Transient Lymphopenia Breaks Costimulatory Blockade‐Based Peripheral Tolerance and Initiates Cardiac Allograft Rejection

Lymphopenia is induced by lymphoablative therapies and chronic viral infections. We assessed the impact of lymphopenia on cardiac allograft survival in recipients conditioned with peritransplant costimulatory blockade (CB) to promote long‐term graft acceptance. After vascularized MHC‐mismatched heterotopic heart grafts were stably accepted through CB, lymphopenia was induced on day 60 posttransplant by 6.5 Gy irradiation or by administration of anti‐CD4 plus anti‐CD8 mAb. Long‐term surviving allografts were gradually rejected after lymphodepletion (MST = 74 ± 5 days postirradiation). Histological analyses indicated signs of severe rejection in allografts following lymphodepletion, including mononuclear cell infiltration and obliterative vasculopathy. Lymphodepletion of CB conditioned recipients induced increases in CD44^high effector/memory T cells in lymphatic organs and strong recovery of donor‐reactive T cell responses, indicating lymphopenia‐induced proliferation (LIP) and donor alloimmune responses occurring in the host. T regulatory (CD4⁺ Foxp³⁺) cell and B cell numbers as well as donor‐specific antibody titers also increased during allograft rejection in CB conditioned recipients given lymphodepletion. These observations suggest that allograft rejection following partial lymphocyte depletion is mediated by LIP of donor‐reactive memory T cells. As lymphopenia may cause unexpected rejection of stable allografts, adequate strategies must be developed to control T cell proliferation and differentiation during lymphopenia.     

The Immunobiology of Inductive Anti-CD40L Therapy in Transplantation: Allograft Acceptance is Not Dependent Upon the Deletion of Graft-Reactive T Cells

CD40–CD40L costimulatory interactions are crucial for allograft rejection, in that treatment with anti‐CD40L mAb markedly prolongs allograft survival in several systems. Recent reports indicate that costimulatory blockade results in deletion of graft‐reactive cells, which leads to allograft tolerance. To assess immunologic parameters that were influenced by inductive CD40–CD40L blockade, cardiac allograft recipients were treated with multiple doses of the anti‐CD40L mAb MR1, which was remarkably effective at prolonging allograft survival. Acute allograft rejection responses such as IL‐2 producing helper cell priming, Th1 priming, and alloantibody production were abrogated by anti‐CD40L treatment. Interestingly, the spleens of mice bearing long‐term cardiac allografts following inductive anti‐CD40L treatment retained precursor donor alloantigen‐reactive CTL, IL‐2 producing helper cells, and Th1 in numbers comparable to those observed in naïve mice. These mice retained the ability to reject donor‐strain skin allografts, but were incapable of rejecting the original cardiac allograft, or a second donor‐strain cardiac allograft. Further, differentiated effector cells were incapable of mediating rejection following adoptive transfer into mice bearing long‐term allografts, suggesting that regulatory cell function, rather than effector cell deletion was responsible for long‐term graft acceptance. Collectively, these data demonstrate that inductive CD40–CD40L blockade does not result in the deletion of graft‐reactive T cells, but induces the maintenance of these cells in a quiescent precursor state. They further point to a tissue specificity of this hyporesponsiveness, suggesting that not all donor alloantigen‐reactive cells are subject to this regulation.     

Regulatory T Cells Are Critical to Tolerance Induction in Presensitized Mouse Transplant Recipients Through Targeting Memory T Cells

Memory T cells are a significant barrier to induction of transplant tolerance. However, reliable means to target alloreactive memory T cells have remained elusive. In this study, presensitization of BALB/c mice with C57BL/6 skin grafts generated a large number of OX40⁺CD44^hieffector/memory T cells and resulted in rapid rejection of donor heart allografts. Recognizing that anti‐OX40L monoclonal antibody (mAb) (α‐OX40L) monotherapy prolonged graft survival through inhibition and apoptosis of memory T cells in presensitized recipients, α‐OX40L was added to the combined treatment protocol of LF15–0195 (LF) and anti‐CD45RB (α‐CD45RB) mAb—a protocol that induced heart allograft tolerance in non‐presensitized recipients but failed to induce tolerance in presensitized recipients. Interestingly, this triple therapy restored donor‐specific heart allograft tolerance in our presensitized model that was associated with induction of tolerogenic dendritic cells and CD4⁺CD25⁺Foxp3⁺ T regulatory cells (Tregs). Of note, CD25⁺ T cell depletion in triple therapy recipients prevented establishment of allograft tolerance. In addition, adoptive transfer of donor‐primed effector/memory T cells into tolerant recipients markedly reduced levels of Tregs and broke tolerance. Our findings indicated that targeting memory T cells, by blocking OX40 costimulation in presensitized recipients was very important to expansion of Tregs, which proved critical to development of tolerance.     

B Cell Depletion With an Anti‐CD20 Antibody Enhances Alloreactive Memory T Cell Responses After Transplantation

Alloreactive memory T cells mediate accelerated allograft rejection and transplant tolerance resistance. Recent studies have shown that B cell deficient–μMT mice fail to mount donor‐specific memory T cell responses after transplantation. At the same time, other studies showed that pretransplant B cell depletion using rituximab (IgG1 anti‐CD20 mAb) combined with cyclosporine A promoted the survival of islet allografts in monkeys. In this study, we investigated the effect of anti‐CD20 antibody‐mediated B cell depletion on the memory T cell alloresponse in mice. Wild‐type and anti‐OVA TCR transgenic mice were treated with an IgG2a anti‐CD20 monoclonal antibody, which depleted nearly all B cells in the peripheral blood and secondary lymphoid organs but spared some B cells in the bone marrow. B cell depletion did not affect the direct alloresponse but resulted in a marked increase of indirect alloresponse after skin transplantation of naïve mice. Furthermore, in allosensitized mice, anti‐CD20 mAb treatment enhanced the reactivation of allospecific memory T cells and accelerated second set rejection of skin allografts. This suggests that the effect of anti‐CD20 antibodies on alloimmunity and allograft rejection might vary upon the nature of the antibodies as well as the circumstances under which they are delivered.     

Different Mechanisms Control Peripheral and Central Tolerance in Hematopoietic Chimeric Mice

Regulatory T cells (Treg) are important in peripheral tolerance, but their role in establishing and maintaining hematopoietic mixed chimerism and generating central tolerance is unclear. We now show that costimulation blockade using a donor‐specific transfusion and anti‐CD154 antibody applied to mice given bone marrow and simultaneously transplanted with skin allografts leads to hematopoietic chimerism and permanent skin allograft survival. Chimeric mice bearing intact skin allografts fail to generate effector/memory T cells against allogeneic targets as shown by the absence of IFNγ‐producing CD44^highCD8⁺ T cells and in vivo cytotoxicity. Depletion of Tregs by injection of anti‐CD4 or anti‐CD25 antibody prior to costimulation blockade prevents chimerism, shortens skin allograft survival and leads to generation of effector/memory cytotoxic T cells. Depletion of Tregs by injection of anti‐CD4 or anti‐CD25 antibody two months after transplantation leads to loss of skin allografts even though mice remain chimeric and exhibit little in vivo cytotoxicity. In contrast, chimerism is lost, but skin allografts survive following naïve T‐cell injection. We conclude that hematopoietic chimerism and peripheral tolerance may be maintained by different mechanisms in mixed hematopoietic chimeras.     

Anti‐LFA‐1 or rapamycin overcome costimulation blockade‐resistant rejection in sensitized bone marrow recipients

While costimulation blockade‐based mixed chimerism protocols work well for inducing tolerance in rodents, translation to preclinical large animal/nonhuman primate models has been less successful. One recognized cause for these difficulties is the high frequency of alloreactive memory T cells (Tmem) found in the (pre)clinical setting as opposed to laboratory mice. In the present study, we therefore developed a murine bone marrow transplantation (BMT) model employing recipients harboring polyclonal donor‐reactive Tmem without concomitant humoral sensitization. This model was then used to identify strategies to overcome this additional immune barrier. We found that B6 recipients that were enriched with 3 × 10⁷ T cells isolated from B6 mice that had been previously grafted with Balb/c skin, rejected Balb/c BM despite costimulation blockade with anti‐CD40L and CTLA4Ig (while recipients not enriched developed chimerism). Adjunctive short‐term treatment of sensitized BMT recipients with rapamycin or anti‐LFA‐1 mAb was demonstrated to be effective in controlling Tmem in this model, leading to long‐term mixed chimerism and donor‐specific tolerance. Thus, rapamycin and anti‐LFA‐1 mAb are effective in overcoming the potent barrier that donor‐reactive Tmem pose to the induction of mixed chimerism and tolerance despite costimulation blockade.     

Allospecific Rejection of MHC Class I‐Deficient Bone Marrow by CD8 T Cells

Avoidance of long‐term immunosuppression is a desired goal in organ transplantation. Mixed chimerism offers a promising approach to tolerance induction, and we have aimed to develop low‐toxicity, nonimmunodepleting approaches to achieve this outcome. In a mouse model achieving fully MHC‐mismatched allogeneic bone marrow engraftment with minimal conditioning (3 Gy total body irradiation followed by anti‐CD154 and T cell–depleted allogeneic bone marrow cells), CD4 T cells in the recipient are required to promote tolerance of preexisting alloreactive recipient CD8 T cells and thereby permit chimerism induction. We now demonstrate that mice devoid of CD4 T cells and NK cells reject MHC Class I‐deficient and Class I/Class II‐deficient marrow in a CD8 T cell–dependent manner. This rejection is specific for donor alloantigens, since recipient hematopoiesis is not affected by donor marrow rejection and MHC Class I‐deficient bone marrow that is syngeneic to the recipient is not rejected. Recipient CD8 T cells are activated and develop cytotoxicity against MHC Class I‐deficient donor cells in association with rejection. These data implicate a novel CD8 T cell–dependent bone marrow rejection pathway, wherein recipient CD8 T cells indirectly activated by donor alloantigens promote direct killing, in a T cell receptor–independent manner, of Class I‐deficient donor cells.     

Rapamycin and CTLA4Ig Synergize to Induce Stable Mixed Chimerism Without the Need for CD40 Blockade

The mixed chimerism approach achieves donor‐specific tolerance in organ transplantation, but clinical use is inhibited by the toxicities of current bone marrow (BM) transplantation (BMT) protocols. Blocking the CD40:CD154 pathway with anti‐CD154 monoclonal antibodies (mAbs) is exceptionally potent in inducing mixed chimerism, but these mAbs are clinically not available. Defining the roles of donor and recipient CD40 in a murine allogeneic BMT model, we show that CD4 or CD8 activation through an intact direct or CD4 T cell activation through the indirect pathway is sufficient to trigger BM rejection despite CTLA4Ig treatment. In the absence of CD4 T cells, CD8 T cell activation via the direct pathway, in contrast, leads to a state of split tolerance. Interruption of the CD40 signals in both the direct and indirect pathway of allorecognition or lack of recipient CD154 is required for the induction of chimerism and tolerance. We developed a novel BMT protocol that induces mixed chimerism and donor‐specific tolerance to fully mismatched cardiac allografts relying on CD28 costimulation blockade and mTOR inhibition without targeting the CD40 pathway. Notably, MHC‐mismatched/minor antigen‐matched skin grafts survive indefinitely whereas fully mismatched grafts are rejected, suggesting that non‐MHC antigens cause graft rejection and split tolerance.     

Suppressing memory T cell activation induces islet allograft tolerance in alloantigen‐primed mice

Memory T cells are known to play a key role in prevention of allograft tolerance in alloantigen‐primed mice. Here, we used an adoptively transferred memory T cell model and an alloantigen‐primed model to evaluate the abilities of different combinations of monoclonal antibodies (mAb) to block key signaling pathways involved in activation of effector and memory T cells. In the adoptively transferred model, the use of anti‐CD134L mAb effectively prevented activation of CD4⁺ memory T cells and significantly prolonged islet survival, similar to the action of anti‐CD122 mAb to CD8⁺ memory T cells. In the alloantigen‐primed model, use of anti‐CD134L and anti‐CD122 mAbs in addition to co‐stimulatory blockade with anti‐CD154 and anti‐LFA‐1 prolonged secondary allograft survival and significantly reduced the proportion of memory T cells; meanwhile, this combination therapy increased the proportion of regulatory T cells (Tregs) in the spleen, inhibited lymphocyte infiltration in the graft, and suppressed alloresponse of recipient splenic T cells. However, we also detected high levels of alloantibodies in the serum which caused high levels of damage to the allogeneic spleen cells. Our results suggest that combination of four mAbs can significantly suppress the function of memory T cells and prolong allograft survival in alloantigen primed animals.     

LFA‐1 Antagonism Inhibits Early Infiltration of Endogenous Memory CD8 T Cells into Cardiac Allografts and Donor‐Reactive T Cell Priming

Alloreactive memory T cells are present in virtually all transplant recipients due to prior sensitization or heterologous immunity and mediate injury undermining graft outcome. In mouse models, endogenous memory CD8 T cells infiltrate MHC‐mismatched cardiac allografts and produce IFN‐γ in response to donor class I MHC within 24 h posttransplant. The current studies analyzed the efficacy of anti‐LFA‐1 mAb to inhibit early CD8 T cell cardiac allograft infiltration and activation. Anti‐LFA‐1 mAb given to C57BL/6 6 (H‐2^b) recipients of A/J (H‐2^a) heart grafts on days –1 and 0 completely inhibited CD8 T cell allograft infiltration, markedly decreased neutrophil infiltration and significantly reduced intragraft expression levels of IFN‐γ‐induced genes. Donor‐specific T cells producing IFN‐γ were at low/undetectable numbers in spleens of anti‐LFA‐1 mAb treated recipients until day 21. These effects combined to promote substantial prolongation (from day 8 to 27) in allograft survival. Delaying anti‐LFA‐1 mAb treatment until days 3 and 4 posttransplant did not inhibit early memory CD8 T cell infiltration and proliferation within the allograft. These data indicate that peritransplant anti‐LFA‐1 mAb inhibits early donor‐reactive memory CD8 T cell allograft infiltration and inflammation suggesting an effective strategy to attenuate the negative effects of heterologous immunity in transplant recipients.     

Alefacept Promotes Immunosuppression‐Free Renal Allograft Survival in Nonhuman Primates via Depletion of Recipient Memory T Cells

Renal allograft tolerance has been achieved in MHC‐mismatched primates via nonmyeloablative conditioning beginning 6 days prior to planned kidney and donor bone marrow transplantation (DBMT). To extend the applicability of this approach to deceased donor transplantation, we recently developed a novel‐conditioning regimen, the “delayed protocol” in which donor bone marrow (DBM) is transplanted several months after kidney transplantation. However, activation/expansion of donor‐reactive CD8⁺ memory T cells (TMEM) occurring during the interval between kidney and DBM transplantation impaired tolerance induction using this strategy. In the current study, we tested whether, Alefacept, a fusion protein which targets LFA‐3/CD2 interactions and selectively depletes CD2^highCD8⁺ effector memory T cells (TEM) could similarly induce long‐term immunosuppression‐free renal allograft survival but avoid the deleterious effects of anti‐CD8 mAb treatment. We found that Alefacept significantly delayed the expansion of CD2^high cells including CD8⁺ TEM while sparing naïve CD8⁺ T and NK cells and achieved mixed chimerism and long‐term immunosuppression‐free renal allograft survival. In conclusion, elimination of CD2^high T cells represents a promising approach to prevent electively the expansion/activation of donor‐reactive TEM and promotes tolerance induction via the delayed protocol mixed chimerism approach.

     

Donor T cells are not required for induction of allograft tolerance in mice treated with antilymphocyte serum, rapamycin, and donor bone marrow cells

BACKGROUND: Postgraft infusion of donor bone marrow cells (BMC) effectively induces tolerance to skin allografts in antilymphocyte serum- and rapamycin-treated recipients in fully major histocompatibility complex-mismatched mouse strain combinations. We used various gene knockout mice to examine the role of donor T cells and B cells in BMC-induced allograft tolerance. METHODS: All recipient mice received ALS on days -1 and 2 and rapamycin (6 mg/kg) on day 7 relative to fully major histocompatibility complex-mismatched skin grafting on day 0. Donor BMC prepared either from mice lacking CD4- and/or CD8a-, or CD3epsilon-expressing cells or B cells, or from corresponding wildtype mice, were given on day 7. The level and phenotypes of chimerism was determined by flow cytometry. RESULTS: All T cell- and B cell-deficient BMC were as effective as wild-type BMC in inducing prolongation of skin graft survival. A low degree of chimerism without donor type T cells was detected in tolerant mice given T cell-deficient BMC or wild-type BMC 60 days after transplantation. Chimeric cells were composed of B cells and macrophages/monocytes. Low level chimerism without donor T or B cells was also present in tolerant mice given B cell-deficient BMC. CONCLUSION: Donor type T cells and T cell chimerism are not required for induction of allograft tolerance by the antilymphocyte serum/rapamycin/donor BMC-infusion protocol. Donor B cells also do not participate in tolerance induction. Thus, infusion of T cell-depleted BMC in conjunction with conventional immunosuppressive regimens will be a simple, safe, and effective way to induce allograft tolerance in clinical organ transplantation.     

Vascularized Osteomyocutaneous Allografts Are Permissive to Tolerance by Induction‐Based Immunomodulatory Therapy

Vascularized composite allografts (VCAs) are unique among transplanted organs in that they are composed of multiple tissues with disparate antigenic and immunologic properties. As the predominant indications for VCAs are non‐life‐threatening conditions, there is an immediate need to develop tolerance induction strategies and to elucidate the mechanisms of VCA rejection and tolerance using VCA‐specific animal models. In this study, we explore the effects of in vitro induced donor antigen‐specific CD4^?CD8^? double negative (DN) Treg‐based therapy, in a fully MHC mismatched mouse VCA such as a vascularized osteomyocutaneous as compared to a non‐VCA such as a full thickness skin (FTS) transplantation model to elucidate the unique features of VCA rejection and tolerance. We demonstrate that combined therapy with antigen‐induced CD4 derived DN Tregs and a short course of anti‐lymphocyte serum, rapamycin and IL‐2/Fc fusion protein results in donor‐specific tolerance to VCA, but not FTS allografts. Macrochimerism was detected in VCA but not FTS allograft recipients up to >60 days after transplantation. Moreover, a significant increase of CD4⁺Foxp3⁺ Tregs was found in the peripheral blood of tolerant VCA recipients. These data suggest that VCA are permissive to tolerance induced by DN Treg‐based induction therapy.

     

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.     

Combination of antibodies inhibits accelerated rejection mediated by memory T cells in xenoantigen-primed mice

Wang F, Xia J, Chen J, Peng Y, Cheng P, Ekberg H, Wang X, Qi Z. Combination of antibodies inhibits accelerated rejection mediated by memory T cells in xenoantigen‐primed mice. Xenotransplantation 2010; 17: 460–468. © 2010 John Wiley & Sons A/S. Abstract: Background: Donor‐reactive memory T cells are known to accelerate allograft rejection; in our previous study, we reported that combined monoclonal antibodies (mAbs) could prolong islet allograft survival in alloantigen‐primed mice. In this study, we examine the effects of donor‐reactive memory T cells on the xenograft survival and methods to prolong the islet graft survival. Methods: To collect donor‐reactive T cells, we performed full‐thickness rat skin xenografting on BALB/c mice and isolated the T cells from the mice after 6–8 weeks. These cells were then adoptively transferred to syngenic mice 1 day before rat‐to‐mouse islet transplantation. Three experimental groups were established in the adoptive transfer model: recipient mice treated with isotype mAbs (isotype group); mice treated with anti‐CD40L mAb (anti‐CD40L group); and mice treated with anti‐CD40L, anti‐OX40L, and anti‐CD122 mAbs (3‐combined group). Results: Lewis rat islet xenografts transplanted in naïve mice showed a mean survival time (MST) of 12.8 days, while the graft rejection was accelerated if the recipient mice were treated with adoptively transferred donor‐reactive T cells (MST, 8.67 days). Treatment with anti‐CD40L mb could not reverse the accelerated rejection (MST, 9.3 days). However, when anti‐CD40L mb was combined with anti‐OX40L and anti‐CD122 mAbs, there was a considerable increase in the MST, which was 72.2 days. Compared to the isotype group, the 3‐combined group had significantly lesser proportion of memory T cells and greater proportion of regulatory T cells (Tregs) in the spleen. Meanwhile, in the 3‐combined group, the production of anti‐rat antibodies was markedly inhibited. Conclusion: Treatment with a combination of antibodies could significantly reverse the accelerated rejection mediated by donor‐reactive memory T cells by inhibiting cellular and humoral immune responses.     

iNKT cell activation plus T‐cell transfer establishes complete chimerism in a murine sublethal bone marrow transplant model

Transplant tolerance induction makes it possible to preserve functional grafts for a lifetime without immunosuppressants. One powerful method is to generate mixed hematopoietic chimeras in recipients by adoptive transfer of donor‐derived bone marrow cells (BMCs). In our murine transplantation model, we established a novel method for mixed chimera generation using sublethal irradiation, CD40‐CD40L blockade, and invariant natural killer T‐cell activation. However, numerous BMCs that are required to achieve stable chimerism makes it difficult to apply this model for human transplantation. Here, we show that donor‐derived splenic T cells could contribute to not only the reduction of BMC usage but also the establishment of complete chimerism in model mice. By cotransfer of T cells together even with one‐fourth of the BMCs used in our original method, the recipient mice yielded complete chimerism and could acquire donor‐specific skin‐allograft tolerance. The complete chimeric mice did not show any remarks of graft versus host reaction in vivo and in vitro. Inhibition of the apoptotic signal resulted in increase in host‐derived CD8⁺ T cells and chimerism brake. These results suggest that donor‐derived splenic T cells having veto activity play a role in the depletion of host‐derived CD8⁺ T cells and the facilitation of complete chimerism.     

Combined Anti‐CD154/CTLA4Ig Costimulation Blockade‐Based Therapy Induces Donor‐Specific Tolerance to Vascularized Osteomyocutaneous Allografts

Tolerance induction by means of costimulation blockade has been successfully applied in solid organ transplantation; however, its efficacy in vascularized composite allotransplantation, containing a vascularized bone marrow component and thus a constant source of donor‐derived stem cells, remains poorly explored. In this study, osteomyocutaneous allografts (alloOMCs) from Balb/c (H2^d) mice were transplanted into C57BL/6 (H2^b) recipients. Immunosuppression consisted of 1 mg anti‐CD154 on day 0, 0.5 mg CTLA4Ig on day 2 and rapamycin (RPM; 3 mg/kg per day from days 0–7, then every other day for 3 weeks). Long‐term allograft survival, donor‐specific tolerance and donor–recipient cell trafficking were evaluated. Treatment with costimulation blockade plus RPM resulted in long‐term graft survival (>120 days) of alloOMC in 12 of 15 recipients compared with untreated controls (median survival time [MST] ≈10.2 ± 0.8 days), RPM alone (MST ≈33 ± 5.5 days) and costimulation blockade alone (MST ≈45.8 ± 7.1 days). Donor‐specific hyporesponsiveness in recipients with viable grafts was demonstrated in vitro. Evidence of donor‐specific tolerance was further assessed in vivo by secondary donor‐specific skin graft survival and third‐party graft rejection. A significant increase of Foxp3⁺ regulatory T cells was evident in tolerant animals. Donor cells populated peripheral blood, thymus, and both donor and recipient bone marrow. Consequently, combined anti‐CD154/CTLA4Ig costimulation blockade‐based therapy induces donor‐specific tolerance in a stringent murine alloOMC transplant model.     

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.     

Future research in immunology for composite tissue allotransplantation

Hand and composite tissue allotransplantation (CTA) holds great potential for reconstructive surgery but its development is currently limited by the side-effects of the immunosuppressive drugs. Induction of specific tolerance, a situation where the recipient does not mount an immune response against the allograft but remains fully immunocompetent, holds exciting promise. Generation of mixed hematopoietic chimerism by infusing the recipient with donor bone marrow cells has been shown to induce tolerance without chronic immunosuppression. Genetic matching of the donor and the recipient is another option for transplanting composite tissues with only an initial course of immunosuppression. Experiments demonstrated long-term survival of musculoskeletal allografts between MHC-matched miniature swine. Finally, new immunosuppressive agents with a more targeted action will reduce side-effects and may prevent the development of chronic rejection. Skin-specific immunosuppression is particularly useful for limb transplants since skin, regarded as the most antigenic component, is easily accessible to topical or irradiation therapies.     

Anti‐huCD20 Antibody Therapy for Antibody‐Mediated Rejection of Renal Allografts in a Mouse Model

We have reported that B6.CCR5^?/? mice reject renal allografts with high serum donor‐specific antibody (DSA) titers and marked C4d deposition in grafts, features consistent with antibody‐mediated rejection (AMR). B6.huCD20/CCR5^?/? mice, where human CD20 expression is restricted to B cells, rejected A/J renal allografts by day 26 posttransplant with DSA first detected in serum on day 5 posttransplant and increased thereafter. Recipient treatment with anti‐huCD20 mAb prior to the transplant and weekly up to 7 weeks posttransplant promoted long‐term allograft survival (>100 days) with low DSA titers. To investigate the effect of B cell depletion at the time serum DSA was first detected, recipients were treated with anti‐huCD20 mAb on days 5, 8, and 12 posttransplant. This regimen significantly reduced DSA titers and graft inflammation on day 15 posttransplant and prolonged allograft survival >60 days. However, DSA returned to the titers observed in control treated recipients by day 30 posttransplant and histological analyses on day 60 posttransplant indicated severe interstitial fibrosis. These results indicate that anti‐huCD20 mAb had the greatest effect as a prophylactic treatment and that the distinct kinetics of DSA responses accounts for acute renal allograft failure versus the development of fibrosis.