Depletion‐Resistant CD4 T Cells Enhance Thymopoiesis During Lymphopenia

Lymphoablation is routinely used in transplantation, and its success is defined by the balance of pathogenic versus protective T cells within reconstituted repertoire. While homeostatic proliferation and thymopoiesis may both cause T cell recovery during lymphopenia, the relative contributions of these mechanisms remain unclear. The goal of this study was to investigate the role of the thymus during T cell reconstitution in adult allograft recipients subjected to lymphoablative induction therapy. Compared with euthymic mice, thymectomized heart allograft recipients demonstrated severely impaired CD4 and CD8 T cell recovery and prolonged heart allograft survival after lymphoablation with murine anti‐thymocyte globulin (mATG). The injection with agonistic anti‐CD40 mAb or thymus transplantation only partially restored T cell reconstitution in mATG‐treated thymectomized mice. After mATG depletion, residual CD4 T cells migrated into the thymus and enhanced thymopoiesis. Conversely, depletion of CD4 T cells before lymphoablation inhibited thymopoiesis at the stage of CD4^?CD8^?CD44^hiCD25⁺ immature thymocytes. This is the first demonstration that the thymus and peripheral CD4 T cells cooperate to ensure optimal T cell reconstitution after lymphoablation. Targeting thymopoiesis through manipulating functions of depletion‐resistant helper T cells may thus improve therapeutic benefits and minimize the risks of lymphoablation in clinical settings.     

The BH3‐mimetic ABT‐737 inhibits allogeneic immune responses

Apoptosis controls the adaptive immune system through regulation of central and peripheral lymphocyte deletion. Therefore, substances that selectively interact with the intrinsic apoptosis pathway in lymphocytes offer unexplored opportunities to pharmacologically modulate the immune response. Here, we present evidence that the BH3‐mimetic ABT‐737 suppresses allogeneic immune responses. In vitro, ABT‐737 prevented allogeneic T‐cell activation, proliferation, and cytotoxicity by apoptosis induction, but without impairing the physiological functions of remaining viable T cells. In vivo, ABT‐737 was highly selective for lymphoid cells and inhibited allogeneic T‐ and B‐cell responses after skin transplantation. The immunosuppressive effect of ABT‐737 was markedly increased in combination with low‐dose cyclosporine A, as shown by the induction of long‐term skin graft survival without significant inflammatory infiltrates in 50% of the recipients in an MHC class I single antigen mismatched model. Thus, pharmacological targeting of Bcl‐2 proteins represents a novel immunosuppressive approach to prevent rejection of solid organ allografts.     

Analysis of therapeutic potential of monocytic myeloid-derived suppressor cells in cardiac allotransplantation

BackgroundMyeloid-derived suppressor cells (MDSCs) and regulatory T cells (Tregs) are attractive immune cells to induce immune tolerance. To explore a strategy for improving the efficacy of MDSC therapies, we examined the impact of adoptive transfer of several types of MDSCs on graft rejection in a murine heart transplantation model.MethodsWe analyzed the effects of induced syngeneic and allogeneic bone marrow-derived MDSCs (BM-MDSCs) on graft survival and suppressive capacity. We also compared the ability of syngeneic monocytic MDSCs (Mo-MDSCs) and polymorphonuclear MDSCs (PMN-MDSCs) to inhibit graft rejection and investigated the suppression mechanisms.ResultsBoth syngeneic and allogeneic donor- or allogeneic third-party-derived BM-MDSCs prolonged graft survival, although syngeneic BM-MDSCs inhibited anti-donor immune responses most effectively in vitro. Syngeneic Mo-MDSCs, rather than PMN-MDSCs, were responsible for immune suppression through downregulating inducible nitric oxide synthase (iNOS) and expanded naturally occurring thymic originated Treg (nTreg) in vitro. Adoptive transfer of Mo-MDSCs, but not PMN-MDSCs, prolonged graft survival and increased Treg infiltration into the graft heart.ConclusionRecipient-derived Mo-MDSCs are most effective in prolonging graft survival via inhibiting T cell response and nTreg infiltration.     

Intrarenal antigens activate CD4+ cells via co-stimulatory signals from dendritic cells

Dendritic cells in the kidney take up antigens, but little is known about their role in providing co-stimulatory signals for the activation of CD4⁺ cells. This study examined the phenotype of dendritic cells in the renal interstitium and in the lymph node draining the kidney before and after intrarenal ovalbumin injection. After intrarenal injection of the antigen, expression of the co-stimulatory molecules CD86 and programmed cell death ligand 1 (PD-L1) increased on renal dendritic cells, whereas expression of only CD86 increased on dendritic cells of the draining lymph node. The activation and proliferation of antigen-specific CD4⁺ cells in the lymph node were assessed by transfer of naïve, fluorescently labeled ovalbumin-specific T cell receptor transgenic cells to mice before antigen administration. Blocking both CD86 and CD80 profoundly inhibited CD4⁺ cell proliferation, but CD86 was the dominant CD28 ligand in the early proliferative response of CD4⁺ cells. Conversely, activation of PD-1, the receptor expressed on CD4⁺ cells that binds PD-L1 and PD-L2, reduced the proliferation of CD4⁺ cells in the draining lymph node. Comparing subcutaneous and intrarenal administration of antigen, it was found that CD4⁺ cell activation was slower and the effects of combined CD80 and CD86 blockade were more profound when antigen was presented via the kidney compared with the skin. In summary, renal dendritic cells take up antigen and participate in the control of antigen-specific CD4⁺ cell proliferation by upregulating co-stimulatory molecules such as CD86 that stimulate CD4⁺ cell proliferation and by signaling through PD-1, which prevents an inappropriately exuberant immune response.Because CD4⁺ cells direct adaptive immune responses in infection, autoimmunity, and allogeneic responses they are relevant to renal infection, pathologic renal inflammation, and renal transplantation. CD4⁺ cells are activated in local draining lymph nodes (LN) after encounters with activated and licensed dendritic cells (DC) presenting relevant antigenic peptides. Licensed DC that have altered their phenotype in inflammation migrate from tissues to present antigen. T cells proliferate, acquire effector functions, and leave the LN several days after antigen is presented.¹ Co-stimulatory signals are important for effective immune responses, providing the “second signal” for CD4⁺ cell activation. Co-stimulatory molecules provide positive or negative signals to enhance or inhibit the immune response. Antigen presentation in the absence of co-stimulatory signals results in anergy and is important in peripheral tolerance. DC co-stimulatory molecule expression is an integral part of DC maturation and largely defines their capacity to activate naïve T cells. The B7 family of co-stimulatory molecules includes the prototypic positive signals B7-1 (CD80) and B7-2 (CD86).² Their ligands are CD28, which is constitutively expressed on CD4⁺ T cells and induces activation,³ and CTLA4 (CD152), which is expressed after T cell activation and limits T cell activation.⁴ The absence of signaling through CD28 impairs naïve CD4⁺ T cell activation.⁵The immune receptor programmed cell death 1 (PD-1) and its ligands, PD-L1 and PD-L2, B7 family members, provide negative co-stimulatory signals. They limit immune responses to avoid an overexuberant response and may prevent the development of pathogenetic self-reactivity.^2,6 PD-1–deficient mice have enhanced immune responses with autoimmunity,^7,8 and evidence is accumulating that PD-1 and its ligands regulate immune responses in peripheral tissues.⁶ Information on the role of PD-1 in the early activation of CD4⁺ T cells is limited because PD-1 expression is delayed after CD4⁺ cell activation.⁹ Expression persists on the cell surface, suggesting involvement in a later phase of CD4⁺ T cell activation, including downregulation of activated T cells. Generally speaking, PD-L2 is expressed largely by DC, whereas PD-L1 may also be expressed by tissue cells.^2,6,10Despite their central role in the immune response, CD4⁺ cells specific for an individual antigen exist at low frequency, even in active immune responses. This low frequency of antigen-specific CD4⁺ cells makes the proliferation and behavior of antigen-specific CD4⁺ cells difficult to study in vivo. The development of T cell receptor (TcR) transgenic mice in which the majority of T cells express a single TcR allows study of how immune signals induce antigen-specific responses by in vivo assessment of relatively large numbers of antigen-specific cells.^1,11 Because the skin is a primary site of entry of infectious threats and subcutaneous injection is simple, studies are performed by injecting antigen subcutaneously. The kidney, a solid internal organ, performs different functions compared with the skin. Whereas the tubulointerstitium may be exposed to foreign antigens via ascending infection, proteins processed by renal DC are more likely to be self-antigens or innocuous foreign antigens. Renal DC form a relatively extensive network in the tubulointerstitium¹² but may not be as potent at inducing T cell proliferation as splenic DC.^13,14These studies sought to define the response of renal DC exposed to antigen in the kidney parenchyma. The timing of proliferation was compared with subcutaneous antigen injection, the expression of co-stimulatory molecules and capacity to present antigen and activate antigen-specific CD4⁺ T cells in the renal draining LN was assessed, and DC co-stimulatory molecules were inhibited for better definition of the mechanisms of immune recognition and antigen presentation in the kidney. A new model of antigen presentation in the renal node was established using direct intrarenal injection and in vivo assessment of transgenic ovalbumin (OVA)-specific CD4⁺ cells. Experiments on dermal presentation of the same antigen allowed comparison of antigen presentation in the kidney with skin DC.     

Allografts Stimulate Cross‐Reactive Virus‐Specific Memory CD8 T Cells with Private Specificity

Viral infections have been associated with the rejection of transplanted allografts in humans and mice, and the induction of tolerance to allogeneic tissues in mice is abrogated by an ongoing viral infection and inhibited in virus‐immune mice. One proposed mechanism for this ‘heterologous immunity’ is the induction of alloreactive T cell responses that cross‐react with virus‐derived antigens. These cross‐reactive CD8 T cells are generated during acute viral infection and survive into memory, but their ability to partake in the immune response to allografts in vivo is not known. We show here that cross‐reactive, virus‐specific memory CD8 T cells from mice infected with LCMV proliferated in response to allografts. CD8 T cells specific to several LCMV epitopes proliferated in response to alloantigens, with the magnitude and hierarchy of epitope‐specific responses varying with the private specificities of the host memory T cell repertoire, as shown by adoptive transfer studies. Last, we show that purified LCMV‐specific CD8 T cells rejected skin allografts in SCID mice. These findings therefore implicate a potential role for heterologous immunity in virus‐induced allograft rejection.     

Immunological characterization of de novo and recall alloantibody suppression by CTLA4Ig in a mouse model of allosensitization

It is well known that CTLA4Ig inhibits allogenic T-cell activation in transplantation. The immunological features and mechanisms associated with alloantibody suppression by CTLA4Ig, however, are poorly understood. Here, we used a mouse model of allosensitization to evaluate the efficacy of CTLA4Ig (abatacept) in suppression of donor-specific antibody (DSA) during de novo and recall alloantibody responses. We found that abatacept inhibited de novo DSA IgM and IgG responses to HLA-A2 expressing skin grafts. Abatacept administered during primary T cell priming also reduced recall IgG responses induced by re-immunization. Suppression of de novo DSA responses by abatacept is associated with a reduction in splenic expression of the germinal center activation marker GL7 and a reduction of CD4⁺ PD1⁺ CXCR5⁺ follicular T helper (Tfh) subset in splenic lymphocytes detected by flow cytometry. The efficacy of abatacept on recall DSA suppression is moderate. In vitro experiments demonstrated that abatacept inhibited DSA IgG secretion by CD138⁺ plasma cells isolated from allograft recipients. Additional experiments using an IgG1 secreting mouse hybridoma cell line showed that abatacept binds to CD80 expressed on these cells with subsequent inhibition of cell proliferation and reduction in IgG ELISpot formation. In conclusion, CTLA4Ig is a potent suppressor of de novo DSA responses and also affects recall responses. The data suggests modification of recall DSA responses is due to a direct suppressive effect on plasma cells.     

Salt Accelerates Allograft Rejection through Serum- and Glucocorticoid-Regulated Kinase-1–Dependent Inhibition of Regulatory T Cells

A high-salt diet (HSD) in humans is linked to a number of complications, including hypertension and cardiovascular events. Whether a HSD affects the immune response in transplantation is unknown. Using a murine transplantation model, we investigated the effect of NaCl on the alloimmune response in vitro and in vivo. Incremental NaCl concentrations in vitro augmented T cell proliferation in the settings of both polyclonal and allospecific stimulation. Feeding a HSD to C57BL/6 wild-type recipients of bm12 allografts led to accelerated cardiac allograft rejection, despite similar mean BP and serum sodium levels in HSD and normal salt diet (NSD) groups. The accelerated rejection was associated with a reduction in the proportion of CD4⁺Foxp3⁺ regulatory T cells (Tregs) and a significant decrease in Treg proliferation, leading to an increased ratio of antigen-experienced CD4⁺ T cells to Tregs in mice recipients of a HSD compared with mice recipients of a NSD. Because serum- and glucocorticoid-regulated kinase-1 (SGK1) has been proposed as a potential target of salt in immune cells, we fed a HSD to CD4^CreSGK1^fl/fl B6-transplanted recipients and observed abrogation of the deleterious effect of a HSD in the absence of SGK1 on CD4⁺ cells. In summary, we show that NaCl negatively affects the regulatory balance of T cells in transplantation and precipitates rejection in an SGK1-dependent manner.     

Contrasting effects of B cell depletion on CD4+ and CD8+ memory T cell responses generated after transplantation

Alloreactive memory T cells play a key role in transplantation by accelerating allograft rejection and preventing tolerance induction. Some studies using µMT mice, which are constitutionally devoid of B cells, showed that B cells were required for the generation of memory T cells after allotransplantation. However, whether B cell depletion in normal adult mice has the same effect on memory responses by CD4⁺ and CD8⁺ T cells activated after transplantation has not been thoroughly investigated. In this study, we tested the effect of anti‐CD20 antibody‐mediated B cell depletion on CD4⁺ and CD8⁺ memory T cell alloresponses after skin transplantation in wild‐type mice. We found that B cell depletion prevented the development of memory alloresponses by CD4⁺ T cells but enhanced that of CD8⁺ memory T cells. Next, we tested the influence of B cell depletion on hematopoietic chimerism. In OT‐II CD4⁺ anti‐OVA TCR transgenic mice sensitized to ovalbumin antigen, B cell depletion also impaired allospecific memory T cell responses and thereby enhanced donor hematopoietic chimerism and T cell deletion after bone marrow transplantation. This study underscores the complexity of the relationships between B and T cells in the generation and reactivation of different memory T cell subsets after transplantation.     

Differential effects of Belatacept on virus-specific memory versus de novo allo-specific T cell responses of kidney transplant recipients and healthy donors

Belatacept, Nulojix®, inhibits the interaction of CD28 on naïve T cells with B7.1/B7.2 (CD80/86) on antigen presenting cells, leading to T cell hyporesponsiveness and anergy and is approved as immunosuppressive drug in kidney transplantation. Due to its specificity for B7.1/2 molecules, side effects are reduced compared to other immunosuppressive drugs like calcineurin- and mTOR-inhibitors. Kidney transplant recipients under Belatacept-based immunosuppression presented with superior renal function and similar graft survival seven years after transplantation compared to cyclosporine treatment. However, de novo Belatacept-based immunosuppression was associated with increased risk of early rejections and viral (EBV) infections in clinical trials, especially in EBV-naïve patients. Since there is no vaccination against EBV infection available, EBV-derived virus like particles (EBV-VLPs) are currently developed as vaccine strategy. Here, we investigated the immunosuppressive effects of Belatacept compared to calcineurin- and mTOR inhibitors on allo- versus virus-specific T cells and the potency of EBV-VLPs to induce virus-specific T cell responses in vitro. Using PBMC of kidney recipients and healthy donors, we could demonstrate selective inhibition of allo-specific de novo T cell responses but not virus-specific memory T cell responses by Belatacept, as measured by IFN-γ production. In contrast, calcineurin inhibitors suppressed IFN-γ production of virus-specific memory CD8⁺ T cells completely. These results experimentally confirm the concept that Belatacept blocks CD28-mediated costimulation in newly primed naïve T cells but does not interfere with memory T cell responses being already independent from CD28-mediated costimulation. Additionally, we could show that EBV-VLPs induce a significant though weak IFN-γ-mediated T cell response in vitro in both kidney recipients and healthy donors. In summary, we demonstrated that immunosuppression of kidney recipients by Belatacept may primarily suppress de novo allo-specific T cell responses sparing virus-specific memory T cells. Moreover, EBV-VLPs could represent a novel strategy for vaccination of immunocompromised renal transplant recipients to prevent EBV reactivation especially under Belatacept-based immunosuppression.     

Soluble CD83 inhibits acute rejection by up regulating TGF-β and IDO secretion in rat liver transplantation

BackgroundAllogeneic transplantation immune tolerance is currently a hot research issue and soluble CD83(sCD83) is a novel immunomodulator with great potential in inducing transplantation tolerance.ObjectiveTo investigate the mechanism of the immune tolerance effect of sCD83 on rat liver transplantation.MethodA rat liver transplantation model was established to study the effects of sCD83 on the expression levels of IL-2, IL-10, and TGF-β in peripheral blood and the mRNA expressions of foxp3, TGF-β, and Indoleamine 2,3-dioxygenase (IDO) in liver. The expression changes of costimulatory molecules CD80, CD86, and MHC-II on the surface of DC cells and the expressions of IDO ⁺ DC cell, TGF-β ⁺ CD4 ⁺ T cell, and CD4 ⁺ CD25 ⁺ Foxp3 ⁺ T cell were analyzed and compared.ResultssCD83 alleviated the rejection activity index (RAI) of rat liver transplantation in the early stage, increased the expressions of TGF-β, IL-10 in peripheral blood and the mRNAs of IDO, TGF-β and foxp3 in the transplanted liver, and down-regulated the expressions of MHC-II, CD86, and CD80 in DC cells, resulting in significant increased numbers of tolerogenic TGF-β ⁺ CD4 ⁺ T cells, Treg cells, and IDO ⁺ DC cells with low expression.ConclusionsCD83 inhibited acute rejection after liver transplantation in an allogeneic rat, and the mechanism was associated with the effect that sCD83 increased the expression of TGF-β, activated IDO immunosuppressive pathway, and increased tolerogenic DC cells and Treg cells.     

Anti‐TCRβ mAb Induces Long‐Term Allograft Survival by Reducing Antigen‐Reactive T Cells and Sparing Regulatory T Cells

TCR specific antibodies may modulate the TCR engagement with antigen–MHC complexes, and in turn regulate in vivo T cell responses to alloantigens. Herein, we found that in vivo administration of mAbs specific for mouse TCRβ (H57–597), TCRα or CD3 promptly reduced the number of CD4⁺ and CD8⁺ T cells in normal mice, but H57–597 mAb most potently increased the frequency of CD4⁺Foxp3⁺ Treg cells. When mice were injected with staphylococcal enterotoxin B (SEB) superantigen and H57–597 mAb, the expansion of SEB‐reactive Vβ8⁺ T cells was completely abrogated while SEB‐nonreactive Vβ2⁺ T cells remained unaffected. More importantly, transient H57–597 mAb treatment exerted long‐lasting effect in preventing T cell responses to alloantigens, and produced long‐term cardiac allograft survival (>100 days) in 10 out of 11 recipients. While Treg cells were involved in maintaining donor‐specific long‐term graft survival, T cell homeostasis recovered over time and immunity was retained against third party allografts. Moreover, transient H57–597 mAb treatment significantly prolonged survival of skin allografts in naïve recipients as well as heart allografts in skin‐sensitized recipients. Thus, transient modulation of the TCRβ chain by H57–597 mAb exhibits potent, long‐lasting therapeutic effects to control alloimmune responses.     

Liver Transplantation in a Patient With CD40 Ligand Deficiency and Hyper‐IgM Syndrome: Clinical and Immunological Assessments

Monoclonal antibodies that disrupt CD40–CD40 ligand (CD40L) interactions are likely to have use in human transplantation. However, the extent of the immunosuppressive effects of CD40–CD40L blockade in humans is unknown. Hyper‐IgM syndrome (HIGM) is a rare primary immunodeficiency syndrome characterized by defects in the CD40–CD40L pathway, severe immune deficiency (IgG), and high or normal IgM levels. However, the effects of CD40L deficiency on T‐ and natural killer (NK)‐cell function is not established. Here, we present a patient with HIGM syndrome who underwent liver transplantation for hepatitis C virus infection. Posttransplantation, NK‐cell antibody‐dependent cytokine release (γ‐interferon) to alloantigens and T cell responses to viral antigens and mitogens were assessed and showed normal CD4⁺, CD8⁺, and NK‐cell responses. We also examined antibody‐dependent cellular cytotoxicity against a CD40⁺ and HLA‐expressing cell line. These experiments confirmed that the patient's NK cells were equivalent to those of normal subjects in mediating antibody‐dependent cellular cytotoxicity despite the absence of CD40–CD40L interactions. Mitogenic stimulation of the patient's peripheral blood mononuclear cells showed no expression of CD40L on T and NK cells compared with increased expression in normal subjects. Taken together, these data suggest that absence of CD40L expression is responsible for aberrant B cell immunity but had little impact on NK‐ and T cell immune responses in vitro.     

Regulatory T cells in immune‐mediated renal disease

Regulatory T cells (Tregs) are CD4+ T cells that can suppress immune responses by effector T cells, B cells and innate immune cells. This review discusses the role that Tregs play in murine models of immune‐mediated renal diseases and acute kidney injury and in human autoimmune kidney disease (such as systemic lupus erythematosus, anti‐glomerular basement membrane disease, anti‐neutrophil cytoplasmic antibody‐associated vasculitis). Current research suggests that Tregs may be reduced in number and/or have impaired regulatory function in these diseases. Tregs possess several mechanisms by which they can limit renal and systemic inflammatory immune responses. Potential therapeutic applications involving Tregs include in vivo induction of Tregs or inducing Tregs from naïve CD4+ T cells or expanding natural Tregs ex vivo, to use as a cellular therapy. At present, the optimal method of generating a phenotypically stable pool of Tregs with long‐lasting suppressive effects is not established, but human studies in renal transplantation are underway exploring the therapeutic potential of Tregs as a cellular therapy, and if successful may have a role as a novel therapy in immune‐mediated renal diseases.     

Triazolopyrimidine derivative NK026680 and donor-specific transfusion induces CD4+CD25+Foxp3+ T cells and ameliorates allograft rejection in an antigen-specific manner

We have previously demonstrated the unique properties of a new triazolopyrimidine derivative, NK026680, which exerts immunosuppressive effects in rat heart transplant model and confers tolerogeneic properties on ex vivo-conditioned dendritic cells in mice. We herein demonstrate that NK026680 promotes the expansion of regulatory T cells (Tregs) with potent immunoregulatory effects when used in combination with donor-specific transfusion (DST).BALB/c (H-2^d) heart graft were transplanted into C57BL/6 (H-2^b) mice following intravenous injection of donor splenocytes (DST) and oral administration of NK026680. The NK026680 plus DST treatment markedly prolonged the survival time of the donor-graft, but not that of the 3rd party-graft (C3H; H-2^k). Treg cells in the recipient spleen on day 0 expanded when stimulated with donor-antigens in vivo and in vitro. After heart transplantation, Treg cells accumulated into the graft and increased in the spleen. NK026680 plus DST also decreased activated CD8⁺ T cells in the spleen and inhibited infiltration of CD8⁺ T cells into the graft. Depletion of CD25⁺ cells inhibited the graft prolonging effect of the NK026680 plus DST treatment.NK026680 administration together with DST induces potent immunoregulatory effects in an antigen-specific manner, likely due to the in vivo generation of donor-specific Tregs.     

Paradoxical Aspects of Rapamycin Immunobiology in Transplantation

Rapamycin has long been considered an immunosuppressive agent due to its antiproliferative effects on immune cells, and is currently used as a component of antirejection regimens in transplantation. Despite the large number of mechanistic and clinical studies investigating the impact of rapamycin on cell‐mediated immunity, several paradoxes concerning rapamycin immunobiology remain. In particular, emerging evidence suggests that under certain circumstances rapamycin can exert immunostimulatory effects, boosting T cell responses in the face of pathogen infections and vaccines. Here, we review recent findings concerning the contradictory outcomes of rapamycin induced mTOR inhibition on CD4⁺ and CD8⁺ T cell responses in transplantation and protective immunity. These studies suggest that the conditions under which T cells are stimulated can profoundly modify the impact of rapamycin on antigen‐specific T cell responses. Thus, further investigation into the cellular and molecular pathways underlying the dichotomous effects of rapamycin in transplantation is required to harness the full potential of this immunomodulatory agent to promote graft survival and maximize protective immunity.     

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.     

Adoptive Transfer of Tracer‐Alloreactive CD4+ T Cell Receptor Transgenic T Cells Alters the Endogenous Immune Response to an Allograft

T cell receptor transgenic (TCR‐Tg) T cells are often used as tracer populations of antigen‐specific responses to extrapolate findings to endogenous T cells. The extent to which TCR‐Tg T cells behave purely as tracer cells or modify the endogenous immune response is not clear. To test the impact of TCR‐Tg T cell transfer on endogenous alloimmunity, recipient mice were seeded with CD4⁺ or CD8⁺ TCR‐Tg or polyclonal T cells at the time of cardiac allograft transplantation. Only CD4⁺ TCR‐Tg T cells accelerated rejection and, unexpectedly, led to a dose‐dependent decrease in both transferred and endogenous T cells infiltrating the graft. In contrast, recipients of CD4⁺ TCR‐Tg T cells exhibited enhanced endogenous donor‐specific CD8⁺ T cell activation in the spleen and accelerated alloantibody production. Introduction of CD4⁺ TCR‐Tg T cells also perturbed the intragraft accumulation of innate cell populations. Transferred CD4⁺ TCR‐Tg T cells alter many aspects of endogenous alloimmunity, suggesting that caution should be used when interpreting experiments using these adoptively transferred cells because the overall nature of allograft rejection may be altered. These results also may have implications for adoptive CD4⁺ T cell immunotherapy in tumor and infectious clinical settings because cell infusion may have additional effects on natural immune responses.     

γδT Cells Are Involved in Liver Transplant Tolerance

The role of nonconventional T cells in innate and adaptive immunity is just emerging; γδT cells play important roles in anti-tumor and anti-infectious diseases. The involvement of γδT cells in immunologic responses to hematopoietic cell transplantation remains controversial; divergent results have been reported depending on the murine strains and model systems. Whether γδT cells are involved in solid organ transplantation is understudied. We have characterized the γδT cells in mouse livers and spleens to evaluate their contributions to liver transplant tolerance posttransplantation using a murine allogeneic liver transplant model which induces spontaneous T regulatory cell (Treg)-dependent tolerance. Our studies revealed that γδT cells comprised about 20% of the population of liver nonparenchymal cells (NPCs). In naïve C3H mice they were CD4, CD8, and NK1.1 negative. The percentage of γδT cells decreased in spontaneously tolerated liver grafts posttransplantation from 20% in naïve C3H livers to <10% in allografts throughout the time course. In contrast, they increased in liver grafts with rejection induced by anti-CTLA4 plus anti-CD25 mAb administration. CD4 and CD8 expression on γδT cells dramatically increased in the tolerated but not rejected livers posttransplantation to >20% of CD4⁺ and 30% of CD8⁺. Our results suggested that γδT cells are involved in allogeneic immune responses. Whether γδT cells function as the causal or the effector cells in allograft tolerance rejection warrants further investigation.