Objective The human amniotic epithel ial cells (hAECs) are a recently identified new type of stem cells.It has previously been shown that hAECs express hepatocyte-related gene and possess intracellular features and functional properties of hepatocytes. The hAECs may be a candidate seed cell for l iver regeneration. To research the survival and migrationin vivo of hAECs via adeno-associated virus-mediated the green fluorescent protein gene (AAV-GFP) transfection, and toexplore the expression of hepatocyte-l ike function. Methods Thirty nude mice (aging 6-8 weeks, half males and females, and weighing 20-22 g) were randomly divided into 3 groups (groups A, B, and C, n=10). The mice of groups A and C were made the 2/3 partial hepatectomy model, and the mice of group B underwent open abdominal operation without hepatectomy. The hAECs transfected by AAV-GFP were transplanted into the inferior end of the spleen in groups A and B with a cell density of 5 × 106/mL and a volume of 0.2 mL; the same volume of normal sal ine was injected in group C. At 4 hours, the nude mice were sacrificed and the samples of l iver, spleen, heart, lung, brain, and kidney were harvested and the general observation, histological observation, and immunofluorescence detection were performed for the hAECs survival, migration, and the functional properties of hepatocytes. Results No tumor tissue was found in l iver and spleen of 3 groups, and HE staining showed no tumor cells. There were a lot of roundl ike and deeply-stained cells with less cytoplasm and large nucleus in the spleen and the l iver of group A; no abnormal cells were found in l iver and spleen of groups B and C and in kidney, heart, bung, and brain of groups A, B, and C. The GFP+ cells were detected in the spleen and l iver of group A with expressing human albumin, but no GFP+ cells was found in l iver and spleen of groups B and C and in heart, kidney, lung, and brain of groups A, B, and C. Conclusion AAV-GFP infected hAECs transplanted into SCID nude mice with hepatectomy can keep the hepatocyte-l ike function. It will be beneficial to further identify their biological characteristics.
Objective To construct the lentiviral vector to co-express enhanced green fluorescent protein (EGFP) gene and human insul in (insulin) gene, and to explore the condition to transfect human umbil ical cord mesenchymal stem cells (hUCMSCs) so as to lay a foundation for tissue engineered adipose reconstruction and transplantation in vivo infuture. Methods The insulin gene was cloned to lentiviral expression vector with EGFP [pLenti6.3-internal ribosome entrysite (IRES)-EGFP] by recombinant DNA technology, the positive clones were screened, and lentiviral packaged systems and target gene plasmid were co-transfected to package virus in 293T cells by lipofectin. The reporter gene expression was observed by fluorescent inverted phase contrast microscope, virus supernatant was collected, purificated and concentrated, and the titer of recombinant viruses was determinated. hUCMSCs from umbilical cord tissue of mature neonates were isolated and cultured by different multiple of infection (MOI, 0, 1, 3, 5, 7, 10, 15, and 20). By recombinant lentiviral infected hUCMSCs with reporter gene green fluorescent protein expression, the best MOI was screened; recombinant lentiviral infected hUCMSCs at the best MOI, then real-time PCR and Western blot methods were appl ied to detect insulin gene and insul in protein expression levels in cells. Results The recombinant lentiviral vector of co-expressing insulin gene and EGFP gene (pLenti6.3-insulin-IRESEGFP) was successfully constructed. Virus could be packaged, purificated and concentrated successfully. The virus titer was 1.3 × 108 TU/mL. The best MOI was 10 and the transfer efficiency was up to 90% in the same time. Real-time PCR results showed that insulin gene expression of transfected group was positive and non-transfected group was negative; Western blot detection confirmed that insul in protein expression of transfected group was positive in cells and supernatant, but that of non-transfected group was both negative. Conclusion Lentiviral vector pLenti6.3-insulin-IRES-EGFP carrying recombinant insulin gene could effectively transfect hUCMSCs and express insul in protein.
Objective The combined appl ication of green fluorescent protein (GFP) and confocal laser scanning microscope three-dimensional reconstruction (CLSM-3DR) were used to monitor the construction and in vivo transplantation of tissue engineered bone (TEB), to provide for technology in selection of scaffolds and three-dimensional constructional methods. Methods After bone marrow mesenchymal stem cells (BMSCs) were isolated from a 2-year-old green goat by a combination method of density gradient centrifugation and adherent culture, and the expressions of CD29, CD60L, CD45, and CD44 in BMSCs were detected by flow cytometry. Plasmid of pLEGFP-N1 was ampl ified, digested by enzymes (Hind III, BamH I, Sal I, and Bgl II), and identified. Transfection of pLEGFP-N1 into PT67 cells was performed under the help of l iposome. Positive PT67 cells were picked out with G418, and prol iferated for harvesting virus. Based on the titre of virus, after BMSCs were infected by virus containing pLEGFP-N1, GFP positive BMSCs were collected and prol iferated for seeding cells. TEB was fabricated by GFP positive BMSCs and decalcified bone matrix (DBM) and observed by CLSM-3DR for the evaluation of the distribution and prol iferation of seeding cells. After TEB was transplanted in the defect of goat femur, CLSM was used for observing the survival and distribution of GFP positive cells in the grafts. Results The isolated cells were fibroblast-l ike morphous, with the positive expression of CD29 and CD44, and negative expression of CD60L and CD45. The digested production of pLEGFP-N1 was collected for ionophoresis, whose results showed the correct fragment length (6 900 bp). The virus of pLEGFP-N1 was harvested by transfection of pLEGFP-N1 into PT67 cells and used for further infection to obtain GFP positive BMSCs. The prol iferated GFP positive BMSCs and DBM were used for fabrication of TEB. The distribution, prol iferation, and migration of BMSCs in TEB were observed by CLSM-3DR. GFP positive cells also were observed in images of TEB graft in goat femur 28 days after transplantation. Conclusion The BMSCs labeled by GFP in three-dimensional scaffold in vivo were monitored well by CLSM-3DR. It suggests a wide use potency in monitoring of three-dimensional cultured TEB.
Objective To construct a recombinant adenovirus vector pAdxsi-GFP-NELL1 that co-expressing green fluorescent protein (GFP) and homo sapiens NEL-l ike 1 (NELL1) protein (a protein bly expressed in neural tissue encoding epidermal growth factor l ike domain), to observe its expression by transfecting the recombinant adenovirus into rat bone marrow mesenchymal stem cells (BMSCs) so as to lay a foundation for further study on osteogenesis of NELL1 protein. Methods From pcDNA3.1-NELL1, NELL1 gene sequence was obtained, then NELL1 gene was subcloned into pShuttle-GFP-CMV (-)TEMP vector which was subsequently digested with enzyme and insterted into pAdxsi vector to package the recombinant adenovirus vector (pAdxsi-GFP-NELL1). After verified by enzyme cutting and gel electrophoresis, pAdxsi-GFPNELL1 was ampl ified in HEK293 cells and purified by CsCl2 gradient purification, titrated using 50% tissue culture infective dose (TCID50) assay. The rat BMSCs were cultured and identified by flow cytometry and directional induction, then were infected with adenoviruses (pAdxsi-GFP-NELL1 and pAdxsi-GFP). NELL1 expression was verified by RT-PCR and immunofluorescence; GFP gene expression was verified by the intensity of green fluorescence under fluorescence microscope. Cell counting kit-8 (CCK-8) was used for investigate the influence of vectors on the prol iferation of rat BMSCs. Results Recombinant adenoviral vector pAdxsi-GFP-NELL1, which encodes a fusion protein of human NELL1, was successfully constructed and ampl ified with titer of 1 × 1011 pfu/mL. The primary BMSCs were cultured and identified by flow cytometric analysis, osteogenic and adipogenic induction, then were used for adenoviral transfection efficiency and cell toxicity tests. An multipl icity of infection of 200 pfu/cell produced optimal effects in transfer efficiency without excessive cell death in vitro. Three days after transfection with 200 pfu/cell pAdxsi-GFP-NELL1 or pAdxsi-GFP, over 60% BMSCs showed green fluorescent by fluorescence microscopy. Imunofluorescence with NELL1 antibody also revealed high level expression of human NELL1 protein in red fluorescent in these GFP expressing cells. RT-PCR analysis confirmed that the exogenous expression of NELL1 upon transfection with pAdxsi-GFPNELL1 at 200 pfu/cell, whereas NELL1 remained undetectable in Ad-GFP-transfected rat BMSCs. The prol iferative property of primary rat BMSCs after adenoviral NELL1 transfection was assayed by CCK-8 in growth medium. Growth curve demonstratedno significant difference among BMSCs transfected with pAdxsi-GFP-NELL1, pAdxsi-GFP, and no treatment control at 7 days (P gt; 0.05). Conclusion Recombinant adenovirus vector pAdxsi-GFP-NELL1 can steady expressing both GFP and NELL1 protein after being transfected into rat BMSCs. It provides a useful tool to trace the expression of NELL1 and investigate its function in vitro and in vivo.
Objective To observe the tissue engineered bonefabricated with the cultured mesenchymal stem cells (MSCs) by the green fluorescent protein (GFP) gene transfer. Methods The recombinant Adeno-XTM-GFP expression vector was purified after being packed and proliferated by the HEK293 cells, and then it was used to infect the rabbit’s MSCs directly afer the virus titer was assayed. The cell morphological changes were observed under the inverted phase contrast microscope, and the expression of GFP was observed under the fluorescence microscope to confirm success of the labeling of MSCs.The GPFlabeled MSCs and the pure MSCs were cultured together in the conventional osteogenic supplements for 3 weeks, and then they were seeded onto the compound scaffold of the calcium phosphate cement (CPC) and the fibrin glue (FG) to form a new kind of the tissue engineered bone. It was implanted into the donator rabbit subcutaneously to be used as the experimental group; in contrast, the pure compound scaffold of the CPC-FG without any MSCs was implanted in the same rabbit as a control. The alkline phosphatase (ALP) activity assay was performed respectively at 1, 2 and 3 weeks after operation. GFP was observed under the laserconfocal microscope at 4 weeks after operation, and the formed new bone was harvested at 4 weeks and evaluated by the Masson staining, the immunohistochemistry staining of osteocalcin (OC) and collagen typeⅠ.Results The virus titer was 3×108pfu/ml after proliferation and purification. Expresstionof GFP was confirmed 96 h after MSCs were infected by the Adeno-XTM-GFP expression vector and the infection rate was proximally 50%-70%. In contrast to MSCs, division and proliferation of the GPF-labeled MSCs were not significantly different. The ALP activity in the experimental group (12.546±1.091, 16.567±0.659, 20.443±0.706) was significantly higher than that in the control group (0.453±0.113, 0.243±0.018, 0.308±0.056), respectively at 1, 2 and 3 weeks after operation (Plt;0.05). The tissue engineered bone formed at 4 weeks. There were newly-formed trabeculae around the pore of the compound scaffold, and theimmunohistochemistry staining of OC and collagen typeⅠ were positive. The laser confocal microscope revealed that the GFP-labeled cells existed in many newlyformed tissues,and the compound scaffold of CPC-FG was partly degraded. Conclusion The engineered bone is similar to the spongy bone and the composed cells originate from the cultured MSCs, all of which can be confirmed by the GFP gene transfer technique.
OBJECTIVE: To construct a plasmid which has a reporter gene for exploring the role of human telomerase reverse transcriptase(hTRT) in in-vitro cell cultivation. METHODS: hTRT was cut by restricted enzyme from plasmid pGRN145 and inserted to plasmid pEGFP-C1 (enhanced green fluorescent protein). RESULTS: Restricted enzyme analysis and DNA sequencing showed that the sequence of the pEGFP -hTRT transgenic plasmid was correct. CONCLUSION: The recombinant vector pEGFP-hTRT has been successfully constructed, and it can be used as a transgenic plasmid in generating immortalized cell lines.
Objective To investigate the enhancing effect of ultrasound microbubbles on transfection of recombinant adenoassociated virus (rAAV) mediated green fluorecent protein (EGFP) gene into retinal ganglion cells (RGC) in vivo.Methods A total of 40 adult Sprague-Dawley (SD) rats were divided into four groups randomly (group A,B,C,D) with 10 rats in each. Group A was the normal control, in which the rats underwent intravitreal injection with 5 mu;l phosphate buffered solution. The rats in group B underwent intravitreal injection with 5 mu;l recombinant adenoassociated virus encoding EGFP gene (rAAV2-EGFP). The rats in group C underwent ultrasound irradiation on eyes right after intravitreal injection with 5 mu;l rAAV2-EGFP; The ultrasound irradiation was performed on the rats in group D right after intravitreal injection with the mixture solution of microbubbles and rAAV2-EGFP ultrasound. After 21 days, RGC were labeled retogradely with fluogold. Seven days after labeling, the retinal flatmounts and frozen sections were made from five rats in each group. Expression of EGFP reporter gene was observed by laser scanning confocal microscope and evaluated via average optical intensity (AOD) and RGC transfection rate. Labeled RGC were counted to evaluate the adverse effects.Results Green fluorescence can be observed exactly in labeled RGC in B,C,and D groups. The AOD and transfection rate in group D was (95.02plusmn;7.25)% and(20.10plusmn;0.74)% , respectively; which were higher than those in group B and C (F=25.970,25.799;P<0.01). The difference of the number of RGC among the four groups was not significant(F=0.877,P>0.05). Conclusion Under the condition of low frequency and with certain energy, ultrasoundmediated microbubble destruction can effectively and safely enhance rAAV delivery to RGC in rats.