Objective To study the effects of the human keratinocyte growth factor 2 (hKGF-2) on the survival and differentiation of human neural stem cells (hNSCs). Methods The hNSCs at 17 passages preserved in liquid nitrogen were resuscitated and cultured for 7 days with normal methods to form neural spheres. The specific Nestin antigen and differentiated cells antigen were identified using immunohistochemistry technology. Some concentrated hNSCs were incubated in 12-well culture plate with 1 mL basic medium [(DMEM/F12 + N2 (1 ∶ 100) + epidermal growth factor (EGF) (20 ng/mL)] and divided into 7 groups, 6 wells each group. hKGF-2 (0, 10, 30, 60, 90, and 120 ng/mL) and bFGF (10 ng/mL) were added in groups A (control), B, C, D, E, F, and G, respectively. The neurospheres and the cell number were recorded for analyzing growth and multiplication of neural spheres. Some concentrated hNSCs were incubated in 6-well culture plate (cover glass coated with polylysine) with 3 mL DMEM/F12 medium and divided into 4 groups, 6 wells each group. N2 (1 ∶ 100), N2 (1 ∶ 100) + hKGF-2 (90 ng/mL), FBS (1 ∶ 20), and FBS (1 ∶ 20) + hKGF-2 (90 ng/mL) were added in groups A1, B1, C1, and D1, respectively. Then, the growth and multiplication of neural spheres were observed during culture; the separated neural spheres was identified and analyzed with indirect immunofluorescence and flow cytometry. Results Reanimated hNSCs could form neural spheres containing a lot of Nestin antigen; differentiated cells by induction expressed the specific antigens of neurofilament 200 (NF- 200) and glial fibrillary acidic protein (GFAP). At 7 days after culture, enlarged neural spheres were observed in each group. The neurospheres and the cell number of hNSCs increased with increased concentration of hKGF-2, showing a gradually increasing tendency; they were significantly higher in groups E, F, and G than that in groups A, B, C, and D (P lt; 0.05); significant differences were found among groups B, C, and D (P lt; 0.05), but no significant difference between groups A and B, and among groups E, F, and G (P gt; 0.05). After induction in vitro, the cell growth showed a progressive increase, significant difference was found among groups (P lt; 0.05); the percentage of NF-200 positive cells in group B1 was significantly higher than that in the other 3 groups (P lt; 0.05); the percentage of GFAP positive cells in group B1 was significantly lower than that in the other 3 groups (P lt; 0.05), but no significant difference among groups A1, C1, and D1 (P gt; 0.05). At 14 days after culture, cell growth reached the peak, which were mainly astero-cells. Conclusion The hNSCs are pure after incubated to 17 passages in vitro. hKGF-2 can promote the clone and the growth of differentiated cells, and increase the proportion of neuron.
Age is the main cause of neurodegenerative changes in the central nervous system (CNS), and the loss of neurons would increase with the migration of the disease. The current treatment is also mainly used to relieve symptoms, while the function of CNS is very difficult to recover. The emergence of endogenous stem cells has brought new hope for the treatment of CNS diseases. However, this nerve regeneration is only in some specific areas, and the recovery of neural function remains unknown. More and more experts in the field of neuroscience have carried out various in vivo or in vitro experiments, in order to increase nerve regeneration and nerve function recovery through mechanism research, in the expectation that the results would be applied to the treatment of CNS diseases. This article reviews the recent progress of endogenous neural stem cells in degenerative diseases of CNS.
Spinal cord injury (SCI), especially the complete SCI, usually results in complete paralysis below the level of the injury and seriously affects the patient’s quality of life. SCI repair is still a worldwide medical problem. In the last twenty years, Professor DAI Jianwu and his team pioneered complete SCI model by removing spinal tissue with varied lengths in rodents, canine, and non-human primates to verify therapeutic effect of different repair strategies. Moreover, they also started the first clinical study of functional collagen scaffold on patients with acute complete SCI on January 16th, 2015. This review mainly focusses on the possible mechanisms responsible for complete SCI. In common, recovery of some sensory and motor functions post complete SCI include the following three contributing reasons. ① Regeneration of long ascending and descending axons throughout the lesion site to re-connect the original targets; ② New neural circuits formed in the lesion site by newly generated neurons post injury, which effectively re-connect the transected stumps; ③ The combined effect of ① and ②. The numerous studies have confirmed that neural circuits rebuilt across the injury site by newborn neurons might be the main mechanisms for functional recovery of animals from rodents to dogs. In many SCI model, especially the complete spinal cord transection model, many studies have convincingly demonstrated that the quantity and length of regenerated long descending axons, particularly like CST fibers, are too few to across the lesion site that is millimeters in length to realize motor functional recovery. Hence, it is more feasible in guiding neuronal relays formation by bio-scaffolds implantation than directing long motor axons regeneration in improving motor function of animals with complete spinal cord transection. However, some other issues such as promoting more neuronal relays formation, debugging wrong connections, and maintaining adequate neural circuits for functional recovery are urgent problems to be addressed.
Endogenous adult neural stem cells are closely related to the normal physiological functions of the brain and many neurodegenerative diseases. Neurons are affected by factors such as extracellular microenvironment and intracellular signaling. In recent years, some specific signaling pathways have been found that affect the occurrence of neural stem cells in adult neural networks, including proliferation, differentiation, maturation, migration, and integration with host functions. In this paper, we summarize the signals and their molecular mechanisms, including the related signaling pathways, neurotrophic factors, neurotransmitters, intracellular transcription factors and epigenetic regulation of neuronal differentiation from both the extracellular and intracellular aspects, providing basic theoretical support for the treatment of central nervous system diseases through neural stem cells approach.
Objective To observe the effects of co-transfection of Nogo extracellular peptide residues 1-40 (NEP1-40) and neurotrophin 3 (NT-3) genes with Schwann cell-derived exosomes (SCDEs) on the survival and differentiation of neural stem cells (NSCs), and lay the foundation for the in vivo experiments of SCDE and NSC co-transplantation. Methods The NEP1-40 and NT-3 genes were transfected into Schwann cells by lentiviral vector, and SCDEs were collected for identification. The NSCs that have been passaged for 3 times were selected and inoculated into the inoculation plate, and they were divided into conventional culture group, simple exosome culture group (adding empty vector plasmid to modify SCDE for culture) and two genes exosome culture group (adding two genes modified SCDE for culture). The activity of cells in each group was detected. The survival and differentiation of NSCs were evaluated by immunofluorescence detection of neuronal nuclei (NeuN), glial fibrillary acidic protein (GFAP) and galactosylceramidase (GALC) positive cells. Results After transfection of these two genes, the fluorescence intensity was higher and the cell state was better. The relative expression levels of messenger RNA and protein of NEP1-40 and NT-3 in the two gene groups were higher than those in the empty plasmid group (P<0.05). The relative expression levels of NEP1-40 and NT-3 proteins in SCDE of the two gene groups were higher than those of the empty vector group (P<0.05). There was no significant difference in the relative expression level of CD63 protein in SCDE between the two groups (P>0.05). In terms of cell activity, the cell activity of the two genes exosome culture group was the strongest, followed by the simple exosome culture group, and the conventional culture group was the weakest. The differences between any two groups were statistically significant (1.28±0.04 vs. 0.72±0.09 vs. 0.41±0.04, P<0.05). In terms of cell survival, NeuN-positive cells (5.23±0.22 vs. 2.36±0.09 vs. 1.00±0.01) and GALC-positive cells (2.29±0.06 vs. 1.75±0.02 vs. 1.00±0.04) of the two genes exosome culture group were the best, followed by the simple exosome culture group, and the conventional culture group were the weakest. The differences between any two groups were statistically significant (P<0.05). In terms of cell differentiation, NeuN-positive cells (0.44±0.02 vs. 0.29±0.01 vs. 0.16±0.01) and GALC-positive cells (0.38±0.07 vs. 0.23±0.02 vs. 0.12±0.01) of the two genes exosome culture group were the best, followed by the simple exosome culture group, and the conventional culture group were the weakest. The differences between any two groups were statistically significant (P<0.05). The differentiation of GFAP-positive cells in the conventional culture group was the best, followed by the simple exosome culture group, and the two genes exosome culture group was the worst (0.52±0.05 vs. 0.42±0.03 vs. 0.30±0.09). The differences between any two groups were statistically significant (P<0.05). Conclusion NEP1-40 and NT-3 genes can be successfully transfected into Schwann cells by lentiviral vector, which can effectively increase the content of related proteins in SCDE, and the exosomes can effectively promote the survival and differentiation of NSCs in vitro.