Project description:Adipose-derived mesenchymal stromal cells (ADSC) are a promising source for cellular therapy of chronic wounds. However, the limited life span during in vitro expansion impedes their extensive use in clinical applications and basic research. We hypothesize that by introduction of an ectopic expression of telomerase into ADSC, the cells' lifespans could be significantly extended. To test this hypothesis, we aimed at engineering an immortalized human ADSC line using a lentiviral transduction with human telomerase (hTERT). ADSC were transduced with a third-generation lentiviral system and a hTERT codifying plasmid (pLV-hTERT-IRES-hygro). A population characterized by increased hTERT expression, extensive proliferative potential and remarkable (potent) multilineage differentiation capacity was selected. The properties for wound healing of this immortalized ADSC line were assessed after 17 passages. Their secretome induced the proliferation and migration of keratinocytes, dermal fibroblasts, and endothelial cells similarly to untransduced ADSC. Moreover, they sustained the complete re-epithelialization of a full thickness wound performed on a skin organotypic model. In summary, the engineered immortalized ADSC maintain the beneficial properties of parent cells and could represent a valuable and suitable tool for wound healing in particular, and for skin regenerative therapy in general.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Human mesenchymal stromal cells (hMSCs) show great potential for clinical and experimental use. Self-renewal and multipotent differentiation capacity are key elements in the increasing interest of this cell type. However, a disadvantage of primary hMSCs is the limited in vitro lifespan, but this can be overcome by introduction of the catalytic subunit of human telomerase reverse transcriptase (TERT). In this paper, the generation and characterization of a TERT-immortalized, non-tumorigenic human bone marrow-derived stromal mesenchymal model cell line is described. The resulting cell line, iMSC#3, maintained capacity to differentiate into osteoblasts and adipocytes, and growth characteristics comparable to primary hMSCs into after long-term culturing (155 population doublings). A detailed characterization of the mRNA- and microRNA transcriptomes during adipocyte differentiation also showed that the iMSC#3 recapitulates this process at the molecular level. Furthermore, iMSC#3 showed no major differences from hMSCs regarding surface marker expression. The cell line had a normal karyotype, and high-resolution array comparative genomic hybridization confirmed that the cells in general had normal copy number. The gene expression profiles of immortalized and primary hMSCs were also similar, whereas the corresponding methylation profiles were more diverse. In conclusion, a human bone marrow-derived stromal cell line was developed, which can be used for basic studies of mesenchymal cells and to functionally study transgenes that might play a role in oncogenic transformation.

Project description:BACKGROUND: Coordinated differentiation of the endometrial compartments in the second half of the menstrual cycle is a prerequisite for the establishment of pregnancy. Endometrial stromal cells (ESC) decidualize under the influence of ovarian progesterone to accommodate implantation of the blastocyst and support establishment of the placenta. Studies into the mechanisms of decidualization are often hampered by the lack of primary ESC. Here we describe a novel immortalized human ESC line. METHODS: Primary ESC were immortalized by the transduction of telomerase. The resultant cell line, termed St-T1b, was characterized for its morphological and biochemical properties by immunocytochemistry, RT-PCR and immunoblotting. Its progestational response was tested using progesterone and medroxyprogesterone acetate with and without 8-Br-cAMP, an established inducer of decidualization in vitro. RESULTS: St-T1b were positive for the fibroblast markers vimentin and CD90 and negative for the epithelial marker cytokeratin-7. They acquired a decidual phenotype indistinguishable from primary ESC in response to cAMP stimulation. The decidual response was characterized by transcriptional activation of marker genes, such as PRL, IGFBP1, and FOXO1, and enhanced protein levels of the tumor suppressor p53 and the metastasis suppressor KAI1 (CD82). Progestins alone had no effect on St-T1b cells, but medroxyprogesterone acetate greatly enhanced the cAMP-stimulated expression of IGFBP-1 after 3 and 7 days. Progesterone, albeit more weakly, also augmented the cAMP-induced IGFBP-1 production but only after 7 days of treatment. The cell line remained stable in continuous culture for more than 150 passages. CONCLUSION: St-T1b express the appropriate phenotypic ESC markers and their decidual response closely mimics that of primary cultures. Decidualization is efficiently induced by cAMP analog and enhanced by medroxyprogesterone acetate, and, to a lesser extent, by natural progesterone. St-T1b cells therefore serve as a useful model for primary ESC.

Project description:Human mesenchymal stromal cells (hMSCs) show great potential for clinical and experimental use. Self-renewal and multipotent differentiation capacity are key elements in the increasing interest of this cell type. However, a disadvantage of primary hMSCs is the limited in vitro lifespan, but this can be overcome by introduction of the catalytic subunit of human telomerase reverse transcriptase (TERT). In this paper, the generation and characterization of a TERT-immortalized, non-tumorigenic human bone marrow-derived stromal mesenchymal model cell line is described. The resulting cell line, iMSC#3, maintained capacity to differentiate into osteoblasts and adipocytes, and growth characteristics comparable to primary hMSCs into after long-term culturing (155 population doublings). A detailed characterization of the mRNA- and microRNA transcriptomes during adipocyte differentiation also showed that the iMSC#3 recapitulates this process at the molecular level. Furthermore, iMSC#3 showed no major differences from hMSCs regarding surface marker expression. The cell line had a normal karyotype, and high-resolution array comparative genomic hybridization confirmed that the cells in general had normal copy number. The gene expression profiles of immortalized and primary hMSCs were also similar, whereas the corresponding methylation profiles were more diverse. In conclusion, a human bone marrow-derived stromal cell line was developed, which can be used for basic studies of mesenchymal cells and to functionally study transgenes that might play a role in oncogenic transformation.

Project description:Human mesenchymal stromal cells (hMSCs) show great potential for clinical and experimental use. Self-renewal and multipotent differentiation capacity are key elements in the increasing interest of this cell type. However, a disadvantage of primary hMSCs is the limited in vitro lifespan, but this can be overcome by introduction of the catalytic subunit of human telomerase reverse transcriptase (TERT). In this paper, the generation and characterization of a TERT-immortalized, non-tumorigenic human bone marrow-derived stromal mesenchymal model cell line is described. The resulting cell line, iMSC#3, maintained capacity to differentiate into osteoblasts and adipocytes, and growth characteristics comparable to primary hMSCs into after long-term culturing (155 population doublings). A detailed characterization of the mRNA- and microRNA transcriptomes during adipocyte differentiation also showed that the iMSC#3 recapitulates this process at the molecular level. Furthermore, iMSC#3 showed no major differences from hMSCs regarding surface marker expression. The cell line had a normal karyotype, and high-resolution array comparative genomic hybridization confirmed that the cells in general had normal copy number. The gene expression profiles of immortalized and primary hMSCs were also similar, whereas the corresponding methylation profiles were more diverse. In conclusion, a human bone marrow-derived stromal cell line was developed, which can be used for basic studies of mesenchymal cells and to functionally study transgenes that might play a role in oncogenic transformation.

Project description:Generation and Characterization of an immortalized human mesenchymal stromal cell line model

Project description:Endometrial-like stromal cells, one of the main components of endometriotic lesions, are an important in vitro model for studying cellular and molecular mechanisms associated with lesion development in endometriosis. However, the short life span of primary endometriotic stromal cells (Ec-ESCs) limits their use. Human telomerase reverse transcriptase (hTERT) plasmids can be used to develop immortalized cell lines. Here we aimed to establish an endometriotic stromal cell line by hTERT immortalization. Primary Ec-ESCs were obtained from a human ovarian endometriotic cyst. The purity was assessed by morphology and the expression of vimentin, cytokeratin, and human interferon-inducible transmembrane protein 1 (hIFITM1). Cells were infected with hTERT lentiviral vector and selected with hygromycin. hTERT mRNA levels were confirmed by RT-qPCR. Immortalized Ec-ESCs (iEc-ESCs) were characterized by examining the expression of morphological markers and key genes of interest, TP53, estrogen receptor β (ERβ), progesterone receptor (PR), and steroidogenic factor-1 (SF-1). Karyotyping and in vitro decidualization studies were also performed. Ec-ESCs were positive for vimentin and hIFITM1 and negative for cytokeratin, indicating that they were representative of Ec-ESC. The fibroblast-like morphology, expression of TP53, ERβ, PR, and SF-1 did not change before and after hTERT immortalization. iEc-ESCs showed an impaired decidualization response like primary Ec-ESCs when compared to normal eutopic stromal cells. Karyotyping showed that 15/19 cells had normal female karyotype, while 4/19 cells had partial trisomy 11q. Collectively, we successfully established and characterized an immortalized endometriotic stromal cell line. It is potentially useful as an in vitro experimental model to investigate endometriosis biology.

Project description:Human mesenchymal stromal cells (hMSCs) show great potential for clinical and experimental use. Self-renewal and multipotent differentiation capacity are key elements in the increasing interest of this cell type. However, a disadvantage of primary hMSCs is the limited in vitro lifespan, but this can be overcome by introduction of the catalytic subunit of human telomerase reverse transcriptase (TERT). In this paper, the generation and characterization of a TERT-immortalized, non-tumorigenic human bone marrow-derived stromal mesenchymal model cell line is described. The resulting cell line, iMSC#3, maintained capacity to differentiate into osteoblasts and adipocytes, and growth characteristics comparable to primary hMSCs into after long-term culturing (155 population doublings). A detailed characterization of the mRNA- and microRNA transcriptomes during adipocyte differentiation also showed that the iMSC#3 recapitulates this process at the molecular level. Furthermore, iMSC#3 showed no major differences from hMSCs regarding surface marker expression. The cell line had a normal karyotype, and high-resolution array comparative genomic hybridization confirmed that the cells in general had normal copy number. The gene expression profiles of immortalized and primary hMSCs were also similar, whereas the corresponding methylation profiles were more diverse. In conclusion, a human bone marrow-derived stromal cell line was developed, which can be used for basic studies of mesenchymal cells and to functionally study transgenes that might play a role in oncogenic transformation.

Project description:Diabetes is a chronic disease characterized by high levels of blood glucose. Diabetic patients should normalize these levels in order to avoid short and long term clinical complications. Presently, blood glucose monitoring is dependent on frequent finger pricking and enzyme based systems that analyze the drawn blood. Continuous blood glucose monitors are already on market but suffer from technical problems, inaccuracy and short operation time. A novel approach for continuous glucose monitoring is the development of implantable cell-based biosensors that emit light signals corresponding to glucose concentrations. Such devices use genetically modified cells expressing chimeric genes with glucose binding properties. MSCs are good candidates as carrier cells, as they can be genetically engineered and expanded into large numbers. They also possess immunomodulatory properties that, by reducing local inflammation, may assist long operation time. Here, we generated a novel immortalized human MSC line co-expressing hTERT and a secreted glucose biosensor transgene using the Sleeping Beauty transposon technology. Genetically modified hMSCs retained their mesenchymal characteristics. Stable transgene expression was validated biochemically. Increased activity of hTERT was accompanied by elevated and constant level of stem cell pluripotency markers and subsequently, by MSC immortalization. Furthermore, these cells efficiently suppressed PBMC proliferation in MLR transwell assays, indicating that they possess immunomodulatory properties. Finally, biosensor protein produced by MSCs was used to quantify glucose in cell-free assays. Our results indicate that our immortalized MSCs are suitable for measuring glucose concentrations in a physiological range. Thus, they are appropriate for incorporation into a cell-based, immune-privileged, glucose-monitoring medical device.