The high‐risk corneal regraft model: a justification for tissue matching in humans

Models of high‐risk corneal graft rejection involve neovascularization induced via innate immune responses, e.g., suture‐mediated trauma. We describe a model of high‐risk corneal graft rejection using corneal graft donor‐recipient pairing based on a single‐antigen disparity. Donor corneas from transgenic mice on B10.BR (H‐2^k) background, in which hen‐egg lysozyme (HEL) as a membrane‐bound antigen (mHEL) was expressed under the major histocompatibility complex (MHC) Class I promoter (KLK‐mHEL, H‐2^k), were transplanted into wild type B10.BR recipient mice. Unmanipulated wild type recipient mice rejected KLK‐mHEL grafts (39%) slowly over 50–60 days. Graft rejection incidence was maximized (100%) and tempo accelerated (27 days) by priming with HEL‐pulsed syngeneic dendritic cells and less so by increasing T‐cell precursor frequency. Rejection also reached maximum levels (100%) and tempo (3–8 days) when mice which had rejected a first graft (‘rejectors’) were regrafted, and was associated with induction of HEL‐specific memory T cells. In contrast, ‘acceptors’ rejected a second graft at rates and tempo similar to naïve mice. These data reveal the importance of (i) donor MHC antigens as alloantigens for indirect recognition, (ii) alloantigen‐specific memory in high‐risk graft rejection involving regrafts, and (iii) suggest a role for tissue matching in human corneal graft to avoid sensitization to donor MHC antigens.     

Graft‐Versus‐Host Disease Following Liver Transplantation: Development of a High‐Incidence Rat Model and a Selective Prevention Method

Graft‐versus‐host disease (GvHD) following liver transplantation (LT) is a rare but serious complication with no presently available animal model and no preventive measures. To develop a rat model of GvHD after LT (LT‐GvHD), we preconditioned hosts with sublethal irradiation plus reduction of natural killer (NK) cells with anti‐CD8α mAb treatment, which invariably resulted in acute LT‐GvHD. Compared with those in the peripheral counterpart, graft CD4⁺CD25^? passenger T cells showed lower alloreactivities in mixed leukocyte culture. Immunohistology revealed that donor CD4⁺ T cells migrated and formed clusters with host dendritic cells in secondary lymphoid organs, with early expansion and subsequent accumulation in target organs. For selectively preventing GvHD, donor livers were perfused ex vivo with organ preservation media containing anti‐TCRαβ mAb. T cell–depleted livers almost completely suppressed clinical GvHD such that host rats survived for >100 days. Our results showed that passenger T cells could develop typical LT‐GvHD if resistant cells such as host radiosensitive cells and host radioresistant NK cells were suppressed. Selective ex vivo T cell depletion prevented LT‐GvHD without affecting host immunity or graft function. This method might be applicable to clinical LT in prediagnosed high‐risk donor–recipient combinations and for analyzing immunoregulatory mechanisms of the liver.     

Continuous Acquisition of MHC:Peptide Complexes by Recipient Cells Contributes to the Generation of Anti‐Graft CD8+ T Cell Immunity

Understanding the evolution of the direct and indirect pathways of allorecognition following tissue transplantation is essential in the design of tolerance‐promoting protocols. On the basis that donor bone marrow–derived antigen‐presenting cells are eliminated within days of transplantation, it has been argued that the indirect response represents the major threat to long‐term transplant survival, and is consequently the key target for regulation. However, the detection of MHC transfer between cells, and particularly the capture of MHC:peptide complexes by dendritic cells (DCs), led us to propose a third, semidirect, pathway of MHC allorecognition. Persistence of this pathway would lead to sustained activation of direct‐pathway T cells, arguably persisting for the life of the transplant. In this study, we focused on the contribution of acquired MHC‐class I on recipient DCs during the life span of a skin graft. We observed that MHC‐class I acquisition by recipient DCs occurs for at least 1 month following transplantation and may be the main source of alloantigen that drives CD8⁺ cytotoxic T cell responses. In addition, acquired MHC‐class I:peptide complexes stimulate T cell responses in vivo, further emphasizing the need to regulate both pathways to induce indefinite survival of the graft.     

UVB‐induced depletion of donor‐derived dendritic cells prevents allograft rejection of immune‐privileged hair follicles in humanized mice

Dendritic cells (DCs) are key targets for immunity and tolerance induction; they present donor antigens to recipient T cells by donor‐ and recipient‐derived pathways. Donor‐derived DCs, which are critical during the acute posttransplant period, can be depleted in graft tissue by forced migration via ultraviolet B light (UVB) irradiation. Here, we investigated the tolerogenic potential of donor‐derived DC depletion through in vivo and ex vivo UVB preirradiation (UV) combined with the injection of anti‐CD154 antibody (Ab) into recipients in an MHC‐mismatched hair follicle (HF) allograft model in humanized mice. Surprisingly, human HF allografts achieved long‐term survival with newly growing pigmented hair shafts in both Ab‐treated groups (Ab‐only and UV plus Ab) and in the UV‐only group, whereas the control mice rejected all HF allografts with no hair regrowth. Perifollicular human CD3⁺ T cell and MHC class II⁺ cell infiltration was significantly diminished in the presence of UV and/or Ab treatment. HF allografts in the UV‐only group showed stable maintenance of the immune privilege in the HF epithelium without evidence of antigen‐specific T cell tolerance, which is likely promoted by normal HFs in vivo. This immunomodulatory strategy targeting the donor tissue exhibited novel biological relevance for clinical allogeneic transplantation without generalized immunosuppression.     

The Effect of MHC Antigen Matching Between Donors and Recipients on Skin Tolerance of Vascularized Composite Allografts

The emergence of skin‐containing vascularized composite allografts (VCAs) has provided impetus to understand factors affecting rejection and tolerance of skin. VCA tolerance can be established in miniature swine across haploidentical MHC barriers using mixed chimerism. Because the deceased donor pool for VCAs does not permit MHC antigen matching, clinical VCAs are transplanted across varying MHC disparities. We investigated whether sharing of MHC class I or II antigens between donors and recipients influences VCA skin tolerance. Miniature swine were conditioned nonmyeloablatively and received hematopoietic stem cell transplants and VCAs across MHC class I (n = 3) or class II (n = 3) barriers. In vitro immune responsiveness was assessed, and VCA skin‐resident leukocytes were characterized by flow cytometry. Stable mixed chimerism was established in all animals. MHC class II–mismatched chimeras were tolerant of VCAs. MHC class I–mismatched animals, however, rejected VCA skin, characterized by infiltration of recipient‐type CD8⁺ lymphocytes. Systemic donor‐specific nonresponsiveness was maintained, including after VCA rejection. This study shows that MHC antigen matching influences VCA skin rejection and suggests that local regulation of immune tolerance is critical in long‐term acceptance of all VCA components. These results help elucidate novel mechanisms underlying skin tolerance and identify clinically relevant VCA tolerance strategies.     

Prevention and restoration of second-set liver allograft rejection in presensitized mice: the role of "passenger" leukocytes, donor major histocompatibility complex antigens, and host cytotoxic effector mechanisms

BACKGROUND: The aim was to determine whether sublethal donor total body irradiation (TBI) might be as effective as lethal TBI in preventing mouse second-set liver allograft rejection, and to evaluate the role of passenger leukocytes, donor major histocompatibility complex (MHC) antigens, and host effector mechanisms in the response to livers from sublethally irradiated donors. METHODS: B10 (H2b) donors received various doses of TBI at different times before their livers were transplanted orthotopically into normal or donor skin-presensitized C3H (H2k) recipients. The influence of irradiation on graft non-parenchymal cells (NPC) was determined by monoclonal antibody staining, and flow cytometric analysis. Hematopoietic cells within the grafts were reconstituted by intravenous infusion of syngeneic or third-party bone marrow cells. Allograft survival was determined in recipients that received no treatment, or that were given spleen cells from either normal B10 donors, or MHC class I - or class II-deficient mice syngeneic with the donors. Cytotoxic activity of graft-infiltrating cells and host spleen cells, and complement-dependent cytotoxic alloantibody titers were determined by isotype release assays. RESULTS: The protective effect of donor TBI was observed both at lethal (9.5 Gy) and sublethal doses (5 and 3 Gy; graft median survival time: >100 days). Extended delay in liver transplantation, allowing hematopoietic recovery and graft reconstitution eliminated the effect. Liver NPC were reduced about 80% within 24 hr of 3 Gy TBI, with a selective reduction in the incidence of B cells. The NPC-depleted livers underwent accelerated rejection when donor (but not third-party) spleen cells (5 x 10(7) were administered systemically to the recipient immediately after graft revascularization. Spleen cells from MHC class I-deficient (but not MHC class II-deficient) mice failed to fully restore accelerated rejection of TBI liver grafts. Freshly isolated graft NPC, or spleen cells from TBI liver recipients, harvested 4 days after transplantation, exhibited lower, donor-specific cytotoxic activity than cells from mice given normal livers. Recipients of TBI livers also showed much lower serum complement-dependent cytotoxic alloantibody titers. CONCLUSIONS: By substantially depleting "passenger leukocytes," sublethal donor TBI undermines anti-donor cell-mediated and humoral immune reactivity and inhibits second-set liver allograft rejection in presensitized recipients. The interval between irradiation and transplantation is important in conferring resistance to rejection. Expression of MHC class I on donor leukocyte infusions is important for overcoming resistance to second-set rejection induced by donor irradiation.     

The role of passenger leukocyte genotype in rejection and acceptance of rat liver allografts

BACKGROUND: Although graft-resident passenger leukocytes are known to mediate acute rejection by triggering direct allorecognition, they may also act in an immunomodulatory fashion and play an important role in tolerance induction. Our purpose in the current study was to utilize rat bone marrow chimeras to evaluate the role of the genotype of passenger leukocytes in both acute rejection and tolerance of liver allografts. METHODS: The fate of livers bearing donor-type, recipient-type, and third-party passenger leukocytes was evaluated in the MHC class I and II mismatched rejector combination ACI-->LEW and the acceptor combination PVG-->DA. RESULTS: We report that although treatment of ACI liver donors with lethal irradiation does not lead to prolongation of graft survival in the ACI-->LEW strain combination, ACI livers bearing recipient-type (LEW) or third-party passenger leukocytes (BN) are rejected at a significantly slower rate. We confirm that lethal irradiation of PVG donor animals leads to abrogation of tolerance induction with acute rejection of their livers by DA recipients. However, the majority of PVG livers carrying donor-type (PVG), recipient-type (DA), or third-party (LEW) passenger leukocytes are accepted for >100 days. These DA recipients develop immune tolerance to the donor parenchyma (PVG). CONCLUSIONS: Our findings demonstrate that long-term acceptance of liver allografts and tolerance induction is not dependent on the presence of donor-type passenger leukocytes and can be achieved with organs carrying donor-type, recipient-type, or third-party passenger leukocytes. The importance of the MHC framework on the surface of passenger leukocytes as a critical regulator of the immune response after transplantation of chimeric organs is substantiated by the delayed tempo of rejection of ACI livers bearing recipient-type or third-party passenger leukocytes in the ACI-->LEW strain combination.     

Sharing of Class I MHC Molecules Between Donor and Host Promotes the Infiltration of Allografts by mHAg‐Reactive CD8+ T cells

Indirect recognition of minor histocompatibility antigens (mHAg) and/or MHC‐encoded allopeptides is an important barrier to long‐term allograft acceptance following solid organ transplantation. Efficient priming of CD8⁺ T cells can occur after allotransplantation as a consequence of cross‐presentation of donor‐derived proteins by the graft recipient's APC. Consistent with this, draining lymph node clonal expansion of OVA‐reactive OT‐I CD8⁺ T cells following placement of OVA‐transgenic skin grafts did not depend on graft expression of K^b. However, OT‐I T cells did accumulate in OVA‐transgenic skin grafts most efficiently only when both the donor and host expressed K^b. OT‐I infiltration of (B6‐OVA × BALB/c)F₁ grafts in B6 recipients was not suppressed by graft expression of H‐2^d. Furthermore, B6 animals transplanted with both B6‐OVA and BALB/c‐OVA skin had more OT‐I T cells infiltrating their B6‐OVA MHC‐matched graft. Therefore, class I MHC matching between donor and host may not always favor an avoidance of alloreactivity within the graft tissue.     

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.     

What Is the Influence of Both Risk Donor and Risk Receiver on Simultaneous Pancreas-Kidney Transplantation?

Introduction

Some factors affect the pancreas of a marginal donor, and although their influence on graft survival has been determined, there is an increasing consensus to accept marginal organs in a controlled manner to increase the pool of organs. Certain factors related to the recipient have also been proposed as having negative influence on graft prognosis. The objective of this study was to analyze the influence of these factors on the results of our simultaneous pancreas-kidney (SPK) transplantation series.

Deletion of the activating NK cell receptor NKG2D accelerates rejection of cardiac allografts

It has already been shown that neutralization of the activating NK cell receptor NKG2D in combination with co‐stimulation blockade prolongs graft survival of vascularized transplants. In order to clarify the underlying cellular mechanisms, we transplanted complete MHC‐disparate BALB/c‐derived cardiac grafts into C57BL/6 wildtypes or mice deficient for NKG2D (Klrk1^?/?). Although median survival was 8 days for both recipient groups, we detected already at day 5 posttransplantation significantly greater intragraft frequencies of NKp46⁺ NK cells in Klrk1^?/? recipients than in wildtypes. This was followed by a significantly greater infiltration of CD4⁺, but a lesser infiltration of CD8⁺ T cell frequencies. Contrary to published observations, co‐stimulation blockade with CTLA4‐Ig resulted in a significant acceleration of cardiac rejection by Klrk1^?/? recipients, and this result was confirmed by applying a neutralizing antibody against NKG2D to wildtypes. In both experimental setups, grafts derived from Klrk1^?/? recipients were characterized by significantly higher levels of interferon‐γ mRNA, and both CD4⁺ and CD8⁺ T cells displayed a greater capacity for degranulation and interferon‐γ production. In summary, our results clearly illustrate that NKG2D expression in the recipient is important for cardiac allograft survival, thus supporting the hypothesis that impairment of NK cells prevents the establishment of graft acceptance.     

Inhibition of Innate Co‐Receptor TREM‐1 Signaling Reduces CD4+ T Cell Activation and Prolongs Cardiac Allograft Survival

The innate receptor “triggering‐receptor‐expressed‐on‐myeloid‐cells‐1” (TREM‐1) enhances downstream signaling of “pattern recognition receptor” (PRR) molecules implicated in inflammatory responses. However the mechanistic role of TREM‐1 in chronic heart rejection has yet to be elucidated. We examined the effect of TREM‐1⁺ antigen‐presenting cells (APC) on alloreactive CD4⁺ lymphocytes. Bm12 donor hearts were transplanted into wild‐type MHC‐class‐II‐mismatched C57BL/6J recipient mice. Progressive allograft rejection of bm12‐donor hearts with decreased organ function, severe vasculopathy and allograft fibrosis was evident within 4 weeks. TREM‐1⁺CD11b⁺MHC‐II⁺F4/80⁺CCR2⁺ APC and IFNγ‐producing CD4⁺ cells were detected during chronic rejection. Peptide inhibition of TREM‐1 attenuated graft vasculopathy, reduced graft‐infiltrating leukocytes and prolonged allograft survival, while being accompanied by sustained low levels of CD4⁺ and CD8⁺ cell infiltration. Remarkably, temporary inhibition of TREM‐1 during early immune activation was sufficient for long‐term allograft survival. Mechanistically, TREM‐1 inhibition leads to reduced differentiation and proliferation of IFNγ‐producing Th1 cells. In conclusion, TREM‐1 influences chronic heart rejection by regulating the infiltration and differentiation of CD4⁺ lymphocytes.     

Basophils Trigger Fibroblast Activation in Cardiac Allograft Fibrosis Development

Fibrosis is a major component of chronic cardiac allograft rejection. Although several cell types are able to produce collagen, resident (donor‐derived) fibroblasts are mainly responsible for excessive production of extracellular matrix proteins. It is currently unclear which cells regulate production of connective tissue elements in allograft fibrosis and how basophils, as potential producers of profibrotic cytokines, are involved this process. We studied this question in a fully MHC‐mismatched model of heart transplantation with transient depletion of CD4⁺ T cells to largely prevent acute rejection. The model is characterized by myocardial infiltration of leukocytes and development of interstitial fibrosis and allograft vasculopathy. Using depletion of basophils, IL‐4–deficient recipients and IL‐4 receptor–deficient grafts, we showed that basophils and IL‐4 play crucial roles in activation of fibroblasts and development of fibrotic organ remodeling. In the absence of CD4⁺ T cells, basophils are the predominant source of IL‐4 in the graft and contribute to expansion of myofibroblasts, interstitial deposition of collagen and development of allograft vasculopathy. Our results indicated that basophils trigger the production of various connective tissue elements by myofibroblasts. Basophil‐derived IL‐4 may be an attractive target for treatment of chronic allograft rejection.     

Pancreatic islets engineered with a FasL protein induce systemic tolerance at the induction phase that evolves into long‐term graft‐localized immune privilege

We have previously shown that pancreatic islets engineered to transiently display a modified form of FasL protein (SA‐FasL) on their surface survive indefinitely in allogeneic recipients without a need for chronic immunosuppression. Mechanisms that confer long‐term protection to allograft are yet to be elucidated. We herein demonstrated that immune protection evolves in two distinct phases; induction and maintenance. SA‐FasL‐engineered allogeneic islets survived indefinitely and conferred protection to a second set of donor‐matched, but not third‐party, unmanipulated islet grafts simultaneously transplanted under the contralateral kidney capsule. Protection at the induction phase involved a reduction in the frequency of proliferating alloreactive T cells in the graft‐draining lymph nodes, and required phagocytes and TGF‐β. At the maintenance phase, immune protection evolved into graft site‐restricted immune privilege as the destruction of long‐surviving SA‐FasL‐islet grafts by streptozotocin followed by the transplantation of a second set of unmanipulated islet grafts into the same site from the donor, but not third party, resulted in indefinite survival. The induced immune privilege required both CD4⁺CD25⁺Foxp3⁺ Treg cells and persistent presence of donor antigens. Engineering cell and tissue surfaces with SA‐FasL protein provides a practical, efficient, and safe means of localized immunomodulation with important implications for autoimmunity and transplantation.     

The Role of Regulatory Cells in Miniature Swine Rendered Tolerant to Cardiac Allografts by Donor Kidney Cotransplantation

To determine the mechanism by which cotransplantation of a kidney allograft induces tolerance to a donor heart in miniature swine, we examined the role of CD25⁺ cells in heart/kidney recipients. Tolerance was induced to class‐I MHC mismatched hearts by cotransplanting a donor‐specific kidney with a 12‐day course of cyclosporine. Peripheral blood leukocytes (PBL) were isolated from tolerant heart/kidney recipients and used in cell‐mediated lympholysis (CML) coculture assays as either unmodified PBL, PBL enriched for CD25⁺ cells or PBL depleted of CD25⁺ cells to assess their ability to suppress CML responses of naïve recipient‐matched leukocytes against mismatched target cells. Primed PBL from tolerant heart/kidney recipients completely suppressed lysis by naïve cells. Complete suppression of the response of naïve recipient‐matched leukocytes against donor‐matched target cells was lost following the depletion of CD25⁺ cells from tolerant heart/kidney animal PBL, but it was reestablished by incubation of naïve cells with small populations of CD25⁺ cells from tolerant heart/kidney animals. These data suggest that peripheral blood from tolerant heart/kidney recipients contains regulatory cells that, upon priming, can suppress the response of naïve‐matched PBL in coculture CML assays, and that suppression appears to be dependent on cells expressing CD25.     

The role of graft-derived dendritic leukocytes in the rejection of vascularized organ allografts. Recent findings on the migration and function of dendritic leukocytes after transplantation

Dendritic cells isolated from lymphoid tissues are potent stimulators of primary allogeneic T-cell responses in vitro and in vivo. Similar major histocompatibility complex class II-bearing dendritic-shaped leukocytes are contained within transplanted organs and these are thought to be important passenger leukocytes that trigger rejection. Recent findings on the migration, phenotype, and function of cardiac dendritic leukocytes (DLs) are reviewed. After transplantation donor DLs migrate rapidly from mouse cardiac allografts into the recipients's spleens. Within the spleens donor DLs associate with recipient CD4+ T cells. Isolated cardiac DLs, like lymphoid dendritic cells, are potent stimulators of T-cell proliferation in vitro. This suggests that DLs function as passenger leukocytes by migrating from grafts into the lymphoid tissues of the recipient and that sensitization to vascularized organ allografts may occur centrally within lymphoid tissues rather than peripherally in the graft itself.     

Studies on the participation of different T cell subsets in rat liver allograft rejection

In this study, we investigated which subsets of rat T cells (CD8 + vs. CD4 + ) are involved in the rejection of liver allografts by the in vivo administration of monoclonal antibody (OX-8 or OX-38, and W3/25 MAb) into thymectomized recipient Lewis (RTI¹) rats prior to DA (RTI^a) liver transplantation. We also compared the results of allograft survival of liver and heart transplants under the same experimental conditions. In order to deplete either CD8 + T cells or CD4 + T cells from recipient animals, 0.4 ml of OX-8 (ascitic form) or a 0.8 ml cocktail of MAb W3/25 and OX-38 (0.4 ml each) was injected into thymectomized recipient rats, respectively. Untreated Lewis rats consistently rejected donor DA liver grafts between 9 and 11 days (n = 7, 9.8 days ± 1.1 days). In contrast, anti-CD8 MAb pretreatment extended the survival times of DA liver grafts for up to 40 days (n = 5, 26.8 days ± 8.4 days). Furthermore, survival of DA liver grafts was significantly prolonged in Lewis rats that had been pretreated with anti-CD4 MAb (n = 7,35.6 days ± 17.9 days). Two out of seven recipient animals survived for more than 60 days. For heart transplantation, untreated Lewis rats rejected DA heart grafts between 6 and 8 days after operation (n = 6, 6.5 days ± 1.2 days). Anti-CD4 MAb treatment prolonged heart graft survival for more than 60 days in all cases (n = 3, > 60 days). However, there was virtually no effect of anti-CD8 MAb treatment on heart graft survival (n = 4, 7.0 days ± 0.9 days). These results suggested that when whole MHC disparity prevailed between donor and recipient, both subsets of T cells were required for the rejection of liver allografts and that class II reactive T cells predominantly mediated liver graft rejection. Furthermore, CD8 + T cells played a differential role in the rejection of rat liver and heart allograft.     

Peritransplant VLA‐4 blockade inhibits endogenous memory CD8 T cell infiltration into high‐risk cardiac allografts and CTLA‐4Ig resistant rejection

Recipient endogenous memory CD8 T cells expressing reactivity to donor class I MHC infiltrate MHC‐mismatched cardiac allografts within 24 hours after reperfusion and express effector functions mediating graft injury. The current study tested the efficacy of Very Late Antigen‐4 (VLA‐4) blockade to inhibit endogenous memory CD8 T cell infiltration into cardiac allografts and attenuate early posttransplant inflammation. Peritransplant anti‐VLA‐4 mAb given to C57BL6 (H‐2^b) recipients of AJ (H‐2^a) heart allografts completely inhibited endogenous memory CD4 and CD8 T cell infiltration with significant decrease in macrophage, but not neutrophil, infiltration into allografts subjected to either minimal or prolonged cold ischemic storage (CIS) prior to transplant, reduced intra‐allograft IFN‐γ‐induced gene expression and prolonged survival of allografts subjected to prolonged CIS in CTLA‐4Ig treated recipients. Anti‐VLA‐4 mAb also inhibited priming of donor‐specific T cells producing IFN‐γ until at least day 7 posttransplant. Peritransplant anti‐VLA plus anti‐CD154 mAb treatment similarly prolonged survival of allografts subjected to minimal or increased CIS prior to transplant. Overall, these data indicate that peritransplant anti‐VLA‐4 mAb inhibits early infiltration memory CD8 T cell infiltration into allografts with a marked reduction in early graft inflammation suggesting an effective strategy to attenuate negative effects of heterologous alloimmunity in recipients of higher risk grafts.     

CD8+ T‐Cell Depletion and Rapamycin Synergize with Combined Coreceptor/Stimulation Blockade to Induce Robust Limb Allograft Tolerance in Mice

The growing development of composite tissue allografts (CTA) highlights the need for tolerance induction protocols. Herein, we developed a mouse model of heterotopic limb allograft in a stringent strain combination in which potentially tolerogenic strategies were tested taking advantage of donor stem cells in the grafted limb. BALB/c allografts were transplanted into C57BL/6 mice treated with anti‐CD154 mAb, nondepleting anti‐CD4 combined to either depleting or nondepleting anti‐CD8 mAbs. Some groups received additional rapamycin. Both depleting and nondepleting mAb combinations without rapamycin only delayed limb allograft rejection, whereas the addition of rapamycin induced long‐term allograft survival in both combinations. Nevertheless, robust donor‐specific tolerance, defined by the acceptance of a fresh donor‐type skin allograft and simultaneous rejection of third‐party grafts, required initial CD8⁺ T‐cell depletion. Mixed donor‐recipient chimerism was observed in lymphoid organs and recipient bone marrow of tolerant but not rejecting animals. Tolerance specificity was confirmed by the inability to produce IL‐2, IFN‐γ and TNF‐α in MLC with donor antigen while significant alloreactivity persisted against third‐ party alloantigens. Collectively, these results show that robust CTA tolerance and mixed donor‐recipient chimerism can be achieved in response to the synergizing combination of rapamycin, transient CD8⁺ T‐cell depletion and costimulation/coreceptor blockade.     

The characterization of reconstituted passenger leukocytes on the induction of tolerance in rat liver transplantation

The tolerance induced by orthotopic liver transplantation [DA (RT1^a) rats to PVG (RT1^c) rats] can be prevented by total body irradiation of the donor rat. Reconstitution of the irradiated donor with DA splenic leukocytes reintroduces this tolerance. To investigate the major histocompatibility complex (MHC) specificity of passenger leukocytes, irradiated DA donors were reconstituted by third-party BN (RT1ⁿ) splenic leukocytes. The reconstitution with BN splenocytes re-established DA-specific tolerance in PVG recipients, as confirmed by subsequent DA cardiac allografting, while BN hearts were rejected with second-set tempo. To determine which cell components play an important role in re-establishing liver graft tolerance, DA splenic leukocytes were further purified into three types: T, B, and adherent cells. Only “T-cell-enriched” preparations restored liver graft tolerance in three out of five PVG recipients. These results suggest that passenger leukocytes of differing MHC types can help to induce liver-specific tolerance and that T cells in the liver graft may be essential to regulate tolerance induction. Received: 31 December 1996 Received after revision: 14 April 1997 Accepted: 15 April 1997