Regulation of skin and islet allograft survival in mice treated with costimulation blockade is mediated by different CD4+ cell subsets and different mechanisms

BACKGROUND: Donor-specific transfusion (DST) and a brief course of anti-CD154 monoclonal antibody (mAb) induces permanent islet and prolonged skin allograft survival in mice. Induction of skin allograft survival requires the presence of CD4 cells and deletion of alloreactive CD8 cells. The specific roles of CD4 and CD4CD25 cells and the mechanism(s) by which they act are not fully understood. METHODS: We used skin and islet allografts, a CD8 T cell receptor (TCR) transgenic model system, and in vivo depleting antibodies to analyze the role of CD4 cell subsets in regulating allograft survival in mice treated with DST and anti-CD154 mAb. RESULTS: Deletion of CD4 or CD25 cells during costimulation blockade induced rapid rejection of skin but only minimally shortened islet allograft survival. Deletion of CD4 or CD25 cells had no effect upon survival of healed-in islet allografts, and CD25 cell deletion had no effect upon healed-in skin allograft survival. In the TCR transgenic model, DST plus anti-CD154 mAb treatment deleted alloreactive CD8 T cells, and anti-CD4 mAb treatment prevented that deletion. In contrast, injection of anti-CD25 mAb did not prevent alloreactive CD8 T cell deletion. CONCLUSIONS: These data document that (1) both CD4CD25 and CD4CD25 cells are required for induction of skin allograft survival, (2) CD4CD25 T cells are not required for alloreactive CD8 T cell deletion, and (3) CD4CD25 regulatory cells are not critical for islet allograft tolerance. It appears that skin and islet transplantation tolerance are mediated by different CD4 cell subsets and different mechanisms.     

Anti-CD3 F(ab')2 fragments are immunosuppressive in vivo without evoking either the strong humoral response or morbidity associated with whole mAb

The use of anti-CD3 monoclonal antibodies to treat organ allograft rejection has been complicated by (1) the morbidity associated with the initial dose, (2) the humoral response of the patients against the mAbs, and (3) the generalized immunosuppression induced by the mAbs. We investigated the potential of F(ab')2 fragments of the anti-murine-CD3 mAb, 145-2C11, to avoid these complications in the murine model. Both whole mAb and F(ab')2 fragments induced T cell depletion. However, injection of F(ab')2 fragments of anti-CD3 mAb did not cause T cell activation, and did not induce the morbidity and mortality observed following injection of whole mAb. The humoral response against the F(ab')2 fragments was significantly reduced compared with the response against the whole mAb. Furthermore, repeated administration of F(ab')2 fragments of anti-CD3 mAb resulted in prolongation of allogeneic skin graft survival superior to that seen following treatment with a single dose of whole mAb. Finally, while T cells from mice treated with whole mAb displayed profound suppression of in vitro CTL generation, T cells from mice treated with F(ab')2 fragments had significant in vitro CTL function. These results suggest that the use of F(ab')2 fragments of anti-CD3 mAb may offer significant advantages over whole mAb for the induction and maintenance of immunosuppression.     

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.     

Role of CD40-CD154 pathway in the rejection of concordant and discordant xenogeneic islets

BACKGROUND: Costimulatory blockade has been shown to allow long-term survival of xenogeneic islets. The aim of the present study was to evaluate the role of recipient CD40 and CD154 in the rejection process of concordant and discordant islet xenotransplantation (Tx). METHODS: Diabetic C57BL/6 mice, CD40- or CD154 knockout (KO) mice were transplanted with either concordant rat or discordant human islets. Experimental design: group 1, control (ie, C57BL/6 mice received islet Tx without therapy); group 2, C57BL/6 mice received islet Tx with anti-CD154 monoclonal Ab (mAb) therapy; group 3, CD40 KO mice; and group 4, CD154 KO mice were used as recipients without therapy. Mouse anti-rat mixed lymphocyte reactions (MLR) were performed using mouse splenocytes obtained from animals transplanted with rat islets in groups 1 to 4. RESULTS: In group 2, short-term anti-CD154 mAb therapy significantly prolonged rat-to-mouse and human-to-mouse xenograft survival, compared to controls. In CD40-KO and CD154-KO recipients, survival of concordant or discordant islets was not prolonged significantly compared to control groups. Mouse anti-donor rat cellular responses were reduced approximately 50% in group 2 but remained unmodified in groups 3 and 4, when compared to group 1. CONCLUSIONS: Improved graft survival and reduced MLR responses against donor cells in vitro among the anti-CD154 mAb-treated mice could be explained by specific targeting of activated T cells with subsequent inactivation by anergy and/or elimination by apoptosis, or complement- or cellular-mediated mechanisms. Rejection of xenografts and strong MLR responses against donor cells in vitro in CD40 or CD154 KO animals is possible through efficient activation of alternate pathways of costimulation.     

Prolonged survival of neonatal porcine islet xenografts in mice treated with a donor-specific transfusion and anti-CD154 antibody

BACKGROUND: Combined treatment with a single donor-specific transfusion (DST) and a brief course of anti-mouse CD154 monoclonal antibody (mAb) to induce co-stimulation blockade leads to long-term murine islet allograft survival. The authors hypothesized that this protocol could also induce long-term survival of neonatal porcine islet cell clusters (NPCC) in chemically diabetic immunocompetent mice and allow their differentiation into functional insulin-producing cells. METHODS: Pancreata from 1- to 3-day-old pigs were collagenase digested and cultured for 8 days. NPCC were recovered and transplanted into the renal subcapsular space. Recipients included chemically diabetic nonobese diabetic (NOD)-scid and C57BL/6 mice that were otherwise untreated, treated with anti-CD154 mAb alone, or treated with DST plus anti-CD154 mAb. Plasma glucose concentration and body weight were measured, and xenografts were examined histologically. RESULTS: NPCC fully differentiated and restored normoglycemia in four of five diabetic NOD-scid recipients but were uniformly rejected by diabetic C57BL/6 recipients. Anti-CD154 mAb monotherapy restored normoglycemia in 4 of 10 (40%) NPCC-engrafted, chemically diabetic C57BL/6 mice, but combined treatment with DST and anti-CD154 mAb restored normoglycemia in 12 of 13 (92%) recipients. Reversal of diabetes required 5 to 12 weeks. Surviving grafts were essentially free of inflammatory infiltrates 15 weeks after transplantation. CONCLUSIONS: Combination therapy with a single DST and a brief course of anti-mouse CD154 mAb without maintenance immunosuppression permits survival and differentiation of NPCC in diabetic C57BL/6 mice. Successful grafts were associated with durable restoration of normoglycemia and the absence of graft inflammation.     

Rat xenograft survival in mice treated with donor-specific transfusion and anti-CD154 antibody is enhanced by elimination of host CD4+ cells

BACKGROUND: Treatment with a donor-specific transfusion (DST) and a brief course of anti-mouse CD154 (anti-CD40-ligand) monoclonal antibody (mAb) prolongs the survival of both allografts and rat xenografts in mice. The mechanism by which allograft survival is prolonged is incompletely understood, but depends in part on the presence of CD4+ cells and the deletion of alloreactive CD8+ T cells. Less is known about the mechanism by which this protocol prolongs xenograft survival. METHODS: We measured rat islet and skin xenograft survival in euthymic and thymectomized mice treated with combinations of DST, anti-CD154 mAb, anti-CD4 mAb, and anti-CD8 mAb. Recipients included C57BL/6, C57BL/6-scid, C57BL/6-CD4null, and C57BL/6-CD8null mice. RESULTS: Pretreatment with a depleting anti-CD4 mAb markedly prolonged the survival of both skin and islet xenografts in mice given DST plus anti-CD154 mAb. Comparable prolongation of xenograft survival was obtained in C57BL/6-CD4null recipients treated with DST and anti-CD154 mAb. In contrast, anti-CD8 mAb did not prolong the survival of either islet or skin xenografts in mice treated with DST and anti-CD154 mAb. Thymectomy did not influence xenograft survival in any treatment group. Adoptive transfer of splenocytes from C57BL/6-CD4null recipients treated with DST and anti-CD154 mAb and bearing long-term skin xenografts revealed the presence of residual xenoreactive cells. CONCLUSIONS: These data suggest that treatment with DST and anti-CD154 mAb induces a state of "functional" transplantation tolerance. They also support the hypothesis that both the induction and maintenance of graft survival based on this protocol depend on different cellular mechanisms in allogeneic and xenogeneic model systems.     

Prolonged Survival of Allogeneic Islets in Cynomolgus Monkeys After Short‐Term Anti‐CD154‐Based Therapy: Nonimmunologic Graft Failure?

Conventional drug therapy and several anti-CD154 mAb-based regimens were tested in the nonhuman primate (NHP) islet allograft model and found to be inadequate because islets were lost to rejection. Short-term therapy with an optimized donor-specific transfusion (DST) + rapamycin (RPM) + anti-CD154 mAb regimen enables immunosuppression drug-free islet allograft function for months following cessation of therapy in the NHP islet allograft model. After a substantial period of drug-free graft function, these allografts slowly and progressively lost function. Pathologic studies failed to identify islet allograft rejection as a destructive islet invasive lymphocytic infiltration of the allograft was not detected. To evaluate the mechanism, immunologic versus nonimmunologic, of the late islet allograft loss in hosts receiving the optimized therapeutic regimen, we performed experiments with islet autografts and studied islet function in NHPs with partial pancreatectomy. The results in both experiments utilizing autologous islet allografts and partially pancreatectomized hosts reinforce the view that the presence of a marginal islet mass leads to slowly progressive nonimmunological islet loss. Long-term clinically successful islet cell transplantation cannot be realized in the absence of parallel improvements in tolerizing regimens and in the preparation of adequate numbers of islets.     

Monoclonal antibodies against human T cell adhesion molecules--modulation of immune function in nonhuman primates.

The cytotoxic T cell is thought to be a primary effector of allograft rejection. In vitro studies have demonstrated that the interaction between cytotoxic T cells and target cells involves cell surface adhesion molecules that result in conjugate formation, with subsequent antigen recognition, T cell activation, and target cell lysis. Experiments have also demonstrated the ability of monoclonal antibodies with specificity for two human T cell adhesion molecules, lymphocyte function associated (LFA) antigen-1 (LFA-1, CD11a, alpha-chain/CD18, beta-chain) and LFA-2 (CD2), to inhibit conjugate formation in vitro. Studies in a nonhuman primate model were undertaken to determine whether the in vivo administration of monoclonal antibodies with specificity for the alpha chain of LFA-1 (CD11a) or with specificity for CD2 could modulate in vivo T cell function. Cynomolgus monkeys (Macaca fascicularis) received 10 daily intravenous infusions of either anti-CD11a, anti-CD2 or both anti-CD11a and anti-CD2 monoclonal antibodies. Antibody administration was well tolerated and resulted in high levels of circulating murine monoclonal antibody in the peripheral circulation. Nearly all the animals generated antimurine antibodies that were specific for both idiotypic and nonidiotypic determinants of the infused mouse protein. Circulating lymphocytes and T cells were not depleted by treatment with anti-CD11a or anti-CD2 mAbs; in fact, treatment with the combination of anti-CD11a plus anti-CD2 or anti-CD11a alone led to increased numbers of circulating lymphocytes and T cells. Modulation of the LFA-1 molecule on circulating T cells occurred as a result of treatment with anti-CD11a (or the combination of anti-CD11a plus anti-CD2), whereas treatment with anti-CD2 (or anti-CD11a plus anti-CD2) did not result in modulation of the CD2 antigen despite detectable levels of circulating anti-CD2 mAb. In vivo T cell function was assessed by placement of skin allografts. As compared with treatment with saline or a control mAb, allograft survival was significantly prolonged in animals treated with anti-CD11a or combination treatment but not in animals receiving anti-CD2 alone. We conclude that the in vivo administration of anti-LFA-1 mAb may be useful for the blockade of effector T cell activity during allograft rejection, that saturation of antigen and antigen modulation may be important for efficacy of such antibody effects in vivo, and that monoclonal antibodies with specificity for functionally important T cell surface molecules may alter T cell function in vivo without lymphocyte depletion.     

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.     

Allograft rejection in CD4+ T cell-reconstituted athymic nude rats--the nonessential role of host-derived CD8+ cells.

PVG-rnu/rnu nude rats reject fully allogenic renal (DA) and skin (BN, AO) allografts after the adoptive transfer of naive CD4+ T cells alone, but rejection is accompanied by the accumulation of many nude-derived CD8+ leukocytes within the graft. In addition, mononuclear cells infiltrating the rejecting renal grafts in these animals display cytotoxic activity in vitro against specific and third-party alloantigens. In this investigation we have treated CD4+ T cell-restored nude rats bearing renal or skin allografts with the mAb MRC OX8 to deplete the host of CD8+ cells. In vivo treatment with OX8 completely eliminated CD8+ cells from rejecting grafts of both kidney and skin, but it did not prevent graft rejection, nor did OX8 treatment abolish the cytotoxic effector cells found in nude rat spleen or in graft-infiltrating cells (GIC) of rejecting renal allografts. The nature of the cytotoxic activity was examined with anti-CD3 mAb 1F4, which was shown to block conventional CD8+ Tc killing in vitro but did not inhibit allogeneic target cell lysis by spleen cells from nude rats. The cytotoxic activity found in GIC of rejecting allografts was not inhibited by anti-CD3 mAb, suggesting that these cytotoxic effector cells were CD3-CD8- and were of extrathymic origin. We conclude that non-thymus-derived CD8+ GIC are not essential for allograft rejection in CD4+ T cell-restored nude rats.     

Increased apoptosis of immunoreactive host cells and augmented donor leukocyte chimerism, not sustained inhibition of B7 molecule expression are associated with prolonged cardiac allograft survival in mice preconditioned with immature donor dendritic cells plus anti-CD40L mAb.

BACKGROUND: We previously reported the association among donor leukocyte chimerism, apoptosis of presumedly IL-2-deficient graft-infiltrating host cells, and the spontaneous donor-specific tolerance induced by liver but not heart allografts in mice. Survival of the rejection-prone heart allografts in the same strain combination is modestly prolonged by the pretransplant infusion of immature, costimulatory molecule-(CM) deficient donor dendritic cells (DC), an effect that is markedly potentiated by concomitant CM blockade with anti-CD40L (CD154) monoclonal antibody (mAb). We investigated whether the long survival of the heart allografts in the pretreated mice was associated with donor leukocyte chimerism and apoptosis of graft-infiltrating cells, if these end points were similar to those in the spontaneously tolerant liver transplant model, and whether the pretreatment effect was dependent on sustained inhibition of CM expression of the infused immature donor DC. In addition, apoptosis was assessed in the host spleen and lymph nodes, a critical determination not reported in previous studies of either spontaneous or "treatment-aided" organ tolerance models. METHODS: Seven days before transplantation of hearts from B10 (H-2b) donors, 2x10(6) donor-derived immature DC were infused i.v. into C3H (H-2k) recipient mice with or without a concomitant i.p. injection of anti-CD40L mAb. Donor cells were detected posttransplantation by immunohistochemical staining for major histocompatibility complex class II (I-Ab) in the cells of recipient lymphoid tissue. CM expression was determined by two-color labeling. Host responses to donor alloantigen were quantified by mixed leukocyte reaction, and cytotoxic T lymphocyte (CTL) assays. Apoptotic death in graft-infiltrating cells and in areas of T-dependent lymphoid tissue was visualized by terminal deoxynucleotidyltransferase-catalyzed dUTP-digoxigenin nick-end labeling and quantitative spectrofluorometry. Interleukin-2 production and localization were estimated by immunohistochemistry. RESULTS: Compared with control heart transplantation or heart transplantation after only DC administration, concomitant pretreatment with immature donor DC and anti-CD40L mAb caused sustained elevation of donor (I-Ab+) cells (microchimerism) in the spleen including T cell areas. More than 80% of the I-Ab+ cells in combined treatment animals also were CD86+, reflecting failure of the mAb to inhibit CD40/ CD80/CD86 up-regulation on immature DC in vitro after their interaction with host T cells. Donor-specific CTL activity in graft-infiltrating cells and spleen cell populations of these animals was present on day 8, but decreased strikingly to normal control levels by day 14. The decrease was associated with enhanced apoptosis of graft-infiltrating cells and of cells in the spleen where interleukin-2 production was inhibited. The highest levels of splenic microchimerism were found in mice with long surviving grafts (>100 days). In contrast, CTL activity was persistently elevated in control heart graft recipients with comparatively low levels of apoptotic activity and high levels of interleukin-2. CONCLUSION: The donor-specific acceptance of rejection-prone heart allografts by recipients pretreated with immature donor DC and anti-CD40L mAb is not dependent on sustained inhibition of donor DC CM (CD86) expression. Instead, the pretreatment facilitates a tolerogenic cascade similar to that in spontaneously tolerant liver recipients that involves: (1) chimerism-driven immune activation, succeeded by deletion of host immune responder cells by apoptosis in the spleen and allograft that is linked to interleukin-2 deficiency in both locations and (2) persistence of comparatively large numbers of donor-derived leukocytes. These tolerogenic mechanisms are thought to be generic, explaining the tolerance induced by allografts spontaneously, or with the aid of various kinds of immunosuppression.     

Anti-CD4 induced rat heart tolerance: no presence of primed T cells and regulatory mechanisms for cytotoxic T cells

Treatment with anti-CD4 monoclonal antibody (mAb) (OX38) induces heart, but not skin graft tolerance in WF (RT1u) to Lewis (RT1l) rat strain combinations. We examined differences in cellular responses between heart-bearing and skin-rejected hosts that were both treated with anti-CD4 mAb. In the tolerant LEW rats bearing WF heart transplants, the secondary WF heart but not skin grafts were accepted. On the other hand, in anti-CD4 treated WF skin-rejected hosts, both secondary WF heart and skin grafts were rapidly rejected. Spleen cells from anti-CD4 treated WF skin-rejected LEW rats but not from WF heart-bearing LEW rats received the same treatment generated CTL after in vitro stimulation with paraformaldehyde (PFA) treated donor WF stimulator spleen cells. Adoptive transfer of spleen cells from WF skin-rejected LEW rats with or without anti-CD4 therapy into the tolerant LEW rats at the secondary WF heart transplantation blocked the secondary heart graft acceptance. However, transfer of spleen cells from WF heart-rejected rats without immunosuppression failed to block acceptance of the secondary heart graft. Our results indicated the lack of primed T cells and presence of regulatory mechanisms for tissue specific T cells in anti-CD4 treated heart bearing hosts.     

Role of T and dendritic cells in mouse islet allografts treated with anti-CD45RB monoclonal antibodies

Currently lifelong immunosuppression is required for organ transplant recipients. Anti-CD45RB monoclonal antibody (mAb) prolongs graft survival by mechanisms that are not yet clear. Therefore, we investigated the role of T and dendritic cells (DC) in islet allografts treated with anti-CD45RB mAb after transplantation of 200 allogeneic islets (BALB/c mouse) under the kidney capsules of diabetic C57BL/6 mice treated with intraperitoneal injections of 100 μg of anti-CD45RB mAb on days 0, 1, 3, 5, and 7. We observed a tilt of the ratios of Th1/Th2 and Tc1/Tc2 to Th2 and Tc2. The numbers of naïve and memory T cells were down-regulated in peripheral blood after transplantation. In addition, the maturation, endocytosis, and interleukin-12 secreted by DC derived from bone marrow cells was suppressed in recipient mice. Therefore, anti-CD45RB mAb alleviated, rejection by suppressive effects on T-lymphocyte subsets and DC.     

Donor apoptotic cell–based therapy for effective inhibition of donor‐specific memory T and B cells to promote long‐term allograft survival in allosensitized recipients

Allosensitization constitutes a major barrier in transplantation. Preexisting donor‐reactive memory T and B cells and preformed donor‐specific antibodies (DSAs) have all been implicated in accelerated allograft rejection in sensitized recipients. Here, we employ a sensitized murine model of islet transplantation to test strategies that promote long‐term immunosuppression‐free allograft survival. We demonstrate that donor‐specific memory T and B cells can be effectively inhibited by peritransplant infusions of donor apoptotic cells in combination with anti‐CD40L and rapamycin, and this treatment leads to significant prolongation of islet allograft survival in allosensitized recipients. We further demonstrate that late graft rejection in recipients treated with this regimen is associated with a breakthrough of B cells and their aggressive graft infiltration. Consequently, additional posttransplant B cell depletion effectively prevents late rejection and promotes permanent acceptance of islet allografts. In contrast, persistent low levels of DSAs do not seem to impair graft outcome in these recipients. We propose that B cells contribute to late rejection as antigen‐presenting cells for intragraft memory T cell expansion but not to alloantibody production and that a therapeutic strategy combining donor apoptotic cells, anti‐CD40L, and rapamycin effectively inhibits proinflammatory B cells and promotes long‐term islet allograft survival in such recipients.     

Anti‐Complement Component C5 mAb Synergizes with CTLA4Ig to Inhibit Alloreactive T cells and Prolong Cardiac Allograft Survival in Mice

While activation of serum complement mediates antibody‐initiated vascular allograft injury, increasing evidence indicates that complement also functions as a modulator of alloreactive T cells. We tested whether blockade of complement activation at the C5 convertase step affects T cell‐mediated cardiac allograft rejection in mice. The anti‐C5 mAb BB5.1, which prevents the formation of C5a and C5b, synergized with subtherapeutic doses of CTLA4Ig to significantly prolong the survival of C57BL/6 heart grafts that were transplanted into naive BALB/c recipients. Anti‐C5 mAb treatment limited the induction of donor‐specific IFNγ‐producing T cell alloimmunity without inducing Th2 or Th17 immunity in vivo and inhibited primed T cells from responding to donor antigens in secondary mixed lymphocyte responses. Additional administration of anti‐C5 mAb to the donor prior to graft recovery further prolonged graft survival and concomitantly reduced both the in vivo trafficking of primed T cells into the transplanted allograft and decreased expression of T cell chemoattractant chemokines within the graft. Together these results support the novel concept that C5 blockade can inhibit T cell‐mediated allograft rejection through multiple mechanisms, and suggest that C5 blockade may constitute a viable strategy to prevent and/or treat T cell‐mediated allograft rejection in humans.     

Activation of T lymphocytes for adhesion and cytokine expression by toxin-conjugated anti-CD3 monoclonal antibodies.

BACKGROUND: Immunosuppressive drugs that target T cells are useful for prolonging allograft survival. The anti-CD3 immunotoxin FN18-CRM9 has been shown to effectively prolong renal allograft survival in a rhesus monkey model of transplantation. However, immunotoxin-treated monkeys showed increased levels of inflammatory cytokines and produced antibodies to donor proteins. To better understand the role of FN18-CRM9 in the production of cytokines and anti-donor antibodies in the monkey model, we examined whether this immunotoxin elicits functional responses in T cells. METHODS: Purified normal rhesus monkey T cells (>98% purity) were incubated with immunotoxin FN18-CRM9 or the unconjugated anti-CD3 monoclonal antibodies and then examined for changes in protein tyrosine phosphorylation, adhesion to fibronectin, gene expression, and proliferation in the presence or absence of anti-CD28 monoclonal antibodies (mAb) and interleukin-2. RESULTS: Immunotoxin treatment of T cells in vitro increased protein tyrosine phosphorylation, cell adhesion to the extracellular matrix, and expression of the inflammatory cytokines interferon-gamma and tumor necrosis factor-alpha. These immunotoxin effects were similar in magnitude to those induced by the unconjugated mAb. In contrast, immunotoxin-induced T cell proliferation was markedly less than that induced by the unconjugated mAb. Interestingly, the mitogenic molecules IL-2 and anti-CD28 mAb did not prevent immunotoxin-induced inhibition of cell proliferation. CONCLUSIONS: The activation of T cells for protein phosphorylation, adhesion, and cytokine expression strongly suggests that the actions of FN18-CRM9 in vivo are not limited to the inhibition of protein synthesis.     

Effects of BWH-4 anti-CD4 monoclonal antibody on rat vascularized cardiac allografts before and after engraftment.

We studied the effects and mechanism of action of BWH-4, an IgG2a mouse antirat CD4 monoclonal antibody that recognizes a distinct epitope on the CD4 molecule, in LEW recipients of (LEW x BN)F1 vascularized heterotopic cardiac allografts. Ten animals received daily injections of 700 micrograms BWH-4 for ten days after engraftment. Median actuarial allograft survival was 37 days for the treated animals compared with 7.5 days for controls (n = 6). There was depletion of peripheral blood CD4+ lymphocytes to 4 +/- 1% one week posttransplant (normal = 48 +/- 4%, n = 6). Six additional animals were treated with a lower dose (100 micrograms) of BWH-4 daily for ten days. Median actuarial allograft survival was 10 days and the circulating CD4+ cells decreased to 30 +/- 6% at one week posttransplant. All six low-dose-treated animals mounted an anti-BN alloantibody response by 3 weeks, while only one of the ten high-dose-treated animals had positive alloantibodies two weeks posttransplant. Lymphocyte-mediated cytotoxicity against donor lymphoblasts was completely abolished in the high-dose-treated animals when compared with acutely rejecting controls. We also used low-dose (100 micrograms) BWH-4 to pretreat eleven experimental animals for 7 days prior to engraftment. The circulating CD4+ cells decreased to only 12 +/- 2% on the day of transplantation and 26 +/- 9% one week posttransplant. However, six (55%) pretreated animals survived more than 55 days. There was a 66% decrease in lymphocyte-mediated cytotoxicity against donor lymphoblasts when compared with acutely rejecting controls. We conclude that the anti-CD4 mAb, BWH-4, prevents acute rejection of vascularized heterotopic rat cardiac allografts; this effect is mediated by depletion of the CD4+ T cell subset, suppression of alloantibody production, and inhibition of lymphocyte-mediated cytotoxicity.     

Anergic T cells generated in vitro suppress rejection response to islet allografts

BACKGROUND: Induction of antigen-specific unresponsiveness to grafts is the ultimate goal for organ transplantation. It has been shown that anergic T cells generated in vivo can be transferred as suppressor cells. Anergic cells generated in vitro have never been successfully used to prevent allograft rejection in vivo. We examined whether anergic cells generated in vitro by blocking CD28/B7 costimulatory pathway can suppress allograft rejection in vivo. METHODS: Anergic T cells were generated in vitro by the addition of anti-B7-1 and anti-B7-2 monoclonal antibodies (mAbs) to primary mixed lymphocyte reaction (MLR) consisting of C57BL/6 (B6) splenocytes as responder and irradiated BALB/c splenocytes as stimulator. We tested the ability of these cells to respond to various stimuli and to suppress alloreactive T-cell responses in vitro. For in vivo studies, 4x10(7) anergic cells were injected intravenously immediately after transplantation of BALB/c islets under the renal subcapsular space of streptozotocin-induced diabetic and 2.5-Gy X-irradiated B6 mice. RESULTS: Anergic cells treated with both mAbs in the primary MLR did not proliferate in secondary MLR against BALB/c and third-party C3H/He stimulators. The cells also failed to respond to immobilized anti-CD3 mAb, although they proliferated in response to concanavalin A or phorbol myristate acetate + ionomycin. The anergic state was reversed by the addition of exogenous IL-2. Furthermore, these cells suppressed the proliferation of naive B6 T cells against either the same (BALB/c) or third-party (C3H/He) stimulator cells. In in vivo studies, irradiated B6 mice rejected BALB/c islet allografts acutely with a mean survival time of 27.0+/-8.3 days, whereas two of six animals injected with the anergic cells accepted the allografts indefinitely (>100 days) with a mean survival time of 52.0+/-38.2 days. CONCLUSIONS: Anergic cells generated in vitro by blocking CD28/B7 costimulatory pathway suppress islet allograft rejection after adoptive transfer. This procedure might be clinically useful for promoting allograft survival.     

Induction of immunological tolerance to islet allografts

T-cell dependent activation of resting B cells involves the interaction of gp39 on T cells with its receptor, CD40, on B cells. We administered either a combination of T-cell-depleted splenic lymphocytes and anti-gp39 monoclonal antibody or antibody alone to establish islet allografts in mice without continuous immunosuppression. Fully allogeneic H-2^q FVB islets were permanently accepted by chemically diabetic H-2^b C57BL/6 mice provided that the recipients were pretreated with both T-celldepleted donor spleen cells and anti-gp39 antibody. Antibody alone was less effective in prolonging allograft survival, but we did observe that anti-gp39 mAb alone can exert an independent, primary effect on islet allograft survival that was dose dependent. Targeting gp39, in combination with lymphocyte transfusion, might prove suitable for tolerance induction and allotransplantation without immunosuppression.     

Long-term survival and function of intrahepatic islet allografts in baboons treated with humanized anti-CD154.

Clinical islet cell transplantation has resulted in insulin independence in a limited number of cases. Rejection, recurrence of autoimmunity, and impairment of normal islet function by conventional immunosuppressive drugs, e.g., steroids, tacrolimus, and cyclosporin A, may all contribute to islet allograft loss. Furthermore, intraportal infusion of allogeneic islets results in the activation of intrahepatic macrophages and endothelial cells, followed by production of proinflammatory mediators that can contribute to islet primary nonfunction. We reasoned that the beneficial effects of anti-CD154 treatment on autoimmunity, alloreactivity, and proinflammatory events mediated by macrophages and endothelial cells made it an ideal agent for the prevention of islet allograft failure. In this study, a nonhuman primate model (Papio hamadryas) was used to assess the effect of humanized anti-CD154 (hu5c8) on allogeneic islet engraftment and function. Nonimmunosuppressed and tacrolimus-treated recipients were insulin independent posttransplant, but rejected their islet allografts in 8 days. Engraftment and insulin independence were achieved in seven of seven baboon recipients of anti-CD154 induction therapy administered on days -1, 3, and 10 relative to the islet transplant. Three of three baboons treated with 20 mg/kg anti-CD154 induction therapy experienced delayed rejection episodes, first detected by elevations in postprandial blood glucose levels, on postoperative day (POD) 31 for one and on POD 58 for the other two. Re-treatment with three doses of anti-CD154 resulted in reversal of rejection in all three animals and in a return to normoglycemia and insulin independence in two of three baboons. It was possible to reverse multiple episodes of rejection with this approach. A loss of functional islet mass, as detected by reduced first-phase insulin release in response to intravenous glucose tolerance testing, was observed after each episode of rejection. One of two baboons treated with 10 mg/kg induction therapy became insulin independent post-transplant but rejected the islet graft on POD 10; the other animal experienced a reversible rejection episode on POD 58 and remained insulin independent and normoglycemic until POD 264. Two additional baboon recipients of allogeneic islets and donor bone marrow (infused on PODs 5 and 11) were treated with induction therapy (PODs -1, 3, 10), followed by initiation of monthly maintenance therapy (for a period of 6 months) on POD 28. Rejection-free graft survival and insulin independence was maintained for 114 and 238 days, with preservation of functional islet mass observed in the absence of rejection. Prevention and reversal of rejection, in the absence of the deleterious effects associated with the use of conventional immunosuppressive drugs, make anti-CD154 a unique agent for further study in islet cell transplantation.