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.     

Lewis rat pancreas, but not cardiac xenografts, are resistant to anti-gal antibody mediated hyperacute rejection

BACKGROUND: The objective of this study was to evaluate the role of anti-Gal Abs and non-anti-Gal Abs in hyperacute rejection (HAR) of concordant pancreas xenografts compared with heart xenografts. In addition, we tested whether rejection of Lewis rat pancreas grafts was T-cell dependent and could be prevented by anti-T-cell treatment. METHODS: To determine the role of anti-Gal Abs in the induction of HAR, Lewis rat pancreas and heart xenografts were transplanted into alpha1,3Galactosyltransferase knockout (GT-Ko) mice treated with normal human serum (NHS) or hyperimmune serum, or into presensitized GT-Ko mice. To investigate whether rejection of pancreas xenograft was mediated by a T-cell dependent response, Lewis rat pancreas grafts were transplanted into streptozotocin (STZ)-induced diabetic GT-Ko mice treated with FK506, anti-CD4 mAbs (GK1.5), and thymectomy. Antidonor-specific IgM and IgG and anti-Gal Abs were analyzed by flow cytometry. Rejected and long-term surviving pancreas xenografts were assessed by functional (blood glucose) and histopathological examination. RESULTS: HAR of Lewis rat pancreas xenografts could not be induced by NHS (0.4 ml), whereas NHS (0.2 ml) resulted in HAR of Lewis heart xenografts. Infusion of Lewis rat-specific hyperimmune serum (0.2 ml) resulted in HAR of Lewis rat pancreas xenografts. In addition, second Lewis rat pancreas grafts were hyperacutely rejected by presensitized GT-Ko mice. Immunohistochemical staining showed a low expression of Galalpha1,3Gal antigen in the endocrine tissue compared with that in the cardiac grafts. The levels of anti-Gal Abs in pancreas xenograft transplantation did not increase in GT-Ko mice after pancreas xenograft transplantation that was significantly increased after heart transplantation. FK506 treatment induced long-term survival of Lewis pancreas xenografts (mean survival time (MST) >90 days). Anti-CD4 treatment delayed rejection of Lewis rat pancreas xenografts with MST of 34.3 days, whereas anti-CD4, in combination with thymectomy, synergistically prolonged survival of pancreas xenograft (MST=70.4 days). CONCLUSION: Pancreas xenograft is resistant to anti-Gal Abs-induced HAR but is susceptible to anti-donor specific Abs. Rejection of Lewis pancreas xenograft in STZ-induced, diabetic, GT-Ko mice is T-cell dependent.     

Long-term survival of hamster islet xenografts in mice under short-course treatment with nondepleting versus depleting anti-CD4 monoclonal antibodies

ABSTRACT: Xenogeneic grafts provide a potential alternative to the current shortage of human organs for transplantation. However, the prevention of rejection and tolerance induction of xenografts still remain to be further explored. Islet xenografts appear more promising than vascularized whole organ xenografts and additionally also more resistant to the recurrence of autoimmune disease than allografts. Recently, the nondepleting monoclonal antibody (mAb), which blocks the CD4 molecule on lymphocytes, was reported to be able to induce tolerance in allotransplantation and CD4 positive cells were further confirmed to be a major factor responsible for cellular xenograft rejection. Therefore, we hypothesize that anti-CD4 nondepleting mAb could also be effective in protecting cellular xenografts and inducing unresponsiveness of recipients. We studied the effect of the nondepleting anti-CD4 mAb YTS177.9 on islet xenograft survival by using the hamster-to-mouse islet transplantation model. Results were compared with that of the depleting anti-CD4 mAb GK1.5 that was shown to have similar binding sites on the CD4 molecule to mAb YTS 177.9. Our data show that mAb YTS 177.9 did effectively prolong the survival of islet xenografts and, in addition, also successfully did induce long-term acceptance of 40% grafts after only three penoperative injections of 0.5 mg mAb per mouse. The average survival of the graft was markedly prolonged to >66.8±37.1 days compared with controls (8.3±1.4 days) or with the depleting anti-CD4 mAb GK1.5 (25.7±5.5 days). However, the latter displayed a more profound inhibition in in vitro and ex vivo mixed lymphocyte xenoreaction than mAb YTS 177.9. Moreover, the activity of this nondepleting mAb was found to be dose-dependent and 80% of grafts survived permanently when the dose was increased to six injections of 0.5 mg mAb. Like mAb GK1.5, mAb YTS 177.9 also prevented rejection when given after a delay of two days posttransplant. In addition, we found that neither depleting nor nondepleting anti-CD8 mAb was effective in this model. Our results strongly suggest that an anti-CD4 nondepleting or blocking mAb alone is able to induce long-term acceptance of islet xenografts and that blocking the CD4 molecule is significantly superior to depleting CD4 positive cells for the protection of islet xenografts. This may indicate that CD4 cells play a major role in xenograft tolerance induction.     

Prolongation of allograft and xenograft survival in mice by anti-CD2 monoclonal antibodies.

Anti-CD2 monoclonal antibodies (mAb) were used to influence graft survival in two transplantation models. Xenogeneic rat islets were transplanted intraportally into mice. Anti-CD2 mAb prolonged xenograft survival and was synergistic with UVB irradiation in prolonging survival. Anti-CD2 mAb was also more potent than an anti-CD4 mAb in this model. Allogeneic cardiac grafts were transplanted across an entire H-2 difference and anti-CD2 mAb prolonged allograft survival in a dose-dependent fashion. Kinetic experiments revealed that anti-CD2 mAb was most potent when administered at the time of allografting. A delay in administration of mAb markedly reduced its immunosuppressive effects. Furthermore, additional doses of mAb given after the initial doses provided no increased immunosuppression and anti-CD2 mAbs did not delay rejection of second-set allografts. These findings support the notion that anti-CD2 mAbs interfere with afferent immunity and that CD2 is most important during the initial steps of an immune response. Investigation of the effect of anti-CD2 mAb on cellular immune functions demonstrated, in agreement with previous results, that it caused antigenic down-modulation of CD2 with relative sparing of CD3, CD4, and CD8 cell surface expression. Concomitantly the MLR, CTL, and NK responses were suppressed.     

Anti-CD40L monoclonal antibody treatment induces long-term, tissue-specific, immunologic hyporesponsiveness to peripheral nerve allografts

The CD40/CD40L costimulatory pathway plays a crucial role in allograft rejection. The purpose of this study was to determine the effectiveness of anti-CD40L monoclonal antibody (mAb) treatment as a method to induce long-term, tissue-specific, immunologic hyporesponsiveness to peripheral nerve allografts. Sciatic nerve allografts were performed from BALB/c donor mice into C57BL/6 recipients. Anti-CD40L mAb (1 mg) was administered intraperitoneally to recipient mice on postoperative days 0, 1, and 2. After a 14-, 28-, or 60-day recovery period, the mice were rechallenged with either a BALB/c cardiac or peripheral nerve allograft. Rejection was assessed by measuring the production of interferon gamma (IFN-gamma), interleukin (IL)-2, -4, and -5, and alloantibodies immunoglobulin (Ig) M and IgG. IFN-gamma, IL-2, IL-4, IL-5, IgM, and IgG responses were much lower in the anti-CD40L mAb group compared with controls. Nerve allograft and nerve isograft rechallenge 60 days following the original nerve allotransplantation produced low cytokine responses, whereas cardiac allograft rechallenge produced high cytokine production, indicative of acute rejection. Short-term anti-CD40L treatment may cause long-term, tissue-specific, immunologic hyporesponsiveness. This may allow time for native axons to traverse the transplanted nerve allograft and replace the graft with autogenous peripheral nerve tissue.     

Prolonged allograft survival in anti-CD4 antibody transgenic mice: lack of residual helper T cells compared with other CD4-deficient mice

BACKGROUND: Investigations of the role of CD4 T lymphocytes in allograft rejection and tolerance have relied on the use of mouse models with a deficiency in CD4 cells. However, in mice treated with depleting monoclonal antibody (mAb) and in MHC class II knockout (KO) mice, there are residual populations of CD4 cells. CD4 KO mice had increased CD4- CD8-TCRalphabeta+ helper T cells, and both strains of KO mice could reject skin allografts at the normal rate. In this study, transgenic mice with no peripheral CD4 cells were the recipients of skin and heart allografts. Results were compared with allograft survival in CD4 and MHC class II KO mice. METHODS: GK5 (C57BL/6 bml mice transgenic for a chimeric anti-CD4 antibody) had no peripheral CD4 cells. These mice, and CD4 and class II KO mice, received BALB/c or CBA skin or cardiac allografts. Some GK5 mice were treated with anti-CD8 mAb to investigate the role of CD8 cells in rejection. CD4 and CD8 cells were assessed by FACS and immunohistochemistry. RESULTS: BALB/c skin on GK5 mice had a mean survival time +/- SD of 24+/-6 days, compared with 9+/-2 days in wild-type mice. Anti-CD8 mAb prolonged this to 66+/-7 days. BALB/c skin survived 10+/-2 days on class II KO and 14+/-2 days on CD4 KO, both significantly less than the survival seen on GK5 recipients (P<0.001). BALB/c hearts survived >100 days in GK5 recipients and in wild-type recipients treated with anti-CD4 mAb at the time of grafting, in contrast to a mean survival time of 10+/-2 days in untreated wild-type mice. Immunohistochemistry revealed that long-term surviving heart allografts from the GK5 recipients had CD8 but no CD4 cellular infiltrate. These hearts showed evidence of transplant vasculopathy. CONCLUSIONS: The GK5 mice, with a complete absence of peripheral CD4 cells, provide the cleanest available model for investigating the role of CD4 lymphocytes in allograft rejection. Prolonged skin allograft survival in these mice compared with CD4 and MHC class II KO recipients was clearly the result of improved CD4 depletion. Nevertheless, skin allograft rejection, heart allograft infiltration, and vascular disease, mediated by CD8 cells, developed in the absence of peripheral CD4 T cells.     

Rejection responses to allogeneic hepatocytes by reconstituted SCID mice, CD4, KO, and CD8 KO mice

INTRODUCTION: The purpose of the current study was to investigate the capacity of CD4+, CD8+, or non-T cells to independently initiate acute rejection of allogeneic hepatocytes using reconstituted SCID, CD4 or CD8 knockout (KO) recipient mice. METHODS: Allogeneic hepatocytes (FVB/N, H-2q) were transplanted into C57BL/6.SCID (H-2b), CD4 KO (H-2b), CD8 KO (H-2b), or beige/beige (H-2b) mice. SCID mice with functioning hepatocellular allografts subsequently received purified non-T cells (NTC), CD4+, or CD8+ splenocytes. Some mice were treated with anti-CD4, anti-CD8, and/or anti-nkl.1 mAb. Recipient mice were also assessed for donor-reactive delayed-type hypersensitivity (DTH) responses and donor-reactive alloantibody production. RESULTS: Median hepatocellular allograft survival time (MST) was 28 days in CD4+ reconstituted SCID mice and 14 days in CD8+ reconstituted SCID mice. SCID hosts reconstituted with NTC demonstrated indefinite hepatocellular allograft survival (>120 days). MST was 10 days in untreated beige/beige (NK cell deficient) mice. MST was 14 days in untreated, 35 days in anti-CD4 mAb treated, and 10 days in anti-nkl.1 mAb treated CD8 KO mice. MST was 10 days in untreated, 35 days in anti-CD8 mAb treated, and 7 days in anti-nk1.1 mAb treated CD4 KO mice. Donor-reactive DTH responses were not detected in reconstituted SCID mice, were minimal in CD4 KO mice, and were prominent in CD8 KO mice after rejection of allogeneic hepatocytes. Similarly, donor-reactive alloantibody, was not detected in CD4 KO hosts, but was readily detected in CD8 KO hosts. CONCLUSIONS: These studies show that both CD4+ and CD8+ T cells (but not host NTC) can independently initiate the rejection of allogeneic hepatocytes. While hepatocyte rejection by isolated CD4+ T cells is not surprising, rejection by CD8+ T cells (in the absence of CD4+ T cells) was unusual, and may explain the failure of "standard" immunosuppressive regimens to suppress acute rejection of allogeneic hepatocytes, as noted in prior studies. Furthermore, NK cells do not appear to be required for either CD4+ T cell or CD8+ T cell initiated hepatocyte rejection.     

Depleting anti-CD4 monoclonal antibody cures new-onset diabetes, prevents recurrent autoimmune diabetes, and delays allograft rejection in nonobese diabetic mice

BACKGROUND: The prevention of recurrent autoimmunity is a prerequisite for successful islet transplantation in patients with type I diabetes. Therapies effective in preserving pancreatic beta-cell mass in patients with newly diagnosed diabetes are good candidates for achieving this goal. Anti-CD3 monoclonal antibody (mAb) and antilymphocyte antisera are the only therapies to date that have cured early diabetic disease in the nonobese diabetic (NOD) mouse. We investigated whether other immunosuppressive therapies, including short-term depleting anti-CD4 mAb or costimulation blockade, would affect the disease progression in recently diabetic NOD mice. We also evaluated the effect of the anti-CD4 mAb on syngeneic and allogeneic graft survival in diabetic NOD recipients. METHODS AND RESULTS: We demonstrate that a short course of anti-CD4 mAb early after hyperglycemia onset cured diabetes. Normal islets and islets with CD4+ and CD8+ T-cell peri-insulitic infiltrate were found in the pancreata of cured NOD mice. A similar regimen prevented the recurrence of autoimmune diabetes in NOD/severe combined immunodeficient disease (SCID) islet isografts and delayed the rejection of allogeneic C57BL/6 islet allografts in diabetic female NOD mice. The co-transfer of diabetogenic splenocytes with splenocytes from anti-CD4 mAb-treated and cured NOD mice into 7-week-old, irradiated, NOD male mice was not able to protect from diabetes occurrence. This indicates that an anti-CD4-mediated cure of diabetes is independent of the induction of immunoregulatory T cells. Anti-CD154 mAb and cytotoxic T-lymphocyte antigen 4 immunoglobulin were ineffective in early-onset diabetes. CONCLUSION: Our results provide the first evidence that newly established autoimmune islet destruction in NOD mice responds to a short course of anti-CD4 mAb. In contrast, costimulation blockade is ineffective in this clinically relevant model.     

Evidence for tissue-directed immune responses: analysis of CD4- and CD8-dependent alloimmunity

BACKGROUND: Transplant rejection has generally been considered a CD4 T-cell-dependent immune process. CD4-independent, CD8 T-cell rejection pathways have recently gained attention because of their relative resistance to immunosuppression. In the current study, the role of the allograft tissue in activation of these distinct pathways was examined by comparing host-immune responses with allogeneic pancreatic islets or hepatocytes transplanted across the same genetic disparity. METHODS: To compare activation of CD4-dependent versus CD8-dependent alloimmunity, islets or hepatocytes retrieved from FVB/N (H-2) mice were transplanted into CD8 or CD4 T-cell-reconstituted severe combined immunodeficiency mice, CD4 or CD8 knockout (KO) mice, and anti-CD4 monoclonal antibody (mAb) or anti-CD8 mAb treated C57BL/6 mice (all H-2). The ability to immunomodulate CD4-dependent allograft rejection (in CD8 KO mice) was examined in the context of several mechanistically distinct immunotherapeutic strategies, including anti-CD4 mAb, donor-specific transfusion and anti-CD154 mAb, and anti-lymphocyte function-associated antigen-1 mAb. RESULTS: The studies demonstrate that, whereas hepatocytes evoke alloreactive CD4-dependent and (CD4-independent) CD8 T-cell immune responses, allogeneic islets only activate CD4-dependent immune pathways. CD4-dependent host-immune responses initiated by pancreatic islet allografts were readily suppressed by a variety of short-term immunotherapies, whereas hepatocyte-initiated CD4-dependent alloimmune responses were not. CONCLUSIONS: These results demonstrate that immune characteristics of the specific allograft tissue uniquely influence the pattern of host immune responses such that the propensity to activate CD4- or CD8-dependent alloimmune responses can be distinguished. Furthermore, CD4-dependent immune responses activated by different tissues from the same donor strain are distinguished by their susceptibility to specific immunotherapy.     

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.     

Blocking of mononuclear cell accumulation, cytokine production, and endothelial activation within rat cardiac allografts by CD4 monoclonal antibody therapy.

CD4 monoclonal antibody therapy prolongs allograft survival in a variety of experimental models and is currently undergoing clinical trials, though surprisingly little is known about the effects of CD4 mAb therapy on intragraft effector mechanisms that mediate rejection. We previously reported the significantly improved survival of (LEWxBN)F1 cardiac allografts in LEW rats treated for 10 days with the new CD4 mAb, BWH-4, at a dose of 700 micrograms/day, i.v., starting at the time of engraftment. Thus, CD4-treated rats showed prolongation of allograft survival to a median of 37 days (range 22 to greater than 100 days) post-Tx, compared with rejection at 7 days in untreated controls. We now report the results of detailed immunohistologic studies of allografts collected from these rats. Comparison of acutely rejecting allografts in untreated rats with well-functioning allografts collected at day 7 post-Tx from CD4-treated rats showed that CD4 mAb: (1) significantly reduced mononuclear cell infiltration, interstitial edema, hemorrhage formation and vascular and extravascular thrombosis; (2) inhibited mononuclear cell induction of receptors for IL-2 and transferrin, and upregulation of class II antigens and ICAM-1 on leukocytes and endothelial cells; (3) suppressed intragraft mononuclear cell and/or endothelial production of the cytokines IL-1, IL-2, IL-6, IFN-gamma, and TNF; and (4) blocked upregulation of endothelial tissue factor and downregulation of thrombomodulin, and consequently inhibited fibrin deposition. Studies of allografts from CD4-treated rats collected at day 30 post-Tx, prior to clinical rejection, showed a resurgence of CD4+ cells within allografts and a dense cellular immune response. We conclude that short-term CD4 mAb therapy has potent and extensive inhibitory effects on cytokine-related mononuclear cell and endothelial activation in vivo, blocking multiple afferent and efferent steps of the alloresponse.     

An increase in the survival of murine H-2-mismatched cultured fetal pancreas allografts using depleting or nondepleting anti-CD4 monoclonal antibodies, and a further increase with the addition of cyclosporine

Depletion of CD4+ T lymphocytes with monoclonal antibodies (mAbs) has been shown to prolong allograft survival in mice. In this study, two rat anti-CD4 mAbs, H129.19 and GK1.5, were administered either alone or in combination with cyclosporine (CsA) to recipients of MHC-mismatched (H-2k to H-2d) cultured fetal pancreas allografts to determine their effect on graft survival. When compared with control mice, splenic CD4+ cells of GK1.5-treated mice were depleted by greater than 95%, but in H129.19-treated mice no depletion of CD4+ cells occurred. Instead, rat Ig was present on the surface of CD4+ cells in H129.19-treated mice. Anti-CD4 therapy with either H129.19 or GK1.5 prolonged fetal pancreas allograft survival to a similar extent, but did not lead to indefinite survival. Blockade of the CD4 antigen by the mAb H129.19 was as effective as the depletion of CD4+ cells by GK1.5 in prolonging allograft survival. Rejection of grafts by day 28 posttransplantation occurred in the absence of CD4+ cells, as determined by both flow cytometric examination of spleen cells and immunoperoxidase staining of the graft site. CsA alone did not prolong graft survival, but its addition to either H129.19 or GK1.5 mAb treatment significantly increased the survival rate of grafts at 28 days compared with mAb treatment alone. These results suggest that CD4+ cell depletion is not essential for effective anti-CD4 mAb therapy--and, further, that CsA may have a direct inhibitory effect on CD8+ cells during 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.     

Viral infection abrogates CD8(+) T-cell deletion induced by costimulation blockade

BACKGROUND: Treatment with a single donor-specific transfusion (DST) plus a brief course of anti-CD154 monoclonal antibody (mAb) prolongs skin allograft survival in mice. It is known that prolongation of allograft survival by this method depends in part on deletion of alloreactive CD8(+) T cells at the time of tolerance induction. Recent data suggest that infection with lymphocytic choriomeningitis virus (LCMV) abrogates the ability of this protocol to prolong graft survival. METHODS: To study the mechanism by which viral infection abrogates allograft survival, we determined (1) the fate of tracer populations of alloreactive transgenic CD8(+) T cells and (2) the duration of skin allograft survival following treatment with DST and anti-CD154 mAb in the presence or absence of LCMV infection. RESULTS: We confirmed that treatment of uninfected mice with DST and anti-CD154 mAb leads to the deletion of alloreactive CD8(+) T cells and is associated with prolongation of skin allograft survival. In contrast, treatment with DST and anti-CD154 mAb in the presence of intercurrent LCMV infection was associated with the failure to delete alloreactive CD8(+) T cells and with the rapid rejection of skin allografts. The number of alloreactive CD8(+) cells actually increased significantly, and the cells acquired an activated phenotype. CONCLUSIONS: Interference with the deletion of alloreactive CD8(+) T cells mediated by DST and anti-CD154 mAb may in part be the mechanism by which viral infection abrogates transplantation tolerance induction.     

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.     

Critical Role for IL-6 in Hypertrophy and Fibrosis in Chronic Cardiac Allograft Rejection

Chronic cardiac allograft rejection is the major barrier to long term graft survival. There is currently no effective treatment for chronic rejection except re-transplantation. Though neointimal development, fibrosis, and progressive deterioration of graft function are hallmarks of chronic rejection, the immunologic mechanisms driving this process are poorly understood. These experiments tested a functional role for IL-6 in chronic rejection by utilizing serial echocardiography to assess the progression of chronic rejection in vascularized mouse cardiac allografts. Cardiac allografts in mice transiently depleted of CD4+ cells that develop chronic rejection were compared with those receiving anti-CD40L therapy that do not develop chronic rejection. Echocardiography revealed the development of hypertrophy in grafts undergoing chronic rejection. Histologic analysis confirmed hypertrophy that coincided with graft fibrosis and elevated intragraft expression of IL-6. To elucidate the role of IL-6 in chronic rejection, cardiac allograft recipients depleted of CD4+ cells were treated with neutralizing anti-IL-6 mAb. IL-6 neutralization ameliorated cardiomyocyte hypertrophy, graft fibrosis, and prevented deterioration of graft contractility associated with chronic rejection. These observations reveal a new paradigm in which IL-6 drives development of pathologic hypertrophy and fibrosis in chronic cardiac allograft rejection and suggest that IL-6 could be a therapeutic target to prevent this disease.     

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.     

Anti-CD25 mAb administration prevents spontaneous liver transplant tolerance

Liver allografts are accepted spontaneously in all mouse strain combinations without immunosuppressive therapy. The mechanisms underlying this phenomenon remain largely undefined. In this study, we examined the effect of CD4+ CD25+ T regulatory cells (Treg) on the induction of mouse liver transplant tolerance. Orthotopic liver transplantation was performed from B10 (H2b) to C3H (H2k) mice. Depleting rat anti-mouse CD25 mAb (PC61) was given to the donors or recipients (250 microg/d IP) pretransplant or to the recipients postoperatively. At day 5 posttransplantation, both effector T cells (mainly CD8) and CD4+ CD25+ Treg were increased in the liver allografts and host spleens compared to na?ve mice. Anti-CD25 mAb administration, either pretransplantation or posttransplantation, reduced the ratio of CD4+ CD25+ Treg to the CD3 T cells of liver grafts and recipient spleens and induced liver allograft acute rejection compared to IgG treatment. Anti-CD25 mAb administration elevated anti-donor T-cell proliferative responses and CTL and NK activities of graft infiltrates and host splenocytes; reduced CTLA4, Foxp3, and IDO mRNA levels; increased IL-10 and IFN-gamma; and decreased IL-4 mRNA levels in the livers or host spleens. The number of apoptotic T cells was reduced significantly in the liver grafts and treated host spleens. Therefore, anti-CD25 mAb administration changed the balance of CD4+ CD25+ Treg to activated T cells of liver graft recipients, preventing liver transplant tolerance. This was associated with enhanced anti-donor immune reactivity, downregulated Treg gene expression, and reduced T cell apoptosis in the grafts and host spleens.