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 isolate and characterize mesenchymal stem cells (MSCs) derived from bone marrow of Banna minipig inbred line (BMI). METHODS: BMI-MSCs was isolated from bone marrow by density gradient centrifugation and cultured in DMEM (containing 15% bovine serum) at 37 degrees C with humidified 5% CO2. These cultured stem cells were characterized in clonal growth, expression of specific markers and capability of differentiation. RESULTS: Mesenchymal stem cells were proliferative and could be expanded rapidly in vitro. Clonal growth of these cells can be observed when small amount of cells was inoculated. These cells were SH2, SH3, SH4, SB10 and SB21 positive. And it was proved that these cells possess osteo-differentiation ability, up-regulated alkaline phosphatase expression and calcium secretion after osteosupplement was added into the media for several days. CONCLUSION: Mesenchymal stem cells derived from bone marrow of BMI possess the general characters of stem cell.
Objective To explore the effect of age and gene therapyon the differentiation of marrow mesenchymal stem cells (MSCs) of the rats. Methods MSCs from the young (1-month-old), adult (9-month-old), and the aged(24monthold) rats were expanded in culture and infected with adenovirus mediated human bone morphogenetic protein 2 gene (Ad-BMP-2). The expression of BMP-2 and osteoblastic markers such as alkaline phosphatase(ALP), collagen Ⅰ(Col Ⅰ), bone sialoprotein(BSP) and osteopontin(OPN) were assayed during the process of differentiation. Their abilities to induce ectopic bone formation in nude mice were also tested. Results There was no significant difference in the expression of BMP-2 among the 3 groups. ALP activity assay and semi-quantitative reverse transcription polymerase chain reaction(RT-PCR) demonstrated that there were no significant differences in the expression of osteoblastic markers ALP, Col-Ⅰ, OPN and BSP amongthe 3 groups. Histomorphometric analysis indicated that there were no significant differences in the volume of the newly formed ectopic bones in nude mice amongthe 3 groups. Conclusion MSCs obtained from the aged ratscan restore their osteogenic activity following human BMP-2 gene transduction, therefore provides an alternative to treating the aged bone disease.
Objective To observe effects of the core binding factor α1 (Cbfα1) in its promoting differentiation of the rabbit marrow mesenchym al stem cells (MSCs) into osteoblasts. Methods The rabbit marrow MSCs were isolated and cult ured in vitro and were divided into 3 groups. In the control group, the marr ow MSCs were cultured by DMEM; in the single inducement group, they were cultured by the condition medium (DMEM, 10% fetal bovine serum, dexamethasone 10 mmol/L, vitamin C 50 mg/L, and βGP 10 mmol/L); and in the experimental group , the ywere transfected with AdEasy1/Cbfα1,and then were cultured by the condition m edium. The alkaline phosphatase(ALP) activity and the experission of osteocalcin as the osteoblast markers were measured with the chemohistological and immunohi stochemical methods at 3 days,1,2,3,and 4 weeks after inducement. Results More than 90% MSCs were grown well in vitro. The GFP was positive in MSCs after their being transfectived with AdEasy1/Cbfα1. The ALP activity and the experission of osteocalcin were significantly upregulated in the transfection group compared with those in the single inducement group and the control group at 1, 2, 3, and 4 weeks (Plt;0.05).The mineralized node began to appear at 2 weeks in the experiment al group and the single induction group, but did not appear in control group. Conclusion Cbfα1 can obviously promote differentiation of the rabb it marrow mesenchymal stem cells into the osteoblasts.
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 monitor the stem cell migration into the bone defect following an injection of the labeled mesenchymal stem cells (MSCs) by the enha nced green fluorescent protein (EGFP)technology and to provide insights into an application of MSCs for the fracture healing. Methods Isolated MSCs from the rabbit femur marrow were culture-expanded and were labeled by the transfection with the recombinant retrovirus containing the EGFP gene. Then, some labeled MSCs were cultured under the osteogenic differentiation condition and the phenotype was examined. After the fracture of their bilateral ulna, 18 rabbits were divide d into two groups. The labeled MSCs were injected into the aural vein at 1×107 cells/kg in the experimental group and the unmarked MSCs were injected in the control group 24 hours before surgery, and 1 and 24 hours after surgery, res pectively. Necropsies were performed 2 days after surgery in the two groups. The sections from the left defects were observed under the fluorescence microscope and the others were analyzed by the bright-field microscopy after the HE staining. Results The EGFP did not affect the MSCs viability. After the labeled cells were incubated in the osteogenic medium alkaline phosphatase, the calcium nodule s were observed. All the rabbits survived. The tissue of haematoma was observed in the bone defects and the fluorescent cells were found in the experimental gr oup, but no fluorescent cells existed in the control group. Conclusion The EG FP labeled MSCs can undergo osteogenic differentiation in vitro and can mig rate into bone defects after their being injected into the peripheral vein.
Objective To study the effect of transforming growth factor β1(TGF-β1) and insulin-like growth factor 1(IGF-1) during the induction course from marrow mesenchymal stem cells (MSCs) to chondrocytes and to observe the effect of cell density on cell induction. Methods Differential time adherent methods were used to purify MSCs obtained from the bone marrow of Kunming mice. MSCs were cultured under special conditionsto induce themto differentiate into chondrocytes. Toluidine blue staining and immunofluoresence were used to identify those induced chondrocytes.TGF-β1 and IGF-1 were used individually or in combination under two different culture patterns: pellet culture and monolayer culture. According to different growth factors, experiment included 3 experimental groups(TGF-β1+IGF-1 group,10 ng/mland 50 ng/ml respectively;TGF-β1 group, 10 ng/ml; and IGF-1 group, 50 ng/ml) and control group(without growth factor). In TGF-β1+IGF-1 group, toluidine blue staining and immunofluoresence staining were carried out at 14 days and 21 days. The effect ofTGF-β1 and IGF-1 on the expression of collagen Ⅱgene was detected by RT-PCR at 7, 14 and 21 days of induction; the expressionsof collagen Ⅱ were compared between two culture patterns. Results In TGF-β1+IGF-1 group, the histological examination and immunofluoresence showed that those inducted chondyocytes could express collagen Ⅱ at 14 days. The gel electrophoresis results showed that the fragment of collagen Ⅱ gene was seen in TGF-β1+IGF-1 group andTGF-β1 group and that no fragment ofcollagen Ⅱ gene was seen in IGF-1 group and control group. The expression of collagen Ⅱ gene was ber in TGF-β1+ IGF-1 group than inTGF-β1 group, showing significant difference(Plt;0.05). Cells expressed more collagen Ⅱ under pellet culture than under monolayer culture. Conclusion IGF-1 could enhance the effect ofTGF-β1 during the induction course from MSCs to chondrocytes. A certain extent of high cell density is more effective for MSCs to differentiate into chondrocytes.
Objective To establish a model of the human marrow mesenchymal stem cells (hMSCs) cultured under the hypoxic condition in adults and to investigate the biological features of MSCs under hypoxia.Methods The bone marrow was obtained by aspiration at the posterior superior iliac spine in 3 healthy adult subjects. hMSCs were isolated by the gradient centrifugation and were cultured in the DMEM-LG that contained 20% fetal bovine serum. The serial subcultivation was performed 10-14 days later. The second passage of the hMSCs were taken, and they were divided into the following 4 groups according to the oxygen concentrations and the medium types: the normoxic group(20%O2, DMEM-LG, Group A), the hypoxic group(1%O2, DMEM-LG,Group B), the normoxic osteoblast induction group(20%O2, conditioned medium, Group C), and the hypoxic osteoblast induction group(1%O2, conditioned medium, Group D). The biological features of the cultured hMSCs under hypoxia were assessed bythe cell count, the MTT method, the colony forming unit-fibroblast, the real-time RT-PCR, and the alkaline phosphatase (ALP) activity, and the alizarinred staining. Results The hMSCs cultured in the Group B and Group D had a significantly higher proliferation rate than those in the Group A (Plt;0.01), and the culture effect was not influenced by the medium type. The hMSCs in the Group B had a significantly higher level of the colony-forming unit capability than the hMSCs cultured in the Group A(Plt;0.01). After the induction, hMSCs in the Group B had a decreasednumber of the osteoblasts than hMSCs in the Group C. The hMSCs in the Group D had a gradually-increasedactivity of ALP, which was significantly lower than that in the Group C(Plt;0.01). The RT-PCR examination revealed that ALP,osteocalcin, and mRNA expressions of collagen type Ⅰ and osteonectin in the Group Csignificantly increased (P<0.01). By comparisonamong the 3 groups, after the 4-week culture the obvious calcium salt deposit and the red-stained calcium nodus could be observed.ConclusionHypoxia can promote the proliferation rate of hMSCs, enhance the colonyforming ability and inhibit the differentiation of the osteoblasts.
Objective To explore the effect of the platelet-rich plasma (PRP) on proliferation and osteogenic differentiation of the bone marrow mesenchymal stem cells (MSCs) in China goat in vitro. Methods MSCs from the bone marrow of China goat were cultured. The third passage of MSCs were treated with PRP in the PRP group (the experimental group), but the cells were cultured with only the fetal calf serum (FCS) in the FCS group (the control group). The morphology and proliferation of the cells were observed by an inverted phase contrast microscope. The effect of PRP on proliferation of MSCs was examined by the MTT assay at 2,4,6 and 8 days. Furthermore, MSCs were cultured withdexamethasone(DEX)or PRP; alkaline phosphatase (ALP) and the calcium stainingwere used to evaluate the effect of DEX or PRP on osteogenic differatiation of MSCs at 18 days. The results from the PRP group were compared with those from the FCS group. Results The time for the MSCs confluence in the PRP group was earlier than that in the FCS group when observed under the inverted phase contrast microscope. The MTT assay showed that at 2, 4, 6 and 8 days the mean absorbance values were 0.252±0.026, 0.747±0.042, 1.173±0.067, and 1.242±0.056 in the PRP group, but 0.137±0.019, 0.436±0.052, 0.939±0.036, and 1.105±0.070 in the FCS group. The mean absorbance value was significantly higher in the PRP group than in the FCS group at each observation time (P<0.01). Compared with the FCS group, the positive-ALP cells and the calcium deposition were decreased in the PRP group; however, DEX could increase boththe number of the positiveALP cells and the calcium deposition. Conclusion The PRP can promote proliferation of the MSCs of China goats in vitro but inhibit osteogenic differentiation.
Objective To study the adhesion characteristic in vitrobetween porous biphasic calcium phosphate(BCP) nanocomposite and bone marrow mesenchymal stem cells (MSCs) that have been induced and proliferated. Methods MSCs obtained from SD ratbone marrow were in vitro induced and proliferated. After their osteoblastic phenotype were demonstrated, MSCs were seeded onto prepared porous BCP nanocomposite(experiment group)and common porous hydroxyapatite (control group). Their adhesion situation was analyzed by scanning electron microscope. The initial optimal cell seeding density was investigated between new pattern porous BCP nanocomposite and MSCs by MTT automated colormetric microassay method. Results The differentiation of MSCs to osteoblastic phenotype were demonstrated by the positive staining of mineralized node, alkaline phosphatase (ALP) and collagen typeⅠ, the most appropriate seeding density between them was 2×106/ml. The maximal number which MSCs could adhere to porous BCP nanocomposite was 1.28×107/cm3. Conclusion MSCs can differentiate to osteoblastic phenotype.The MSCs were well adhered to porous BCP nanocomposite.