Prolonged survival of rat liver allografts transfected with Fas ligand-expressing plasmid

BACKGROUND: Transplantation of Fas ligand (FasL) gene-transfected tissues can have opposite effects. For example, cotransplantation of pancreas islets with myoblasts transfected with FasL-expressing plasmid vector (pFasL) prevented graft rejection, whereas the expression of FasL directly within islets using adenovirus vector led to graft destruction. It was also reported that FasL expression on pancreas islets led to neutrophilic infiltration and rapid destruction of the islets. From these results, overexpression of FasL in transfected tissues may lead directly to self destruction through an autocrine Fas-FasL pathway or graft destruction through neutrophil recruitment. To date there have been no reports of successful transplantation of FasL gene-transfected solid organs. METHODS: Rat pFasL was transfected at a dose of 90, 180, 270, or 360 microg into rat liver with an inactivated hemagglutinating virus of Japan conjugated to liposome vesicles (HVJ-liposome), and the gene-transfected livers were transplanted to allogeneic rats. RESULTS: In 18 rats transfected with 180 microg of pFasL, 14 (78%) did not develop fulminant hepatitis. FasL-mRNA was detected in these livers at 3, 5, 7, and 14 days after transfection. The expression of FasL protein was also observed in the transfected liver, and the transfection rate by this method was 11.1+/-1.9%. The livers were then transplanted to allogeneic recipients, resulting in significant (P<0.01) prolonged recipient survival times. Histological observation showed that the pFasL-transfected liver allografts caused apoptotic cell death in infiltrating activated T cells. In contrast, transfection of pFasL higher than 180 microg resulted in lethal hepatitis in all rats, and its low dose (90 microg) did not induce the hepatitis or prolong recipient survival. CONCLUSION: Our results indicate that rat liver allografts can be protected to host immune responses by an adequate level (approximately 10%) of FasL expression in the livers using HVJ-liposome incorporating pFasL.     

Minimum number of islets required to maintain euglycemia and their reduced immunogenicity after transplantation into diabetic mice

In streptozocin (SZ)-induced diabetic mice, 200 islets, but not 50 islets, consistently restore euglycemia within 1 week of transplantation. To determine the minimum number of islets sufficient to maintain euglycemia in a diabetic mouse, we first transplanted 50 and 150 syngeneic islets simultaneously into the right (RK) and left kidney (LK), respectively, and then removed the LK 1 week post-transplantation. The remaining 50 islets maintained euglycemia in 8 of 11 mice with normal intravenous glucose tolerance tests (IVGTT). Protection of 50 islets for at least 7 days was necessary because removal of the 150 islets at 5 or 3 days resulted in a much lower incidence of persistent euglycemia. Similarly, 25 islets were capable of maintaining euglycemia in 2 of 9 mice once hyperglycemia was reversed by split-transplantation of 25 (RK) and 175 (LK) islets. To examine if 50-islet allografts survive longer than 200-islet allografts, we split-transplanted 50 DBA/2 islets in the RK and 150 islets of either B6 (syngeneic), DBA/2 (allogeneic), or C3H/He (third party allogeneic) mouse origin in the LK in 3 groups of diabetic C57BL/6 (B6) mice. The survival of 50 DBA/2 islets in each group after removal of the LK on day 7 was compared to that of 200 DBA/2 islets in control B6 mice. Maximum prolongation of allograft survival was obtained with 50 DBA/2 islets that were split-transplanted with syngeneic B6 islets. These results clearly demonstrate that 50 islets are sufficient to maintain normal glucose tolerance once euglycemia is induced by transplantation of a larger number (i.e., 200) of islets and that 50 islet allografts are much less immunogenic than 200-islet allografts.     

Interleukin-4 or interleukin-10 expressed from adenovirus-transduced syngeneic islet grafts fails to prevent beta cell destruction in diabetic NOD mice

BACKGROUND: We performed ex vivo adenoviral gene transfer in a mouse pancreatic islet transplant model to test the efficacy of this expression system. We then determined whether adenoviral-mediated expression of mouse interleukin (IL) 4 or IL-10 from transduced syngeneic islet grafts could prevent disease recurrence in diabetic nonobese diabetic (NOD) mice. METHODS: An adenoviral vector expressing beta-galactosidase (AdCMV betaGal) was used to transduce BALB/c islets (2.5 x 10(3) plaque-forming units/islet), which were analyzed for glucose responsiveness, islet cell recovery, and efficiency of gene transfer. In vivo function and reporter gene expression were examined with AdCMV betaGal-transduced islet grafts in alloxan-induced diabetic syngeneic recipients. Adenoviruses expressing either IL-4 or IL-10 were used in a similar fashion to infect NOD islets, which were characterized in vitro, as well as transplanted into diabetic syngeneic recipients. RESULTS: In vitro functional studies showed no significant difference between control or transduced islets, with 50+/-4% of AdCMV betaGal-infected islet cells staining positive for beta-galactosidase. Transplant recipients became nomoglycemic within 48 hr after transplant, and, although beta-galactosidase expression decreased over time, it was detectable in the graft for up to 8 weeks. Despite the nanogram quantities of IL-4 or IL-10 produced/day from each graft equivalent in vitro, transduced and transplanted NOD islets failed to prevent disease recurrence. CONCLUSIONS: These results suggest that adenoviruses are efficient for at least medium term gene expression from islets in vivo, but neither IL-4 nor IL-10 alone can prevent autoimmune disease recurrence in NOD mice.     

Synergistic effect of microencapsulation and immunoalteration on islet allograft survival in bioartificial pancreas

Recently, we reported successful transplantation (Tx) of microencapsulated (mc) islets. However, graft failure observed in several cases was associated with an increased foreign body reaction compared to long-term functioning grafts. This study was performed to investigate the impact of an immunoalterating islet pretreatment (12-14 days culture at 22 degrees C) on graft function. After microencapsulation in barium alginate beads the islets were cultured for another day. Diabetic LEWIS rats (blood glucose >19 mM) were transplanted with 3500 immunoaltered mc-Wistar islets intraperitoneally. Controls were transplanted with 3500 non-cultured syngeneic or allogeneic mc-islets. Additional syngeneic and allogeneic controls were transplanted with 6000 non-cultured, non-encapsulated islets intraperitoneally. Seventy percent of the recipients of microencapsulated, long-term low temperature cultured islets maintained normoglycemia at least for 15 weeks, while this was true in only 17% of those animals receiving microencapsulated non-pretreated allogeneic islets. Islets in non-encapsulated controls were rejected within several days. Graft function correlated with histologically proven viable islets within the capsules. Microencapsulation of islets markedly prolonged allograft survival compared to non-encapsulated islets; application of an immunoaltering low-temperature culture further improved graft function significantly. These data may support the hypothesis of induction of a reaction against microcapsules by the antigen release from the graft which may be avoided by immunoaltering islet pretreatment.     

Love, courage, and honor

OBJECTIVES: Despite the increasing success of whole-organ pancreas transplantation, the success of clinical islet allografts has remained limited. One of the factors limiting the success is the difficulty in monitoring islet allografts after transplantation. The aim of these studies is to develop a method of "biopsying" human islet allografts using a forearm islet implantation site. METHODS: A subtherapeutic number of isolated human islets were placed in the forearm under the muscle fascia in three human recipients with Type I insulin dependent diabetes. All of the recipients had undergone successful cadaveric renal transplantation at least one year prior and were maintained on their baseline immunosuppression. Aliquots of the islet grafts were removed 7 and 14 days to assess engraftment and graft infiltrate. To verify that the islets were viable, 400 were handpicked and transplanted into B6-scid mice made diabetic with streptozotocin. RESULTS: The biopsy site was found in all three cases. In one patient, no islets were recovered. In two other patients, viable islet tissue was recovered 7 days after transplantation. Immunohistology at 7 days showed the presence of both insulin and glucagon-staining cells in the islets. At 14 days in these two patients, a mononuclear cell infiltrate was observed in the explanted islet biopsies. Immunohistology showed the relative absence of insulin-staining cells with intact glucagon-staining cells. This finding is consistent with recurrent autoimmunity in the islet grafts. DISCUSSION: This preliminary study shows that the forearm biopsy site is a useful method to retrieve human islet grafts after transplantation. The islets engraft and are easily found in the first weeks after transplantation. These data suggest that recurrent autoimmunity may affect islet allografts. Further studies will be needed to determine if the histology in the forearm will correlate with the fate of intraportal or intraperitoneal islet allografts. Although they were shown to reduce the incidence of early allograft failure, their influence on the long-term graft survival remains to be proven.     

Characterization of mixed syngeneic-allogeneic and syngeneic-xenogeneic islet-graft rejections in mice. Evidence of functional impairment of the remaining syngeneic islets in xenograft rejections

Allogeneic mouse islets or xenogeneic rat islets, or fetal porcine islets were implanted under the renal capsule of C57BL/6 mice either alone or carefully mixed with syngeneic islets. With this experimental model the syngeneic islets, although not rejected themselves, are exposed to cytokines and inflammatory mediators released during either allograft or xenograft rejection. No differences in insulin content could be observed between mixed islet grafts and pure syngeneic islet grafts 6 wk after transplantation. Neither was there any morphological evidence of a non-specific destruction of syngeneic islets. These findings suggest that the mechanisms of both allograft and xenograft rejections are highly specific. The hormone release from the mixed syngeneic-allogeneic grafts was similar to that from pure syngeneic islet grafts. In contrast, a pronounced impairment of both the first and second phases of insulin release was observed 2 wk after implantation in mixed syngeneic-xenogeneic islet grafts. When perfusing the mixed islet graft after completed rejection of the concordant xenogeneic rat islets (6 wk after implantation), the insulin release from the remaining syngeneic mouse islets was identical to that of control grafts. However, syngeneic mouse islets exposed to the rejection mechanism of the discordant xenogenic pig islet-like cell clusters did not attain a complete functional recovery.     

Possible use of erythrocyte antioxidant enzymes as markers of the course of disease in patients with hemoblastoses

Induction of tolerance to fully major histocompatibility complex (MHC)-mismatched rat islet allografts implanted at two different islet transplant sites (liver and kidney capsule [KC]) was examined. Streptozotocin-induced diabetic Lewis (RT1(1)) rats remained hyperglycemic (> 200 mg/dl) after intrahepatic preimmunization by injection of 200 low-temperature cultured (24 degrees C for 7 days) Wistar-Furth (WF, RT1u) rat islets into the portal vein with one injection (1 ml) of rat antilymphocyte serum intraperitoneally. Three weeks later, 1,200 WF islets that had been cultured to remove passenger lymphoid cells were transplanted into the liver via the portal vein or under the KC. The intrahepatic transplants survived 60.2 +/- 11.9 days, and all six of the KC transplants maintained normoglycemia for > 100 days after the preimmunization regimen. In contrast, survival of fresh islet transplants was not significantly improved by this preimmunization protocol at either transplantation site. This study demonstrates that indefinite islet allograft survival can be achieved across a full MHC mismatch by intrahepatic preimmunization with a small number of cultured donor islets and a brief period of immunosuppression followed by transplantation of low-temperature cultured donor islets.     

Selective training of the vastus medialis muscle using electrical stimulator for chondromalacia patella

Islet allografts transplanted into Type I diabetic recipients may be destroyed by allorejection or recurrent autoimmune diabetes. We studied islet transplantation in three murine models in order to determine the relative sensitivity of autoimmunity and alloimmunity to two immunosuppressive agents that may be useful in clinical islet transplantation: 15-deoxyspergualin (DSG) and anti-CD4 antibody (GK 1.5). In the model in which only allorejection occurs (BALB/c islets transplanted into streptozotocin-induced diabetic CBA or streptozotocin-induced diabetic NOD recipients), both DSG and anti-CD4 antibody treatment led to indefinite survival of allogeneic islets (>100 days in both treatments). In the second model in which only recurrent autoimmunity can destroy islet grafts (islets from NOD donors transplanted into spontaneously diabetic NOD recipients), only anti-CD4 treatment caused prolonged graft survival [MST 36.7 +/- 6.8 days vs 9.8 +/- 1.8 days (controls), P < 0.0002]. Treatment with DSG did not cause any increase in graft survival (MST 12.6 +/- 5.4 days, NS). Finally, using a model in which both autoimmunity and allorejection may occur (BALB/c to spontaneously diabetic NOD mice), treatment with anti-CD4 caused marked graft prolongation [42.0 +/- 14.5 days vs 7.2 +/- 0.8 days (control), P < 0.002] while DSG again did not prolong graft survival with respect to untreated recipients (9.8 +/- 3.0, NS). We conclude that recurrent autoimmunity in the NOD mouse involves a CD4+ T cell that is not sensitive to DSG. Anti-CD4 antibody may be useful in human clinical islet transplantation trials because it seems to prevent both allorejection and recurrent autoimmunity.     

Accelerated rejection of Fas ligand-expressing heart grafts

The Fas/Fas ligand (FasL) system plays an important role in the induction of lymphoid apoptosis and has been implicated in the suppression of immune responses. Recently, there has been renewed interest in immune privilege, as it was shown that two privileged sites (the eye and testes) constitutively express FasL, which kills lymphoid cells that invade these areas. We have established murine FasL-transgenic mice (B6) under the control of the cardiac alpha-myosin heavy chain promotor, and transplanted FasL-expressing F1(B6 x C3H/HeJ) heart grafts into syngeneic (F1) and allogeneic (C3H/HeJ) recipients. FasL-expressing F1 heart allografts placed in C3H/HeJ recipients as well as FasL-expressing F1 isografts placed in nontransgenic and FasL-transgenic F1 were more rapidly rejected, and their survival was much shorter than that of nontransgenic control F1 allografts placed in C3H/HeJ. Native control and FasL-expressing hearts looked normal in mice up to 8 wk of age on hematoxylin-eosin staining. Control heart allografts undergoing ordinally acute rejection showed moderate focal lymphocyte infiltrates, while FasL-expressing F1 allografts and isografts showed massive hemorrhage, edema, and massive neutrophil infiltration as early as 1 day after transplantation. In conclusion, FasL expression and surgical procedure (ischemia/reperfusion) were synergistic in the induction of accelerated heart graft rejection, while allogenicity was not necessary. It may be necessary to find ways of controlling neutrophilic reaction/apoptosis in infiltrating lymphocytes to use FasL in clinical organ transplantation.     

Long-term expression, systemic delivery, and macrophage uptake of recombinant human glucocerebrosidase in mice transplanted with genetically modified primary myoblasts

A critical requirement for treatment of Gaucher disease via systemic delivery of recombinant GC is that secreted enzyme be in a form available for specific takeup by macrophages in vivo. In this article we investigated if transplanted primary myoblasts can sustain expression of human GC in vivo and if the secreted transgene product is taken up by macrophages. Transduced primary murine myoblasts were implanted into syngeneic C3H/HeJ mice. The results demonstrated that transplanted mice sustained long-term expression of transferred human GC gene in vivo. Furthermore, human GC is secreted into the circulation of mice transplanted with syngeneic primary myoblasts retrovirally transduced with human GC cDNA. The transplanted primary myoblasts differentiate and fuse with adjacent mature myofibers, and express the transgene product for up to 300 days. Human GC in the circulation reaches levels of 20-280 units/ml of plasma. Immunohistochemical studies of the target organs revealed that the secreted human GC is taken up by macrophages in liver and bone marrow. Immunochemical identification of reisolated myoblasts from transplanted mice showed that MFG-GC-transduced cells also survived as muscle stem cells in the implanted muscle. These results present in encouraging prospect for the treatment of Gaucher disease.     

Markedly improved survival in malignant sacro-coccygeal teratomas--16 years, experience

Addition of 10% albumin to the digestion medium has been suggested to enhance yield and integrity of harvested islets by inhibition of proteolytic activities and to improve endocrine function early after transplantation. The aim of this study was to evaluate in vivo by means of intravital fluorescence microscopy whether this rapid reversal of hyperglycemia after transplantation is due to improved graft vascularization. Pancreatic islets were isolated from Syrian golden hamsters by collagenase digestion using either solely Hank's balanced salt solution (HBSS) or HBSS supplemented with 10% human serum albumin. Islets were then transplanted into the dorsal skinfold chamber of syngeneic animals (control: N = 8 animals, n = 50 islets; albumin: N = 7, n = 41). The grafts' microvasculature was analysed on days 6, 10, and 14 after transplantation. Immunohistochemical staining for insulin was performed at the end of the microscopic observation period. Islet isolation with albumin supplementation did not increase islet yield. However, photomicroscopic analysis suggested a beneficial effect on the isolation process with improved islet integrity and prevention of outer margin irregularities, in particular in large islets. Analysis of revascularization 6 days after transplantation revealed in the control group a functional capillary density (FCD) of 477 +/- 47 cm-1. On day 10 FCD increased to 680 +/- 42 cm-1 with no further changes on day 14, indicating complete revascularization. Islets in the albumin group demonstrated a comparable FCD of 598 +/- 49 cm-1 on day 10 and complete revascularization on day 14 (655 +/- 45 cm-1). The angio-architecture of the islets was found similar in both groups, presenting with a glomerulum-like capillary network, comparable to that of pancreatic islets in situ. We conclude that the addition of 10% serum albumin to the collagenase digestion medium improves the preservation of the structural integrity of isolated pancreatic islets, however, does not influence the process of graft vascularization. Thus, improved early graft function may rather be due to superior preservation of islet cell integrity and function.     

Primary mouse myoblast purification, characterization, and transplantation for cell-mediated gene therapy

The transplantation of cultured myoblasts into mature skeletal muscle is the basis for a new therapeutic approach to muscle and non-muscle diseases: myoblast-mediated gene therapy. The success of myoblast transplantation for correction of intrinsic muscle defects depends on the fusion of implanted cells with host myofibers. Previous studies in mice have been problematic because they have involved transplantation of established myogenic cell lines or primary muscle cultures. Both of these cell populations have disadvantages: myogenic cell lines are tumorigenic, and primary cultures contain a substantial percentage of non-myogenic cells which will not fuse to host fibers. Furthermore, for both cell populations, immune suppression of the host has been necessary for long-term retention of transplanted cells. To overcome these difficulties, we developed novel culture conditions that permit the purification of mouse myoblasts from primary cultures. Both enriched and clonal populations of primary myoblasts were characterized in assays of cell proliferation and differentiation. Primary myoblasts were dependent on added bFGF for growth and retained the ability to differentiate even after 30 population doublings. The fate of the pure myoblast populations after transplantation was monitored by labeling the cells with the marker enzyme beta-galactosidase (beta-gal) using retroviral mediated gene transfer. Within five days of transplantation into muscle of mature mice, primary myoblasts had fused with host muscle cells to form hybrid myofibers. To examine the immunobiology of primary myoblasts, we compared transplanted cells in syngeneic and allogeneic hosts. Even without immune suppression, the hybrid fibers persisted with continued beta-gal expression up to six months after myoblast transplantation in syngeneic hosts. In allogeneic hosts, the implanted cells were completely eliminated within three weeks. To assess tumorigenicity, primary myoblasts and myoblasts from the C2 myogenic cell line were transplanted into immunodeficient mice. Only C2 myoblasts formed tumors. The ease of isolation, growth, and transfection of primary mouse myoblasts under the conditions described here expand the opportunities to study muscle cell growth and differentiation using myoblasts from normal as well as mutant strains of mice. The properties of these cells after transplantation--the stability of resulting hybrid myofibers without immune suppression, the persistence of transgene expression, and the lack of tumorigenicity--suggest that studies of cell-mediated gene therapy using primary myoblasts can now be broadly applied to mouse models of human muscle and non-muscle diseases.     

Death of solid tumor cells induced by Fas ligand expressing primary myoblasts

Anticancer therapy for solid tumors suffers from inadequate methods for the localized administration of cytotoxic agents. Fas ligand (FasL) has been reported to be cytotoxic to a variety of cells, including certain tumor cell lines. We therefore postulated that myoblasts could serve as non-transformed gene therapy vehicles for the continuous localized delivery of cytotoxic anticancer agents such as FasL. However, contrary to previous reports, fluorescence activated cell sorting (FACS) analyses revealed that both primary mouse and human myoblasts express Fas, the receptor for FasL. To avoid self-destruction and test the cytotoxic potential of myoblasts, the cells were isolated from mice deficient in Fas (lpr/lpr), the mouse counterpart of human autoimmune lymphoproliferative syndrome (ALPS). These primary mouse myoblasts were transduced with a retroviral vector encoding mouse FasL and expression of a biologically active and soluble form of the molecule was confirmed by the apoptotic demise of cocultured Fas-expressing Jurkat cells, the standard in the field. To test whether the lpr myoblasts expressing FasL could be used in anticancer therapy, human rhabdomyosarcoma derived cell lines were assayed for Fas and then tested in the apoptosis coculture assay. The majority of Fas-expressing muscle tumor cells were rapidly killed. Moreover, FasL expressing myoblasts were remarkably potent; indeed well characterized cytotoxic antibodies to Fas were only 20% as efficient at killing rhabdomyosarcoma cells as FasL expressing myoblasts. These findings together with previous findings suggest that primary myoblasts, defective in Fas but genetically engineered to express FasL, could function as potent anticancer agents for use in the localized destruction of solid tumors in vivo by three synergistic mechanisms: (1) directly via Fas/FasL mediated apoptosis, (2) indirectly via neutrophil infiltration and immunodestruction, and (3) as allogeneic inducers of a bystander effect via B and T cells.     

Fas-mediated cytotoxicity is not required for rejection of murine nonvascularized heterotopic cardiac allografts

BACKGROUND: Using mice with loss-of-function mutations in the Fas and Fas ligand (FasL) genes (lpr and gld, respectively) in transplantation experiments has resulted in contradictory findings concerning the role of Fas/FasL-mediated cytotoxicity in allograft rejection. The observation that these mutant mice develop an abnormal lymphocyte phenotype with increasing age that is hyporesponsive in vitro led us to examine the possibility that this characteristic might explain seemingly discordant observations in the literature. Therefore, to distinguish between the effects of Fas/FasL pathway disruption and the effects of immune senescence on in vivo cytotoxicity and allograft rejection, we evaluated the survival of cardiac allografts in gld, lpr, and wild-type mice of varying ages. METHODS: Six- to 21-week-old C3H, C3H/HeJ-Fasl(gld), C57B1/6, and B6.MRL-Fas(lpr) recipients were transplanted with heterotopic, nonvascularized cardiac allografts from neonatal Balb/c, C3H, C57Bl/6, and B6.MRL-Fas(lpr) donors. Mixed lymphocyte reactions were performed in naive gld, lpr, and wild-type animals, 6 and 12 weeks of age. Rejected allografts in gld, lpr, and wild-type recipients and functioning syngeneic transplants were evaluated for intragraft apoptosis by a DNA fragmentation detection assay. RESULTS: Graft survival was not significantly different between 6-week-old gld and lpr recipients and their respective wild-type controls. However, allograft rejection was delayed significantly in older (13-week) gld mice compared with age-matched wild-type mice (P=0.02) or young (6-week) gld animals (P=0.04). Similarly, 21-week-old lpr mice exhibited prolonged graft survival compared with 6-week-old lpr animals (P=0.01). Reduced alloreactive proliferative responses in 12-week-old gld and lpr mice were observed when compared with age-matched wild-type strains. Rejecting allografts displayed a similar level of intragraft apoptotic cells regardless of mutant or wild-type phenotype or age of recipient. CONCLUSIONS: The findings of this study confirm that Fas/FasL-mediated cytotoxicity is not required for murine cardiac allograft rejection. Our findings also demonstrate that the observed delayed graft rejection in lpr and gld mice is a consequence of an age-related alteration of the immune system, specific to gld and lpr mice and associated with an in vivo and in vitro hyporeactivity to alloantigens.     

Dynamics of glucose-induced insulin release from mouse islets transplanted under the kidney capsule

Mouse pancreatic islet grafts under the kidney capsule of syngeneic hosts were removed and perifused in vitro 1-40 weeks after the transplantation. In comparison with fresh islets, 12- to 40-week-old grafts exhibited an attenuated first phase of glucose-stimulated insulin release. In grafts 1, 12, 28, or 40 weeks old, but not in fresh islets, the mean secretory rate during the initial 10 min of stimulation was significantly lower than that during the subsequent 15 min. When expressed in relation to insulin content, the insulin output in response to 11 mmol/L glucose was no less from grafts than from fresh islets; in grafts 12 or 40 weeks old at 16.7 mmol/L glucose, the fractional output above baseline was significantly diminished during the initial 10 min, but not subsequently. Immediately on switching from basal to stimulatory glucose concentration, there was a transient drop in insulin secretion from the grafts, especially after more than 12 weeks of transplantation and in response to 16.7, as compared with 11, mmol/L glucose. When glucose was switched back from stimulatory to basal concentration, grafts also frequently exhibited a transient increase in the insulin secretory rate. Neither initial drops nor "off responses" were seen in untransplanted islets. The modifications of the secretory dynamics in islet grafts suggest that transplantation influences the balance between the stimulatory and inhibitory influences of glucose on the beta-cell's secretory machinery.     

Prevention of autoimmune but not allogeneic destruction of grafted islets by different therapeutic strategies

Grafting autoimmune-diabetic recipients with allogeneic islets, graft rejection and disease recurrence as major problems of reaching indefinite survival and tolerance induction have to be solved. Anti-CD25 and anti-CD4 monoclonal antibodies were successfully used after allogeneic islet transplantation in experimentally diabetic rats. A temporary anti-CD25 therapy also prevented disease recurrence in autoimmune-diabetic BB rats, while this was not yet reported for an anti-CD4 treatment. In autoimmune-diabetic NOD mice disease recurrence can be successfully treated using an anti-CD4 monoclonal antibody. We, therefore, compared the efficacy of a short-term anti-CD25 and anti-CD4 treatment regarding the prevention of allograft rejection and disease recurrence in autoimmune-diabetic BB/OK rats. Both monoclonal antibodies were combined with low doses of Cyclosporin A. Untreated BB/OK rats relapsed into hyperglycaemia within 3 weeks independent of the islet donor, LEW.1A, LEW.1BB/OK or BB/OK rats. However, after grafting MHC-identical allogeneic (LEW.1BB/OK) or syngeneic (BB/OK) islets we observed about 30% spontaneous acceptance. Both the anti-CD25 and anti-CD4 therapy significantly prolonged the survival of allogeneic grafted islets. After MHC-identical allogeneic and syngeneic islet transplantation the temporary immunotherapy increased the proportion of permanent acceptors to 63% and 75%, respectively. The efficacy of both treatment strategies in prolonging allograft survival and prevention of disease recurrence was identical. In summary, anti-CD25 as well as anti-CD4 therapy prevented autoimmune but not allogeneic islet destruction in autoimmune-diabetic BB/OK rats. In conclusion, targeting different immune cells by monoclonal antibodies with different specificities can lead to very similar results with respect to an interruption of allograft rejection and autoimmune reaction.     

Hypotensive action of bromocriptine in the DOCA-salt hypertensive rat: contribution of spinal dopamine receptors

Clinical islet transplantation is potentially the treatment of choice for people with type I diabetes. Rates of insulin independence in islet transplant recipients are disappointingly low, and the relative contribution of the rejection response compared with the loss of islet function is still unclear. We have compared the mixed lymphocyte islet coculture (MLIC) with the mixed lymphocyte acinar cell coculture (MLAC) and the mixed lymphocyte response (MLR) as in vitro models of allograft rejection to MHC and tissue-specific antigens expressed by human islets and acinar cells. The reduced number of MHC class II antigen-positive cells in islets and acinar tissue compared to those in the stimulator lymphocyte population of the MLR, correlated with a reduced proliferative response in the MLIC and MLAC. Enhancement of MHC class II antigen expression by islets using TNFalpha and IFNgamma did not increase their stimulatory capacity in the islet cocultures, which may have been due to a corresponding absence of B7 expression. The lack of T cell proliferation to acinar cells despite cytokine-induced enhancement of MHC class II expression and detectable B7 expression appeared to be due to the inhibitory effect of exocrine enzymes on lymphocyte proliferation. In conclusion, we suggest that a rejection response to islets and acinar tissue is possible due to the accompanying MHC class II-positive cells and that, in this model, islet and acinar-specific antigens do not significantly contribute to that response. Acinar cells may have the potential to stimulate lymphocytes directly, but this was not evident by proliferation in the MLAC. Rejection appears to contribute to the low survival rate of human islet allografts, but it is unlikely that this is the sole explanation, and other factors should be considered.     

Ex vivo adenovirus-mediated gene delivery leads to long-term expression in pancreatic islet transplants

BACKGROUND: Replication-deficient adenovirus, one of the most efficient vectors in gene therapy, has been limited by transient transgene expression due to its episomal location and loss during cell division, as well as a host immune response against viral proteins. METHODS: Murine pancreatic islets were infected ex vivo with ad5-cytomegalovirus (CMV)-beta-galactosidase and transplanted into diabetic recipients with normalization of glucose metabolism. RESULTS: High levels of beta-galactosidase activity were detectable histologically for at least 20 weeks after transplant, and beta-galactosidase and viral mRNA were also present that long. Sera from transplanted animals did not significantly inhibit ad5-CMV-interleukin-2-Ig infection of HeLa cells in vitro, whereas sera from intravenously delivered ad5-CMV-beta-galactosidase drastically diminished HeLa cell infection, suggesting the presence of reduced levels of antibodies in transplanted animals as compared with intravenously infected animals. Immunofluorescent staining of islet isografts infected with ad5-CMV-beta-galactosidase revealed the presence of CD8+ and CD4+ T lymphocytes at all time points, however, no islet destruction was seen. CONCLUSIONS: Treatment of islet isografts ex vivo with ad5-CMV-beta-galactosidase results in prolonged transgene expression, possibly due to an attenuated immune response against adenovirus.     

Human pancreatic beta-cell deoxyribonucleic acid-synthesis in islet grafts decreases with increasing organ donor age but increases in response to glucose stimulation in vitro

Human pancreatic beta-cell proliferation may be crucial for the success of islet transplantation. The aim of this study was to test the hypothesis that adult human beta-cells proliferate in vitro and in vivo and respond with increased rates of replication to factors known to promote rodent islet-cell proliferation, i.e. glucose, human recombinant GH, and FCS. For this purpose, human islets were prepared from a total of 19 adult heart-beating organ donors and cultured for 48 h with or without the additives described above. 3H-thymidine was added to the medium during the last 60 min of culture. After immunohistochemical staining for insulin and autoradiography, the labeling index (LI; i.e. % of labeled beta-cells over total number of beta-cells) was estimated by light microscopy. Islets also were transplanted under the kidney capsule of normal or alloxan-diabetic nude mice. After 2 weeks, 3H-thymidine was injected and the islet grafts prepared for determination of LI, as described above. Islets cultured at 5.6 mM glucose showed an increased beta-cell proliferation compared with islets cultured at 2.8 mM glucose (P < 0.05). However, culture at 11 mM glucose failed to further increase beta-cell proliferation. Addition of GH (1 microg/ml) to the medium, in the presence of 1% FCS and 5.6 mM glucose, did not influence the rate of beta-cell proliferation. In islets transplanted to hyperglycemic nude mice, beta-cell proliferation was similar to that observed in islets grafted into normoglycemic nude mice. Proliferation, however, decreased with increasing organ donor age. This study shows that pancreatic beta-cells from adult man are able to proliferate both in vitro and in vivo. Moreover, beta-cells from adult human donors respond with increased proliferation to glucose in vitro and show a decreased proliferation in vivo with increasing donor age.     

The thymic way to transplantation tolerance

Within the past three decades, extensive research has been carried out with the aim to prevent graft rejection by minimizing the side effects related to the use of immunosuppressants. The major goal in transplantation research remains the development of strategies that would allow one to achieve a state of donor-specific unresponsiveness in order to promote a condition of true tolerance without the need of immunosuppressants. Recent evidence has been provided that this is a pursuing goal, at least in experimental animals. The thymus plays the major role in the development of self-tolerance, and initial work in the late 1960s indicated that the thymus also plays a critical role in the induction of acquired tolerance to exogenous antigens. Recently, the interest in acquired thymic tolerance has been renewed by the observation that, in the rat, the thymus is an immunologically privileged site in which isolated pancreatic islets can be engrafted and survive indefinitely. Moreover, intrathymic injection of the islets induced donor-specific unresponsiveness, which allowed survival of a second donor-strain islet cell allograft transplanted into an extrathymic site. These findings on cellular allografts have been extended to vascularized organ allografts.(ABSTRACT TRUNCATED AT 250 WORDS)