Elsie Zahr

Reversal of Diabetes by Pancreatic Islet Transplantation into a Subcutaneous, Neovascularized Device

Background. Transplantation of pancreatic islets for the treatment of type 1 diabetes allows for physiologic glycemic control and insulin-independence when sufficient islets are implanted via the portal vein into the liver. Intrahepatic islet implantation requires specific infrastructure and expertise, and risks inherent to the procedure include bleeding, thrombosis, and elevation of portal pressure. Additionally, the relatively higher drug metabolite concentrations in the liver may contribute to the delayed loss of graft function of recent clinical trials. Identification of alternative implantation sites using biocompatible devices may be of assistance improving graft outcome. A desirable bioartificial pancreas should be easy to implant, biopsy, and retrieve, while allowing for sustained graft function. The subcutaneous (SC) site may require a minimally invasive procedure performed under local anesthesia, but its use has been hampered so far by lack of early vascularization, induction of local inflammation, and mechanical stress on the graft. Methods. Chemically diabetic rats received syngeneic islets into the liver or SC into a novel biocompatible device consisting of a cylindrical stainless-steel mesh. The device was implanted 40 days prior to islet transplantation to allow embedding by connective tissue and neovascularization. Reversal of diabetes and glycemic control was monitored after islet transplantation. Results. Syngeneic islets transplanted into a SC, neovascularized device restored euglycemia and sustained function long-term. Removal of graft-bearing devices resulted in hyperglycemia. Explanted grafts showed preserved islets and intense vascular networks. Conclusions. Ease of implantation, biocompatibility, and ability to maintain long-term graft function support the potential of our implantable device for cellular-based reparative therapies.

Rapamycin impairs in vivo proliferation of islet beta-cells

Background. Progressive graft dysfunction is commonly observed in recipients of islet allografts treated with high doses of rapamycin. This study aimed at evaluating the effect of rapamycin on pancreatic islet cell proliferation in vivo. Methods. The murine pregnancy model was utilized, since a high rate of &bgr;-cell proliferation occurs in a well-defined time frame. Rapamycin (0.2 mg/kg/day) was given to C57BL/6 mice for 5–7 days starting on day 7.5 of pregnancy. Cell proliferation was evaluated by detection of bromodeoxyuridine incorporation by immunohistochemistry. Results. Pregnancy led to increased &bgr;-cell proliferation and islet yield with skewing in islet size distribution as well as higher pancreatic insulin content, when compared to that of nonpregnant females. These effects of pregnancy on &bgr;-cell proliferation and mass were significantly blunted by rapamycin treatment. Minimal effect of rapamycin was observed on islet function both in vivo and in vitro. Rapamycin treatment of islets in vitro resulted in reduced p70s6k phosphorylation, which was paralleled by increased ERK1/2 phosphorylation. Conclusions. Rapamycin treatment reduces the rate of &bgr;-cell proliferation in vivo. This phenomenon may contribute to impair &bgr;-cell renewal in transplanted patients and to the progressive dysfunction observed in islet graft recipients.

Prolonged allogeneic islet graft survival by protoporphyrins.

Transplantation of islets of Langerhans in patients with type 1 diabetes allows for improved metabolic control and insulin independence. The need for chronic immunosuppression limits this procedure to selected patients with brittle diabetes. Definition of therapeutic strategies allowing permanent engraftment without the need for chronic immunosuppression could overcome such limitations. We tested the effect of the use of protoporphyrins (CoPP and FePP), powerful inducers of the cytoprotective protein hemeoxygenase 1 (HO-1), on allogeneic islet graft survival. Chemically induced diabetic C57BL/6 mice received DBA/2 islets. Treatment consisted in peritransplant administration of CoPP or saline. Islets were either cultured in the presence of FePP or vehicle before implant. Short-course administration of CoPP led to long-term islet allograft survival in a sizable proportion of recipients. Long-term graft-bearing animals rejected third-party islets while accepting a second set donor-specific graft permanently, without additional treatment. Preconditioning of islets with FePP by itself led to improved graft survival in untreated recipients, and provided additional advantage in CoPP-treated recipients, resulting in an increased proportion of long-term surviving grafts. Preconditioning of the graft with protoporphyrins prior to implant resulted in reduction of class II expression. Administration of protoporphyrins to the recipients of allogeneic islets also resulted in transient powerful immunosuppression with reduced lymphocyte proliferative responses, increased proportion of regulatory cells (CD4+CD25+), decreased mononuclear cell infiltrating the graft, paralleled by a systemic upregulation of HO-1 expression. All these mechanisms may have contributed to the induction of donor-specific hyporesponsiveness in a proportion of the protoporphyrintreated animals.

The effect of simultaneous CD154 AND LFA-1 blockade on the survival of allogeneic islet grafts in nonobese diabetic mice

Background. The rate of success in clinical transplantation of islets of Langerhans has dramatically improved with perspectives of wide-scale applicability for patients with type 1 diabetes. One drawback is the need for lifelong immunosuppression, which is associated with significant side effects. Immunomodulatory strategies devoid of side effects and with tolerogenic potential, such as co-stimulatory blockade, would be a great improvement if successful. In this study, the authors have explored the effect of simultaneous blockade of CD40/CD154 and intercellular adhesion molecule (ICAM)/lymphocyte function-associated antigen (LFA)-1 interactions. Methods. Spontaneously diabetic nonobese diabetic (NOD) mice underwent transplantation with allogeneic (C57BL/6) islets and were treated with anti-CD154 monoclonal antibody (mAb) (500 &mgr;g, three doses), anti–LFA-1 mAb (100 &mgr;g, three doses), or a combination of both in the early peritransplant period. In another set of experiments, LFA-1 engagement was impaired by transplanting islets isolated from ICAM-1–knockout (KO) mice. Results. Untreated animals rejected their grafts within 10 days. LFA-1 blockade alone did not result in improved islet graft survival, whereas CD154 blockade alone increased graft survival to 18 days. Simultaneous blockade of both pathways led to significantly improved islet graft survival to 30 days (ICAM-1–KO islets plus anti-CD154), 35 days (anti–LFA-1 plus anti-CD154), and 44 days (ICAM-1–KO islets plus anti–LFA-1 plus anti-CD154). Conclusions. These data suggest that a synergistic effect for prolonged graft survival can be obtained by simultaneously targeting CD154 and LFA-1 in the challenging model of islet allotransplantation in NOD mice. The observation of similar results with anti–LFA-1 mAb and with ICAM-1–KO grafts suggests a key role of direct antigen presentation for the activation of LFA-1–driven signaling.

Long-term islet allograft survival in nonobese diabetic mice treated with tacrolimus, rapamycin, and anti-interleukin-2 antibody

Background. Nonobese diabetic (NOD) mice develop autoimmune diabetes with features similar to those observed in the human disease. The concurrence of allorecognition and recurrence of autoimmunity might explain why most of the treatments successful in preventing islet allograft destruction in other nonautoimmune combinations often fail in NOD recipients. To assess the value of the NOD mouse model for the evaluation of treatments relevant to clinical islet transplantation, the authors have tested the effect of a protocol closely resembling the one successfully used in the Edmonton clinical trial on the survival of islet allografts in NOD mice. Methods. C57BL/6 islets were transplanted under the kidney capsule of spontaneously diabetic NOD mice. Treatment consisted of a combination of rapamycin, tacrolimus, and anti–interleukin (IL)-2 monoclonal antibody. Control groups received each treatment alone, a combination of two agents, or no treatment. Results. Untreated animals invariably lost their graft within 13 days. Administration of rapamycin and tacrolimus significantly prolonged graft survival, with two of seven animals bearing a functional graft longer than 100 days. Addition of anti–IL-2 antibody therapy further improved graft survival, with six of eight grafts functioning longer than 100 days and two of eight grafts functioning longer than 200 days. Conclusions. In view of the limited success obtained with other treatments in this model, the dramatic prolongation of graft survival observed in the authors’ study, by using a therapy that mimics one successfully used in clinical trials, seems to validate the NOD mouse as a meaningful model for the study of therapeutic interventions for the prevention of islet graft loss.

Riboflavin inhibits IL-6 expression and p38 activation in islet cells.

Riboflavin is a water-soluble vitamin that reduces the production of proinflammatory mediators and oxygen radicals. Because islet β-cells are very sensitive to oxidative stress and to cytokines, we investigated the possible cytoprotective effects of riboflavin on insulinoma NIT-1 cells and on isolated rodent islets. NIT-1 cells and islets cultured in the presence or absence of 10 μM riboflavin were studied at baseline and after exposure to cytokines (TNF-α, IL-1β, INF-γ). Riboflavin treatment did not affect islet cell viability as assessed by flow cytometry for caspases activation. However, riboflavin prevented the cytokine-induced increase in IL-6 mRNA expression and p38 phosphorylation analyzed by real-time PCR and immunoassay, respectively. In summary, nontoxic doses of riboflavin prevent cytokines-induced p38 phosphorylation and IL-6 upregulation in islet cells. This observation, together with the safety profile of riboflavin in the clinical setting, makes it an appealing agent for islet cytoprotection in islet transplantation protocols.

Rapamycin Impairs β-Cell Proliferation In Vivo

During pregnancy a high rate of beta-cell proliferation occurs, making of this a useful model for the study of islet cell expansion in vivo. We used the murine pregnancy model to assess the effect of Rapamycin treatment on islet cell proliferation in vivo. Rapamycin is routinely used for the prevention of graft rejection in transplanted patients, including islet transplant recipients. As expected, pregnancy led to increased beta-cell proliferation, islet yield and skewing in size distribution after isolation and pancreatic insulin content, when compared to non-pregnant females. Rapamycin treatment resulted in reduced beta cell proliferation in pregnant mice, while minimal effects of Rapamycin treatment were observed on islet function both in vivo and in vitro. Rapamycin treatment of islets resulted in reduced phosphorylation of p70s6k, a downstream effector molecule of mTOR and increased ERK1/2 phosphorylation. In conclusion, beta-cell replication is reduced under Rapamycin treatment in vivo, suggesting that this mechanism may be operational and impair beta-cell renewal in transplanted patients.

Alpha-1 Antitrypsin Treatment of Spontaneously Diabetic Nonobese Diabetic Mice Receiving Islet Allografts

Alpha-1 antitrypsin (AAT) is a serine protease inhibitor able to prevent diabetes onset in nonobese diabetic (NOD) mice and to prolong islet allograft survival in a nonautoimmune murine model. In this study, we explored the effect of chronic administration of human AAT (hAAT) on allogeneic (C57BL/6) islet graft survival in spontaneously diabetic female NOD mice. Mice received intraperitoneal treatment with saline, Prolastin (1 or 2 mg/mouse) or Aralast (2 mg/mouse) on days -1, 0, 3, 6, and 9. Saline-treated mice rejected the grafts 10.0 +/- 2.5 days after transplantation (n = 9). Prolastin 1 mg (n = 9) and 2 mg (n = 3) resulted in rejection on 8.7 +/- 1.4 (not significant) and 13.0 +/- 4.3 days (P < .03), respectively. Aralast-treated mice showed prolongation of graft survival (13 +/- 5.9 days; n = 5; P < .03). Notably, repeated administrations of either hAAT formulation led to sudden death of a proportion of treated animals. Collectively, our preliminary data indicate that prolongation of islet allograft survival in the stringent autoimmune diabetic NOD mouse model can be achieved with hAAT monotherapy. The death of a proportion of treated animals may be consequent to immunization to hAAT and lethal hypersensitivity. Interestingly, this phenomenon was not observed in a non-autoimmune mouse strain (C57BL/6) despite extended hAAT treatment (>100 days).

Insulin2 Gene (Ins2) Transcription by NOD Bone Marrow-derived Cells Does Not Influence Autoimmune Diabetes Development in NOD-Ins2 Knockout Mice

Insulin is a critical autoantigen for the development of autoimmune diabetes in non‐obese diabetic (NOD) mice. About 80% of NOD females and 30–40% of NOD males develop diabetes. However, Insulin2 (Ins2) knockout NOD mice develop autoimmune diabetes with complete penetrance in both sexes, at an earlier age, and have stronger autoimmune responses to insulin. The severe diabetes phenotype observed in NOD‐Ins2−/− mice suggests that lack of Ins2 expression in the thymus may compromise immunological tolerance to insulin. Insulin is a prototypical tissue specific antigen (TSA) for which tolerance is dependent on expression in thymus and peripheral lymphoid tissues. TSA are naturally expressed by medullary thymic epithelial cells (mTEC), stromal cells in peripheral lymphoid tissues and bone marrow (BM)‐derived cells, mainly CD11c+ dendritic cells. The natural expression of TSA by mTEC and stromal cells has been shown to contribute to self‐tolerance. However, it is unclear whether this also applies to BM‐derived cells naturally expressing TSA. To address this question, we created BM chimeras and investigated whether reintroducing Ins2 expression solely by NOD BM‐derived cells delays diabetes development in NOD‐Ins2−/− mice. On follow‐up, NOD‐Ins2−/− mice receiving Ins2‐expressing NOD BM cells developed diabetes at similar rates of those receiving NOD‐Ins2−/− BM cells. Diabetes developed in 64% of NOD recipients transplanted with NOD BM and in 47% of NOD mice transplanted with NOD‐Ins2−/− BM (P = ns). Thus, NOD‐Ins2−/− BM did not worsen diabetes in NOD recipients and Ins2 expression by NOD BM‐derived cells did not delay diabetes development in NOD‐Ins2−/− mice.

Ischemic Preconditioning Improves Islet Recovery After Pancreas Cold Preservation

Increasing evidence supports the beneficial effects of ischemic preconditioning (IPC) of organs on subsequent ischemia. The aim of this study was to assess the effects of IPC of the pancreas on islet cell recovery after cold preservation using a rat model. The pancreas was deprived of perfusion (celiac artery and superior mesenteric artery occlusion) for 10 minutes followed by 10 minutes of reperfusion. Islet isolation was performed after 18 hours of cold ischemia. Glands undergoing IPC yielded significantly greater numbers of islets than controls. Following overnight culture, a significantly greater proportion of islets was recovered from IPC-treated pancreata. Microarray genomic analysis of pancreatic tissue revealed a significant differential expression of approximately 600 unique mRNA strands within IPC pancreata compared to only <100 unique mRNA strands within non-IPC pancreata (>2-fold change; P < .05). Proteomic analysis revealed significant differential expression of at least 5 proteins >1.5-fold change; P < .05) within the IPC vs control group. Our data indicated that IPC of the pancreas prior to cold preservation was associated with improved islet cell recovery after cold ischemia. IPC of the pancreas may represent a viable therapeutic intervention to increase islet transplantation success from a single donor and to maximize organ utilization.