Although application of the Edmonton protocol has markedly improved outcomes for pancreatic islet transplantation, the insulin independence rate after islet transplantation from one donor pancreas has proven to remain low. During the isolation process and subsequent clinical transplantation, islets are subjected to severe adverse conditions that impair survival and ultimately contribute to graft failure. Pancreas preservation with the two-layer method (TLM) has proven to improve transplant results by protecting isolated islets against apoptosis through the mitochondrial pathway. However, pancreas storage with TLM cannot protect against activation of c-Jun NH 2 -terminal kinase (JNK) in isolated islets. This study investigated whether delivery of a JNK inhibitory peptide (JNKI) via the protein transduction system can prevent apoptosis of islet cells immediately after isolation. For efficient delivery of the (JNKI into isolated islets, we synthesized JNKI as a C-terminal fusion peptide with the 11-arginine protein transduction domain (11R-JNKI). 11R efficiently delivered the JNKI into isolated islets and 11R-JNKI prevented islet apoptosis immediately after isolation and improved islet graft function. These findings suggest that peptide drugs could be useful for the prevention of the impairment of islet † These authors contributed equally to this study. cells and lead to improvement in the outcomes for pancreatic islet transplantation.
Aims/hypothesis Although application of the Edmonton protocol has markedly improved the outcome for pancreatic islet transplantation, the insulin independence rate after islet transplantation from one donor pancreas has remained low. During the isolation process and subsequent clinical transplantation, islets are subjected to severe adverse conditions that impair survival and ultimately contribute to graft failure. The aim of this study was to map the c-Jun NH 2 -terminal kinase (JNK) pathway that mediates islet loss during islet transplantation and to clarify whether intraportal injection with JNK inhibitor during islet transplantation can prevent islet graft loss. Methods We measured JNK activity in the liver, fat and muscle of diabetic mice and in the liver immediately after islet transplantation. We examined the effect of intraportal injection of JNK inhibitory peptide at islet transplantation. Results JNK activity became progressively higher at least until 24 h after transplantation. The cell-permeable peptide of JNK inhibitor was delivered not only in the liver but also in other insulin target organs, preventing JNK activation in the liver at least until 24 h after transplantation and reducing JNK activity in these insulin target organs. Moreover, the peptide inhibitor prevented islet graft loss immediately after transplantation and improved islet transplant outcome. Conclusions/interpretation These findings suggest that control of the JNK pathway is extremely important in islet transplantation and that intraportal injection of JNK inhibitor during islet transplantation (addition of JNK inhibitor to transplant media) could prevent the impairment of islet cells, leading to improved outcome for pancreatic islet transplantation.
PDX-1 plays a central role in regulating insulin gene transcription and differentiation of insulin-producing cells. It was previously reported that, due to its own Antennapedia-like protein transduction domain (PTD), exogenous PDX-1 protein can permeate cells and induces insulin gene expression in pancreatic ducts, thought to be islet progenitor cells. These data suggest that PDX-1 protein transduction could be a safe and valuable strategy for facilitating differentiation of progenitor cells into insulin-producing cells without requiring gene transfer technology. Here it is shown that after an initial ionic cell-surface interaction, PDX-1 proteins are rapidly internalized by lipid raft-dependent macropinocytosis. HeLa cells were treated with both FITC-conjugated PDX-1 PTD and FM 4-64, a general fluorescent marker of endocytosis. A punctate cytoplasmic distribution of PDX-1 PTD, which colocalized with FM 4-64, was observed in treated cells. Because expression of dominant-negative dynamin-1 did not block PDX-1 PTD uptake, PDX-1 protein transduction is independent on phagocytosis and clathrin-or caveolar-mediated endocytosis. Cells were pretreated with amiloride, a specific inhibitor of the Na + /H + exchange required for macropinocytosis, or cytochalasin D, an F-actin elongation inhibitor. Treatment of cells with both macropinosome inhibitors resulted in the reduction in PDX-1 PTD transduction into vesicles, suggesting that PDX-1 PTD-mediated cellular entry occurs by lipid raft-mediated macropinocytosis. Taken together, these observations provide the mechanism of PDX-1 protein transduction and suggest that the protein transduction system could work for experimental and therapeutic strategies.
We have shown in this study that DSP-7238 is a potent DPP IV inhibitor that has high specificity for DPP IV and substrate selectivity against GLP-1. We have also found that chronic treatment with DSP-7238 improves glycaemic control and ameliorates beta-cell damage in a mouse model with impaired insulin sensitivity and secretion. These findings indicate that DSP-7238 may be a new therapeutic agent for the treatment of type 2 diabetes.
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