Transferability of a modified embryonic stem cell test using a new endpoint for developmental neurotoxicity.

We developed and analyzed a new surrogate endpoint of the mouse embryonic stem cell test (EST) for developmental neurotoxicity. To determine the sensitivity, specificity, and transferability of the new endpoint, a pre-validation team from three independent laboratories optimized and standardized the protocol for neuronal differentiation of mouse embryonic stem cells (mESCs) by measuring the neuronal differentiation rates of mESCs under different culture conditions, such as the presence or absence of basic fibroblast growth factor (bFGF) in the growth media and varying lengths of culture. In addition, a component ratio of neuronal cells was measured by using flow cytometry analysis of ß-III tubulin (Tuj1)-positive cells and real-time polymerase chain reaction analysis of microtubule-associated protein 2 (MAP2) mRNA. Our results showed that the best growth was achieved by culturing mESCs for 12 d in N2B27 medium without bFGF or ascorbic acid. Lead (II) acetate and aroclor 1254 were used to test the usefulness of the new endpoint. When we used the known ID(50) values for lead (II) acetate in the EST model, it was classified as non-embryotoxic; however, when we used the new ID(50) values that we determined in this study, it was classified as weakly embryotoxic. Aroclor 1254 and penicillin G were also classified as weakly embryotoxic and non-embryotoxic compounds, respectively, when cardiac and neuronal differentiation ID(50) values were used. Therefore, our new surrogate endpoint for developmental neurotoxicity is not only sensitive and specific but also transferable among laboratories.

Embryotoxicity of lead (II) acetate and aroclor 1254 using a new end point of the embryonic stem cell test.

We developed a new end point of the mouse stem cell test (EST) for developmental neurotoxicity. We tested 2 developmental neurotoxicants, namely, lead (II) acetate and Aroclor 1254, using this EST. Our results showed that lead (II) acetate is nonembryotoxic, and Aroclor 1254 is weakly embryotoxic. To identify a new end point for developmental neurotoxicity, we used the default method of neuronal differentiation for D3 mouse embryonic stem cells with basic fibroblast growth factor (bFGF) and ascorbic acid. Flow cytometry and real-time polymerase chain reaction were used to quantify the inhibition of neuronal differentiation. Our results showed that both lead (II) acetate and Aroclor 1254 reduced the percentage of microtubule-associated protein 2 (MAP-2)-positive cells and the messenger RNA (mRNA) expression level of MAP-2 in a dose-dependent manner. These results suggested that these methods can be used to develop an additional end point of the EST for developmental neurotoxicity using default differentiation of mouse embryonic stem cells.

The effects of cyclin-dependent kinase inhibitors on adipogenic differentiation of human mesenchymal stem cells.

The molecular mechanisms that couple growth arrest and cell differentiation were examined during adipogenesis. Here, to understand the cyclin-dependent kinase inhibitor (CKI) genes involved in the progression of adipogenic differentiation, we examined changes in the protein and mRNA expression levels of CKI genes in vitro. During the onset of growth arrest associated with adipogenic differentiation, two independent families of CKI genes, p27Kip1 and p18INK4c, were significantly increased. The expressions of p27Kip1 and p18INK4c, regulated at the level of protein and mRNA accumulation, were directly coupled to adipogenic differentiation. This finding was supported by the inhibition of adipogenic differentiation caused by short interfering RNA (siRNA). In this study, we investigated the regulatory effects of transforming growth factor beta-1 (TGFbeta-1) on CKI genes involved in adipogenic differentiation of bone marrow-derived human mesenchymal stem cells (hMSCs). Only the up-regulation of p18INK4c during adipogenic differentiation, and not that of the p27Kip1 gene was prevented by treatment with TGFbeta-1, one of the factors that inhibit adipogenesis in vitro. This finding indicates a close correlation between adipogenic differentiation and p18INK4c induction in hMSCs. Thus, these data demonstrate a role for the differentiation-dependent cascade expression of cyclin-dependent kinase inhibitors in regulating adipogenic differentiation, thereby providing a molecular mechanism that couples growth arrest and differentiation.

Analysis of gene expression profiles in insulin-sensitive tissues from pre-diabetic and diabetic Zucker diabetic fatty rats.

Insulin resistance occurs early in the disease process, preceding the development of type 2 diabetes. Therefore, the identification of molecules that contribute to insulin resistance and leading up to type 2 diabetes is important to elucidate the molecular pathogenesis of the disease. To this end, we characterized gene expression profiles from insulin-sensitive tissues, including adipose tissue, skeletal muscle, and liver tissue of Zucker diabetic fatty (ZDF) rats, a well characterized type 2 diabetes animal model. Gene expression profiles from ZDF rats at 6 weeks (pre-diabetes), 12 weeks (diabetes), and 20 weeks (late-stage diabetes) were compared with age- and sex-matched Zucker lean control (ZLC) rats using 5000 cDNA chips. Differentially regulated genes demonstrating > 1.3-fold change at age were identified and categorized through hierarchical clustering analysis. Our results showed that while expression of lipolytic genes was elevated in adipose tissue of diabetic ZDF rats at 12 weeks of age, expression of lipogenic genes was decreased in liver but increased in skeletal muscle of 12 week old diabetic ZDF rats. These results suggest that impairment of hepatic lipogenesis accompanied with the reduced lipogenesis of adipose tissue may contribute to development of diabetes in ZDF rats by increasing lipogenesis in skeletal muscle. Moreover, expression of antioxidant defense genes was decreased in the liver of 12-week old diabetic ZDF rats as well as in the adipose tissue of ZDF rats both at 6 and 12 weeks of age. Cytochrome P450 (CYP) genes were also significantly reduced in 12 week old diabetic liver of ZDF rats. Genes involved in glucose utilization were downregulated in skeletal muscle of diabetic ZDF rats, and the hepatic gluconeogenic gene was upregulated in diabetic ZDF rats. Genes commonly expressed in all three tissue types were also observed. These profilings might provide better fundamental understanding of insulin resistance and development of type 2 diabetes.

Ribozyme-mediated cleavage of the human survivin mRNA and inhibition of antiapoptotic function of survivin in MCF-7 cells.

Survivin is a new member of the inhibitor of apoptosis protein (IAP) family that is implicated in the control of cell proliferation and the regulation of cell life span. This protein is selectively expressed in most human carcinomas but not in normal adult tissues. To down-regulate a human survivin expression as a strategy for cancer gene therapy, we designed two hammerhead ribozymes (RZ-1, RZ-2) targeting human survivin mRNA. RZ-1 and RZ-2 efficiently cleaved the human survivin mRNA at nucleotide positions +279 and +289, which was identified by in vitro cleavage assay using in vitro transcribed ribozymes and truncated survivin mRNA substrate. To investigate the function of the ribozymes in cells, the sequences of the ribozymes were cloned into replication-deficient adenoviral vector and transferred to breast cancer cell, MCF-7. The infection with adenovirus encoding the ribozymes resulted in a significant reduction of survivin mRNA (74% and 73%, respectively) and protein. As revealed by nuclear condensation/ fragmentation and flow cytometry analysis, inhibition of survivin gene by ribozymes increased apoptosis and sensitivity induced by etoposide or serum starvation. Our results suggest that the designed hammerhead ribozymes against survivin mRNA are good candidates for feasible gene therapy in the treatment of cancer.

Biodistribution and in vivo efficacy of genetically modified human mesenchymal stem cells systemically transplanted into a mouse bone fracture model.

Human mesenchymal stem cells (hMSCs) have generated a great deal of interest in clinical application due to their ability to undergo multi-lineage differentiation. Recently, ex vivo genetic modification of hMSCs was attempted to increase their differentiation potential. The present study was conducted to evaluate the biodistribution and in vivo efficacy of genetically modified hMSCs. To accomplish this, Runx2, which is a key transcription factor associated with osteoblast differentiation, was transduced into hMSCs using lentiviral vectors expressing green fluorescent protein (GFP) or luciferase. Here, we developed an experimental fracture in mice femur to investigate the effects of Runx2-transduced hMSCs on bone healing and migration into injury site. We conducted bio-luminescence imaging (BLI) using luciferase-tagged vector and quantitative real-time PCR using GFP probe to investigate the biodistribution of Runx2-transduced hMSCs in the fracture model. The biodistribution of hMSC cells in the fractured femur was observed at 14 days post-transplantation upon both BLI imaging and real-time PCR. Moreover, the fractured mice transplanted with Runx2-transduced hMSCs showed superior bone healing when compared to mock-transduced hMSC and MRC5 fibroblasts which were used as control. These data suggested that transplanted genetically modified hMSCs systemically migrate to the fractured femur, where they contribute to bone formation in vivo.

Telomerase reverse transcriptase related with telomerase activity regulates tumorigenic potential of mouse embryonic stem cells.

Embryonic stem cell (ESC) research gave rise to the possibility that stem cell therapy could be used in the treatment of incurable diseases such as neurodegenerative disorders. However, problems related to the tumorigenicity of undifferentiated ESCs must be resolved before such cells can be used in the application of cell replacement therapies. In the present study, we attempted to determine biomarkers that predicted tumor formation of undifferentiated ESCs in vivo. We differentiated mouse ESCs (R1 cell line) into neural lineage using a 5-step method, and evaluated the expression of oncogenes (p53, Bax, c-myc, Bcl2, K-ras), telomerase-related genes (TERT, TRF), and telomerase activity and telomere length during differentiation of ESCs. The expression of oncogenes did not show a significant change during differentiation steps, but the expression of telomerase reverse transcriptase (TERT) and telomerase activity correlated with mouse ESCs differentiation. To investigate the possibility of mouse TERT (mTERT) as a biomarker of tumorigenicity of undifferentiated ESCs, we established mTERT knockdown ESCs using the shRNA lentivirus vector and evaluated its tumorigenicity in vivo using nude mice. Tumor volumes significantly decreased, and appearances of tumor formation in mice were delayed in the TERT-knockdown ESC treated group compared with the undifferentiated ESC treated group. Altogether, these results suggested that mTERT might be potentially beneficial as a biomarker, rather than oncogenes of somatic cells, for the assessment of ESCs tumorigenicity.

Characterization and biodistribution of human mesenchymal stem cells transduced with lentiviral-mediated BMP2.

Recently, the genetic modification of mesenchymal stem cells (MSCs) has led to increased differentiation potential. For the therapeutic application of genetically modified MSCs, it is crucial to evaluate their characteristics and safety. In this study, we investigated the effects of bone morphogenetic protein 2 (BMP2) gene transfer on the characteristics and biodistribution of human MSCs. Lentiviral-mediated BMP2 transduction to MSCs enhanced osteocyte differentiation and decreased adipocyte differentiation. Although there is no significant difference in cell proliferation capacity, MSCs transduced BMP2 proliferate somewhat higher than nontransduced or GFP transduced MSCs. No significant changes were observed in surface antigen expression in genetically modified MSCs. In vivo transplantation of lentiviral-mediated BMP2 gene transferred MSCs to nude mice did not result in tumor formation. To evaluate the biodistribution of genetically modified cells, MSCs carrying BMP2 were injected into the tail vein of femur fractured mice. The introduced MSCs were detected in the spleen, testis and fractured femur 28 days post-implantation. These findings suggest that diverse safety tests for genetically modified MSCs should be considered, particularly when a lentivirus mediated gene transfer method is used.

Stable siRNA-mediated silencing of antizyme inhibitor: regulation of ornithine decarboxylase activity.

Ornithine decarboxylase (ODC) is the rate-limiting enzyme involved in the biosynthesis of polyamines essential for cell growth and differentiation. Aberrant upregulation of ODC, however, is widely believed to be a contributing factor in tumorigenesis. Antizyme is a major regulator of ODC, inhibiting ODC activity through the formation of complexes and facilitating degradation of ODC by the 26S proteasome. Moreover, the antizyme inhibitor (AZI) serves as another factor in regulating ODC, by binding to antizyme and releasing ODC from ODC-antizyme complexes. In our previous report, we observed elevated AZI expression in tumor specimens. Therefore, to evaluate the role of AZI in regulating ODC activity in tumors, we successfully down-regulated AZI expression using RNA interference technology in A549 lung cancer cells expressing high levels of AZI. Two AZI siRNAs, which were capable to generate a hairpin dsRNA loop targeting AZI, could successively decrease the expression of AZI. Using biological assays, antizyme activity increased in AZI-siRNA-transfected cells, and ODC levels and activity were reduced as well. Moreover, silencing AZI expression decreased intracellular polyamine levels, reduced cell proliferation, and prolonged population doubling time. Our results directly demonstrate that downregulation of AZI regulates ODC activity, intracellular polyamine levels, and cell growth through regulating antizyme activity. This study also suggests that highly expressed AZI may be partly responsible for increased ODC activity and cellular transformation.