Epithelial cells/progenitor cells in developing human lower respiratory tract: Characterization and transplantation to rat model of pulmonary injury

Introduction: For cell-based therapies of lung injury, several cell sources have been extensively studied. However, the potential of human fetal respiratory cells has not been systematically explored for this purpose. Here, we hypothesize that these cells could be one of the top sources and hence, w...

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Published in:Bioimpacts 2023-11, Vol.13 (6), p.505-520
Main Authors: Ganji, Fatemeh, Ebrahimi, Marzieh, Shirani, Ali, Golmohammadi, Mahtab, Gholipourmalekabadi, Mazaher, Kashanian, Maryam, Koolaeinezhad, Kiana, Davari, Hamid Reza, Mousavi, Seyed Ali Javad, Aghayan, Hamid Reza, Arjmand, Babak, Heshmat, Ramin, Karkuki Osguei, Nushin, Samadikuchaksaraei, Ali
Format: Article
Language:English
Subjects:
Animal models
Antibodies
bronchi
Coronary artery disease
Electron microscopy
Epithelial cells
fetal stem cells
fetus
Fetuses
Flow cytometry
Gene expression
Heart diseases
Keratin
lung
Lung transplantation
Lungs
Microscopy
Organoids
Progenitor cells
Respiratory tract
Stem cells
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Summary:Introduction: For cell-based therapies of lung injury, several cell sources have been extensively studied. However, the potential of human fetal respiratory cells has not been systematically explored for this purpose. Here, we hypothesize that these cells could be one of the top sources and hence, we extensively updated the definition of their phenotype. Methods: Human fetal lower respiratory tissues from pseudoglandular and canalicular stages and their isolated epithelial cells were evaluated by immunostaining, electron microscopy, flow cytometry, organoid assay, and gene expression studies. The regenerative potential of the isolated cells has been evaluated in a rat model of bleomycin-induced pulmonary injury by tracheal instillation on days 0 and 14 after injury and harvest of the lungs on day 28. Results: We determined the relative and temporal, and spatial pattern of expression of markers of basal (KRT5, KRT14, TRP63), non-basal (AQP3 and pro-SFTPC), and early progenitor (NKX2.1, SOX2, SOX9) cells. Also, we showed the potential of respiratory-derived cells to contribute to in vitro formation of alveolar and airway-like structures in organoids. Cell therapy decreased fibrosis formation in rat lungs and improved the alveolar structures. It also upregulated the expression of IL-10 (up to 17.22 folds) and surfactant protein C (up to 2.71 folds) and downregulated the expression of TGF-β (up to 5.89 folds) and AQP5 (up to 3.28 folds). Conclusion: We provide substantial evidence that human fetal respiratory tract cells can improve the regenerative process after lung injury. Also, our extensive characterization provides an updated phenotypic profile of these cells.
ISSN:2228-5660
2228-5652
2228-5660
DOI:10.34172/bi.2023.26456