Islet transplantation in experimental diabetes in the rat. III. Studies in allogeneic streptozotocin-treated rats.

Diabetes of various degrees of severity was induced experimentally in rats by different doses of streptozotocin. These animals served as recipients for isolated islets of Langerhans from allogeneic donors. The islets were transplanted to different regions in the organism by paravascular or intravascular injection. As in pancreatectomized rats, the endocrine effect of the islets was only transient and consisted of disappearance of glycosuria, normalization of blood glucose and amelioration of intravenous glucose tolerance tests. When the islets were injected intravascularly (lung, liver) the influence of the transplanted islets was observable over a longer period than after subcutaneous or another paravascular transplantation. As in pancreatectomized animals, the period of survival was markedly prolonged in rats which had received a transplant compared to those which had not. The islets responded to glucose stimulation in vivo with insulin secretion similar to that of control rats, while only a very slight elevation of the low basis levels in streptozotocin-treated rats was observed.     

Long-term survival of neonatal porcine islets in nonhuman primates by targeting costimulation pathways

We evaluated the ability of neonatal porcine islets to engraft and restore glucose control in pancreatectomized rhesus macaques. Although porcine islets transplanted into nonimmunosuppressed macaques were rapidly rejected by a process consistent with cellular rejection, recipients treated with a CD28-CD154 costimulation blockade regimen achieved sustained insulin independence (median survival, >140 days) without evidence of porcine endogenous retrovirus dissemination. Thus, neonatal porcine islets represent a promising solution to the crucial supply problem in clinical islet transplantation.     

Biphasic release of insulin from islets of Langerhans after their transplantation into the liver of rats

The ability of transplanted islets to release insulin after stimulation with glucose was analysed. Three months after islet transplantation into the liver of diabetic rats the liver was perfused in vitro with different glucose-containing perfusion fluids. Transplanted islets preserve their functional integrity for at least three months and contribute substantially to the observed amelioration of the diabetic state. They are able to release insulin after stimulation with 16 mM glucose with a typical biphasic secretion profile. Insulin containing islets were identified by light microscopy in the tissue of the liver.     

Isolated islet transplantation in experimental diabetes.

Pancreatic islets have been isolated from the exocrine pancreas of inbred rats by the collagenase digestion method. Transplantation of isolated islets into the portal venous system of streptozotocin diabetic recipients resulted in complete abrogation of the diabetic state as measured by non-fasting serum glucose level, 24 h urinary output, rate of weight gain and glucose tolerance test. Transplantation to other sites resulted in less than optimal survival and function of islets. Allogeneic islets, transplanted across weak histocompatibility barriers, can survive and function for prolonged periods of time when transplanted recipients are immunosuppressed with antilymphocyte serum (ALS). Recipients of allogeneic islets, after a period of immunosuppression with ALS, become permanently tolerant to the allografted islets and to subsequent skin grafts from similar allogeneic donors. Allografted islets are able to prevent the occurrence of diabetic renal and ophthalmic changes that occur in control diabetic animals which had not undergone transplantation.     

Ex vivo gene transfer of viral interleukin-10 to BB rat islets: no protection after transplantation to diabetic BB rats

Allogeneic and autoimmune islet destruction limits the success of islet transplantation in autoimmune diabetic patients. This study was designed to investigate whether ex vivo gene transfer of viral interleukin-10 (vIL-10) protects BioBreeding (BB) rat islets from autoimmune destruction after transplantation into diabetic BB recipients. Islets were transduced with adenoviral constructs (Ad) expressing the enhanced green fluorescent protein (eGFP), alpha-1 antitrypsin (AAT) or vIL-10. Transduction efficiency was demonstrated by eGFP-positive cells and vIL-10 production. Islet function was determined in vitro by measuring insulin content and insulin secretion and in vivo by grafting AdvIL-10-transduced islets into syngeneic streptozotocin (SZ)-diabetic, congenic Lewis (LEW.1 W) rats. Finally, gene-modified BB rat islets were grafted into autoimmune diabetic BB rats. Ad-transduction efficiency of islets increased with virus titre and did not interfere with insulin content and insulin secretion. Ad-transduction did not induce Fas on islet cells. AdvIL-10-transduced LEW.1 W rat islets survived permanently in SZ-diabetic LEW.1 W rats. In diabetic BB rats AdvIL-10-transduced BB rat islets were rapidly destroyed. Prolongation of islet culture prior to transplantation improved the survival of gene-modified islets in BB rats. Several genes including those coding for chemokines and other peptides associated with inflammation were down-regulated in islets after prolonged culture, possibly contributing to improved islet graft function in vivo. Islets transduced ex vivo with vIL-10 are principally able to cure SZ-diabetic rats. Autoimmune islet destruction in diabetic BB rats is not prevented by ex vivo vIL-10 gene transfer to grafted islets. Graft survival in autoimmune diabetic rats may be enhanced by improvements in culture conditions prior to transplantation.     

Small rat islets are superior to large islets in in vitro function and in transplantation outcomes

Barriers to the use of islet transplantation as a practical treatment for diabetes include the limited number of available donor pancreata. This project was designed to determine whether the size of the islet could influence the success rate of islet transplantations in rats. Islets from adult rats were divided into two groups containing small (diameter <125 microm) or large (diameter >150 microm) islets. An average pancreas yielded three times more small islets than large. Smaller islets were approximately 20% more viable, with large islets containing a scattered pattern of necrotic and apoptotic cells or central core cell death. Small islets in culture consumed twice as much oxygen as large islets when normalized for the same islet equivalents. In static incubation, small islets released three times more insulin under basal conditions than did large islets. During exposure to high glucose conditions, the small islets released four times more insulin than the same islet equivalencies of large islets, and five times more insulin was released by the small islets in response to glucose and depolarization with K+. Most importantly, the small islets were far superior to large islets when transplanted into diabetic animals. When marginal islet equivalencies were used for renal subcapsular transplantation, large islets failed to produce euglycemia in any recipient rats, whereas small islets were successful 80% of the time. The results indicate that small islets are superior to large islets in in vitro testing and for transplantation into the kidney capsule of diabetic rats.     

Immune attack on pancreatic islet transplants in the spontaneously diabetic BioBreeding/Worcester (BB/W) rat is not MHC restricted

Spontaneous diabetes mellitus in the BB/W rat is preceded by lymphocytic insulitis that destroys pancreatic beta cells. Cultured pancreatic islets and adrenal cortex from inbred rats of variable MHC were transplanted to RT1/u BB/W rats without allograft rejection. Islet grafts from RT1/u and non-RT1/u rats evidenced lymphocytic insulitis in BB/W recipients that became diabetic or evidenced lymphocytic insulitis within endogenous islets. These findings suggest that BB immune insulitis is not MHC restricted and may be directed against islet transplants from non-RT1/u animals.     

Overexpression of suppressor of cytokine signaling 1 in islet grafts results in anti-apoptotic effects and prolongs graft survival

AimsA significant portion of islet grafts are destroyed by apoptosis and fail to become functional after transplantation. Strategies that enhance islet resistance to apoptosis may prevent graft loss. The aim of this study was to investigate whether overexpression of suppressor of cytokine signaling 1 (SOCS1) in islet grafts could achieve an anti-apoptotic effect and prolong graft survival.Main methodsWe used a chimeric adenovirus vector (Ad5F35) to enhance SOCS1 expression in isolated rat islets, and assessed its protective action against TNF-α-induced apoptosis. After transplanting SOCS1-overexpressing islets into allogeneic recipients with streptozotocin-induced diabetes, graft survival and in situ apoptosis were analyzed using immunohistochemistry.Key findingsThe isolated rat islets infected with Ad5F35–SOCS1 showed significantly higher SOCS1 expression than Ad5F35–EGFP and mock infected islets. The Ad5F35 transfection and SOCS1 overexpression on islets did not affect their insulin secretory function. After treatment with rat TNF-α and cycloheximide in vitro, Ad5F35–-SOCS1 infected islets exhibited a lower apoptotic ratio than controls (Ad5F35–EGFP and mock infected islets). The diabetic recipients transplanted with Ad5F35–SOCS1 infected islets displayed longer time of normoglycemia than recipients transplanted with mock infected islets. Furthermore, histological analysis indicated that the infected grafts with local overexpression of SOCS1 showed decreased apoptosis in the early post-transplant period.SignificanceThese results demonstrate that overexpression of SOCS1 in islet grafts prior to transplantation can significantly protect them from apoptotic loss and prolong their survival. This approach might find a clinical counterpart.     

A Double Mechanism for the Mesenchymal Stem Cells' Positive Effect on Pancreatic Islets

The clinical usability of pancreatic islet transplantation for the treatment of type I diabetes, despite some encouraging results, is currently hampered by the short lifespan of the transplanted tissue. In vivo studies have demonstrated that co-transplantation of Mesenchymal Stem Cells (MSCs) with transplanted pancreatic islets is more effective with respect to pancreatic islets alone in ensuring glycemia control in diabetic rats, but the molecular mechanisms of this action are still unclear.The aim of this study was to elucidate the molecular mechanisms of the positive effect of MSCs on pancreatic islet functionality by setting up direct, indirect and mixed co-cultures.MSCs were both able to prolong the survival of pancreatic islets, and to directly differentiate into an “insulin-releasing” phenotype. Two distinct mechanisms mediated these effects: i) the survival increase was observed in pancreatic islets indirectly co-cultured with MSCs, probably mediated by the trophic factors released by MSCs; ii) MSCs in direct contact with pancreatic islets started to express Pdx1, a pivotal gene of insulin production, and then differentiated into insulin releasing cells. These results demonstrate that MSCs may be useful for potentiating pancreatic islets'' functionality and feasibility.     

Arginine stimulated insulin and glucagon release from islets transplanted into the liver of diabetic rats

We investigated the ability of intraportal transplanted islets to release insulin and glucagon after stimulation with arginine. Furthermore, the islet volume and hormone content of the recipient pancreas were analyzed. Three months after syngeneic portal islet transplantation the liver of STZ-diabetic rats was perfused in vitro in the presence of different arginine concentrations. Transplanted islets preserve their functional integrity for at least three months indicated by a stimulus adequate insulin release and contribute substantially to the observed amelioration of the diabetic state. The islet and B-cell volume as well as the insulin and glucagon content of the recipient pancreas are still markedly decreased three months after islet transplantation when compared with healthy controls.     

Intracranial pancreatic islet transplantation increases islet hormone expression in the rat brain and attenuates behavioral dysfunctions induced by MK-801 (dizocilpine)

The treatment of rodents with non-competitive antagonist of the N-Methyl-d-aspartate (NMDA) receptor, MK-801 (dizocilpine), induces symptoms of psychosis, deficits in spatial memory and impairment of synaptic plasticity. Recent studies have suggested that insulin administration might attenuate the cognitive dysfunctions through the modulatory effect on the expression of NMDA receptors and on the brain insulin signaling. Intrahepatic pancreatic islet transplantation is known as an efficient tool for correcting impaired insulin signaling. We examined the capacity of syngeneic islets grafted into the cranial subarachnoid cavity to attenuate behavioral dysfunctions in rats exposed to MK-801. Animals were examined in the open field (OF) and the Morris Water Maze (MWM) tests following acute or subchronic administration of MK-801. We found well-vascularized grafted islets expressing insulin, glucagon and somatostatin onto the olfactory bulb and prefrontal cortex. Significantly higher levels of insulin were detected in the hippocampus and prefrontal cortex of transplanted animals compared to the non-transplanted rats. All animals expressed normal peripheral glucose homeostasis for two months after transplantation. OF tests revealed that rats exposed to MK-801 treatment, showed hyper-responsiveness in motility parameters and augmented center field exploration compared to intact controls and these effects were attenuated by the grafted islets. Moreover, in the MWM, the rats treated with MK-801 showed impairment of spatial memory that were partially corrected by the grafted islets. In conclusion, intracranial islet transplantation leads to the expression of islet hormones in the brain and attenuates behavioral and cognitive dysfunctions in rats exposed to MK-801 administration without altering the peripheral glucose homeostasis.     

Engraftment of cells from porcine islets of Langerhans following transplantation of pig pancreatic primordia in non-immunosuppressed diabetic rhesus macaques

Transplantation therapy for human diabetes is limited by the toxicity of immunosuppressive drugs. If toxicity can be minimized, there will still be a shortage of human donor organs. Xenotransplantation of porcine islets is a strategy to overcome supply problems. Xenotransplantation in mesentery of pig pancreatic primordia obtained very early during organogenesis [embryonic day 28 (E28)] is a way to obviate the need for immunosuppression in rats or rhesus macaques and to enable engraftment of a cell component originating from porcine islets implanted beneath the renal capsule of rats. Here, we show engraftment in the kidney of insulin and porcine proinsulin mRNA-expressing cells following implantation of porcine islets beneath the renal capsule of diabetic rhesus macaques transplanted previously with E28 pig pancreatic primordia in mesentery. Donor cell engraftment is confirmed using fluorescent in situ hybridization (FISH) for the porcine X chromosome and is supported by glucose-stimulated insulin release in vitro. Cells from islets do not engraft in the kidney without prior transplantation of E28 pig pancreatic primordia in mesentery. This is the first report of engraftment following transplantation of porcine islets in non-immunosuppressed, immune-competent non-human primates. The data are consistent with tolerance to a cell component of porcine islets induced by previous transplantation of E28 pig pancreatic primordia.     

Engraftment of cells from porcine islets of Langerhans following transplantation of pig pancreatic primordia in non-immunosuppressed diabetic rhesus macaques

Transplantation therapy for human diabetes is limited by the toxicity of immunosuppressive drugs. If toxicity can be minimized, there will still be a shortage of human donor organs. Xenotransplantation of porcine islets is a strategy to overcome supply problems. Xenotransplantation in mesentery of pig pancreatic primordia obtained very early during organogenesis [embryonic day 28 (E28)] is a way to obviate the need for immunosuppression in rats or rhesus macaques and to enable engraftment of a cell component originating from porcine islets implanted beneath the renal capsule of rats. Here, we show engraftment in the kidney of insulin and porcine proinsulin mRNA-expressing cells following implantation of porcine islets beneath the renal capsule of diabetic rhesus macaques transplanted previously with E28 pig pancreatic primordia in mesentery. Donor cell engraftment is confirmed using fluorescent in situ hybridization (FISH) for the porcine X chromosome and is supported by glucose-stimulated insulin release in vitro. Cells from islets do not engraft in the kidney without prior transplantation of E28 pig pancreatic primordia in mesentery. This is the first report of engraftment following transplantation of porcine islets in non-immunosuppressed, immune-competent non-human primates. The data are consistent with tolerance to a cell component of porcine islets induced by previous transplantation of E28 pig pancreatic primordia.     

Cyclosporine-induced tolerance requires antigens capable of initiating an immune response

We studied two example where indefinite graft survival could be obtained in rats. In the first, strain DA hearts were permanently accepted in allogeneic PVG rats if the recipients were treated for at least 7 consecutive days with cyclosporine A (CsA) after transplantation. In the second, DA pancreatic islets were permanently accepted in PVG rats if the islets were cultured in vitro for 14 days in high oxygen. When cultured islet-grafted PVG rats were injected with lymphocytes from other PVG rats previously sensitized to DA alloantigens, the islet grafts were destroyed within 14 days. By contrast, it was difficult to cause the DA heart allografts to cease beating with the same adoptive transfer protocol; approximately two-thirds of the heart-grafted animals maintained their grafts. This difference was not due to the CsA as cultured islets transplanted in the presence of CsA were still susceptible to rejection by sensitized lymphocytes. However, islets that had not been cultured in high oxygen prior to transplantation and that were maintained with CsA were not rejected after the injection of sensitized lymphocytes. These results suggest that CsA can most readily induce a state of tolerance when the graft is capable of initiating an immune response.     

Beneficial effect of pretreatment of islets with fibronectin on glucose tolerance after islet transplantation.

The scarcity of available islets is an obstacle for clinically successful islet transplantation. One solution might be to increase the efficacy of the limited islets. Isolated islets are exposed to a variety of cellular stressors, and disruption of the cell-matrix connections damages islets. We examined the effect of fibronectin, a major component of the extracellular matrix, on islet viability, mass and function, and also examined whether fibronectin-treated islets improved the results of islet transplantation. Islets cultured with fibronectin for 48 hours maintained higher cell viability (0.146 +/- 0.010 vs. 0.173 +/- 0.007 by MTT assay), and also had a greater insulin and DNA content (86.8 +/- 3.6 vs. 72.8 +/- 3.2 ng/islet and 35.2 +/- 1.4 vs. 30.0 +/- 1.5 ng/islet, respectively) than islets cultured without fibronectin (control). Absolute values of insulin secretion were higher in fibronectin-treated islets than in controls; however, the ratio of stimulated insulin secretion to basal secretion was not significantly different (206.9 +/- 23.3 vs. 191.7 +/- 20.2% when the insulin response to 16.7 mmol/l glucose was compared to that of 3.3 mmol/l glucose); the higher insulin secretion was thus mainly due to larger islet cell mass. The rats transplanted with fibronectin-treated islets had lower plasma glucose and higher plasma insulin levels within 2 weeks after transplantation, and had more favorable glucose tolerance 9 weeks after transplantation. These results indicate that cultivation with fibronectin might preserve islet cell viability, mass and insulin secretory function, which could improve glucose tolerance following islet transplantation.     

Maternal protein malnutrition does not impair insulin secretion from pancreatic islets of offspring after transplantation into diabetic rats

Pancreatic islets from adult rats whose mothers were protein restricted during lactation undersecrete insulin. The current work analyzes whether this secretory dysfunction can be improved when the pancreatic islets are grafted into hyperglycemic diabetic rats. Two groups of rats were used: the adult offspring from dams that received a low protein diet (4%) during the initial 2/3 of lactation (LP) and, as a control, the adult offspring from dams that consumed a normal protein diet (23%) during the entire period of lactation (NP). Islets from NP- and LP-rats were transplanted into diabetic recipient rats, which were generated by streptozotocin treatment. The islets were transplanted via the portal vein under anesthesia. The fed blood glucose levels were monitored during the 4 days post-transplantation. Transplanted islets from LP-rats (T LP) decreased the fed glucose levels of diabetic rats 34% (21.37 ± 0.24 mM, p<0.05); however, the levels still remained 2-fold higher than those of the sham-operated controls (6.88 ± 0.39 mM, p<0.05). Grafts with NP-islets (T NP) produced the same effect as the LP-islets in diabetic rats. The high fasting blood glucose levels of diabetic rats were improved by the transplantations. Islet grafts from both rat groups recovered 50% of the retroperitoneal fat mass of the diabetic rats (0.55 ± 0.08 g/100 g of body weight for T NP and 0.56 ± 0.07 g/100 g of body weight for T LP, p<0.05). Because pancreatic islets from both the NP- and LP-rats were able to regulate fasting blood glucose concentrations in hyperglycemic rats, we propose that the altered function of pancreatic islets from LP-rats is not permanent.     

Cold storage preservation of islet and pancreas grafts as assessed by in vivo function after transplantation to diabetic hosts

The major goal of hypothermic (4–8 °C) preservation of intact pancreases or isolated islets will be to provide sufficient time for HLA typing, cross matching, selection, and preparation of recipients—logistical efforts requiring 12–72 hr for clinical kidney transplantation, usually <48 hours. Some investigators have studied in vitro function of islets after cold storage, but the critical test of viability—permanent restoration of normoglycemia after transplantation to diabetic recipients—has been tested in only a few experiments. Reversal of hyperglycemia by syngeneic or autogenic transplants in diabetic animals has been achieved after CS of dispersed pancreatic tissue from neonatal rats in GIB media for ? 146 hr, adult dogs in TCM 199 for ?24 hr, and adult DL-ethionine-treated rats in RPMI 1640 for ?72 hr. In the neonatal rat donor model, intravenous glucose tolerance test (IVGTT) results were similar in recipients of fresh or stored islets; in the dog model, IVGTT test results were variable, but generally inferior in recipients of stored as compared to fresh islets; in the adult rat donor model, recipients of ?24-hr coldstorage islets had insulin and IVGTT K values similar to those of recipients of fresh islets, but the success rate progressively declined for CS times >24 hr. Various agents were added to the media, but the need or the optimal concentrations were not critically determined by using different recipes for different groups of recipients. Cold storage of intact pancreas autografts has been tested in dogs; simple electrolyte solutions are satisfactory for 24 hr, but only a silica gel-filtered plasma-based solution has been reliable for 48 hr. Pulsatile machine perfusion (PMP) of canine pancreas grafts for 24 hr has had a success rate similar to CS in some experiments and lower in others. PMP has been almost totally unreliable for >24 hr. Further refinements are needed if preservation of islets for >24 hr and pancreases for >48 hr are to be consistently successful. If current experimental techniques are effective for human islets or pancreases, however, these times are sufficient to complete the logistical maneuvers required before transplantation.     

Transplantation and in vitro perifusion of rat islets of Langerhans after slow cooling and warming in the presence of either glycerol or dimethyl sulfoxide

The cryoprotectants dimethyl sulfoxide (Me2SO) and glycerol have been used for the cryopreservation of fetal rat pancreases but only Me2SO has been reported for the cryopreservation of adult rat islets. Since glycerol may be preferred to Me2SO for clinical use, this study was undertaken to compare the effectiveness of these cryoprotectants during the slow cooling of isolated adult rat islets. Islets of Langerhans prepared from the pancreases of WAG rats by collagenase digestion were stored at -196 degrees C after slow cooling (0.3 degrees C/min) to -70 degrees C in the presence of multimolar concentrations of either Me2SO or glycerol. Samples were rewarmed slowly (approximately 10 degrees C/min) and dilution of the cryoprotectant was achieved using medium containing sucrose. Function was assessed by determination of the time course of the glucose-induced insulin release during in vitro perifusion at 37 degrees C and also by isograft transplantation. Transplants were carried out by intraportal injection of a minimum of 1700 frozen and thawed islets into streptozotocin-induced diabetic recipients and tissue function was assessed by monitoring blood glucose levels and body weight changes. Without exception the islets frozen and thawed in the presence of glycerol failed to reduce high serum glucose levels of recipient rats and in vitro dynamic release curves showed to demonstrate a glucose-sensitive insulin release pattern. Reversal of the diabetic conditions was achieved in two of five animals receiving islets which had been frozen and thawed with 2 M Me2SO; and in one of three animals receiving islets cryopreserved with 3 M Me2SO. Nevertheless, perifusion studies showed that the pattern of insulin secretion from groups of cryopreserved islets which did show an ability to secrete insulin was atypical compared with that of untreated controls, suggesting that the tissue was altered or damaged in some way.     

Piscine islet xenotransplantation

Tilapia, a teleost fish species with large anatomically discrete islet organs (Brockmann bodies; BBs) that can be easily harvested without expensive and fickle islet isolation procedures, make an excellent donor species for experimental islet xenotransplantation research. When transplanted into streptozotocin-diabetic nude or severe combined immunodeficient mice, BBs provide long-term normoglycemia and mammalian-like glucose tolerance profiles. However, when transplanted into euthymic recipients, the mechanism of islet xenograft rejection appears very similar to that of islets from "large animal" donor species such as the very popular fetal/neonatal porcine islet cell clusters (ICCs). Tilapia islets are more versatile than ICCs and can be transplanted (1) into the renal subcapsular space, the cryptorchid or noncryptorchid testis, or intraportally as neovascularized cell transplants; (2) as directly vascularized organ transplants; or (3) intraperitoneally after microencapsulation. Unlike the popular porcine ICCs, BBs function immediately after transplantation; thus, their rejection can be assessed on the basis of loss of function as well as other parameters. We have also shown that transplantation of tilapia BBs into nude mice can be used to study the possible implications of cross-species physiological incompatibilities in xenotransplantation. Unfortunately, tilapia BBs might be unsuitable for clinical islet xenotransplantation because tilapia insulin differs from human insulin by 17 amino acids and, thus, would be immunogenic and less biologically active in humans. Therefore, we have produced transgenic tilapia that express a "humanized" tilapia insulin gene. Future improvements on these transgenic fish may allow tilapia to play an important role in clinical islet xenotransplantation.