eLife (Sep 2022)

Contribution of Trp63CreERT2-labeled cells to alveolar regeneration is independent of tuft cells

  • Huachao Huang,
  • Yinshan Fang,
  • Ming Jiang,
  • Yihan Zhang,
  • Jana Biermann,
  • Johannes C Melms,
  • Jennifer A Danielsson,
  • Ying Yang,
  • Li Qiang,
  • Jia Liu,
  • Yiwu Zhou,
  • Manli Wang,
  • Zhihong Hu,
  • Timothy C Wang,
  • Anjali Saqi,
  • Jie Sun,
  • Ichiro Matsumoto,
  • Wellington V Cardoso,
  • Charles W Emala,
  • Jian Zhu,
  • Benjamin Izar,
  • Hongmei Mou,
  • Jianwen Que

DOI
https://doi.org/10.7554/eLife.78217
Journal volume & issue
Vol. 11

Abstract

Read online

Viral infection often causes severe damage to the lungs, leading to the appearance of ectopic basal cells (EBCs) and tuft cells in the lung parenchyma. Thus far, the roles of these ectopic epithelial cells in alveolar regeneration remain controversial. Here, we confirm that the ectopic tuft cells are originated from EBCs in mouse models and COVID-19 lungs. The differentiation of tuft cells from EBCs is promoted by Wnt inhibition while suppressed by Notch inhibition. Although progenitor functions have been suggested in other organs, pulmonary tuft cells don’t proliferate or give rise to other cell lineages. Consistent with previous reports, Trp63CreERT2 and KRT5-CreERT2-labeled ectopic EBCs do not exhibit alveolar regeneration potential. Intriguingly, when tamoxifen was administrated post-viral infection, Trp63CreERT2 but not KRT5-CreERT2 labels islands of alveolar epithelial cells that are negative for EBC biomarkers. Furthermore, germline deletion of Trpm5 significantly increases the contribution of Trp63CreERT2-labeled cells to the alveolar epithelium. Although Trpm5 is known to regulate tuft cell development, complete ablation of tuft cell production fails to improve alveolar regeneration in Pou2f3-/- mice, implying that Trpm5 promotes alveolar epithelial regeneration through a mechanism independent of tuft cells.

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