Prevention of renal allograft rejection in primates by blocking the B7/CD28 pathway.

BACKGROUND: There is accumulating evidence that blockade of the costimulatory pathways offers a valid approach for immune suppression after solid organ transplantation. In this study, the efficacy of anti-CD80 and anti-CD86 monoclonal antibodies (mAbs) in combination with cyclosporine (CsA) to prevent renal allograft rejection was tested in non-human primates. METHODS: Rhesus monkeys were transplanted with a partly major histocompatibility complex-matched kidney on day 0. Anti-CD80 and anti-CD86 mAbs were administered intravenously daily for 14 days starting at day - 1. CsA was given intramuscularly for 35 days starting just after transplantation. The kidney function was monitored by determining serum creatinine levels. RESULTS: The combination of anti-CD80 and anti-CD86 mAbs completely abrogated the mixed lymphocyte reaction. Untreated rhesus monkeys rejected the kidney allograft in 5-7 days. Treatment with anti-CD80 plus anti-CD86 mAbs resulted in a significantly prolonged graft survival of 28+ 7 days (P=0.025). There were no clinical signs of side effects or rejection during treatment. Kidney graft rejection started after the antibody therapy was stopped. The anti-mouse antibody response was delayed from day 10 to 30 after the first injection. No difference in graft survival was observed between animals treated with CsA alone or in combination with anti-CD80 and anti-CD86 mAbs. However, treatment with anti-CD80 and anti-CD86 mAbs reduced development of vascular rejection. CONCLUSIONS: In combination, anti-CD80 and antiCD86 mAbs abrogate T-cell proliferation in vitro, delay the anti-mouse antibody response in vivo, and prevent graft rejection and development of graft vascular disease in a preclinical vascularized transplant model in non-human primates.     

The complement dependent cytotoxicity (CDC) immune effector mechanism contributes to anti-CD154 induced immunosuppression

BACKGROUND: In many situations, anti-CD154 (CD40 ligand) monoclonal antibody (mAb) treatment is very potent in producing allograft tolerance. In accordance to our previously reported results, combined donor specific transfusion (DST)3 plus anti-CD154 mAb (MR1) treatment enables the permanent engraftment of DBA/2 (H-2(d)) islets into B6AF1 (H-2(b/kd)) recipients in all cases. It has been widely assumed that the MR1 anti-154 is a noncytolytic neutralizing mAb, and it exerts immune suppressive effects by blockade of CD40/CD154 signal pathway. In this study, we sought to test the role of complement dependent cytotoxicity (CDC) immune effector mechanism in MR1 anti-CD154 induced immunosuppression. METHODS: We have evaluated the contributions of CDC in the context of the potent tolerizing effects of DST plus anti-CD154 mAb treatment regiment in recipients of islet allografts. We have used CD40 knockout (KO) mice and complement C5 deficient mice DBA/2 as islet allograft recipients as well as cobra venom factor (CVF), a complement blocker, treatment. RESULTS: The absence of direct and indirect CD40/CD154 pathway signals does not prevent islet allograft acute rejection. Interestingly, MR1 anti-CD154 induces islet allograft tolerance in the absence of CD40/CD154 pathway. In a wild-type major histocompatibility complex (MHC) mismatched strain combination, DST results in accelerated islet allograft rejection. Combination of DST and MR1 anti-CD154 treatment prevents presensitization and permits permanent engraftment. However, administration of CVF abolishes the tolerance induction. Moreover, DST plus MR1 anti-CD154 regiment, a potent tolerizing therapy, does not prevent acute islet allograft rejection when complement C5 deficient DBA/2 mice are used as recipients. Thus, the mechanisms of the tolerizing effects by MR1 anti-CD154 are not limited to blockade of CD40/CD154 signals. The CDC immune effector mechanism contributes to MR1 anti-CD154 induced immunosuppression.     

No synergy between ATG induction and costimulation blockade induced kidney allograft survival in rhesus monkeys

BACKGROUND: Costimulation blockade with antibodies directed against human CD40 and CD86 leads to prolonged kidney allograft survival in rhesus monkeys, but fails to induce permanent graft acceptance. We have tested whether costimulation blockade is more effective after peripheral T-cell ablation with antithymocyte globulin (ATG), with the aim to remove already primed autoreactive cells present in the normal repertoire. METHODS: Rhesus monkeys were transplanted with a mismatched kidney allograft. ATG was given around the time of transplantation (day -1 and 0). Costimulation blockade with anti-CD40+anti-CD86 was given at tapering dosages from day -1 to 56. Cyclosporin A (CsA) was given from day 42 onwards and first rejections occurring after day 42 were treated with prednisone. RESULTS: We observed accelerated rejection in ATG-treated monkeys, compared to animals receiving only costimulation blockade. The accelerated rejection of the kidney allograft occurred despite the application of rejection therapy with steroids and CsA. Three of the five ATG-treated animals were found seropositive for donor-specific alloantibodies. Early biopsies (day 21) from animals treated with ATG and anti-CD40+anti-CD86 show substantially reduced expression of cytotoxic T lymphocyte-associated antigen-4 (CTLA-4) and forkhead box P3 (FOXP3) in focal infiltrates as compared to animals treated with only costimulation blockade. Furthermore, we observed the rapid reappearance of CD8 T-cells with a memory phenotype (disappearance of naive CD95/CD11a T-cells) in peripheral blood. CONCLUSION: We conclude that (subtotal) T-cell depletion using ATG does not add to costimulation blockade induced kidney allograft survival.     

Long-term limb allograft survival using a short course of anti-CD45RB monoclonal antibody, LF 15-0195, and rapamycin in a mouse model

BACKGROUND: The purpose of this study was to determine if a short course of monoclonal antibody (mAb) against CD45RB, LF 15-0195, and rapamycin would achieve long-term survival by inducing tolerance in a mouse limb transplant model. METHODS: Group 1 (n=9) consisted of nine isogenic (C57BL/6) transplants. Group 2 (n=3) included C57BL/6-to-BALB/c transplants receiving no drug therapy. Group 3 mice (n=4) were treated with mAb (3 mg/kg) and LF (2 mg/kg), and Group 4 (n=13) was treated with mAb, LF, and rapamycin (2 mg/kg). Both treatment groups received drug treatment for only 14 days posttransplantation. Animals were sacrificed if they displayed evidence of rejection or when deemed to be tolerant (defined as >day 100). RESULTS: All isografts had normal histology and graft function on day 100. Untreated C57BL/6-to-BALB/c allografts developed acute rejection within 10 days. The combination of mAb and LF prolonged allograft survival to a mean of 39+/-7 days. In Group 4, two animals had to be sacrificed at days 28 and 76 due to acute urinary retention. Transplant tolerance was achieved in 8 of the remaining 11 animals with a mean survival time of 100+/-12 days. Donor specific tolerance was demonstrated through permanent acceptance of skin grafts from the donor strain and rejection of skin grafts from C3H mice. Three Group 4 animals showed clinical and histological signs of mild, chronic rejection. Dendritic cells isolated from tolerant recipients exerted a suppressive effect in mixed lymphocyte reaction. CONCLUSION: A short course of anti-CD45RB mAb and LF 15-0195 prolonged limb allograft survival. The addition of rapamycin induced limb allograft tolerance which is associated with the generation of tolerogenic dendritic cells that suppressed T-cell proliferation.     

Operational tolerance induced by pretreatment with donor dendritic cells under blockade of CD40 pathway.

BACKGROUND: Dendritic cells can mount immune response as competent antigen presenting cells. Recently, it has been reported that immature dendritic cells induce prolongation of allograft survival. However, the ability of mature dendritic cells to induce operational tolerance is unclear. Therefore, in this study, we examined the ability of splenic mature dendritic cells to induce operational tolerance to fully allogeneic antigens using mouse heterotopic heart transplantation model. METHODS: CBA (H2k) mice received i.v. injections with donor splenic dendritic cells or B cells in the absence or presence of monoclonal antibody (mAb) specific for CD40 ligand or CD80/CD86 2 weeks before transplantation of a C57BL/10 (H2b) heart. RESULTS: When donor dendritic cells were injected i.v. 2 weeks before transplantation, rejection response was accelerated compared with that of naive mice [median survival time (MST) = 7 and 8 days, respectively]. However, when CD40 pathway was blocked by anti-CD40 ligand mAb, i.v. injection of donor dendritic cells but not B cells induced indefinite graft survival (MST >100 and 20 days, respectively). Mice treated with anti-CD40 ligand mAb alone rejected their grafts with a MST of 18 days. Intravenous injection of donor dendritic cells and B cells in combination with anti-CD80/CD86 mAbs was less effective to induce graft prolongation (MST = 9.5 and 13 days, respectively). CONCLUSIONS: Therefore, under blockade of CD40 pathway, mature dendritic cells were tolerogens in vivo independent of CD80/86 pathways.     

Non-depleting anti-CD4, but not anti-CD8, antibody induces long-term survival of xenogeneic and allogeneic hearts in alpha1,3-galactosyltransferase knockout (GT-Ko) mice

The anti-galactose-alpha1,3-galactose (Gal) antibody (Ab) response following pig-to-human transplantation is vigorous and largely resistant to currently available immunosuppression. The recent generation of GT-Ko mice provides a unique opportunity to study the immunological basis of xenograft-elicited anti-Gal Ab response in vivo, and to test the efficacy of various strategies at controlling this Ab response [1]. In this study, we compared the ability of non-depleting anti-CD4 and anti-CD8 to control rejection and antibody production in GT-Ko mice following xenograft and allograft transplantation. Hearts from baby Lewis rat or C3H mice were transplanted heterotopically into GT-Ko. Non-depleting anti-CD4 (YTS177) and anti-CD8 (YTS105) Abs were used at 1 mg/mouse, and given as four doses daily from day -2 to 1 then q.o.d. till day 21. Xenograft rejection occurred at 3 to 5 days post-transplantation in untreated GT-Ko recipients, and was histologically characterized as vascular rejection. Anti-CD4, but not anti-CD8, Ab treatment prolonged xenograft survival to 68 to 74 days and inhibited anti-Gal Ab as well as xeno-Ab production. In four of the five hearts from anti-CD4 mAbs-treated GT-Ko mice, we observed classic signs of chronic rejection, namely, thickened intima in the lumen of vessels, significant IgM deposition, fibrosis and modest mononuclear cell infiltrate of Mac-1+ macrophages and scattered T cells (CD8>CD4). Xenograft rejection in untreated, as well as anti-CD4- and anti-CD8-treated, recipients was associated with increased intragraft IL-6, IFN-gamma and IL-10 mRNA. C3H allografts were rejected in 7 to 9 days by untreated GT-Ko mice and were histologically characterized as cellular rejection. Treatment with anti-CD4 and anti-CD8 mAb resulted in graft survivals of >94.8 and 11.8 days, respectively. Anti-CD4 mAb treatment resulted in a transient inhibition of alloreactive and anti-Gal Ab production. The presence of circulating alloreactive and anti-Gal Abs at >50 days post-transplant was associated with significant IgM and IgG deposition in the graft. Yet, in the anti-CD4 mAb-treated group, the allografts showed no signs of rejection at the time of sacrifice (>100 days post-transplantation). All rejected allografts had elevated levels of intragraft IL-6, IFN-gamma and IL-10 mRNA, while the long-surviving anti-CD4-treated allografts had reduced mRNA levels of these cytokines. Collectively, our studies suggest that the elicited xeno-antibody production and anti-Gal Ab production in GT-Ko mice are CD4+ T-cell dependent. The majority of xenografts succumbed to chronic rejection, while allografts survived with minimal histological change, despite elevated levels of circulating alloAbs. Thus, immunosuppression with anti-CD4 mAb therapy induces long-term survival of allografts more effectively than to xenografts.     

CD45RB-targeting strategies for promoting long-term allograft survival and preventingchronic allograft vasculopathy

BACKGROUND: CD45RB is a potent immunomodulatory target to achieve long-term allograft survival. We evaluated the in vivo effect of anti-CD45RB monoclonal antibody (mAb) treatment in combination with conventional immunosuppression or costimulatory blockade strategies as a therapeutic modality for future clinical application. METHODS: A fully MHC-mismatched vascularized mouse cardiac allograft model was used to test the interactions between anti-CD45RB mAb and conventional immunosuppressive drugs or costimulatory blockade of the CD40/CD154 or B7/CD28 pathway. Chronic rejection was examined histologically for development of chronic allograft vasculopathy. RESULTS: Cyclosporine significantly abrogated the effect of anti-CD45RB therapy. In contrast, rapamycin acted synergistically with anti-CD45RB mAb in promoting long-term allograft survival. CD154 blockade further enhanced the tolerogenic efficacy of anti-CD45RB mAb. These synergistic effects of combination treatments also prevented the development of chronic allograft vasculopathy. CONCLUSION: CD45RB-targeting strategy in combination with the use of rapamycin or costimulatory blockade promotes allograft tolerance and prevents chronic rejection.     

Critical Role for CD8+ T Cells in Allograft Acceptance Induced by DST and CD40/CD154 Costimulatory Blockade

Donor-specific transfusion (DST) and CD40/CD154 costimulation blockade is a powerful immunosuppressive strategy which prolongs survival of many allografts. The efficacy of DST and anti-CD154 mAb for prolongation of hepatocellular allograft survival was only realized in C57BL/6 mice that have both CD4- and CD8-dependent pathways available (median survival time, MST, 82 days). Hepatocyte rejection in CD8 KO mice which is CD4-dependent was not suppressed by DST and anti-CD154 mAb treatment (MST, 7 days); unexpectedly DST abrogated the beneficial effects of anti-CD154 mAb for suppression of hepatocyte rejection (MST, 42 days) and on donor-reactive alloantibody production. Hepatocyte rejection in CD4 KO mice which is CD8-dependent was suppressed by treatment with DST and anti-CD154 mAb therapy (MST, 35 days) but did not differ significantly from immunotherapy with anti-CD154 mAb alone (MST, 32 days). Induction of hepatocellular allograft acceptance by DST and anti-CD154 mAb immunotherapy was dependent on host CD8(+) T cells, as demonstrated by CD8 depletion studies in C57BL/6 mice (MST, 14 days) and CD8 reconstitution of CD8 KO mice (MST, 56 days). These studies demonstrate that both CD4(+) and CD8(+) T-cell subsets contribute to induction of hepatocellular allograft acceptance by this immunotherapeutic strategy.     

Anti-CD45RB Monoclonal Antibody Prolongs Renal Allograft Survival in Cynomolgus Monkeys

Previously, an anti-CD45RB monoclonal antibody (mAb) has been shown to induce murine allograft tolerance. The present study was performed to assess the ability of an anti-human CD45RB mAb to prevent rejection in a monkey MHC-mismatched kidney transplant model. The recipients were allocated into the following treatment groups: (1) isotype control IgG; (2) mouse anti-human CD45RB IgG1 (6G3); (3) human-mouse chimeric anti-CD45RB-IgG1 (C6G3-IgG1); (4) human-mouse chimeric anti-CD45RB-IgG2 (C6G3-IgG2); (5) tacrolimus at a subtherapeutic dose and (6) tacrolimus and C6G3-IgG1 in combination. Monotherapy with anti-CD45RB mAb significantly prolonged renal allograft survival to a median survival of 21 days. Adding a subtherapeutic dose of tacrolimus improved the efficacy of the anti-CD45RB mAb, achieving a median survival of 85 days, whereas a subtherapeutic dose of tacrolimus alone only moderately prolonged survival to 27 days. Treatment with anti-CD45RB mAb resulted in an alteration of the CD45RB(hi) : CD45RB(lo) cell ratio in the peripheral blood. We have, for the first time, demonstrated that an anti-human CD45RB mAb (6G3) can prolong graft survival. Induction with an anti-CD45RB mAb improves the efficacy of tacrolimus in the prevention of rejection. These encouraging results indicate that an anti-CD45RB mAb may be valuable in future clinical transplantation.     

Dose-related mechanisms of immunosuppression mediated by murine anti-CD3 monoclonal antibody in pancreatic islet cell transplantation and delayed-type hypersensitivity

Although anti-CD3 mAb therapy is used extensively in clinical transplantation, the dose-related effects and mechanisms of action are not clearly defined. We have examined the dose-related effects of an antimurine CD3 mAb, 145-2C11, in pancreatic islet cell allograft and the delayed type hypersensitivity reaction models of T-cell-dependent immunity. Low-dose anti-CD3 therapy (0.5 micrograms/day) administered over several days mediated superficially equal, effective clinical immunosuppression as a single high-dose intravenous injection (400 micrograms). T cells harvested from animals treated with high-dose anti-CD3 were unresponsive to in vitro restimulation. In contrast, T cells isolated from low-dose treated animals retained in vitro proliferative capacity when restimulated with polyvalent anti-CD3 mAb. The terminal complement components were not required to support in vivo immunosuppression mediated by anti-CD3 mAb as C5 deficient mice were immunosuppressed by the administration of this mAb. In some pancreatic islet cell allograft recipients, permanent engraftment, but not tolerance, was achieved. Replacement of donor leukocytes produced acute rejection in hosts bearing long-term, well-accepted grafts. Prolonged anti-CD3 mAb treatment may provide sufficient time for replacement or inactivation of donor leukocytes.     

Association of rapamycin and co-stimulation blockade using anti-B7 antibodies in renal allotransplantation in baboons.

BACKGROUND: Co-stimulation blockade has already been shown to induce transplantation tolerance in rodents, but until now has failed in large animal models. We therefore sought to investigate whether the addition of rapamycin to a co-stimulation blockade regimen could induce tolerance in baboon recipients of a renal allograft and to characterize the immunological characteristics of rejection. METHODS: Two baboons were used for a pharmacological and toxicological analysis and received anti-B7.1 and anti-B7 antibodies every other day for 60 days. Three groups of baboons underwent classical heterotopic renal allotransplantation; the first group received no treatment (control group; n = 2), the second received a combination of anti-CD80 and anti-CD86 monoclonal antibodies (mAbs) (B7 group; n = 4), and the third received the anti-B7 antibody treatment as above with an additional treatment of rapamycin (B7-Rapa; n = 4). Graft survival as well as immunological analyses were performed. RESULTS: Anti-B7 mAb monotherapy prolonged allograft survival in three out of four of the animals, one of whom survived rejection free for 87 days but died from a pulmonary embolism; the fourth animal died without rejection. The addition of rapamycin to the regimen did not prolong survival further; three of the four animals underwent early rejection whereas the fourth survived long term but eventually rejected at day 114. Whereas alloimmunization only occurred in this latter animal, rejection was always characterized by a substantial lymphocyte and monocyte infiltration, associated with a strong pro-inflammatory/cytotoxic mRNA accumulation in the anti-B7-treated animals, but to a lesser extent in the B7-Rapa group. T cells extracted and cloned from a biopsy taken at a stable post-transplant time showed a lower frequency of anti-donor alloreactivity in vitro than those extracted from a rejected tissue. Nevertheless, these non-responding clones failed to show regulatory activity in vitro. CONCLUSIONS: We thus confirm that blocking the CD28/B7 pathway by anti-B7 mAbs could prolong graft survival in baboons, but the addition of rapamycin was insufficient to induce tolerance.     

Marked inhibition of transplant vascular sclerosis by in vivo-mobilized donor dendritic cells and anti-CD154 mAb

BACKGROUND: Combination of donor dendritic cells (DC) and anti-CD40 Ligand (L) (CD154) monoclonal antibody (mAb) markedly prolongs heart or skin allograft survival, but the influence of this strategy in models of chronic rejection is unknown. Our aim was to ascertain the influence of in vivo-mobilized immature donor DC plus anti-CD40L mAb on vascular sclerosis in functional murine aortic allografts. METHODS: C3H He/J (C3H;H2k) mice received 2 x 106 freshly isolated, immunobead-purified (>90%) fms-like tyrosine kinase 3 ligand-mobilized C57BL/10 (B10;H2b) CD11c+ DC intravenously (IV), together with 500 microg of anti-CD40L mAb (MR1) intraperitoneally (IP) on days -7, 0, 4, and 10. Controls received either no donor cells, no mAb, or were untreated. B10 aortic grafts were transplanted in the abdominal aorta on day 0. At day 30, antidonor T-cell proliferative and cytotoxic responses and both complement fixing and immunoglobulin (Ig)G alloantibody levels were determined. Grafts were harvested on days 30 and 60 and examined by histology and immunohistochemistry. RESULTS: DC infusion alone enhanced ex vivo antidonor proliferative and cytotoxic T-cell activity. By contrast, complement-fixing alloantibody levels were reduced. Anti-CD40L mAb alone strongly suppressed each of these responses. Graft inflammatory cell infiltration, intimal smooth muscle cell proliferation, fibrosis, and elastic lamina disruption observed in untreated animals were reduced in response to anti-CD40L mAb or donor DC alone. Antidonor immune reactivity, including IgG levels, and intimal proliferation were all markedly suppressed to an overall greater extent in mice given both treatments. CONCLUSION: Whereas blockade of the CD40-CD40L pathway ameliorated transplant vasculopathy, preservation of near-normal vessel architecture was achieved by simultaneous administration of donor DC. This strategy represents a novel application of DC for suppression of chronic rejection.     

Blockade of the PD-1/PD-1L pathway reverses the protective effect of anti-CD40L therapy in a rat to mouse concordant islet xenotransplantation model

BACKGROUND: We have previously demonstrated that costimulatory blockade with anti-CD40L monoclonal antibody (mAb) prolongs the survival of non-vascularized concordant rat to mouse islet xenografts. Here, we examine whether signaling through the PD-1/PD-1L pathway is required for the anti-CD40L therapy to prolong concordant islet graft survival using a novel anti-murine PD-1 mAb (clone 4F10). METHODS: C57BL/6 mice received a cellular concordant islet xenograft under the left kidney capsule and four experimental groups were prepared. Group I: untreated control; group II: recipient mice were treated with three doses of 0.5 mg of anti-CD40L mAb (clone MR1) on days 0, 2 and 4; group III: mice were treated with 0.5 mg of anti-PD-1 (CD279) mAb (clone 4F10) every other day for 8 days; and finally group IV: mice received the combined treatment that consisted of anti-CD40L plus anti-PD-1 mAb. RESULTS: Concordant islet xenografts transplanted in control untreated mice showed a median survival time (MST) of 17 +/- 7.43 days, whereas anti-CD40L treatment led to a significant prolongation of graft survival (MST: 154 +/- 65.56, P < 0.0001). The administration of anti-PD-1 alone significantly accelerated graft rejection compared to non-treated controls (MST: 10 +/- 2.24 vs. MST: 17 +/- 7.43, P < 0.0004). Remarkably, the combined administration of anti-CD40L and anti-PD-1 reversed the protective effect obtained with anti-CD40L alone (anti-CD40L, MST: 154 +/- 65.56 vs. anti-CD40L plus anti-PD-1, MST: 10 +/- 7.72, P < 0.0002). CONCLUSION: Overall, our data indicate that the PD-1/PD-1L pathway is required for the achievement of prolonged graft survival in anti-CD40L-treated mice in a setting of rat to mouse concordant islet xenotransplantation.     

CTLA-4Ig in Combination with Anti-CD40L Prolongs Xenograft Survival and Inhibits Anti-Gal Ab Production in GT-Ko Mice

The generation of GT-Ko mice has provided unique opportunities to study allograft and xenograft rejection in the context of anti-alpha1,3-Gal antibody (anti-Gal Ab) responses. In this study we used the allotransplantation model of C3H hearts into galactosyltransferase-deficient (GT-Ko) mice and the xenotransplantation model of baby Lewis rat hearts into GT-Ko mice to investigate the ability of CTLA-41g in combination with anti-CD40L mAb to control graft rejection and anti-Gal Ab production. Murine CTLA-41g or anti-CD40L monotherapy prolonged allograft survival, and the combination of these reagents was most immunosuppressive. However short-term treatment with murine cytotoxic T lymphocyte associated antigen-4 (muCTLA-41g) and/or CD40 ligand (CD154) monoclonal antibodies (anti-CD40L mAbs) was unable to induce indefinite allograft survival. CTLA-4-immunoglobulin fusion protein (CTLA-41g) or anti-CD40L monotherapy only marginally prolonged xenograft survival; the combination of human CTLA-41g and anti-CD40L significantly prolonged xenograft survival (74days), while the combination of murine CTLA-41g and anti-CD40L resulted in graft survival of >120days. CTLA-41g or anti-CD40L monotherapy or the combination of these agents inhibited the production of alloAbs, including anti-Gal Abs. CTLA-41g or anti-CD40L monotherapy partially controlled xenoAb and anti-Gal Ab production, while the combination was more effective. These observations corroborate our previous observations that humoral, including anti-Gal Ab, responses and rejection following allograft or concordant xenograft transplantation in GT-Ko mice are T-cell dependent and can be controlled by costimulation blockade.     

Treatment with humanized monoclonal antibodies against CD80 and CD86 combined with sirolimus prolongs renal allograft survival in cynomolgus monkeys

BACKGROUND: Co-stimulatory blockade has been shown to prolong allograft survival in different transplant models. We investigated the effect of combining humanized anti-CD80 and anti-CD86 monoclonal antibodies (mAb) with sirolimus in cynomolgus monkey renal transplant recipients. METHODS: After renal transplantation, groups of four animals were treated daily with sirolimus, sirolimus and nine weekly doses of mAb, two weekly doses of mAb, or sirolimus and two weekly doses of mAb. RESULTS: Survival was significantly better in monkeys treated with the combination of sirolimus and mAb when compared with treatment with either agent alone (P=0.0067 by log-rank analysis). When combined with sirolimus, nine weekly doses of mAb did not result in an additional survival benefit compared with only two mAb doses (P=0.74). None of the treatment regimens used in this study resulted in development of transplantation tolerance. CONCLUSIONS: Sirolimus can be successfully combined with humanized mAb against CD80 and CD86. Induction with a short course of mAb is effective in prolonging allograft survival in combination with sirolimus.     

Suppression of the humoral response to anti-CD3 monoclonal antibody

Anti-CD3 monoclonal antibodies are used clinically to treat organ allograft rejection. Their administration can result in reversal of rejection even in episodes resistant to other modes of therapy. A major limitation to their use has been the humoral response of the patients against the mAbs, resulting in loss of therapeutic efficacy. We have established an animal model for anti-CD3 treatment using the antimurine CD3 mAb, 145-2C11. Exposure of mice to this mAb, like exposure of humans to its antihuman analog OKT3, results in suppression of graft rejection but also stimulates a strong humoral response that abrogates the efficacy of further treatments. Administration of an additional dose of anti-CD3 mAb did not prolong skin graft survival--and, in some instances, resulted in a lethal anaphylactic reaction. In an attempt to suppress the humoral response against the anti-CD3 mAb, anti-CD4 mAb was administered prior to the anti-CD3 mAb treatment. Pretreatment of mice with anti-CD4 mAb (GK1.5) almost completely suppressed the humoral response to anti-CD3 mAb, and permitted readministration of the anti-CD3 mAB without loss of efficacy as assessed by prolongation of skin graft survival. The data suggest that the use of anti-CD4 mAb to suppress the humoral response against anti-CD3 mAb should be attempted clinically, as it might permit repeated courses of anti-CD3 administration, thus significantly improving the efficacy of these agents in the therapy of organ allograft rejection.     

Patterns of immune responses evoked by allogeneic hepatocytes: evidence for independent co-dominant roles for CD4+ and CD8+ T-cell responses in acute rejection.

INTRODUCTION: This is the first in a series of reports that characterizes immune responses evoked by allogeneic hepatocytes using a functional model of hepatocyte transplantation in mice. METHODS: "Donor" hepatocytes expressing the transgene human alpha-1-antitrypsin (hA1AT-FVB/N, H2q) were transplanted into C57BL/6 (H2b) or MHC II knockout (H2b) hosts treated with anti-CD4, anti-CD8, or a combination of anti-CD4 and anti-CD8 monoclonal antibodies (mAbs). Hepatocyte rejection was determined as a loss of circulating ELISA-detectable transgene product (hA1AT). In addition, some C57BL/6 mice underwent transplantation with FVB/N heterotopic cardiac allografts and were treated with anti-CD4 mAb. Cardiac allograft rejection was determined by palpation. Graft recipients were tested for donor-reactive alloantibodies and donor-reactive delayed-type hypersensitivity (DTH) responses. RESULTS: The median survival time (MST) of allogeneic hepatocytes in normal C57BL/6 mice was 10 days (no treatment), 10 days (anti-CD4 mAb), 14 days (anti-CD8 mAb), and 35 days (anti-CD4 and anti-CD8 mAbs). The MST of hepatocytes in B6 MHC class II knockout mice was 10 days (no treatment) and 21 days (anti-CD8 mAb). The MST of cardiac allografts was 11 days (no treatment) and >100 days (anti-CD4 mAb). Donor-reactive DTH responses were readily detected in both untreated and mAb-treated recipients. Donor-reactive alloantibody was barely detectable in untreated hosts. CONCLUSIONS: These studies demonstrate that allogeneic hepatocytes are highly immunogenic and stimulate strong cell-mediated immune responses by both CD4+ and CD8+ T cells, even when treated with agents that can cause acceptance of cardiac allografts. Indeed, CD4+ or CD8+ T cells seem to independently cause hepatocellular allograft rejection. Allogeneic hepatocytes evoked strong donor-reactive DTH responses but were poor stimuli for donor-reactive antibody production. This is an unusual pattern of immune reactivity in allograft recipients.     

4-1BB promotes long-term survival in skin allografts treated with anti-CD45RB and anti-CD40L monoclonal antibodies

4-1BB (CD137) is a T-cell co-stimulatory molecule that promotes T cell activation. Using a skin transplantation model, we observed that simultaneous administration of monoclonal antibodies (mAb) targeting CD45RB and CD40L prolonged skin allograft in co-stimulation blockade (CTLA4-Ig and anti-CD40L mAb)-resistant mice, because of reducing CD8(+) T cells and CD4(+) CD45RB(high) T cells. Anti-CD45RB mAb (45RB) blocks the activation of T helper 1 (Th1) cells and generates regulatory T cells (T(reg)). The experimental design included five groups: group 1, control; group 2, 45RB-MR1; group 3, 45B-MR1 + 4-IBBL; group 4, anti-CD4 mAb plus group 3 treatment; group 5, anti-CD8 mAb plus group 3 treatment. In this study we highlight the involvement of 4-1BB/4-1BBL in the development of T-cell responses. C57BL/6 recipients of BALB/c skin grafts were treated with 45RB, anti-CD40L mAb (MR1), and antagonistic anti-4-1BBL mAb (4-1BBL) on days 0, 2, 4, 6, and 8 posttransplantation. Additional 4-1BBL further prolonged skin graft survival, although the percentage of splenocyte-derived CD8(+) T cells was reduced similarly in both groups. Use of 4-1BBL seems to have additive effects on T(reg) cells, which play a major role in the maintenance of tolerance. Even after immunosuppressive therapy in combination with CD4(+) T-cell depletion, we did not achieve prolonged graft survival, possibly because of the absense of T(reg) cells, which require CD4-independent CD8(+) T cells, based on the observation of increasing proportion of CD8(+) T cells in similar degree as the control group.     

Use of anti-CD40 ligand monoclonal antibody as antirejection therapy in a murine peripheral nerve allograft model

Monoclonal antibody directed against CD40 ligand prevents acute allograft rejection in several models of solid-organ transplantation. This study describes the use of CD40 ligand as antirejection therapy in a mouse peripheral nerve allograft model. C3H mice received 8-mm nerve isografts (n = 2) or nerve allografts from C57BL donors. Treated animals (n = 11) received anti-CD40 ligand antibody applied to the graft and by intraperitoneal injections postoperatively. At 3 weeks, nerve histology from treated animals was comparable to isografts, whereas untreated allografts demonstrated virtually no signs of regeneration. Walking-track analysis demonstrated a trend toward improved functional recovery in treated animals. In conclusion, blockade of the CD40 pathway suppresses nerve allograft rejection in mice, and facilitates regeneration comparable to isografts.     

Anti-CD40L monoclonal antibodies can replace anti-CD4 monoclonal antibodies for the nonmyeloablative induction of mixed xenogeneic chimerism

BACKGROUND: We have previously demonstrated that xenogeneic bone marrow engraftment and donor-specific tolerance can be induced in mice receiving anti-CD4, -CD8, -Thy-1.2, and -NK1.1 monoclonal antibodies (mAbs) on Days -6 and -1, 3 Gy total body irradiation (TBI), and 7 Gy thymic irradiation on Day 0, followed by injection of T-cell depleted (TCD) rat bone marrow cells. We have recently demonstrated that anti-CD40L mAb treatment is sufficient to completely overcome CD4 cell-mediated resistance to allogeneic marrow engraftment and rapidly induce CD4 cell tolerance in an allogeneic combination. METHODS: We investigated the ability of anti-CD40L mAb to promote mixed xenogeneic chimerism and donor-specific tolerance in B6 mice receiving anti-CD8, -Thy1.2 and -NK1.1 mAbs and 3 Gy TBI followed by TCD bone marrow transplantation (BMT) from F344 rats. RESULTS: Administration of anti-CD4 mAb in this model could be completely replaced by one injection of anti-CD40L mAb. Evidence for deletional tolerance was obtained in mixed chimeras prepared with this anti-CD40L-based regimen. However, anti-NK1.1 and anti-Thy1.2 mAb could not be replaced by anti-CD40L mAb. CONCLUSIONS: These results demonstrate that anti-CD40L in combination with xenogeneic BMT can tolerize preexisting peripheral and intrathymic CD4 cells to xenoantigens. However, anti-CD40L does not prevent NK cell and/or gammaDelta cell-mediated rejection of xenogeneic bone marrow.