Kaempferol Promotes Transplant Tolerance by Sustaining CD4+FoxP3+ Regulatory T Cells in the Presence of Calcineurin Inhibitor

Calcineurin inhibitor cyclosporine is widely used as an immunosuppressant in clinic. However, mounting evidence has shown that cyclosporine hinders tolerance induction by dampening Tregs. Therefore, it is of paramount importance to overcome this pitfall. Kaempferol was reported to inhibit DC function. Here, we found that kaempferol delayed islet allograft rejection. Combination of kaempferol and low‐dose, but not high‐dose, of cyclosporine induced allograft tolerance in majority of recipient mice. Although kaempferol plus either dose of cyclosporine largely abrogated proliferation of graft‐infiltrating T cells and their CTL activity, both proliferation and CTL activity in mice treated with kaempferol plus low‐dose, but not high‐dose, cyclosporine reemerged rapidly upon treatment withdrawal. Kaempferol increased CD4+FoxP3+ Tregs both in transplanted mice and in vitro, likely by suppressing DC maturation and their IL‐6 expression. Reduction in Tregs by low dose of cyclosporine was reversed by kaempferol. Kaempferol‐induced Tregs exhibited both allospecific and non‐allospecific suppression. Administering IL‐6 abrogated allograft tolerance induced by kaempferol and cyclosporine via diminishing CD4+FoxP3+ Tregs. Thus, for the first time, we demonstrated that kaempferol promotes transplant tolerance in the presence of low dose of cyclosporine, which allows for sufficient Treg generation while minimizing side effects, resulting in much‐needed synergy between kaempferol and cyclosporine.     

CD4+CD28null T cells are not alloreactive unless stimulated by interleukin‐15

Proinflammatory, cytotoxic CD4⁺CD28^null T cells can be substantially expanded in patients with end‐stage renal disease. These cells have been associated with the risk for rejection, but their alloreactive potential is unknown. CD4⁺CD28^null T cells were stimulated with HLA‐mismatched antigen presenting cells in the absence/presence of exogenous cytokines. Alloreactive potential was evaluated based on proliferation, degranulation, cytotoxicity, and cytokine production. Further, their suppressive capacity was assessed by measuring inhibition of proliferating alloreactive CD28⁺ T cells. CD4⁺CD28^null T cells contained alloreactive (CD137⁺) T cells but did not proliferate in response to allogeneic stimulation, unless interleukin (IL)‐15 was added. However, they could proliferate on stimulation with cytomegalovirus antigen without exogenous cytokines. IL‐15 increased the frequency of proliferating alloreactive CD4⁺CD28^null T cells to 30.5% without inducing CD28 expression (P < .05). After allogeneic stimulation together with IL‐15 and IL‐21, frequency of degranulating CD107a⁺CD4⁺CD28^null T cells increased significantly from 0.6% to 5.8% (P < .001). Granzyme B and perforin positivity remained similar, but production of interferon‐γ and tumor necrosis factor‐α increased by the combination of IL‐15 and IL‐21 (P < .001 and P < .05, respectively). Finally, CD4⁺CD28^null T cells did not show significant suppression. Thus, CD4⁺CD28^null T cells represent a population with absent alloreactivity unless IL‐15 is present.     

Neuro‐immune interactions in inflammation and host defense: Implications for transplantation

Sensory and autonomic neurons of the peripheral nervous system (PNS) play a critical role in regulating the immune system during tissue inflammation and host defense. Recent studies have identified the molecular mechanisms underlying the bidirectional communication between the nervous system and the immune system. Here, we highlight the studies that demonstrate the importance of the neuro‐immune interactions in health and disease. Nociceptor sensory neurons detect immune mediators to produce pain, and release neuropeptides that act on the immune system to regulate inflammation. In parallel, neural reflex circuits including the vagus nerve‐based inflammatory reflex are physiological regulators of inflammatory responses and cytokine production. In transplantation, neuro‐immune communication could significantly impact the processes of host‐pathogen defense, organ rejection, and wound healing. Emerging approaches to target the PNS such as bioelectronics could be useful in improving the outcome of transplantation. Therefore, understanding how the nervous system shapes the immune response could have important therapeutic ramifications for transplantation medicine     

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

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

DEPTOR modulates activation responses in CD4+ T cells and enhances immunoregulation following transplantation

DEPTOR is an evolutionarily conserved cell‐intrinsic binding partner of mTOR that functions as a negative regulator of signaling responses. In this study, we show that DEPTOR is expressed within CD4⁺ T cells, and we observed that its relative level of expression modulates differentiation as well as glucose utilization within CD4⁺ T effectors in vitro. Using knock‐in mice, we also find that induced expression of DEPTOR within CD4⁺ T regulatory cells stabilizes Foxp3 expression, shifts metabolism toward oxidative phosphorylation, and increases survival and suppressive function. In vivo, fully MHC mismatched cardiac allograft survival is significantly prolonged in knock‐in recipients and sustained recipient expression of DEPTOR in combination with costimulatory blockade induces long‐term graft survival. Furthermore, we show that the induced expression of DEPTOR in CD4⁺ T effectors fails to inhibit acute allograft rejection. Rather, prolonged survival is dominantly mediated via induced expression and function of DEPTOR within recipient CD4⁺ T regulatory cells. These collective findings identify DEPTOR as a novel protein that functions in CD4⁺ T cells to augment immunoregulation in vitro and in vivo.     

Belatacept‐Resistant Rejection Is Associated With CD28+ Memory CD8 T Cells

Recently, newer therapies have been designed to more specifically target rejection in an effort to improve efficacy and limit unwanted toxicity. Belatacept, a CD28‐CD80/86 specific reagent, is associated with superior patient survival and graft function compared with traditional therapy, but its adoption as a mainstay immunosuppressive therapy has been tempered by increased rejection rates. It is essential that the underlying mechanisms associated with this rejection be elucidated before belatacept is more widely used. To that end, we designed a study in a nonhuman primate kidney transplant model where animals were treated with either a belatacept‐ or a tacrolimus‐based immunosuppressive regimen. Interestingly, we found that elevated pretransplant frequencies of CD28⁺CD8⁺T_EMRA cells are associated with rejection on belatacept but not tacrolimus treatment. Further analysis showed that the CD28⁺CD8⁺T_EMRA cells rapidly lose CD28 expression after transplant in those animals that go on to reject with the allograft infiltrate being predominantly CD28^?. These data suggest that CD28⁺ memory T cells may be resistant to belatacept, capable of further differentiation including loss of CD28 expression while maintaining effector function. The unique signaling requirements of CD28⁺ memory T cells provide opportunities for the development of targeted therapies, which may synergize with belatacept to prevent costimulation‐independent rejection.     

The Therapeutic Potential of T Cell Metabolism

Transplant rejection mediated by the adaptive immune system remains a major barrier to achieving long‐term tolerance and graft survival. Emerging evidence indicates that lymphocytes rapidly shift their metabolic programs in response to activation, co‐stimulatory, and cytokine signals to support required effector cell differentiation and function. These observations have led to the hypothesis that manipulating the metabolic programs of immune cells could serve as a powerful therapeutic strategy for attenuating deleterious immune responses and facilitating durable tolerance in the setting of allogeneic solid organ or bone marrow transplant. In this mini‐review, we introduce the fundamentals of metabolism, highlight the current understanding of how adaptive immune cells utilize their metabolic programs, and discuss the potential for targeting metabolism as a therapeutic approach to induce tolerance in the transplant setting.     

Anti‐CD40 antibody 2C10 binds to a conformational epitope at the CD40‐CD154 interface that is conserved among primate species

The antagonistic anti‐CD40 antibody, 2C10, and its recombinant primate derivative, 2C10R4, are potent immunosuppressive antibodies whose utility in allo‐ and xenotransplantation have been demonstrated in nonhuman primate studies. In this study, we defined the 2C10 binding epitope and found only slight differences in affinity of 2C10 for CD40 derived from four primate species. Staining of truncation mutants mapped the 2C10 binding epitope to the N‐terminal portion of CD40. Alanine scanning mutagenesis of the first 60 residues in the CD40 ectodomain highlighted key amino acids important for binding of 2C10 and for binding of the noncross‐blocking anti‐CD40 antibodies 3A8 and 5D12. All four 2C10‐binding residues defined by mutagenesis clustered near the membrane‐distal tip of CD40 and partially overlap the CD154 binding surface. In contrast, the overlapping 3A8 and 5D12 epitopes map to an opposing surface away from the CD154 binding domain. This biochemical characterization of 2C10 confirms the validity of nonhuman primate studies in the translation of this therapeutic antibody and provides insight its mechanism of action.     

Pathogen Stimulation History Impacts Donor‐Specific CD8+ T Cell Susceptibility to Costimulation/Integrin Blockade–Based Therapy

Recent studies have shown that the quantity of donor‐reactive memory T cells is an important factor in determining the relative heterologous immunity barrier posed during transplantation. Here, we hypothesized that the quality of T cell memory also potently influences the response to costimulation blockade‐based immunosuppression. Using a murine skin graft model of CD8⁺ memory T cell–mediated costimulation blockade resistance, we elicited donor‐reactive memory T cells using three distinct types of pathogen infections. Strikingly, we observed differential efficacy of a costimulation and integrin blockade regimen based on the type of pathogen used to elicit the donor‐reactive memory T cell response. Intriguingly, the most immunosuppression‐sensitive memory T cell populations were composed primarily of central memory cells that possessed greater recall potential, exhibited a less differentiated phenotype, and contained more multi‐cytokine producers. These data, therefore, demonstrate that the memory T cell barrier is dependent on the specific type of pathogen infection via which the donor‐reactive memory T cells are elicited, and suggest that the immune stimulation history of a given transplant patient may profoundly influence the relative barrier posed by heterologous immunity during transplantation.     

Cytomegalovirus‐Responsive CD8+ T Cells Expand After Solid Organ Transplantation in the Absence of CMV Disease

Cytomegalovirus (CMV) is a major cause of morbidity and mortality in solid organ transplant recipients. Approximately 60% of adults are CMV seropositive, indicating previous exposure. Following resolution of the primary infection, CMV remains in a latent state. Reactivation is controlled by memory T cells in healthy individuals; transplant recipients have reduced memory T cell function due to chronic immunosuppressive therapies. In this study, CD8⁺ T cell responses to CMV polypeptides immediate‐early‐1 and pp65 were analyzed in 16 CMV‐seropositive kidney and heart transplant recipients longitudinally pretransplantation and posttransplantation. All patients received standard of care maintenance immunosuppression, antiviral prophylaxis, and CMV viral load monitoring, with approximately half receiving T cell–depleting induction therapy. The frequency of CMV‐responsive CD8⁺ T cells, defined by the production of effector molecules in response to CMV peptides, increased during the course of 1 year posttransplantation. The increase commenced after the completion of antiviral prophylaxis, and these T cells tended to be terminally differentiated effector cells. Based on this small cohort, these data suggest that even in the absence of disease, antigenic exposure may continually shape the CMV‐responsive T cell population posttransplantation.     

Inflammation Causes Resistance to Anti‐CD20–Mediated B Cell Depletion

B cells play a central role in antibody‐mediated rejection and certain autoimmune diseases. However, B cell–targeted therapy such as anti‐CD20 B cell–depleting antibody (aCD20) has yielded mixed results in improving outcomes. In this study, we investigated whether an accelerated B cell reconstitution leading to aCD20 depletion resistance could account for these discrepancies. Using a transplantation model, we found that antigen‐independent inflammation, likely through toll‐like receptor (TLR) signaling, was sufficient to mitigate B cell depletion. Secondary lymphoid organs had a quicker recovery of B cells when compared to peripheral blood. Inflammation altered the pharmacokinetics (PK) and pharmacodynamics (PD) of aCD20 therapy by shortening drug half‐life and accelerating the reconstitution of the peripheral B cell pool by bone marrow–derived B cell precursors. IVIG (intravenous immunoglobulin) coadministration also shortened aCD20 drug half‐life and led to accelerated B cell recovery. Repeated aCD20 dosing restored B cell depletion and delayed allograft rejection, especially B cell–dependent, antibody‐independent allograft rejection. These data demonstrate the importance of further clinical studies of the PK/PD of monoclonal antibody treatment in inflammatory conditions. The data also highlight the disconnect between B cell depletion on peripheral blood compared to secondary lymphoid organs, the deleterious effect of IVIG when given with aCD20 and the relevance of redosing of aCD20 for effective B cell depletion in alloimmunity.     

Selective CD28 Blockade Results in Superior Inhibition of Donor‐Specific T Follicular Helper Cell and Antibody Responses Relative to CTLA4‐Ig

Donor‐specific antibodies (DSAs) are a barrier to improved long‐term outcomes after kidney transplantation. Costimulation blockade with CTLA4‐Ig has shown promise as a potential therapeutic strategy to control DSAs. T follicular helper (Tfh) cells, a subset of CD4⁺ T cells required for optimal antibody production, are reliant on the CD28 costimulatory pathway. We have previously shown that selective CD28 blockade leads to superior allograft survival through improved control of CD8⁺ T cells relative to CTLA4‐Ig, but the impact of CD28‐specific blockade on CD4⁺ Tfh cells is unknown. Thus, we identified and characterized donor‐reactive Tfh cells in a murine skin transplant model and then used this model to evaluate the impact of selective CD28 blockade with an anti‐CD28 domain antibody (dAb) on the donor‐specific Tfh cell–mediated immune response. We observed that the anti‐CD28 dAb led to superior inhibition of donor‐reactive CXCR5⁺PD‐1^high Tfh cells, CD95⁺GL7⁺ germinal center B cells and DSA formation compared with CTLA4‐Ig. Interestingly, donor‐reactive Tfh cells differentially upregulated CTLA4 expression, suggesting an important role for CTLA4 in mediating the superior inhibition observed with the anti‐CD28 dAb. Therefore, selective CD28 blockade as a novel approach to control Tfh cell responses and prevent DSA after kidney transplantation warrants further study.     

Prevention of Allograft Rejection by Use of Regulatory T Cells With an MHC‐Specific Chimeric Antigen Receptor

CD4⁺CD25^highFOXP3⁺ regulatory T cells (Tregs) are involved in graft‐specific tolerance after solid organ transplantation. However, adoptive transfer of polyspecific Tregs alone is insufficient to prevent graft rejection even in rodent models, indicating that graft‐specific Tregs are required. We developed a highly specific chimeric antigen receptor that recognizes the HLA molecule A*02 (referred to as A2‐CAR). Transduction into natural regulatory T cells (nTregs) changes the specificity of the nTregs without alteration of their regulatory phenotype and epigenetic stability. Activation of nTregs via the A2‐CAR induced proliferation and enhanced the suppressor function of modified nTregs. Compared with nTregs, A2‐CAR Tregs exhibited superior control of strong allospecific immune responses in vitro and in humanized mouse models. A2‐CAR Tregs completely prevented rejection of allogeneic target cells and tissues in immune reconstituted humanized mice in the absence of any immunosuppression. Therefore, these modified cells have great potential for incorporation into clinical trials of Treg‐supported weaning after allogeneic transplantation.     

In Vivo Mobilization and Functional Characterization of Nonhuman Primate Monocytic Myeloid‐Derived Suppressor Cells

Increasing evidence from small animal models shows that myeloid‐derived suppressor cells (MDSCs) can play a crucial role in inhibiting allograft rejection and promoting transplant tolerance. We identified CD3^?CD20^?HLA‐DR^?CD14⁺CD33⁺CD11b⁺ cells in peripheral blood of healthy rhesus macaques. These putative monocytic MDSCs constituted 2.1% ± 1.7% of lin^?HLA‐DR^? peripheral blood mononuclear cells. Administration of granulocyte‐macrophage colony‐stimulating factor (CSF) and granulocyte CSF increased their incidence to 5.3% ± 3.4%. The total number of MDSCs that could be flow sorted from a single whole rhesus leukapheresis product was 38 ± 13 × 10⁶ (n = 10 monkeys). Freshly isolated or cryopreserved MDSCs from mobilized monkeys incorporated in cultures of anti‐CD3– and anti‐CD28–stimulated autologous T cells markedly suppressed CD4⁺ and CD8⁺ T cell proliferation and cytokine secretion (interferon γ, IL‐17A). Moreover, these MDSCs enhanced CD4⁺CD25^hiFoxp3⁺ regulatory T cell (Treg) expansion while inhibiting proliferation of activated memory T cells and increasing Treg relative to effector and terminally differentiated memory T cells. Inhibition of arginase‐1, but not inducible nitric oxide synthase activity, partially reversed the inhibitory effect of the MDSCs on CD8⁺ T cell proliferation. Consequently, functional MDSCs can be isolated from nonhuman primates for prospective use as therapeutic cellular vaccines in transplantation.

     

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.