Stem/progenitor cells, because of their self-renewal and multiple cell type differentiation abilities, have good potential in regenerative medicine. We previously reported a lung cell population that expressed the stem cell marker SSEA-1 was abundant in neonatal but scarce in adult mice. The current study further characterized the stem/progenitor property of neonatal and adult mouse lung-derived SSEA-1+ cells. The results showed that the neonatal pulmonary SSEA-1+ cells exhibited enhanced ability in organoid generation compared to those of adult cells, suggesting the stem/progenitor activity is increased in the neonatal stage. The neonatal pulmonary SSEA-1+ cells generated airway-like, bronchoalveolar-like, and alveolar-like organoids that suggested the multilineage cell differentiation ability. In addition, fibroblast growth factor 7 facilitated the activity of neonatal pulmonary SSEA-1+ cells in organoid generation with increased alveolar cell differentiation. Furthermore, neonatal pulmonary SSEA-1+ cells could colonize and develop in the decellularized and injured lungs. These results demonstrated the stem/progenitor property of lung-derived neonatal-stage SSEA-1+ cells that suggested the potential for regenerative medicine. In addition, studies have revealed that the type 2 immunity is transiently increased in neonatal lungs. However, little is known about the effect of type 2 immunity on postnatal lung development. For this purpose, the neonatal lung-derived SSEA-1+ cells were cultured with IL-4/IL-13 during the organoid development. Results showed that short-term exposed the cells with IL-4/IL-13 could enhance the stem/progenitor activity for the organoid generation with normal epithelium development. However, extended IL-4/IL-13 stimulation resulted in decreased ciliated cell differentiation and increased mucus accumulation, suggesting the impairment of epithelial homeostasis. The IL-4 and IL-13 were signaled through STAT6 to mediate the cell proliferation and cell differentiation of the neonatal pulmonary SSEA-1+ cells. The results suggested that the transiently higher type 2 immunity in postnatal lungs plays a role to facilitate neonatal lung growth, but the excessive inflammation leads to abnormal epithelium development. Collectively, we observed the cell population and the stem/progenitor activity of pulmonary SSEA-1+ cells are enriched in the neonatal stages. Moreover, the IL-4/IL-13 further enhanced the stem/progenitor activity of neonatal pulmonary SSEA-1+ cells. Our results suggested the interactions of the pulmonary stem/progenitor cells with their immune environment to mediate neonatal lung growth and development.