Single cell decomposition of multicellular aging programs associated with impaired lung regeneration

  1. Janine Gote-Schniering
  2. M. Camila Melo-Narváez
  3. Gowtham Boosarpu
  4. David Lauer
  5. Sai Rama Sridatta Prakki
  6. Huijuan Wang
  7. Matthias Brunner
  8. Simrah Khan
  9. Meshal Ansari
  10. Michael Ammeter
  11. Eshita Jain
  12. Nikola Puda
  13. Konstantin Wiedemann
  14. Carina Steinchen
  15. Sara Ashgapour
  16. Ariane Eceiza
  17. Michael Dudek
  18. Christoph H. Mayr
  19. Yuexin Chen
  20. Ilias Angelidis
  21. Önder Yildirim
  22. Percy Knolle
  23. Gerald Burgstaller
  24. Melanie Königshoff
  25. Safwen Kadri
  26. Martin Mück-Häusl
  27. Fabian J. Theis
  28. Mareike Lehmann
  29. Herbert B. Schiller
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Abstract

Aging impairs the regenerative capacity of mammalian organs and is a major risk factor for organ fibrosis. Mechanisms underlying persistent fibrosis after lung injury in old individuals remain unclear. We used longitudinal single-cell RNA-seq after lung injury and dissected aging effects computationally and experimentally at baseline and during repair. In old mice, sustained fibroblast activation in the resolution phase of fibrosis was associated with prolonged epithelial senescence and persistent epithelial-mesenchymal crosstalk. Single-cell interpretable tensor decomposition analysis revealed that aging most strongly affected T/B-lymphocytes and macrophages. Notably, we identified a Granzyme K-high CD8+ T cell state that was unique to aged mice, co-localized with epithelial progenitors, and its co-culture or Gzmk treatments in lung organoids impaired progenitor function by inducing stem cell senescence. In summary, our study highlights the effects of immune aging on epithelial progenitor function and provides a time-resolved high resolution map of lung regeneration in the context of aging.

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