory cell fates. Moreover, hypoxia is sufficient to convert alveolar type 2 cells derived from both human fetal and adult lungs to airway cells, including aberrant basal-like cells that exist in human fibrotic lungs. These findings reveal roles for hypoxia and HIF activity in the developing human lung epithelium and have implications for aberrant cell fate changes in pathological lungs.
Keywords: HIFs; KLF4; KLF5; aberrant basal cells; airway differentiation; alveolar type 2 cells; human lung epithelial progenitors; hypoxia; hypoxia-inducible factors; organoids.
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