The prevention of diabetes by the immunomodulatory agent FTY720 (fingolimod) was studied in the LEW.1AR1-iddm (IDDM) rat, an animal model of human type 1 diabetes. Immune cell subtypes and cytokine profiles in pancreatic islets, secondary lymphoid tissue, and serum were analyzed for signs of immune cell activation. Animals were treated with FTY720 (1 mg/kg body weight) for 40 d starting on d 50 of life. Changes in gene and protein expression of cytokines, CD8 markers, monocyte chemoattractant protein-1, inducible NO synthase, and caspase 3 were evaluated. Treatment with FTY720 prevented diabetes manifestation and islet infiltration around d 60 of life, the usual time of spontaneous diabetes development. On d 120, 30 d after the end of FTY720 therapy, diabetes prevention persisted. However, six of 12 treated animals showed increased gene expression of IL-1beta, TNF-alpha, and CD8 markers in pancreas-draining lymph nodes, indicating immune cell activation. In parallel, serum concentrations of these proinflammatory cytokines were increased. These six animals also showed macrophage infiltration without proinflammatory cytokine expression in a small minority (2-3%) of islets. Interestingly, regulatory T lymphocytes were significantly increased in the efferent vessels of the pancreas-draining lymph nodes only in animals without signs of immune cell activation but not in the rats with immune cell activation. This provides an indication for a lack of protective capacity in the animals with activated immune cells. Thus, FTY720 treatment prevented the manifestation of diabetes by promoting the retention of activated immune cells in the lymph nodes, thereby avoiding islet infiltration and beta-cell destruction by proinflammatory cytokines.
Combination therapy of anti-TCR and fingolimod was effective in the reversal of T1D. Combination therapy increased the pancreatic β cell mass to normoglycemic control levels. Combination therapy leads to a full reversal of pancreatic islet infiltration. Anti-TCR monotherapy did not abolish islet infiltration. Combination therapy was successful only immediately after diabetes manifestation.
Due to shortage of donor tissue a cure for type 1 diabetes by pancreas organ or islet transplantation is an option only for very few patients. Gene therapy is an alternative approach to cure the disease. Insulin generation in non-endocrine cells through genetic engineering is a promising therapeutic concept to achieve insulin independence in patients with diabetes. In the present study furin-cleavable human insulin was expressed in the liver of autoimmune-diabetic IDDM rats (LEW.1AR1/Ztm-iddm) and streptozotocin-diabetic rats after portal vein injection of INS-lentivirus. Within 5-7 days after the virus injection of 7 × 10(9) INS-lentiviral particles the blood glucose concentrations were normalized in the treated animals. This glucose lowering effect remained stable for the 1 year observation period. Human C-peptide as a marker for hepatic release of human insulin was in the range of 50-100 pmol/ml serum. Immunofluorescence staining of liver tissue was positive for insulin showing no signs of transdifferentiation into pancreatic β-cells. This study shows that the diabetic state can be efficiently reversed by insulin release from non-endocrine cells through a somatic gene therapy approach.
Anti–tumor necrosis factor-α (TNF-α) therapy (5 mg/kg body weight), alone or combined with the T-cell–specific antibody anti–T-cell receptor (TCR) (0.5 mg/kg body weight), was performed over 5 days immediately after disease manifestation to reverse the diabetic metabolic state in the LEW.1AR1-iddm rat, an animal model of human type 1 diabetes. Only combination therapy starting at blood glucose concentrations below 15 mmol/L restored normoglycemia and normalized C-peptide. Increased β-cell proliferation and reduced apoptosis led to a restoration of β-cell mass along with an immune cell infiltration–free pancreas 60 days after the end of therapy. This combination of two antibodies, anti-TCR/CD3, as a cornerstone compound in anti–T-cell therapy, and anti–TNF-α, as the most prominent and effective therapeutic antibody in suppressing TNF-α action in many autoimmune diseases, was able to reverse the diabetic metabolic state. With increasing blood glucose concentrations during the disease progression, however, the proapoptotic pressure on the residual β-cell mass increased, ultimately reaching a point where the reservoir of the surviving β-cells was insufficient to allow a restoration of normal β-cell mass through regeneration. The present results may open a therapeutic window for reversal of diabetic hyperglycemia in patients, worthwhile of being tested in clinical trials.
Pluripotent cell lines such as embryonic stem cells are an attractive source for a potential cell replacement therapy. However, transplantation of differentiated cells harbors the risk of teratoma formation, presenting a serious health risk. To overcome this obstacle, a negative selection system was established that permits selective removal of undifferentiated cells during in vitro differentiation. Use of the HSV1 thymidine kinase and eGFP under the control of the Oct4 promoter allowed the destruction of undifferentiated ES cells by ganciclovir treatment; differentiated cells were unharmed. Clonal ES cells remained pluripotent and showed positive staining for a wide range of embryonic markers. Thus, treatment with ganciclovir during in vitro differentiation effectively removed the population of undifferentiated cells and provided a pure population of completely differentiated cells. This approach may pave the way for a safe application of ES cells in regenerative medicine in the future.
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