Background： mouse pulmonary stem / progenitor cells ( mPSC ) is a kind of cell has the ability for self-renewal and differentiation. Due to mPSC is able to generate new-born cells and repopulate tissue, so the growth and development of mPSC is key of the alveolgenesis. Thus, mPSCs have been considered as an attractive source of cell-based therapy. Recently, it’s been reported that alveolar stage occurred with a burst of TGF-β3 elevation. Therefore, TGF-β3 probably is the main regulator of driving mPSCs into alveolar type 1 cells. Aim： To study the mechanism of TGF-β signaling for the stemness and differentiation potential of mouse pulmonary stem / progenitor cells. Methods： In this thesis, we cultured mPSCs from neonatal lung, and further purified mPSCs through flow cytometer. We used TGF-β receptor inhibitors, LY364947 blocked the activation of smad3 signaling pathway by TGF-β. Then, we analyzed the area and population of mPSCs, cell morphologic of features, and cell expression marker to investigate the effects on mPSCs in the presence / absence of TGF-β signal. Result： We cultured mPSCs through sorting primary culture from neonatal ICR mice lung. The mPSCs underwent spontaneous differentiation. We found that progenitor cells marker ( sox2, nanog, oct-4 ) decreased, and alveolar type 1 cells markers (T1α, Caveolin-1 ) during the spontaneous differentiation. In addition, the cuboidal doom shape colony cells expanded and area per cell increase dramatically. We blocked TGF-β / smad3 signal by LY364947, and found that the cuboidal doom shape, area per cell and the feature of mPSCs maintained. Moreover, the LY364947 group cell number was much more compared to the control group, and the control group underwent spontaneous differentiation. Conclusion： Our results showed that LY364947 once blocking TGF-β / smad3 signaling pathway, the differentiation process was disturbed and the property of the mPSCs maintained. It indicated that TGF-β / smad3 signaling is quite important for mPSCs differentiation, and it could be a great target for regulated mPSCs in the future.