Objective To construct the rhesus monkey Schwann cells (SCs) modified with human glial cell derived neurotrophic factor (hGDNF) gene. Methods The coding sequence of hGDNF amplified by PCR from pUC19-hGDNF was inserted into eukaryotic expression vector pBABE-puro. The recombinant eukaryotic expression vector pBABE-puro-hGDNF was identified with restriction enzyme digestion and DNA sequencing. The SCs were isolated from rhesus monkeys, cultured and purified. The SCs were transfected with the recombinant retrovirus vector containing hGDNF gene. The mRNA and protein expressions of hGDNF were analyzed by real-time fluorescent quantitative PCR and Western blot. Results The PCR product of hGDNF coding sequence was a 596 bp specific segment. The recombinant eukaryotic expression vector was digested into a 596 bp specific segment by specific restriction enzyme and another segment. The 596 bp segment confirmed by DNA sequencing was consistent with hGDNF sequence on GenBank. Restriction enzyme digestion and sequencing results showed that the coding sequence of hGDNF was successfully inserted into the recombinant retrovirus vector and the mRNA and protein expressions of hGDNF were significantly higher in transfected SCs than non-transfected SCs (P lt; 0.05). Conclusion The rhesus monkey SCs modified with hGDNF gene are successfully constructed and hGDNF can be released continuously and stably, which will provide a foundation for the further research about cell therapy of hGDNF-SCs in the repair of injured nerve.
Objective To explore a new method for the pre-degeneration of peripheral nerve in vitro for obtaining many effective Schwann cells so as to provide a large number of seed cells for the research and application of tissue engineered nerves. Methods The bone marrow derived cells (BMDCs) from transgenic green fluorescent protein C57BL/6 mouse and the sciatic nerve segments from the C57BL/6 mouse were co-cultured to prepare the pre-degeneration of sciatic nerve in vitro (experimental group, group A), and only sciatic nerve was cultured (control group, group B). At 7 days after culture, whether BMDCs can permeate into the sciatic nerve in vitro for pre-degeneration was observed by gross and immunohistofluorescence staining. And then Schwann cells were obtained from the sciatic nerves by enzymic digestion and cultured. The cell number was counted, and then the purity of primary Schwann cells was determined using immunohistofluorescence staining and flow cytometer analysis. Results At 7 days after pre-degeneration, gross observation showed that enlargement was observed at nerve stumps, and neuroma-like structure formed; the group A was more obvious than group B. Immunohistofluorescence staining showed many BMDCs permeated into the nerve segments, with positive F4/80 staining in group A. After culture, the yield of Schwann cells was (5.59 ± 0.19) × 104 /mg in group A and (3.20 ± 0.21) × 104/mg in group B, showing significant difference (t=2.14, P=0.03). At 48 hours after inoculation, the cells had blue bipolar or tripolar cell nuclei with small size and red soma by immunohistofluorescence staining; fibroblasts were flat polygonal with clear nucleus and nucleolus, showing negative p75NTR staining; and there were few of fibroblasts in group A. The purity of Schwann cells was 88.4% ± 5.8% in group A and 76.1% ± 3.7% in group B, showing significant difference (t=2.38, P=0.04). And the flow cytometer analysis showed that the purity was 89.6% in group A and 74.9% in group B. Conclusion BMDCs can promote the pre-degeneration of peripheral nerve in vitro, and it is a new method to effectively obtain Schwann cells for tissue engineered nerve.
Objective To obtain highly purified and large amount of Schwann cells (SCs) by improved primary culture method, to investigate the biocompatibility of small intestinal submucosa (SIS) and SCs, and to make SIS load nerve growth factor (NGF) through co-culture with SCs. Methods Sciatic nerves were isolated from 2-3 days old Sprague Dawley rats and digested with collagenase II and trypsin. SCs were purified by differential adhesion method for 20 minutes and treated with G418 for 48 hours. Then the fibroblasts were further removed by reducing fetal bovine serum to 2.5% in H-DMEM. MTT assay was used to test the proliferation of SCs and the growth curve of SCs was drawn. The purity of SCs was calculated by immunofluorescence staining for S-100. SIS and SCs at passage 3 were co-cultured in vitro. And then the adhesion, proliferation, and differentiation of SCs were investigated by optical microscope and scanning electron microscope (SEM). The NGF content by SCs was also evaluated at 1, 2, 3, 4, 5, and 7 days by ELISA. SCs were removed from SIS by repeated freeze thawing after 3, 5, 7, 10, 13, and 15 days of co-culture. The NGF content in modified SIS was tested by ELISA. Results The purity of SCs was more than 98%. MTT assay showed that the SCs entered the logarithmic growth phase on the 3rd day, and reached the plateau phase on the 7th day. SCs well adhered to the surface of SIS by HE staining and SEM; SCs were fusiform in shape with obvious prominence and the protein granules secreted on cellular surface were also observed. Furthermore, ELISA measurement revealed that, co-culture with SIS, SCs secreted NGF prosperously without significant difference when compared with the control group (P gt; 0.05). The NGF content increased with increasing time. The concentration of NGF released from SIS which were cultured with SCs for 10 days was (414.29 ± 20.87) pg/cm2, while in simple SIS was (4.92 ± 2.06) pg/cm2, showing significant difference (P lt; 0.05). Conclusion A large number of highly purified SCs can be obtained by digestion with collagenase II and trypsin in combination with 20-minute differential adhesion and selection by G418. SIS possesses good biocompatibility with SCs, providing the basis for further study in vivo to fabricate the artificial nerve conduit.
Objective To investigate the effect of carboxymethylated chitosan (CMCS) on the proliferation, cell cycle, and secretion of neurotrophic factors in cultured Schwann cells (SCs). Methods SCs were obtained from sciatic nerves of 20 Sprague Dawley rats (3-5 days old; male or female; weighing, 25-30 g) and cultured in vitro, SCs were identified and purified by immunofluorescence against S-100. The cell counting kit 8 (CCK-8) assay was used to determine the proliferation of SCs. The SCs were divided into 4 groups: 50 μg/mL CMCS (group B), 100 μg/mL CMCS (group C), 200 μg/mL CMCS (group D), and the same amount of PBS (group A) were added. The flow cytometry was used to analyze the cell cycle of SCs; the real-time quantitative PCR and Western blot analysis were used to detect the levels of never growth factor (NGF) and ciliary neurotrophic factor (CNTF) in cultured SCs induced by CMCS. Results The purity of cultured SCs was more than 90% by immunofluorescence against S-100; the CCK-8 results indicated that CMCS in concentrations of 10-1 000 μg/mL could promote the proliferation of SCs, especially in concentrations of 200 and 500 μg/mL (P lt; 0.01), but no significant difference was found between 200 and 500 μg/mL (P gt; 0.05). CMCS at a concentration of 200 μg/mL for 24 hours induced the highest proliferation, showing significant difference when compared with that at 0 hour (P lt; 0.01). The percentage of cells in phase S and the proliferation index were significantly higher in groups B, C, and D than in group A (P lt; 0.05), in groups C and D than in group B (P lt; 0.05); and there was no significant difference between group C and group D (P gt; 0.05). Real-time quantitative PCR and Western blot results showed that the levels of NGF and CNTF in groups B, C, and D were significantly higher than those in group A (P lt; 0.05), especially in group D. Conclusion CMCS can stimulate the proliferation, and induce the synthesis of neurotrophic factors in cultured SCs.
ObjectiveTo establish an efficient method of isolating and culturing high activity and high purity of Schwann cells, and to identify the cells at the levels of transcription and translation. MethodsThe sciatic nerves harvested from a 4-week-old Sprague Dawley rat were digested in the collagenase I for 15 minutes after dissecting, and then the explants were planted in culture flask directly. The cells were cultured and passaged in vitro, the growth state and morphological changes of the cells were observed under inverted phase contrast microscope. MTT assay was used to test the proliferation of cells and the cells growth curve was drawn. RT-PCR and immunohistochemistry staining were used to detect S100 and glial fibrillary acidic protein (GFAP) at the levels of transcription and translation, respectively. The purity of cells was caculated under microscope. ResultsAfter the digestion of collagenase I, fibroblast-like cells appeared around explants within 24 hours, with slender cell body and weak refraction. After tissues were transferred to another culture flask, a large number of dipolar or tripolar cells were seen after 48 hours, with slender ecphyma, plump cell body, and b refraction, and the cells formed colonies within 72 hours. The cells were covered with the bottom of culture flask within 48-72 hours after passaging at a ratio of 1∶2, and spiral colonies appeared. Cells showed vigorous growth and full cytoplasm after many passages. MTT assay results showed that the cells at passage 3 entered the logarithmic growth phase on the 3rd day, reached the plateau phase on the 7th day with cell proliferation, and the growth curve was “S” shape. RT-PCR results showed that the cells expressed S100 gene and GFAP gene, and immunohistochemistry staining showed that most of the cells were positively stained, indicating that the majority of cells expressing S100 protein and GFAP protein. The purity of Schwann cells was 98.37% ± 0.30%. ConclusionHigh activity and high purity of Schwann cells can be acquired rapidly by single-enzyme digestion and explant-culture method.
Objective To establ ish the methods to get high activity, high purity, and adequate Schwann cells (SCs), and to provide sufficient seed cells for the peripheral nerve repair. Methods Six 5-day-old, male or female, Sprague Dawley rats were selected and the sciatic nerve (control group) and dorsal root gangl ion (DRG) (ex perimental group) were harvested.Then the sciatic nerves and DRG were digested by co-enzyme and dispersed by medium containing serum to isolate SCs. Freshlyisolated SCs from rats were cultured, purified and subcultured. The 1st generation of SCs were chosen to draw the growth curve of SCs by the counting method and to detect the prol iferation of SCs by MTT assay at 8 days of culture, the purity of SCs by immunocytochemistry of anti-S-100 and the brain-derived neurotrophic factor (BDNF) concentration by ELISA. Results A total of 36-43 DRGs could be obtained in each rat. The number of obtained single SC in experimental group [(7.5 ± 0.6)× 106] was significantly higher than that in control group [(3.5 ± 0.4)× 106 ] (t=13.175, P=0.000). SCs reached logarithm prol iferation phase at 3 days. With time, the cell number and the prol iferation absorbance (A) value of 2 groups all showed upward trend. The number and A value of experimental group were significantly higher than those of control group (P lt; 0.05). The SCs purity of experimental group (92.08% ± 3.45%) was significantly higher than that of control group (77.50% ± 3.57%) (t=6.689, P=0.001).The concentrations of BDNF at 3 days and 5 days in experimental group were significantly higher than those of control group (P lt; 0.05). Conclusion The sufficient amount, high purity, and viabil ity of SCs from DRGs can meet the needs of studies on peripheral nerve repairment.
Objective Bone marrow mesenchymal stem cells (BMSCs) are multi potent and thus are able to differentiate into a number of different cell types under certain culture condition. However, the effect of age on the differentiation remains unknown. To explore the effect of the microenvironment formed by Schwann cells (SCs) on BMSCs differentiation into neurons and ol igodendrocytes in rats at different ages in vitro. Methods SCs were extracted and purified from the distal sciatic nerves of neonatal Wistar rats. BMSCs were isolated from bone marrow of Wistar rats (aged 1 month, 6 months, and 12 months, respectively) and cultured in vitro. The cells were identified by immunofluorescent staining. The BMSCs at passage 2 were labeled by PKH26 and cocultured with SCs at passage 3 in equal proportions in two layer Petri dish. According to the BMSCs from the rats at different ages, experiment was divided into 3 groups: SCs were cocultured with 1-month-old rat BMSCs (group A), 6-month-old rat BMSCs (group B), and 12-month-old rat BMSCs (group C), respectively. The morphological changes of cocultured BMSCs were observed by inverted phase contrast microscope, the expressions of neuron-specific enolase (NSE) and myel in basic protein (MBP) in the cocultured BMSCs were tested by immunofluorescent staining, and the expression of neuregul in 1 (NRG1) was detected by ELISA method. Results SCs and BMSCs were isolated and cultured successfully. The identification of SCs showed positive expression of S-100 and BMSCs showed positive expressions of CD29, CD44, and CD90. At 7 days after coculture, the BMSCs in group A began retraction, and became round or tapered with the processes and had a nerve cells or ol igodendrocytes-l ike morphology, but most BMSCs in groups B and C showed no obvious morphological changes under inverted phase contrast microscope. Immunofluorescent staining showed that the positive expression rates of NSE in groups A, B, and C were 22.39% ± 2.86%, 12.89% ± 1.78%, and 2.69% ± 0.80%, respectively, and the positive expression rates of MBP in groups A, B, and C were 16.13% ± 2.39%, 6.33% ± 1.40%, and 0.92% ± 0.17%, respectively. There were significant differences in terms of NSE and MBP positive expression rates among 3 groups (P lt; 0.05). ELISA analysis showed that NRG1 in the supernatant of group A was increased after coculture in a time-dependent manner. At 6, 9, and 12 days of coculture, NRG1 content was higher in group A than in groups B and C, and in group B than in group C, showing significant differences (P lt; 0.05). Conclusion The microenvironment formed by SCs can promote BMSCs differentiation into neurons and ol igodendrocytes, but the differentiation capabil ity of BMSCs decreases with aging, and the variety of growth factors secreted by SCs is l ikely important factors that induce the differentiation of BMSCs into neurons and ol igodendrocytes.
Objective Native extracellular matrix (ECM) is comprised of a complex network of structural and regulatory proteins that are arrayed into a tissue-specific, biomechanically optimal, fibrous matrix. The multifunctional nature of the native ECM will need to be considered in the design and fabrication of tissue engineering scaffolds. To investigate the extraction techniques of naturally derived nerve ECM and the feasibil ity of nerve tissue engineering scaffold. Methods Ten fresh canine sciatic nerves were harvested; nerve ECM material was prepared by hypotonic freeze-thawing, mechanicalgrinding, and differential centrifugation. The ECM was observed by scanning electron microscope. Immunofluorescencestaining was performed to detect specific ECM proteins including collagen type I, laminin, and fibronectin. Total collagen and glycosaminoglycan (GAG) contents were assessed using biochemical assays. The degree of decellularization was evaluated with staining for nuclei using Hoechst33258. The dorsal root gangl ion and Schwann cells of rats were respectively seeded onto nerve tissue-specific ECM films. The biocompatibil ity was observed by specific antibodies for cell markers. Results Scanning electron microscope analysis revealed that nerve-derived ECM consisted of a nanofibrous structure, which diameter was 30-130 nm. Immunofluorescence staining confirmed that the nerve-derived ECM was made up of collagen type I, laminin, and fibronectin. The histological staining showed that the staining results of sirius red, Safranin O, and toluidine blue were positive. Hoechst33258 staining showed no DNA within the decellularized ECM. Those ECM films had good biocompatibil ity for dorsal root gangl ion and Schwann cells. The cotents of total collagen and GAG in the nerve-derived ECM were (114.88 ± 13.33) μg/ mg and (17.52 ± 2.34) μg/mg, showing significant difference in the content of total collagen (P lt; 0.01) and no significant difference in the content of GAG (P gt; 0.05) when compared with the contents of normal nerve tissue [(54.07 ± 5.06) μg/mg and (25.25 ± 1.56) μg/mg)]. The results of immunofluorescence staining were positive for neurofilament 200 after 7 days and for S100 after 2 days. Conclusion Nerve-derived ECM is rich in collagen type I, laminin, and fibronectin and has good biocompatibil ity, so it can be used as a nerve tissue engineering scaffold.
Objective To construct chemically extracted acellular nerve allograft (CEANA) with Schwann cells (SCs) from different tissues and to compare the effect of repairing peripheral nerve defect. Methods Bone marrow mesenchymal stem cells (BMSCs) and adi pose-derived stem cells (ADSCs) were isolated and cultured from 3 4-week-old SD mice with weighing 80-120 g. BMSCs and ADSCs were induced to differentiated MSC (dMSC) and differentiated ADSC (dADSC) in vitro.dMSC and dADSC were identified by p75 protein and gl ial fibrillary acidic protein (GFAP). SCs were isolated and culturedfrom 10 3-day-old SD mice with weighing 6-8 g. CEANA were made from bilateral sciatic nerves of 20 adult Wistar mice with weighing 200-250 g. Forty adult SD mice were made the model of left sciatic nerve defect (15 mm) and divided into 5 groups (n=8 per group) according to CEANA with different sources of SCs: autografting (group A), acellular grafting with SCs (5 × 105) (group B), acellular grafting with dMSCs (5 × 105) (group C), acellular grafting with dADSCs (5 × 105) (group D), and acellular grafting alone (group E). Motor and sensory nerve recovery was assessed by Von Frey and tension of the triceps surae muscle testing 12 weeks after operation. Then wet weight recovery ratio of triceps surae muscles was measured and histomorphometric assessment of nerve grafts was evaluated. Results BMSCs and ADSCs did not express antigens CD34 and CD45, and expressed antigen CD90. BMSCs and ADSC were differentiated into similar morphous of SCs and confirmed by the detection of SCs-specific cellsurface markers. The mean 50% withdrawal threshold in groups A, B, C, D, and E was (13.8 ± 2.3), (15.4 ± 6.5), (16.9 ± 5.3), (16.3 ± 3.5), and (20.0 ± 5.3) g, showing significant difference between group A and group E (P lt; 0.01). The recovery of tension of the triceps surae muscle in groups A, B, C, D, and E was 87.0% ± 9.7%, 70.0% ± 6.6%, 69.0% ± 6.7%, 65.0% ± 9.8%, and 45.0%± 12.1%, showing significant differences between groups A, B, C, D, and group E (P lt; 0.05). No inflammatory reactionexisted around nerve graft. The histological observation indicated that the number of myel inated nerve fiber and the myel in sheath thickness in group E were significantly smaller than that in groups B, C, and D (P lt; 0.01). The fiber diameter of group B was significantly bigger than that of groups C and D (P lt; 0.05) Conclusion CEANA supplementing with dADSC has similar repair effect in peripheral nerve defect to supplementing with dMSC or SCs. dADSC, as an ideal seeding cell in nerve tissue engineering, can be benefit for treatment of peripheral nerve injuries.
Objective To study the migration of Schwann cells from the nerve autograft in the acellular nerve allograft of the rats in vivo. Mehtods The sciatic nerves (20 mm long) of the SD rats were harvested and prepared for the acellular nerve grafts by the chemical extraction. Then, they were observed by the gross view, HE staining, and Antilamininstaining, respectively. Another 32 female SD rats weighing 250-300 g were obtained for the study. A 2-mm-long nerve autograft was interposed between the two 10-mm-long nerve allografts to form a 22-mm-long composite. Then, the composite was placed in the muscle space, together with a sole 22-mm-long nerve allograftas a control. They were harvested at 5,10,15 and 20 days, respectively, and were then given the HE staining and the S-100 staining. Results The acellular nerve graft was semitransparent under the gross view. HE staining showed that no cell was observed within the nerve graft. Anti-laminin staining showed that the basal membrane was partially interrupted, with a positive result (dark brown). All the nerve grafts in both the groups exhibited the existenceof the cells. The S-100 positive cells were observed from the 15th day at the far ends of the two allografts of the composite; however, there were no suchcells observed within the sole nerve allograft. Conclusion Schwann cells from the sciatic nerves (2 mm- long) of the rats can migrate in the acellular nerve allograft to the far ends of the neighboring 10-mm-long nerve allografts at 15 days after operation, which offers the theoretical basis forthe repair of the longrange nerve defect by the composite of the acellular nerve allografts with the interposed nerve autograft.