Role of reentry of in vivo alloMHC peptide-activated T cells into the adult thymus in acquired systemic tolerance

Transfer of multiple loci of donor's genes to induce recipient tolerance in organ transplantation

Donor organ rejection remains a significant problem. The present study aimed to assess whether transferring a donor's major histocompatibility complex (MHC) genes to the recipient could mitigate rejection in organ transplantation. Seven loci of MHC genes from donor mice were amplified and ligated into vectors; the vectors either contained one K locus, seven loci or were empty (control). The vectors were subsequently injected into the thymus of recipients (in heterotransplants, recipient rats received the vector containing one K locus), following which donor mouse hearts were transplanted. Following the transplantation of allograft and heterograft, electrocardiosignals were viable for a significantly longer duration in recipient mice and rats receiving the donor histocompatibility-2 complex (H-2)^d genes compared with those in controls, and in mice that received seven vectors compared with those receiving one vector. Mixed lymphocyte cultures containing cells from these recipients proliferated significantly less compared with mixed lymphocyte cultures containing controls. Also, hearts from H-2^d genes-treated recipients demonstrated less lymphocyte infiltration and necrosis compared with the control recipient. The present study concluded that allograft and heterograft rejection may be mitigated by introducing the donor's MHC into the recipient; transferring seven loci has been demonstrated to be more effective than transferring one locus.

Severe Changes in Thymic Microenvironment in a Chronic Experimental Model of Paracoccidioidomycosis

T cell maturation takes place within the thymus, a primary lymphoid organ that is commonly targeted during infections. Previous studies showed that acute infection with Paracoccidioides brasiliensis (Pb), the causative agent of paracoccidioidomycosis (PCM), promotes thymic atrophy that is associated with the presence of yeast cells in the organ. However, as human PCM is a chronic infection, it is imperative to investigate the consequences of Pb infection over the thymic structure and function in chronic infection. In this sense, we developed a new experimental model where Pb yeast cells are injected through the intraperitoneal route and mice are evaluated over 120 days of infection. Thymuses were analyzed in chronically infected mice and we found that the thymus underwent extensive morphological alterations and severe infiltration of P. brasiliensis yeast cells. Further analyses showed an altered phenotype and function of thymocytes that are commonly found in peripheral mature T lymphocytes. We also observed activation of the NLRP3 inflammasome in the thymus. Our data provide new information on the severe changes observed in the thymic microenvironment in a model of PCM that more closely mimics the human infection.

MCP-1/CCR2 interactions direct migration of peripheral B and T lymphocytes to the thymus during acute infectious/inflammatory processes

Mature lymphocyte immigration into the thymus has been documented in mouse, rat, and pig models, and highly increases when cells acquire an activated phenotype. Entrance of peripheral B and T cells into the thymus has been described in healthy and pathological situations. However, it has not been proposed that leukocyte recirculation to the thymus could be a common feature occurring during the early phase of a Th1 inflammatory/infectious process when a large number of peripheral cells acquire an activated phenotype and the cellularity of the thymus is seriously compromised. The data we present here demonstrate that in well-established Th1 models triggered by different types of immunogens, for example, LPS treatment (a bacterial product), Candida albicans infection (a fungus), and after Trypanosoma cruzi infection (a parasite), a large number of mature peripheral B and T cells enter the thymus. This effect is dependent on, but not exclusive of, the available space in the thymus. Our data also demonstrate that MCP-1/CCR2 (where MCP-1 is monocyte chemoattractant protein-1) interaction is responsible for the infiltration of peripheral cells to the thymus in these Th1-inflammatory/infectious situations. Finally, systemic expression of IL-12 and IL-18 produced during the inflammatory process is ultimately responsible for these migratory events.

Tolerance and lymphoid organ structure and function

This issue of Frontiers in Immunologic Tolerance explores barriers to tolerance from a variety of views of cells, molecules, and processes of the immune system. Our laboratory has spent over a decade focused on the migration of the cells of the immune system, and dissecting the signals that determine how and where effector and suppressive regulatory T cells traffic from one site to another in order to reject or protect allografts. These studies have led us to a greater appreciation of the anatomic structure of the immune system, and the realization that the path taken by lymphocytes during the course of the immune response to implanted organs determines the final outcome. In particular, the structures, microanatomic domains, and the cells and molecules that lymphocytes encounter during their transit through blood, tissues, lymphatics, and secondary lymphoid organs are powerful determinants for whether tolerance is achieved. Thus, the understanding of complex cellular and molecular processes of tolerance will not come from “96-well plate immunology,” but from an integrated understanding of the temporal and spatial changes that occur during the response to the allograft. The study of the precise positioning and movement of cells in lymphoid organs has been difficult since it is hard to visualize cells within their three-dimensional setting; instead techniques have tended to be dominated by two-dimensional renderings, although advanced confocal and two-photon systems are changing this view. It is difficult to precisely modify key molecules and events in lymphoid organs, so that existing knockouts, transgenics, inhibitors, and activators have global and pleiotropic effects, rather than precise anatomically restricted influences. Lastly, there are no well-defined postal codes or tracking systems for leukocytes, so that while we can usually track cells from point A to point B, it is exponentially more difficult or even impossible to track them to point C and beyond. We believe this represents one of the fundamental barriers to understanding the immune system and devising therapeutic approaches that take into account anatomy and structure as major controlling principles of tolerance.

The molecular signature underlying the thymic migration and maturation of TCRαβ+ CD4+ CD8 thymocytes

BACKGROUND

After positive selection, the newly generated single positive (SP) thymocytes migrate to the thymic medulla, where they undergo negative selection to eliminate autoreactive T cells and functional maturation to acquire immune competence and egress capability.

METHODOLOGY/PRINCIPAL FINDINGS

To elucidate the genetic program underlying this process, we analyzed changes in gene expression in four subsets of mouse TCRαβ(+)CD4(+)CD8(-) thymocytes (SP1 to SP4) representative of sequential stages in a previously defined differentiation program. A genetic signature of the migration of thymocytes was thus revealed. CCR7 and PlexinD1 are believed to be important for the medullary positioning of SP thymocytes. Intriguingly, their expression remains at low levels in the newly generated thymocytes, suggesting that the cortex-medulla migration may not occur until the SP2 stage. SP2 and SP3 cells gradually up-regulate transcripts involved in T cell functions and the Foxo1-KLF2-S1P(1) axis, but a number of immune function-associated genes are not highly expressed until cells reach the SP4 stage. Consistent with their critical role in thymic emigration, the expression of S1P(1) and CD62L are much enhanced in SP4 cells.

CONCLUSIONS

These results support at the molecular level that single positive thymocytes undergo a differentiation program and further demonstrate that SP4 is the stage at which thymocytes acquire the immunocompetence and the capability of emigration from the thymus.

The role of the thymus in tolerance

The thymus serves as the central organ of immunologic self-nonself discrimination. Thymocytes undergo both positive and negative selection, resulting in T cells with a broad range of reactivity to foreign antigens but with a lack of reactivity to self-antigens. The thymus is also the source of a subset of regulatory T cells that inhibit autoreactivity of T-cell clones that may escape negative selection. As a result of these functions, the thymus has been shown to be essential for the induction of tolerance in many rodent and large animal models. Proper donor antigen presentation in the thymus after bone marrow, dendritic cell, or solid organ transplantation has been shown to induce tolerance to allografts. The molecular mechanisms of positive and negative selection and regulatory T-cell development must be understood if a tolerance-inducing therapeutic intervention is to be designed effectively. In this brief and selective review, we present some of the known information on T-cell development and on the role of the thymus in experimental models of transplant tolerance. We also cite some clinical attempts to induce tolerance to allografts using pharmacologic or biologic interventions.

New strategies in immune tolerance induction

Induction of tolerance in clinical organ transplantation that will obviate the use of chronic immunosuppression and preserve host immune response to other antigens remains the goal of transplant research. The thymus plays a critical role in the ability of the immune system to discriminate between self- and nonself-antigens or harmful and harmless alloantigens. We now know that multiple factors determine how the immune system responds to a self-antigen or foreign antigen. These determinants include developmental stage of the host, stage of T-cell maturity, site of antigen encounter, type and maturity of antigen-presenting cells, and presence and type of costimulatory molecules. Our understanding of the mechanisms of T-cell interactions with peptide/ major histocompatibility complex in peripheral lymphoid organs has led to experiments that translate into peripheral T-cell tolerance. The induction of high-avidity peripheral alloreactive T cells in the early phase of organ transplantation makes it difficult to achieve long-term alloantigen-specific tolerance without the use of transient perioperative immunosuppression. Therefore, protocols that induce robust tolerance in rodent and nonhuman primate models involve the use of donor antigen combined with a short course of perioperative immunosuppression. These studies suggest that the underlying mechanisms of peripheral tolerance include deletion, anergy, immune deviation, and regulatory T cells. This review focuses on recent advances in tolerance induction in experimental animal models and discusses their relevance to the development of protocols for the induction and maintenance of clinical transplant tolerance.

Re-entry of mature T cells to the thymus: an epiphenomenon?

In certain situations mature post-thymic T cells are able to leave their residence in the secondary lymphoid tissues and re-enter the thymus. The physiological significance of this phenomenon is discussed.

Back to the thymus: peripheral T cells come home

The thymus has long been known as the generative organ for the T-cell arm of the immune system. To perform this role, the thymus was thought to require protection from antigenic and cellular insult from the 'outside world', with the notable exception of the continual influx of progenitor cells required to initiate the complicated process of T-cell differentiation. Overwhelming evidence that mature T cells can recirculate and persist in the thymus has required us to revamp this earlier view of the thymus as detached from outside influence. In this review, we consider the evidence for T-cell recirculation into the thymus, discuss the likely means and location of mature T-cell entry, and speculate on the potential consequences of such close apposition between differentiating thymocytes and mature recirculating lymphocytes.

Homeostatic expansion permits T cells to re-enter the thymus and deliver antigen in a tolerogenic fashion

We previously have shown that delivery of alloantigen on T cells can be used to induce tolerance through central deletion. Here, we analyzed the requirements for tolerance induced by T cells. Adoptively transferred allogeneic T cells undergo extensive homeostatic proliferation in the periphery of lethally irradiated hosts receiving a syngeneic bone marrow transplant, and acquire a memory-like cell surface phenotype. Analysis of the kinetics of thymic re-entry of transferred T cells revealed that T cells undergo homeostatic proliferation in the periphery prior to re-entry into the thymus. Prevention of homeostatic proliferation results in a failure of transferred T cells to re-enter the thymus. In the absence of homeostatic proliferation, adoptively transferred T cells were unable to induce tolerance. These date suggest that homeostatic proliferation of T cells resulting in an activated cell surface phenotype is required for thymic re-entry and is mechanistically linked to the ability of T cells to induce tolerance.

Class I MHC allochimeric presentation of composite immunogenic and self epitopes induces tolerance to genetically diverse rat strains

Functional topography of rat class I major histocompatibility complex (MHC) molecule was studied. The alpha1-helical sequences that are shared by class I RT1.A(l) and RT1.A(u) were substituted in the RT1.A(a) molecule to produce the composite [alpha(1h)(l/u)]-RT1.A(a) MHC class I allochimeric molecule. Dominant immunogenic epitopes that induce accelerated rejection were identified within the hypervariable regions of the alpha1 domain of RT1.A(a), RT1.A(l), and RT1.A(u). Peri-transplant portal venous delivery of MHC class I allochimeric proteins, that included composite alpha1 helical immunodominant epitopes of RT1.A(u) and RT1.A(l), induced donor-specific tolerance to RT1(u) (Wistar Furth, WF) and RT1(l) Lewis, LEW) disparate cardiac allografts in ACI (RT1(a)) hosts. Allochimeric generated tolerance was characterized by absence of T cell deletion or anergy. Donor specific IgM allo-Abs was not detected, while IgG alloresponse was markedly attenuated in sera of tolerant hosts. Further, long-term allografts in allochimeric-conditioned hosts exhibited moderate B cell infiltration when compared to rejecting controls. Analysis of intragraft cytokines revealed selective upregulation of IL-10 and marked inhibition of IL-2, IFN-gamma, and IL-4. Our findings indicate the emergence of a peripherally induced tolerant state, afforded by the novel approach of soluble class I allochimeric conditioning that presents donor immunogenic epitopes in the context of recipient class I determinants.

Donor T-cell alloreactivity against host thymic epithelium limits T-cell development after bone marrow transplantation

Acute graft-versus-host disease (aGVHD) impairs thymus-dependent T-cell regeneration in recipients of allogeneic bone marrow transplants through yet to be defined mechanisms. Here, we demonstrate in mice that MHC-mismatched donor T cells home into the thymus of unconditioned recipients. There, activated donor T cells secrete IFN-gamma, which in turn stimulates the programmed cell death of thymic epithelial cells (TECs). Because TECs themselves are competent and sufficient to prime naive allospecific T cells and to elicit their effector function, the elimination of host-type professional antigen-presenting cells (APCs) does not prevent donor T-cell activation and TEC apoptosis, thus precluding normal thymopoiesis in transplant recipients. Hence, strategies that protect TECs may be necessary to improve immune reconstitution following allogeneic bone marrow transplantation.

Thymic rejuvenation and the induction of tolerance by adult thymic grafts

The thymus, the site of origin of T cell immunity, shapes the repertoire of T cell reactivity through positive selection of developing T cells and prevents autoimmunity through negative selection of autoreactive T cells. Previous studies have demonstrated an important role for the thymus not only in central deletional tolerance, but also in the induction of peripheral tolerance by vascularized renal allografts in juvenile miniature swine recipients. The same protocol did not induce tolerance in thymectomized recipients nor in recipients beyond the age of thymic involution. We subsequently reported that vascularized thymic lobe grafts from juvenile donors were capable of inducing tolerance in thymectomized juvenile hosts. However, the important question remained whether aged, involuted thymus could also induce tolerance if transplanted into thymectomized hosts, which, if true, would imply that thymic involution is not an intrinsic property of thymic tissue but is rather determined by host factors extrinsic to the thymus. We report here that aged, involuted thymus transplanted as a vascularized graft into juvenile recipients leads to rejuvenation of both thymic structure and function, suggesting that factors extrinsic to the thymus are capable of restoring juvenile thymic function to aged recipients. We show furthermore that rejuvenated aged thymus has the ability to induce transplant tolerance across class I MHC barriers. These findings indicate that it may be possible to manipulate thymic function in adults to induce transplantation tolerance after the age of thymic involution.

Induction of regulatory T cells from mature T cells by allogeneic thymic epithelial cells in vitro

The ability of thymic epithelial cells (TEC) to re-educate mature T cells to be regulatory T cells has not been addressed. In the present study, this issue was directly investigated by co-culturing of mature T cells and allo-TECs. B6 macrophage cell line 1C21-cultured BALB/c splenocytes responded to B6 antigens in vitro. However, BALB/c splenocytes precultured with B6-derived TECs 1-4C18 or 1C6 did not proliferate to B6 antigens, but responded to rat antigens. Exogenous interleukin-2 (IL-2) failed to revise the unresponsiveness of these T cells. Allo-TEC-cultured T cells predominantly expressed Th2 cytokines (IL-4 and IL-10). B6 TEC-cultured BALB/c splenocytes markedly inhibited the immune responses of naïve BALB/c splenocytes to B6 antigens, but not to rat or the third-party mouse antigens. BALB/c nude mice that received naïve syngeneic splenocytes rejected B6 or rat skin grafts by 17 days postskin grafting; however, co-injection of B6 TEC-cultured BALB/c splenocytes significantly delayed B6 skin graft rejection (P < 0.01), with the unchanged rejection of rat skin grafts. These studies demonstrate that allo-TECs are able to 'educate' mature T cells to be regulatory cells, and suggest that regulatory cells derived from mature T cells by TECs may play an important role in T cell tolerance to allo- and auto-antigens.

Thymic output in aged mice

Using GFP to mark recent thymic emigrants (RTEs) in mice carrying a GFP transgene driven by the recombination-activating gene 2 promoter, we demonstrate that RTEs are readily detectable even in 2-year-old mice, despite the fact that the proportion of the peripheral T cell pool comprised of RTEs declines with age. Although the number of RTEs decreases after reaching a peak at 6 weeks of age, thymic output as a function of thymic size is surprisingly age-independent. The CD4:CD8 ratio of RTEs declines with age, partly because of a striking decrease in steady-state proliferation of CD4+ RTEs in older mice. RTEs in aged mice undergo phenotypic maturation in the lymphoid periphery with delayed kinetics compared with young mice. RTEs from aged mice secrete less IL-2, proliferate less well, and achieve only weak expression of early-activation markers compared with more mature naïve peripheral T cells from the same mice. The proportion of GFP- cells in the CD4+ and CD8+ thymic compartments increases with age, partly as a result of leakiness in the aged thymus, allowing reentry of naïve peripheral T cells.

Role of the thymus in transplantation tolerance in miniature swine: V. Deficiency of the graft-to-thymus pathway of tolerance induction in recipients of cardiac transplants

BACKGROUND

We have previously shown that both thymic immigrants (graft to thymus pathway) and thymic emigrants (thymus to graft pathway) are involved in tolerance to renal allografts in miniature swine treated with a short course of calcineurin inhibitors. This study investigates the role of these pathways in cardiac transplant survival in recipients treated with a short course of tacrolimus.

METHODS

Eleven animals received two-haplotype fully MHC-mismatched cardiac grafts with a 12-day course of tacrolimus. Recipients were thymectomized on day -21 (n=5) or day 0 (n=3), or were left euthymic (n=3). Two of the day -21 thymectomized animals received a day 0 host-MHC matched thymocyte infusion.

RESULTS

Euthymic recipients of cardiac grafts treated with an immunosuppressive regimen identical to that previously shown to induce tolerance in euthymic recipients of renal allografts all rejected their grafts. Although no animal became tolerant, animals that were euthymic or thymectomized on day 0, as well as recipients of day 0 host-type thymocyte infusions following thymectomy on day -21, developed donor-specific hyporesponsiveness and maintained their cardiac grafts for markedly prolonged periods. In contrast, all animals thymectomized on day -21 that did not receive thymocyte infusions developed strong antidonor CTL responses and rejected their grafts by day 35.

CONCLUSIONS

The graft-to-thymus pathway that plays an important role in tolerance induction to renal allografts appears to be relatively deficient in recipients of cardiac grafts. Strategies to increase donor antigen migration to the host thymus might therefore assist in tolerance induction to cardiac allografts.

Long-Term Acceptance of Fully Allogeneic Cardiac Grafts by Cotransplantation of Vascularized Thymus in Miniature Swine

BACKGROUND

We have previously reported the ability of both thymokidney and vascularized thymic lobe (VTL) allografts to induce transplantation tolerance to renal allografts across a full major histocompatibility complex (MHC) mismatch in thymectomized miniature swine. However, whether vascularized thymus is capable of inducing tolerance to less tolerogeneic organs when it is transplanted simultaneously is not yet known. The present study investigates cardiac allograft survival and the mechanism of long-term acceptance in recipient swine following cotransplantation of VTL and cardiac grafts from fully MHC-mismatched donors.

METHODS

Animals received a heart graft, a heart graft and a VTL, or a heart graft and a donor thymocyte infusion. Immunosuppressive regimens consisted of 12 or 28 days of tacrolimus.

RESULTS

All animals that received a VTL maintained their grafts significantly longer than their counterparts that received only a heart graft, and those receiving 28 days of tacrolimus maintained their heart grafts long-term. Recipients of a donor thymocyte infusion demonstrated slightly prolonged cardiac graft survival but all rejected their grafts, highlighting the importance of thymic stroma. Cytotoxic T-lymphocyte responses against third-party antigens by cells from tolerant animals showed restriction by both self and donor MHC, whereas responses of controls were restricted to self MHC only. The presence of donor dendritic cells in the VTL grafts and results of co-culture assays suggest that both central and regulatory mechanisms were involved in achieving long-term acceptance.

CONCLUSION

This is the first demonstration of the long-term acceptance of fully MHC-mismatched cardiac allografts in large animals.

Vascularized Thymic Lobe Transplantation in a Pig-to-Baboon Model: A Novel Strategy for Xenogeneic Tolerance Induction and T-cell Reconstitution

BACKGROUND

This laboratory has previously demonstrated the induction of allogeneic tolerance by vascularized thymic lobe (VTL) transplantation in miniature swine. We report here our initial attempt to induce tolerance by VTL transplantation in the clinically relevant, discordant, pig-to-baboon model of xenotransplantation.

METHODS

Six baboons received xenografts of hDAF VTLs. Four of these baboons also received omental thymic tissue implants. All recipients were treated with an immunosuppressive conditioning regimen that included thymectomy, splenectomy, extracorporeal immunoadsorption of anti-alpha Gal antibodies, and T-cell depletion. Two control baboons received sham operations, of which one also received 5x10 hDAF porcine thymocytes/kg intravenously.

RESULTS

Transplanted VTL grafts supported early thymopoiesis of recipient-type immature thymocytes, and facilitated engraftment of nonvascularized thymic omental implants. Recipients of the VTL grafts demonstrated donor-specific unresponsiveness in MLR assays, development of peripheral CD45RAhigh/CD4 double positive (DP) cells, and positive cytokeratin staining of thymic stroma in the grafts for 2 months following xenotransplantation. The control baboons did not show these markers of thymic reconstitution. The eventual return of Gal natural antibodies led to the destruction of graft epithelial cells and the rejection of all VTL grafts by 3 months posttransplantation.

CONCLUSIONS

VTL transplantation from hDAF swine to baboons induced early thymopoiesis in the recipients and donor-specific cellular unresponsiveness in vitro. When coupled with additional strategies aimed at silencing humoral rejection, VTL transplantation may significantly prolong xenograft survival and result in long-term tolerance.

Tolerance to rat heart grafts induced by intrathymic immunomodulation is mediated by indirect recognition primed CD4+CD25+ Treg cells

BACKGROUND

In a rat model (PVG.R8-to-PVG.1U) disparate for one class I antigen, RT.1Aa, we previously demonstrated that intrathymic immunomodulation with donor antigens resulted in prolonged survival of cardiac allografts that underwent chronic rejection. However, long-term survivors developed a regulatory cell population that prevented both acute and chronic rejection when adoptively transferred into secondary graft recipients. The purpose of this study was to characterize these regulatory cells with particular emphasis on CD4+CD25+ Treg cells.

METHODS

Spleens, lymph nodes, and peripheral blood lymphocytes of secondary tolerant recipients were characterized using antibodies to various T cell markers in flow cytometry. In vitro MLR and in vivo adoptive transfer experiments were conducted to investigate the involvement of CD4+CD25+ T cells in the observed tolerance. The presence of various cytokines in the sera of graft recipients and MLR culture supernatants was tested using ELISA.

RESULTS

Tolerant recipients compared with naive rats had substantially higher percentages of CD4+CD25+ T cells in the spleen (28+/-3% vs. 11+/-5%) and blood (23+/-6% vs. 9+/-4%). Tolerant animals also had higher levels of serum IL-10 than naive and rejecting animals. CD4+CD25+ T cells from secondary long-term graft survivors inhibited donor-specific proliferative responses in vitro that was associated with high IL-10 production. Importantly, depletion of CD4+CD25+ T cells from splenocytes of tolerant rats abrogated their ability to transfer tolerance to tertiary graft recipients.

CONCLUSIONS

Our data demonstrate that cardiac allograft tolerance in this model is mediated by CD4+CD25+ Treg cells primed by indirect recognition and is associated with high levels of IL-10.

Induction of central tolerance by mature T cells

Induction of immunological tolerance is highly desirable for the treatment and prevention of autoimmunity, allergy, and organ transplant rejection. Adoptive transfer of MHC class I disparate mature T cells at the time of reconstitution of mice with syngeneic bone marrow resulted in specific tolerance to allogeneic skin grafts that were matched to the T cell donor strain. Mature allogeneic T cells survived long-term in reconstituted hosts and were able to re-enter the thymus. Analysis of T cell development using transgenic mice expressing an alloantigen-reactive TCR revealed that expression of allogeneic MHC class I on adoptively transferred mature T cells mediated negative selection of developing alloreactive T cells in the thymus. Thus, mature allogeneic T cells are able to mediate central deletion of alloreactive cells and induce transplantation tolerance without the requirement for any other alloantigen-expressing cell type.

Rapamycin-treated, alloantigen-pulsed host dendritic cells induce ag-specific T cell regulation and prolong graft survival

Tolerogenic properties of dendritic cells (DC), particularly those in the immature state, and their therapeutic potential are increasingly being recognized. Among several distinct approaches to generate stably immature DC, pharmacologic manipulation stands out as a promising and clinically applicable option. We have shown recently that the immunophilin ligand rapamycin (Rapa) can inhibit DC maturation and their effector functions. Here, we examined the impact of Rapa exposure on subsequent alloantigen (Ag) presentation by myeloid DC via the indirect pathway. Rapa-treated, allogeneic lysate-pulsed host DC (Rapa-DC) were inferior stimulators of syngeneic T cells, compared to lysate-pulsed control DC. Rapa exposure did not block alloAg uptake by DC nor impair their in vivo homing to splenic T cell areas after adoptive transfer. T cells primed by Rapa-treated, alloAg-pulsed DC showed decreased capacity to produce IL-2 and IFNgamma, and were hyporesponsive to subsequent challenge via both the direct and indirect pathways, in an Ag-specific manner. When infused 1 week before transplantation, these Rapa-DC significantly prolonged alloAg-specific heart graft survival. This effect was reversed by systemic IL-2 administration but enhanced by either repeated infusion of the cells or a short post-transplant course of FK506. These therapeutic effects, achieved by targeting both major pathways of allorecognition, provide the basis for a clinically applicable strategy to suppress graft rejection.

Vascularized thymic lobe transplantation in miniature swine: thymopoiesis and tolerance induction across fully MHC-mismatched barriers

As the major site of self-nonself discrimination in the immune system, the thymus, if successfully transplanted, could potentially carry with it the induction of central tolerance to any other organ or tissue from the same donor. We have recently developed a technique for transplantation of an intact, vascularized thymic lobe (VTL) in miniature swine. In the present study, we have examined the ability of such VTL allografts to support thymopoiesis and induce transplantation tolerance across fully MHC-mismatched barriers. Six miniature swine recipients received fully MHC-mismatched VTL grafts with a 12-day course of tacrolimus. Three of these recipients were thymectomized before transplantation and accepted their VTL allografts long-term, with evidence of normal thymopoiesis. In contrast, three euthymic recipients rejected their VTL allografts. Donor renal allografts, matched to the donor VTL grafts, were transplanted without immunosuppression into two of the three thymectomized recipients, and one of the three euthymic recipients. These renal allografts were accepted by thymectomized recipients, but rejected by the euthymic recipient in an accelerated fashion. This study thus demonstrates that successful transplantation of a vascularized thymus across a fully MHC-mismatched barrier induces tolerance in this preclinical, large-animal model. This procedure should enable studies on the role of the thymus in transplantation immunology as well as offer a potential strategy for tolerance induction in clinical transplantation.

Dendritic cells: regulators of alloimmunity and opportunities for tolerance induction

Dendritic cells (DCs) are uniquely well-equipped antigen-presenting cells (APCs) regarded classically as sentinels of the immune response, which induce and regulate T-cell reactivity. They play critical roles in central tolerance and in the maintenance of peripheral tolerance in the normal steady state. Following cell or organ transplantation, DCs present antigen to T cells via the direct or indirect pathways of allorecognition. These functions of DCs set in train the rejection response, but they also serve as potential targets for suppression of alloimmune reactivity and promotion of tolerance induction. Much evidence from various model systems now indicates that DCs can induce specific T-cell tolerance. Although underlying mechanisms have not been fully elucidated, the capacity to induce T-regulatory cells may be an important property of tolerogenic or regulatory DCs. Efforts to generate "designer" DCs with tolerogenic properties in the laboratory using specific cytokines, immunologic or pharmacologic reagents, or genetic engineering approaches have already met with some success. Alternatively, targeting of DCs in vivo (e.g. by infusion of apoptotic allogeneic cells) to take advantage of their inherent tolerogenicity has also demonstrated exciting potential. The remarkable heterogeneity and plasticity of these important APCs present additional challenges to optimizing DC-based therapies that may lead to improved tolerance-enhancing strategies in the clinic.

Thymic transplantation in miniature swine: III. Induction of tolerance by transplantation of composite thymokidneys across fully major histocompatibility complex-mismatched barriers

BACKGROUND

This study determines whether composite thymokidney (TK) grafts, created by implantation of autologous thymic tissue beneath the donor's renal capsule before transplantation, could induce allogeneic transplantation tolerance across two-haplotype fully major histocompatibility complex (MHC)- mismatched barriers in juvenile MGH-miniature swine.

METHODS

TK grafts were prepared by implanting autologous thymic tissue under the renal capsule of donor animals 2 to 3 months before transplantation. Four recipients were treated with a T-cell-depleting immunotoxin and received fully MHC-mismatched TK grafts plus a 12-day course of cyclosporine A (CsA). Control animals were treated with CsA alone or both CsA and immunotoxin, but with a normal kidney or a kidney implanted with autologous lymph node rather than thymus. Renal graft function was assessed by plasma creatinine levels and histologic analyses. Immunologic status was monitored by cell-mediated lympholysis assays.

RESULTS

All four recipients of fully MHC-mismatched TK transplants treated with immunotoxin and a 12-day course of CsA accepted their composite renal allografts long-term. All control recipients receiving a TK and CsA alone, a normal kidney or a composite kidney containing lymph node tissue acutely rejected their grafts.

CONCLUSIONS

To our knowledge, this is the first demonstration that functional vascularized thymic grafts can induce transplantation tolerance across fully MHC-mismatched barriers in a large animal model.

Role of CD41CD251 regulatory T cells from naive host thymus in the induction of acquired transplant tolerance by immunization with allo-major histocompatibility complex peptide

BACKGROUND

Immunization with allo-major histocompatibility complex peptide induces operational tolerance, whereas thymectomy abrogates this effect. We hypothesized that recent thymic emigrants with regulatory function are important in the induction of acquired transplant tolerance in this system.

METHODS

In this study, we examined the possibility of restoring transplant tolerance to thymectomized (TMX) ACI recipients with concomitant adoptive transfer of syngeneic T cells indirectly primed with a single immunodominant Wistar Furth allo-major histocompatibility complex class I peptide (peptide 5, residues 93-109) and unmodified thymocytes or CD4+CD25+ thymic T cells.

RESULTS

Co-transfer of in vivo allopeptide-primed T cells and naive syngeneic thymic T cells on day -7 restored permanent acceptance of cardiac allografts to 70% of transiently antilymphocyte serum-immunosuppressed TMX recipients. Similarly, the adoptive transfer of allopeptide-primed T cells led to 100% donor-specific permanent graft acceptance among transiently antilymphocyte serum-immunosuppressed TMX recipients with renal subcapsular syngeneic thymic grafts. To demonstrate the role of regulatory T cells among new thymic emigrants in the induction of tolerance, we showed that the co-transfer of CD4+CD25+ but not CD4+CD25- thymic T cells with allopeptide-primed syngeneic T cells restored tolerance to TMX recipients. It seems that the induction of transplant tolerance in this system is dependent on the presence of CD4+CD25+ regulatory T cells among the recent thymic emigrants.

CONCLUSIONS

This study suggests that CD4+CD25+ regulatory T cells specific for the induction of transplant tolerance are similar in origin, phenotype, and function to those involved in the maintenance of self-tolerance and the prevention of autoimmunity.

Thymic function and allogeneic T-cell responses in stem-cell transplantation

The thymus is the primary site of T-cell production early in life, and has now been shown to continue to function in both healthy and immunocompromised individuals late into life. Positive and negative selection occurring in the thymus are two of the most important processes that govern the development and specificity of peripheral T cells, including their restriction to self HLA and their ability to respond in an alloreactive manner. In the chimeric state that follows successful allogeneic stem-cell transplants, the specificity of alloreactive cells may be governed by either host- or recipient-derived cellular elements, as well as maturing lymphoid cells, which are, in turn, derived from donor stem cells or host cells surviving transplant conditioning. The ability to measure recent thymic emigrants via the detection of T-cell receptor excision circles has facilitated studies of thymic function in immunodeficient individuals, including HIV-1 infected subjects and recipients of autologous or allogeneic stem-cell transplant (SCT). These studies have now demonstrated that thymic function is likely to play a beneficial role in immune reconstitution in these settings, but have yet to clearly demonstrate what clinical variables are the most important determinants of thymic persistence. It is also not yet clear how much the degree of thymic function following allogeneic SCT influences the alloreactive T-cell repertoire, although studies in animal models and early clinical studies suggest that GvHD results in thymic injury and dysfunction. Future studies will further clarify how thymic function shapes the repertoire of T cells that mediate alloreactivity, as well as protective pathogen-specific immune responses, following SCT. Finally, these studies will also demonstrate whether endogenous mediators of thymic function could be selectively applied to regulate post-SCT thymic function and alloreactivity.

Potential of tolerogenic dendritic cells for transplantation

Dendritic cells (DC) are professional antigen (Ag)-presenting cells considered traditionally as the passenger leukocytes that, after migration from transplanted tissues, stimulate allospecific naive T cell responses and trigger acute rejection. However, there is recent evidence that, besides their role in central T lymphocyte deletion in the thymus, DC perform a crucial function to induce/maintain peripheral T cell tolerance. This paper outlines conceptual models that try to explain how DC may induce/maintain tolerance. It also considers how such ideas have been implemented recently in an effort to generate tolerogenic DC to induce donor Ag-specific tolerance/ immunosuppression and prolonged allograft survival. These approaches include genetic engineering of donor- or recipient-derived DC to express molecules capable of promoting tolerance to alloAg.