ObjectiveTo explore the expressions of nerve growth factor (NGF) and leukemia inhibitory factor (LIF) in both asthmatic mice and respiratory syncytial virus(RSV)-infected mice,explore if there is a same neurogenic mechanism between ashtma and RSV infection,in order to find a new treatment target for asthma. MethodsOne hundred healthy Balb/c inbred mice were randomly divided into a control group,a RSV group,an asthma group,an asthma with RSV group,and a dexamethasone group. The lung tissue pathology was observed by hematoxylin-eosin staining(HE). The quantitative analysis of NGF mRNA and LIF mRNA of lung tissue was detected by RT-PCR. The expression of NGF protein and LIF protein was detected by immunohistochemical method. ResultsUnder light mocroscope,there were alveolar septum widening,alveolar epithelium swelling,and interstitial edema in the RSV group. There were widen alveolar septum,narrowed bronchial lumen,thicken bronchial wall and a large number of inflammatory cells infiltration around the small blood vessels,alveolar and bronchioles both in the asthma group and the asthma with RSV group,with the latter being more serious. Compared with the RSV group,the inflammation was relieved significantly in the dexamethason group. There were mRNA and protein expressions of NGF and LIF in all groups, which were highest in the asthma with RSV group,then the RSV group and the asthma group,and lowest in the dexamethasone group. ConclusionsThe expressions of LIF and NGF in the lung of mice after RSV infection and futher increase when combined with asthma. Dexamethason can inhibit the expression of NGF and LIF to some extent.
ObjectiveTo study the effects of leukemia inhibitory factor (LIF) and basic fibroblast growth factor (bFGF) on the proliferation and differentiation of human bone marrow mesenchymal stem cells (hBMSCs). MethodshBMSCs at passage 4 were divided into 4 groups according to different culture conditions:cells were treated with complete medium (α-MEM containing 10%FBS, group A), with complete medium containing 10 ng/mL LIF (group B), with complete medium containing 10 ng/mL bFGF (group C), and with complete medium containing 10 ng/mL LIF and 10 ng/mL bFGF (group D). The growth curves of hBMSCs at passage 4 in different groups were assayed by cell counting kit 8; cellular morphologic changes were observed under inverted phase contrast microscope; the surface markers of hBMSCs at passage 8 including CD44, CD90, CD19, and CD34 were detected by flow cytometry. ResultsThe cell growth curves of each group were similar to the S-shape; the cell proliferation rates in 4 groups were in sequence of group D > group C > group B > group A. Obvious senescence and differentiation were observed very early in group A, cells in group B maintained good cellular morphology at the early stage, with slow proliferation and late senescence; a few cells in group C differentiated into nerve-like cells, with quick proliferation; and the cells in group D grew quickly and maintained cellular morphology of hBMSCs. The expressions of CD44 and CD90 in groups A and C at passage 8 cells were lower than those of groups B and D; the expressions of CD19 and CD34 were negative in 4 groups, exhibiting no obvious difference between groups. ConclusionLIF combined with bFGF can not only maintain multiple differentiation potential of hBMSCs, but also promote proliferation of hBMSCs.