OBJECTIVE: To investigate the characteristic and phenotype of ectomesenchymal stem cells of human fetal facial processes and the procedure of spontaneous differentiation to smooth muscle cells. METHODS: The primary ectomesenchymal cells of E 50 human fetal facial processes were isolated by 2.5 g/L trypsin and cultured with DMEM/F 12 with 10(-6) U/L leukemia inhibitor factor(LIF). The morphology and growth rate were observed by inverted microscop. After being withdrawn LIF, the characteristic of cells were identified by immunohistochemistry and RT-PCR. Ultrastructure was observed by transmission electron microscope. RESULTS: The cultured cells displayed monolayer growth and were fibroblast-like with 2-4 processes. The cells were stainely positived for anti-human natural killer cell marker-1, Vimentin, S-100, neuron specific enolase, myoglobin and VIII factor, but negatively for glial fibrillary acidic protein, neural fiblament, alpha-SMA and cytokeratin in immunohistochemistry. Two days after being withdrawn the LIF, cells expressed alpha-SMA in protein and mRNA levels. The cells were rich in muscular filament-like structure and dense bodies under transmission electron microscope. CONCLUSION: Cultured cells are undifferentiated ectomesenchymal stem cells. The cells have the potential for differentiating spontaneously to smooth muscle cell.
Objective To investigate the possibility of theadipose tissue-derived stromal cells(ADSCs) to differentiate into the neuron-like cells and to explore a new cell source for the transplantation related to the central nervous system. Methods Adipose was digested by collagenase, cultured in the fetal bovine serum containing a medium. Trypse was used to digest the cells and the cell passage was performed. The 3rd to the 9th passage ADSCs were used to make an induction. Isobutylmethylxanthine, indomethacin, insulin, and dexamethasone were used to induce the ADSCs to differentiate into the neuron-like cells and adipocytes. Sudan black B and immunocytochemistry were used to identify the cells. Results A population of the ADSCs could be isolated from the adult human adipose tissue, they were processed to obtain a fibroblast-like population of the cells and could be maintained in vitro for an extendedperiod with the stable population doubling, and they were expanded as the undifferentiated cells in culture for more than 20 passages, which indicated their proliferative capacity. They expressed vimentin and nestin, and characteristics of the neuron precursor stem cells at an early stage of differentiation. And the majority of the ADSCs also expressed the neuron-specific enolase and βⅢ-tubulin, characteristics of the neurons. Isobutyl-methyxanthine, indomethacin, insulin, and dexamethasone induced 40%-50% of ADSCs to differentiate into adipocytes and 0.1%0.2% of ADSCs into neuron-like cells. The neuron-like cells had a complicated morphology of the neurons, and they exhibited a neuron phenotype, expressed nestin, vimentin, neuron-specific enolase and βⅢ-tubulin, but some neuron-like cells also expressed thesmooth muscle actin (SMA), and the characteristics of the smooth muscle cells; however, the neurons from the central nervous system were never reported to express this kind of protein. Therefore, the neuron-like cells from the ADSCs could be regarded as functional neurons. Conclusion Ourresults support the hypothesis that the adult adipose tissue contains the stem cells capable of differentiating into the neuron-like cells, and they can overcome their mesenchymal commitment, which represents an alternative autologous stemcell source for transplantation related to the central nervous system.
Objective To investigate the myogenic differentiation of mesenchymal stem cells (MSCs) after being transplanted into the local muscle tissues. Methods The serious muscleinjured model was established by the way of radiation injury, incising, and freezing injury in 36 mouses. Purified MSCs derived from bone marrow of male mouse and MSCs induced by5-azacytidine(5-Aza-CR) were transplanted into the local of normal muscle tissues and injured muscle tissues of femal mouse. The quantity of MSCs and the myogenic differentiation of implanted MSCs were detected by the method of double labeling, which included fluorescence in situ DNA hybridization (FISH) and immuno-histochemistry on the 1st, 3rd, 6th, 9th, 12th, and 15th day after transplantation. Results The quantity of implanted MSCs decreased as timepassed. MSCs’ differentiation into myoblasts and positive expression of desmin were observed on the 15th day in purified MSCs group and on the 6th day in induced MSCs groups. Conclusion MSCs could differentiate into myoblasts after being implanted into the local of muscle tissues. The differentiationoccurs earlier in the induced MSCs group than that in purified MSCs group.
Objective To investigate the feasibility of differentiation of the marrow mesenchymal stem cells (MSCs) into the cells of the skin appendages andthe mechanism of their involvement in the wound healing. Methods The bone marrow was collected from Wistar rats by the flushing of the femurs, MSCs were isolated and purified by the density gradient centrifugation. Then, the MSCs were amplified and labelled with 5-bromo-2′-deoxyuridine (BrdU). The full-thickness skin wounds with an area of 1 cm×1 cm were made on the midback of the homogeneous male Wistar rats. At the same time, 1×106/ml BrdU-labelled MSCs were infused from thepenile vein. The specimens were harvested from the wound tissues on the 3rd dayand the 7th day after operation and were immunohistochemically stained by either BrdU or BrdU and pan-keratin. Results The BrdU positive cells appeared in thehypodermia, the sebaceous glands, and the hair follicles of the wounds, as wellas the medullary canal of the femurs. The double-staining showed the BrdU positive cells in the sebaceous glands and the hair follicles of the wounds expressedpan-keratin simultaneously. Conclusion During the course of the wound healing, MSCs are involved in the wound repair and can differentiate into the cells ofthe skin appendages under the microenvironment of the wound.
Objective To compare the myogenic differentiation abil ity in vitro of rabbit adipose-derived stem cells (ADCSs) from different sites so as to provide ideal seed cells for repair and reconstruction of urinary tract. Methods Adipose tissues were obtained from the nape of the neck, post peritoneum, and vicinity of epididymis of a 4-month-old male New Zealand rabbit and ADSCs were harvested through collagenase digestion. ADSCs were purified by differential attachment method. The protein marker CD44 of rabbit ADSCs was used to identify the stem cells by immunocytochemistry, then the5th generation of ADSCs were induced to differentiate into adipogenic, osteogenic, and myogenic cells. Multi- differentiation was confirmed by Oil red O staining, von Kossa staining, and RT-PCR. Myogenic differentiation abil ities of ADSCs from 3 different sites were compared between the control group (L-DMEM medium containing 10%FBS) and the experimental group (myogenic medium) by RT-PCR method. Results ADSCs could be easily isolated from adipose tissues of the nape of the neck, post peritoneum, and vicinity of epididymis. ADSCs displayed a typical cobblestone morphology. Brown particles could be seen in ADSCs by CD44 immunocytochemistry staining. Oil red O staining showed red fat drops in ADSCs after 14 days of adipogenic culture. Black matrix could be seen in ADSCs by von Kossa staining after 28 days of osteogenic culture. RT-PCR detection showed moderate α-actin expression in the control group and b α-actin expression in the experimental group after 42 days of myogenic culture. The growth rate of α-actin from the adipose tissue of post peritoneum (28.622% ± 4.879%) was significantly lower (P lt; 0.05) than those from the adipose tissues of the nape of the neck (35.471% ± 3.434%) and vicinity of epididymis (38.446% ± 4.852%). Conclusion The ADSCs from different sites show different myogenic differentiation abil ities in vitro. ADSCs from the adipose tissues of the nape of the neck and vicinity of epididymis can be used as ideal seed cells for tissue engineering of lower urinary tract.
Objective To study the effect of core-binding factor α1(Cbfa1)on the mesenchymal stem cells(MSCs) osteoblastic differentiation.Methods The MSCs were isolated from Japan white rabbits and cultured in vitro. The 3rd generation MSCs were infected with Cbfa1 recombinant adenovirus. The expression of Cbfa1 was detected by immunofluorescence after being infected for 3 days and the proliferation was estimated by MTT method from the 1st day to the 7th day. Then the MSCs were divided into four groups: the commonly cultured group, the simply induced group, the control adenovirus treatment group, and the Cbfa1 adenovirus treatment group. The expressions of mRNA for a various of osteoblast gene markers such as alkaline phosphatase, osteocalcin, osteopontin and type I collagen were analyzed based on reverse transcriptase polymerase chain reaction (RT-PCR). The change of adipose and myoblastic differentiation gene marker PPARγ2 and MyoD expression were detected by RT-PCR respectively.Results Positive staining of Cbfa1 was found in the MSCs infected with Cbfa1 adenovirus, and there was no significant difference in cell proliferation among the experimental groups(Pgt;0.05). The RT-PCR indicated that all the osteoblast gene markers except type I collagen were up-regulated in the Cbfa1 adenovirus treatment group. In contrast, the expressions of PPARγ2 and MyoD were restrained. Conclusion Cbfa1 can directly promote the differentiation of MSCs into osteoblasts.
Objective To investigate the neural markers’ expression in the differentiation of marrow stromal stem cells(MSCs) into neural cells. Methods Rats MSCs were expanded as undifferentiated cells in vitro for 5 to7 generations and cultured in a modified neuronal medium(MNM) after 24 hours of all-trans retinoidacid(ATRA) pretreatment. Immunocytochemistry was used to detect the expression of nestin、neuron-specific nuclear protein(NeuN)、microtubule-associated protein2 (MAP-2) and glial fibrillary acidic protein(GFAP) at different timepoints. Results After ATRA and MNM treatment, MSCs progressively assumed neuronal morphological characteristics. Nestin occurred first after 24 hours of ATRA treatment; then NeuN expressed after 2 hours of MNM treatment; the last one was MAP-2 and it was detected after 9 hours of MNM treatment. Other markers continuously expressed except that the expression of nestin peaked after 18 hours of MNM induction and remarkably decreased after 36 hours. Conclusion ATRA and MNM could promote the differentiation of MSCs into neural cells and the expression of neural-specific markers was consistent with current knowledge regarding the timepoints of markers expression in the neuronal development which provides a good model in vitro for neuronal development research.
ObjectiveTo review the research advance of differentiation of induced pluripotent stem cells (iPS) into Schwann cells in vitro in recent years. MethodsRelated literatures on differentiation of iPS into Schwann cells in vitro at present were consulted, the induction methods of iPS differentiating into Schwann cells in vitro were summarized, and the differentiated cells were identified and detected. ResultsThe research results indicate that iPS can differentiate into Schwann cells. So far, the iPS have to differentiate into neural crest cells or neural crest stem cells firstly, and then differentiate into Schwann cells. S100-β and glial fibrillary acidic protein (GFAP) are recognized as the marker of Schwann cells. The evidence of generating Schwann cells was that the neural crest cells or neural crest stem cells were labelled by p75+, HNK1+, or nestin+ before differentiation, and by S100-β+ and GFAP+ after induction. ConclusionDespite the increasing reported studies of Schwann cells from iPS, there have been few successful induction methods, so this field of cytology needs further study.
Objective To explore the method that can inducethe mesenchymal stem cells (MSCs) to differentiate into the neuronlike cells in vitro.Methods The neuron-like cells were isolated froman SD rat (age, 3 months; weight, 200 g). They underwent a primary culture; theinduced liquid supernatant was collected, and was identified by the cell immunohistochemistry. The C3H1OT1/2 cells were cultured, as an MSCs model, and they were induced into differentiation by β-mercaptoethanol (Group A) and by the liquid supernatant of the neuron-like primary cells (Group B), respectively. The cells were cultured without any induction were used as a control (Group C). Immunohistochemistrywas used to identify the type of the cells. Results The result of the immunochemistry showed that the cells undergoing the primary culture expressed the neurofilament protein (NF) and the neuronspecific enolase (NSE), and they were neuron-like cells. β-mercaptoethanol could induce the C3H1OT1/2 cells toexpress NF and NSE at 2 h, and the expression intensity increased at 5 h. The liquid supernatant of the primarily-cultured neuron-like cells could induce theC3H1OT1/2 cells to express NF and NSE at 1 d, but the expression intensity induced by the liquid supernatant was weaker than that induced by β-mercaptoethanol. The positivity rate and the intensity expression of NSE were higher than those of NF. Conclusion MSCs can differentiate into the neuron-like cells by β-mercaptoethanol and the microenvironment humoral factor, which can pave the way for a further study of the differentiation of MSCs and the effectof the differentiation on the brain trauma repair.
To explore the expression of Wnt-1 during the process of inducing neural stem cells (NSCs) into neurons by using all-trans-retinoic acid (ATRA) in vitro and the effect of Wnt-1 on NSCs differentiation. Methods NSCs isolated from cerebral cortex of SD rat embryo (12-16 days’ gestation) were cultured. The concentration of cells at passage 3 were adjusted to 1 × 106 cells /mL and treated with ATRA at 0.5, 1.0, 5.0 and 10.0 μmol/L, respectively. Differentiation ratio of NSCsinto neurons in each group was detected by double-labelling immunofluorescence technique and flow cytometry, and 1.0 μmol/ L was selected as the best concentration for ATRA to promote NSCs differentiation. In experimental group, NSCs at passage 3 were cultured with ATRA at 1.0 μmol/L in vitro, and expression of Wnt-1 was detected by immunocytochemistry staining, realtime flurescent quantitive PCR and Western blot at 3, 5, 7 and 9 days after culture, respectively. The cells at passage 3 receiving no ATRA served as control group. Results Immunocytochemistry staining: in the control group, there was l ittle Wnt-1 protein expression; in the experimental group, peak expression of Wnt-1 and numerous positive cells occurred at 3 days after culture, the positive expression of Wnt-1 was still evident at 5 days after culture, and there was significant difference between two groups in integrated absorbance (IA) value at 3 and 5 days after culture(P lt; 0.05), obvious decrease of positive expression of Wnt-1 was evident, and no significant difference was evident between two groups in IA value at 7 and 9 days (P gt; 0.05). Real-time fluorescence quantitative PCR: the relative expression of Wnt-1 mRNA in the control group was 0.021 7 ± 0.072 1; the relative expression of Wnt-1 mRNA in the experimental group at 3, 5, 7 and 9 days was 0.512 2 ± 0.280 0, 0.216 4 ± 0.887 0, 0.038 5 ± 0.299 4 and 0.035 5 ± 0.309 5, respectively, indicating the value decreased over time, and there were significant difference between two groups at 3 and 5 days (P lt; 0.05), and no significant difference at 7 and 9 days (P gt; 0.05) . Western blot detection: specific and visible staining band was noted; in the control group, Wnt-1 protein expression was 0.005 1 ± 0.558 3; in the experimental group, Wnt-1 protein expression at 3, 5, 7 and 9 days was 0.451 7 ± 0.071 3, 0.311 7 ± 0.080 5, 0.007 3 ± 0.052 7 and 0.004 7 ± 0.931 4, respectively, suggesting the value decreased over time; there were significant differences between two groups at 3 and 5 days (P lt; 0.05), and no significant differences at 7 and 9 days (P gt; 0.05). Conclusion With the induction of ATRA at 1.0 μmol/L, Wnt-1 and NSCs differentiation in early stage are positively correlated. Its possible mechanism may rely on the activation of such signals as classic Wnt-1 signal pathway, indicating Wnt-1 relates to the differentation of NSCs into neurons.