Combined Coinhibitory and Costimulatory Modulation with Anti-BTLA and CTLA4Ig Facilitates Tolerance in Murine Islet Allografts

Complex interactions between positive and negative cosignaling receptors ultimately determine the fate of the immune response. The recently identified coinhibitory receptor, B and T lymphocyte attenuator (BTLA), contributes to regulation of autoimmune and potentially alloimmune responses. We investigated the role of BTLA in a fully major histocompatibility complex-mismatched mouse islet transplant model. We report that anti-BTLA mAb (6F7) alone does not accelerate graft rejection. Rather, while CTLA4Ig alone improved allograft survival, the addition of anti-BTLA mAb to CTLA4Ig led to indefinite (>100 days) allograft survival. Immediately after treatment with anti-BTLA mAb and CTLA4Ig, islet allografts showed intact islets and insulin production despite a host cellular response, with local accumulation of Foxp3+ cells. We clearly demonstrate that combined therapy with anti-BTLA mAb and CTLA4Ig mice induced donor-specific tolerance, since mice accepted a second donor-specific islet graft without further treatment and rejected third party grafts. CTLA4Ig and anti-BTLA mAb limited the initial in vivo proliferation of CFSE-labeled allogeneic lymphocytes, and anti-BTLA mAb enhanced the proportion of PD-1 expressing T cells while depleting pathogenic BTLA+ lymphocytes. We conclude that targeting the BTLA pathway in conjunction with CTLA4Ig costimulatory blockade may be a useful strategy for promoting immunological tolerance in murine islet allografts.     

CTLA4-Ig-modified dendritic cells inhibit lymphocyte-mediated alloimmune responses and prolong the islet graft survival in mice

The induction of antigen specific tolerance is critical for prevention and treatment of allograft rejection. In this study, we transfected CTLA4-Ig gene into dendritic cells (DCs), and investigated their effect on inhibition of lymphocyte activity in vitro and induction of immune tolerance on pancreatic islet allograft in mice. An IDDM C57BL/6 murine model induced by streptozotocin is as model mouse. The model mice were transplanted of the islet cells isolated from the BALB/c mice to their kidney capsules, and injected of CTLA4-Ig modified DCs (mDCs). The results showed that mDCs could significantly inhibit T lymphocyte proliferation and induce its apoptosis; whereas, unmodified DCs (umDCs) promoted the murine lymphocyte proliferation. Compared with injection of umDCs and IgG1 modified DCs, the injection of mDCs prolonged IDDM mice's allograft survival, and normalized their plasma glucose (PG) levels within 3 days and maintained over 2 weeks. The level of IFN-gamma was lower and the level of IL-4 was higher in mDCs treated recipient mice than that in control mice, it indicated that mDCs led to Th1/Th2 deviation. After 7 days of islet transplantation, HE stain of the renal specimens showed that the islets and kidneys were intact in structure, and islet cells numbers are increased in mDCs treated mice. Our studies suggest that DCs expressing CTLA4-Ig fusion protein can induce the immune tolerance to islet graft and prolong the allograft survival through the inhibition of T cell proliferation in allogeneic mice.     

Role of the CTLA4 pathway in hyporesponsiveness induced by intratracheal delivery of alloantigen

BACKGROUND: The authors previously reported that intratracheal delivery (ITD) of donor alloantigen induced donor-specific hyporesponsiveness to C57BL/10 cardiac allografts in CBA recipients and that blockade of the B7 pathways abrogated that hyporesponsiveness. In this study, the authors used a CD28-deficient model to evaluate which signal, either through CD28 or cytotoxic T-lymphocyte-associated antigen (CTLA4), is involved in the induction of hyporesponsiveness. METHODS: Seven days before transplantation of hearts from C3H/HeJ (H2k) mice into C57BL/6 (H2b) or CD28-deficient (C57BL/6 background) mice, the transplant recipients were given ITD of donor splenocytes (1 x 10(7)), alone or in combination with human CTLA4-immunoglobulin (Ig) (200 microg). RESULTS: ITD of C3H splenocytes induced donor-specific hyporesponsiveness to C3H cardiac grafts in C57BL/6 recipients (graft median survival time [MST], 40 days). Administration of CTLA4-Ig concurrently with ITD abrogated the prolonged allograft survival (MST, 12 days). Interestingly, ITD of C3H splenocytes induced prolonged survival of C3H allografts in CD28-deficient recipients (MST, 55 days). Furthermore, administration of CTLA4-Ig combined with ITD of C3H splenocytes abrogated the prolonged survival of C3H allografts in CD28-deficient recipients (MST, 7 days), whereas recipients given isotype-control antibody in combination with ITD of splenocytes had prolonged survival of C3H allografts (MST, 58 days). CONCLUSIONS: Taken together, the authors' findings indicate that a signal through CTLA4, rather than through CD28, plays an important role in the induction of hyporesponsiveness by ITD of alloantigen in this model.     

A dendritic cell line genetically modified to express CTLA4-IG as a means to prolong islet allograft survival

BACKGROUND: Dendritic cells are potent antigen-presenting cells that bind allogeneic T cells. They are thus candidates for targeting immunoregulatory molecules to the alloreactive T cell compartment and suppressing the alloimmune response. METHOD: A dendritic cell line derived from the BALB/c mouse (H2d) was genetically modified to express the immunoregulatory molecule CTLA4-Ig. The ability of these dendritic cell transfectants to downregulate the alloimmune response was tested in an islet transplant model. Allogeneic C57Bl/6 (H2b) mice were rendered diabetic with streptozocin, and they received BALB/c islet (H2d) transplants. Mice were administered 25 million untransfected or CTLA4-Ig-transfected D2SC/1 cells i.v. on the day of islet transplantation and 6 days later[fnc]. RESULT: Mice treated with CTLA4-Ig-transfected D2SC/1 cells demonstrated prolonged allograft survival (mean = 20 days, median = 17 days, SD = 9.39) compared with mice treated with untransfected D2SC/1 cells (mean = 12 days, median = 11 days, SD=2.74) or untreated control mice (mean = 11 days, median = 11 days SD = 1.41). Third party allograft survival was not prolonged in mice receiving similar treatment. CONCLUSIONS: These results demonstrate that a genetically modified dendritic cell line can suppress the alloimmune response and prolong islet allograft survival in an allospecific manner. The findings also suggest that genetically modified dendritic cells may be useful in targeting alloreactive T cells and prolonging allograft survival.     

Immunomodulation by adenoviral-mediated SCD40-Ig gene therapy for mouse allogeneic islet transplantation

BACKGROUND: The success of pancreatic islet transplantation is limited because of immune rejection of allogeneic transplanted tissue and potential adverse side effects of nonspecific immunosuppression. Local expression of an immunosuppressive agent at the site of islet transplant could promote long-term engraftment without associated systemic side effects. METHODS: We have examined the ability of adenoviral vector mediated local production of sCD40-immunoglobulin (Ig), blocking the CD40-CD40 ligand (CD40L) costimulatory pathway, from genetically modified allogeneic islets to facilitate long-term engraftment in fully allogeneic mouse model. RESULTS: Transplantation of islets infected with an adenoviral vector expressing sCD40-Ig resulted in allograft survival longer than 120 days in five of the nine recipient mice (56%). However, mice that received mock infected (n=5) or control adenoviral vector (Ad.eGFP; n=6) rejected the allograft with a median survival of 15 and 16 days, respectively. Histopathology demonstrated that the grafts of the long-term surviving animals preserved islets with minimal mononuclear cell infiltration. CONCLUSION: These results demonstrate that local inhibition of the CD40-CD40L pathway by adenoviral gene transfer of sCD40-Ig to the islets prior to transplant significantly prolonged islet allograft acceptance. This approach could be used clinically to facilitate islet transplantation.     

Multiple Combination Therapies Involving Blockade of ICOS/B7RP-1 Costimulation Facilitate Long-Term Islet Allograft Survival

In recent years a series of novel costimulatory molecules have been identified, including inducible costimulator (ICOS). In a fully major histocompatibility complex (MHC)-mismatched mouse model of islet transplantation, we demonstrate that while monotherapy with CTLA4-Ig, CD40 ligand monoclonal antibody (CD40L mAb) or rapamycin each improves islet allograft survival, graft rejection eventually develops. Immunohistologic analysis of rejected grafts revealed increased ICOS expression, suggesting a role for this costimulatory molecule as an alternate pathway for T-cell activation. The combination of a blocking anti-ICOS mAb with each of the above therapies resulted in significantly improved islet allograft survival, confirming the importance of ICOS signaling in islet allograft rejection. Mechanistic studies conducted in mice treated with anti-ICOS mAb and rapamycin demonstrated a lack of donor-specific immunological tolerance and an absence of regulatory T-cell activity. However, a dramatic effect was seen on acute anti-donor responses whereby anti-ICOS mAb and rapamycin significantly reduced the initial expansion and function of alloreactive T cells. These data demonstrate that blockade of the ICOS/B7RP-1 pathway has potential therapeutic benefit given its role in enhancing islet allograft survival and regulating acute alloresponses in vivo.     

Anti-CD40 therapy extends renal allograft survival in rhesus macaques

BACKGROUND: Organ transplant recipients currently require lifetime immunosuppressive therapy, with its accompanying side effects. Biological agents that block T-cell costimulatory pathways are important components of strategies being developed to induce transplantation tolerance. The aim of this study was to test the effect of a novel chimeric anti-human CD40 monoclonal antibody (Chi 220), either alone or in combination with CTLA4-Ig, on the survival of renal allografts in a nonhuman primate model. METHODS: Captive-bred adolescent male rhesus monkeys (Macaca mulatta) (4-10 kg) were used as recipients and donors. Four treatment protocols were tested: Chi220 monotherapy, CTLA4-Ig monotherapy, Chi220 combined with CTLA4-Ig, and H106 (anti-CD40L) combined with CTLA4-Ig. Control animals received human albumin. Recipients were followed for survival, renal allograft function as determined by measurement of serum blood urea nitrogen (BUN) and creatinine, chemistries (sodium, potassium, chloride, and bicarbonate), complete blood cell count (CBC) with differential, and the development of donor-specific alloantibody. RESULTS: Treatment with Chi220 for 14 days prolonged renal allograft survival (MST 38.5 vs. 7 days in untreated controls). Notably, simultaneous blockade of the CD28/B7 pathway did not further augment graft survival but did suppress the development of donor-specific antibodies, an effect not achieved with Chi220 alone, despite peripheral B cell depletion. Finally, treatment with Chi220 suppressed the primary immune response to cytomegalovirus, resulting in severe systemic manifestations. CONCLUSIONS: Blockade of the CD40 pathway with anti-CD40 mAb is immunosuppressive in a large animal, preclinical renal transplant model. The potential effect of this therapy on viral immune responses will be important to consider for the design of safe clinical trials.     

Mechanisms of survival prolongation of murine cardiac allografts using the treatment of CTLA4-Ig and MR1

BACKGROUND: [corrected] The present study was undertaken to determine the role of costimulatory blockade in a murine cardiac transplant model. MATERIALS AND METHODS: We blocked the CD28/B7 and CD154/CD40 costimulatory pathways by transient administration of CTLA4-Ig and MR1 antibody to study the effects on allograft survival time, deviation of Th1 and Th2 cytokine secretion, and other mechanisms related to prolonged survival. RESULTS: Costimulatory blockade prolonged the mean survival time (MST) of cardiac allografts to 43 days for the treated group vs 8 days for the untreated group (P < .01). The costimulatory blockade down-regulated the expression of 2 Th1 cytokines (interferon-gamma [IFN-gamma] and interleukin-2 [IL-2]) and 2 Th2 cytokines (IL-4 and IL-10), reduced the numbers of graft-infiltrating CD4+ and CD8+ lymphocytes, and inhibited the expression of both perforin/GrB and FasL in allografts. CONCLUSIONS: Combined administration of CTLA4-Ig/MR1 inhibited acute rejection reactions in murine cardiac allografts, prolonging the survival of cardiac grafts through several mechanisms, including inhibition of Th1 and Th2 cytokine expression, graft infiltration by CD4+ and CD8+ T lymphocytes, and reduced both perforin/GrB and Fas-FasL.     

B7-H4 induces donor-specific tolerance in mouse islet allografts

Negative cosignaling molecules play an important role in regulating T-cell responses to alloantigen stimulation. We recently reported that adenoviral-mediated transduction of islet allografts with B7-H4 inhibits allograft rejection. In this study, we investigate the mechanism for B7-H4-induced prolongation of mouse islet allograft survival. Streptozotocin-induced diabetic C57BL/6 mice were rendered normoglycemic by renal subcapsular implants of B7-H4-transduced BALB/c islets. Grafts and spleens were removed after days 2, 10, and 60 (n = 8 each) for characterization of kinetics of Foxp3 and interleukin 10 (IL-10) expression. Mixed lymphocyte reaction (MLR) was done at day 60. Ten mice were subjected to nephrectomy at 60 days and then five were implanted with secondary BALB/c islets and five were given third-party CBA/J islets. An increase in Foxp3 and IL-10 mRNA expression was detected in recipients' spleens at day 60 and this was associated with increased quantities of Foxp3(+) cells. Splenocytes at day 60 showed hyporesponsiveness during MLR to alloantigen stimulation. Proliferation was partially restored after CD25(+) T-cell depletion. Secondary BALB/c islets survived for 79 ± 29 days compared with 21 ± 3.6 days for CBA/J islets (p < 0.001). Local expression of B7-H4 induces long-term unresponsiveness to donor-specific alloantigens, and is associated with T regulatory cells, suggesting the development of tolerance.     

Long-Term Survival of Intestinal Allografts Induced by Costimulation Blockade, Busulfan and Donor Bone Marrow Infusion

Tolerance-inducing strategies that infuse donor bone marrow cells in conjunction with costimulation blockade have not been applied to intestinal transplantation. Intestines from BALB/c mice were transplanted into C57BL/6 recipients treated with anti-CD40L mAb, CTLA4-Ig, donor bone marrow, and busulfan. The majority of mice transplanted after completion of this regimen developed hematopoietic macrochimerism, although the degree of chimerism varied widely between recipients, and experienced long-term allograft survival. T cells from these mice demonstrated donor-specific hyporesponsiveness in vitro. However, T cells from chimeric mice proliferated to donor alloantigen in vivo. Furthermore, chimeric mice bearing intestinal allografts were capable of rejecting subsequently placed donor-strain skin grafts. These data suggest that although long-term allograft survival occurs in the absence of acute or chronic rejection, recipient mice are not completely unresponsive to donor alloantigens. When intestinal transplantation was performed at the time of initial bone marrow infusion (initiation of the chimerism protocol), most recipients failed to develop chimerism and promptly rejected the intestinal allograft. Although this is the most effective protocol that we have tested using this stringent model of transplantation, our observations suggest that modifications will be necessary before it can be reliably applied to the transplantation of highly immunogeneic organs like the intestine.     

Differences in suppressor of cytokine signaling-1 (SOCS-1) expressing islet allograft destruction in normal BALB/c and spontaneously-diabetic NOD recipient mice

BACKGROUND: The ability to block interferon signaling represents an important strategy in designing therapies to prevent beta-cell destruction during islet allograft rejection. METHODS: The SOCS proteins regulate cytokine signaling by blocking activation of JAK/STAT proteins. Using islets isolated from SOCS-1 transgenic mice (SOCS-1-Tg; these mice express SOCS-1 under the control of the human insulin promoter and are on the C57BL6/J background), we investigated whether SOCS proteins can prevent the destruction pancreatic islet cells transplanted beneath the kidney capsule of major histocompatibility complex mismatched normal BALB/c and spontaneously-diabetic NOD mouse recipients. RESULTS: Immunohistochemical staining for insulin confirmed the presence of donor SOCS-1-Tg islets in islet allografts harvested at 22 days posttransplant, whereas grafts of control non-Tg islets were destroyed by 14 days. In contrast, SOCS-1-Tg allogeneic islets were not protected from beta-cell destruction in clinically diabetic NOD mice. The islet allografts functioned for 1 week posttransplant; however, hyperglycemia returned after 2 weeks and the grafts were destroyed. Rejection of SOCS-1-Tg and non-Tg islets in autoimmune diabetic NOD mice was associated with an infiltrate of both CD4+ and CD8+ T cells and a T2-type cytokine response (IL-4) rather than the conventional T1-type cytokine response observed during islet allograft rejection. Self-antigen upregulation in response to IFN-gamma stimulation did not appear to be a factor in rejection of the islet allografts. CONCLUSIONS: These results demonstrate that expression of SOCS-1 in islets delays islet allograft rejection but cannot circumvent destruction of the islets by the recurrence of the tissue-specific autoimmune process of spontaneous diabetes.     

Desferrioxamine treatment prevents chronic islet allograft damage

BALB/cByJ islet allografts are acutely rejected when transplanted into allogeneic mice (CBA/J). Culture of the tissue for 7 days in 95% O2 before grafting is a suboptimal treatment for the reduction of immunogenicity in this strain combination. Approximately half the animals reject these transplants in a chronic fashion. Chronic islet rejection differs from acute rejection of uncultured allogeneic islets. During chronic rejection, beta cells within the transplanted tissue degranulate but remain intact when the animal returns to the diabetic condition. Acute islet rejection is characterized by the destruction of beta cells that remain heavily granulated as long as they remain intact. We examined the effect of the iron chelating agent, desferrioxamine, on chronic islet allograft damage. Desferrioxamine inhibited chronic islet allograft damage but did not influence the process of rejection of uncultured islet tissue. This effect of desferrioxamine could not be attributed to a direct immunosuppressive effect of this agent.     

Induction of immunologic tolerance to cardiac allograft by simultaneous blockade of inducible co-stimulator and cytotoxic T-lymphocyte antigen 4 pathway

BACKGROUND: Inducible co-stimulator (ICOS) is one of the most recently described members of the CD28 family, and it plays an important role in immune responses. To investigate the role of ICOS in allograft rejection, the authors studied graft survival after cardiac transplantation in mice. METHODS: Hearts from BALB/c mice were transplanted into C3H/He mice. Immunohistochemical staining and flow cytometry were performed. Monoclonal antibody to ICOS or ICOS-immunoglobulin (Ig) was injected intraperitoneally. The authors performed mixed lymphocyte reaction (MLR). RESULTS: ICOS was expressed strongly by graft-infiltrating cells during rejection of the allograft. Blockade of the ICOS pathway with anti-ICOS antibody and ICOSIg significantly prolonged graft survival time relative to that in untreated mice; however, all cardiac allografts were eventually rejected by a single treatment. Treatment with both ICOSIg and cytotoxic T-lymphocyte antigen 4 (CTLA4) Ig induced not only long-term acceptance of the cardiac allograft but also donor-specific tolerance, which was shown by acceptance of donor but not third-party skin. Graft arterial intimal hyperplasia in these cardiac allografts was remarkably less than that in cardiac allografts treated with tacrolimus. Addition of anti-ICOS antibody or ICOSIg to MLR resulted in inhibition of T-cell proliferation. CONCLUSIONS: Inhibition of T-cell proliferation with ICOSIg and CTLA4Ig was more effective than that with ICOSIg alone. Thus, ICOS appears to be an important regulator of T-cell activation, and may be an effective therapy in clinical cardiac transplantation.     

Distinct requirements for host CD80/CD86 costimulatory molecules in cardiac versus islet rejection

The role of B7 family members CD80 and CD86 in providing costimulatory signals to T cells is well established. Interestingly, previous studies show that host CD80/CD86 expression is required for cardiac allograft rejection. However, the role for host costimulation by CD80/CD86 molecules for the rejection of neovascularized islet allografts and xenografts is unknown. The purpose of this study was to determine whether islet allografts and/or rat islet xenografts required host CD80/CD86 molecules for acute rejection. Streptozotocin-induced diabetic C57Bl/6 (B6, H-2(b)) or B6 CD80/CD86 double-deficient mice were grafted with allogeneic BALB/c (H-2(d)) islet allografts or with WF (RT1(u)) islet xenografts. Nondiabetic B6 mice were grafted with BALB/c heterotopic cardiac allografts. Consistent with previous reports, BALB/c islet allografts were acutely rejected in wild-type B6 mice could survive long-term (>100 days) in B6 CD80/CD86-deficient animals. In stark contrast, both islet allografts and WF rat islet xenografts demonstrated acute rejection in both control B6 and in B6 CD80/CD86 deficient hosts. In conclusion, varied studies imply that the inherent pathways for rejecting primarily vascularized versus cellular allografts or xenografts may be distinct. The present study illustrates this concept by showing a marked difference in the role of host-derived CD80/CD86 costimulatory molecules for cardiac allograft versus islet allograft/xenograft rejection in vivo. Although such costimulation is rate limiting for cardiac allograft rejection, these same molecules are not necessary for acute rejection of either islet allografts or xenografts.     

A major role for host MHC class I antigen presentation for promoting islet allograft survival

The purpose of this study was to determine the role for CD8 T cells versus generalized MHC class I-restricted antigen presentation in islet allograft rejection and tolerance. Diabetic C57BI/6 (B6, H-2(b)) controls, C57BI/6 CD8-deficient (CD8 KO), or MHC class I-deficient C57BI/6 (beta 2m KO) recipients were grafted with allogeneic BALB/c (H-2(d)) islets. Islet allografts were acutely rejected in untreated B6, CD8 KO, and in beta 2m KO mice, indicating that neither CD8 T cells nor host MHC class I is required for allograft rejection. We then determined the efficacy of costimulation blockade in these same strains. Costimulation blockade with anti-CD154 therapy facilitated long-term islet allograft survival in both B6 and in CD8 KO recipients. However, anti-CD154 treated beta 2m KO recipients were completely refractory to anti-CD154 therapy; all treated animals acutely rejected islet allografts with or without therapy. Also, anti-NK1.1 treatment of wild-type B6 mice abrogated graft prolongation following anti-CD154 therapy. Taken together, results show a dramatic distinction between two forms of MHC class I-restricted pathways in allograft prolongation. Although anti-CD154-induced allograft survival was CD8 T-cell independent, an intact host MHC class I-restricted (beta 2m-dependent) pathway is nevertheless necessary for allograft survival. This pathway required NK1.1+ cells, implicating NK and/or NKT cells in promoting allograft prolongation in vivo.     

Inhibition of cellular immune responses to encapsulated porcine islet xenografts by simultaneous blockade of two different costimulatory pathways

BACKGROUND: Transplantation of human islets has been successful clinically. Since human islets are scarce, we are studying microencapsulated porcine islet xenografts in nonobese diabetic (NOD) mice. We have evaluated the cellular immune response in NOD mice with and without dual costimulatory blockade. METHODS: Alginate-poly-L-lysine-encapsulated adult porcine islets were transplanted i.p. in untreated diabetic NODs and NODs treated with CTLA4-Ig to block CD28/B7 and with anti-CD154 mAb to inhibit CD40/CD40-ligand interactions. Groups of mice were sacrificed on subsequent days; microcapsules were evaluated by histology; peritoneal cells were analyzed by FACS; and peritoneal cytokines were quantified by ELISA. Controls included immunoincompetent NOD-Scids and diabetic NODs given sham surgery or empty microcapsules. RESULTS: Within 20 days, encapsulated porcine islets induced accumulation of large numbers of macrophages, eosinophils, and significant numbers of CD4 and CD8 T cells at the graft site, and all grafts were rejected. During rejection, IFNgamma, IL-12 and IL-5 were significantly elevated over sham-operated controls, whereas IL-2, TNFalpha, IL-4, IL-6, IL-10, IL-1beta and TGFbeta were unchanged. Treatment with CTLA4-Ig and anti-CD154 prevented graft destruction in all animals during the 26 days of the experiment, dramatically inhibited recruitment of host inflammatory cells, and inhibited peritoneal IFNgamma and IL-5 concentrations while delaying IL-12 production. CONCLUSIONS: When two different pathways of T cell costimulation were blocked, T cell-dependent inflammatory responses were inhibited, and survival of encapsulated islet xenografts was significantly prolonged. These findings suggest synergy between encapsulation of donor islets and simultaneous blockade of two host costimulatory pathways in prolonging xenoislet transplant survival.     

A more persistent tolerance to islet allografts through bone marrow transplantation in minimal nonmyeloablative conditioning therapy

INTRODUCTION: Islet transplantation is a therapeutic approach to prevent diabetes complications. However, the side effects of the required lifelong immunosuppressive regimens to prevent graft rejection restrict the impact of type 1 diabetes. One strategy to overcome these limitations is tolerance induction and graft acceptance through hematopoietic chimerism. In this study we investigated whether tolerance to major histocompatibility complex (MHC) and minor-disparate islet allografts could be induced by minimal nonmyeloablative conditioning and whether more persistent donor-specific islet allografts were accepted if the grafts were implanted with simultaneous bone marrow cells. METHODS: The donor and recipient mice were BALB/c(H-2(b)) and C57BL/6(H-2(d)), respectively. In group 1 streptozotocin-induced diabetic C57BL/6(H-2(d)) mice received only 500 islets of BALB/c(H-2(b)). Group 2 recipients conditioned with antilymphocyte serum, 100 cGy total body irradiation and cyclophosphamide were given islet cells of BALB/c(H-2(b)), but group 3 were simultaneously given 30 x 10(6) BALB/c(H-2(b)) mice BMCs and islet cells similar to group 2. RESULTS: We obtained 5% to 6% allogeneic donor chimerism and 60% graft survival at 80 days after islet transplantation in group 3. We observed lymphocyte infiltration around the islet without destruction of endocrine cells and the presence of strong insulin/glucagon-stained cells in group 3. CONCLUSION: This minimal nonmyeloablative conditioning therapy induced donor chimerism and immune tolerance between MHC- and minor-disparate (BALB/c-->C57BL/6) mice and long-term islet graft survival was obtained through cotransplantation of bone marrow cells.     

CTLA4-Ig abrogates the anti-globulin response and prolongs cardiac allograft survival after anti-CD2 treatment

CD2 is expressed on T cells and NK cells and is important in T cell activation, making it a potential target for immune intervention. Here, we report a series of experiments aimed at defining the ability of mAbs directed against the CD2 molecule to prevent cardiac allograft rejection in low and high responder rat strain combinations. Administration of the mouse anti-rat CD2 mAbs OX34 or OX55 around the time of transplantation prolonged survival of fully allogeneic Lewis (RT1l) cardiac allografts in low responder DA (RT1a) recipients (MST 14 days for OX55 and >100 days for OX34). Treatment with OX34 prolonged graft survival in the reciprocal high responder DA to Lewis rat strain combination (MST 19 days) and when combined with CTLA4-Ig resulted in long-term graft survival (MST>100 days). Despite these in vivo effects, OX34 had little effect on in vitro assays of lymphocyte activation. Instead, the ability of OX34 to extend allograft survival correlated with T cell depletion. Administration of OX34 induced a similar degree of CD4 T cell depletion in DA and Lewis recipients, but the CD4 depletion observed was more transient in Lewis recipients. Lewis, but not DA strain rats, developed an anti-murine Ig response. Combined treatment with CTLA4-Ig abolished the anti-globulin response to OX34 in Lewis recipients, prolonged circulation of OX34 and increased the extent and duration of CD4 depletion. We conclude that anti-CD2 treatment effectively prolongs cardiac allograft survival and addition of CTLA4-Ig increases its efficacy by abrogating the production of neutralising antibodies.     

Comparison of successful and unsuccessful islet/Sertoli cell cotransplant grafts in streptozotocin-induced diabetic mice

Sertoli cells (SC) protect islet allografts from immune destruction in diabetic rodents. In this study, we examined the difference between successful and rejected islet/SC cografts in order to further improve this procedure for optimal extension of islet allograft survival. We cotransplanted 500 BALB/c islets with 1-8 million BALB/c SC under the kidney capsule of diabetic BALB/c, C3H-HeJ, and C57BL/6 mice. Cotransplantation of islets with up to 8 million SC was not detrimental to long-term islet graft function in syngeneic mice. However, large numbers of SC were detrimental to islet graft survival in allogeneic mice with the optimal dose for cotransplantation of 4 or 1 million SC in C3H-HeJ or C57BL/6 mice, respectively. Examination of successful grafts, from euglycemic recipients, revealed the presence of SC arranged in tubule structures with islets surrounding these tubules. Cellular infiltrate in successful grafts revealed CD4 T cells and macrophages along the periphery and within the grafts, and very few CD8 T cells. Conversely, examination of unsuccessful grafts, harvested from hyperglycemic recipients at the time of rejection, revealed the presence of SC arranged randomly with islets adjacent to the Sertoli cells, when present, and massive CD4 and CD8 T cell as well as macrophage cell infiltration. Prolongation of islet allograft survival appeared to be a function of SC transplant mass and recipient genetic background. A consequence of long-term graft acceptance is the formation of SC tubule structures, which may be an additional requirement for optimal protection of islet allografts.     

Development of an immunoprivileged site to prolong islet allograft survival

Sertoli cells (SC) play a critical role in the maintenance of the immunoprivileged environment of the testis. We hypothesized that preengrafting SC would allow one to develop a vascularized immunoprivileged ectopic site that provides protection for mouse islet allografts. SC, prepared from 9-day Balb/c mice, were transplanted under the kidney capsule in adult Balb/c mice. After SC engraftment (approximately 30 days), mice were rendered diabetic and subsequently implanted with Balb/c or CBA/J islets directly adjacent to the established SC grafts. Preengrafted SC (5.7 +/- 0.2 x 106) had no adverse effect on syngeneic islet graft function. When allogeneic islets were transplanted into the immunoprivileged ectopic site created by preengrafting 6.4 +/- 0.3 x 10(6) SC, mean graft survival was slightly prolonged (32.4 +/- 6.0 days) compared with control mice that received allogeneic islets alone (16.3 +/- 1.5 days; p = 0.329). In contrast, when 4.8 +/- 0.4 x 10(6) SC were preengrafted, islet allograft survival was significantly prolonged (66.1 +/- 9.8 days; p = 0.001). Four of eight mice, preimplanted with 4.8 +/- 0.4 x 10(6) SC, remained normoglycemic throughout the follow-up period (83.8 +/- 8.6 days) and returned to a diabetic state only when the kidneys bearing the composite grafts were removed. Transplantation of islets into an immunoprivileged ectopic site created by preengrafting SC did not affect islet function and, moreover, provided a means of developing an immunopriveliged ectopic site that permits prolonged islet allograft survival without systemic immunosuppression.