Immunotoxin Against a Donor MHC Class II Molecule Induces Indefinite Survival of Murine Kidney Allografts

Rejection of donor organs depends on the trafficking of donor passenger leukocytes to the secondary lymphoid organs of the recipient to elicit an immune response via the direct antigen presentation pathway. Therefore, the depletion of passenger leukocytes may be clinically applicable as a strategy to improve graft survival. Because major histocompatibility complex (MHC) class II⁺ cells are most efficient at inducing immune responses, selective depletion of this population from donor grafts may dampen the alloimmune response and prolong graft survival. In a fully MHC mismatched mouse kidney allograft model, we describe the synthesis of an immunotoxin, consisting of the F(ab′)₂ fragment of a monoclonal antibody against the donor MHC class II molecule I‐A^k conjugated with the plant‐derived ribosomal inactivating protein gelonin. This anti–I‐A^k gelonin immunotoxin depletes I‐A^k expressing cells specifically in vitro and in vivo. When given to recipients of kidney allografts, it resulted in indefinite graft survival with normal graft function, presence of Foxp3⁺ cells within donor grafts, diminished donor‐specific antibody formation, and delayed rejection of subsequent donor‐type skin grafts. Strategies aimed at the donor arm of the immune system using agents such as immunotoxins may be a useful adjuvant to existing recipient‐orientated immunosuppression.     

Correlations between leptin, body composition, bone mineral density, and bone metabolism in kidney transplant recipients

INTRODUCTION: In kidney transplant recipients leptin levels are often elevated and bone mineral density (BMD) decreased. However, to date there are no about correlations between leptin and BMD in this population. It has been suggested that leptin is a predictor of BMD in postmenopausal women. Moreover, leptin acts as a marker of fat stores. We examined the relationships between leptinemia, some markers of nutritional status, BMD, and bone metabolism in kidney transplant recipients. We also assessed whether leptin was a significant and independent predictor of BMD in this population. METHODS: BMD and fat content (global, percentage, trunk) were measured using dual-energy X-ray absorptiometry in 27 kidney allograft recipients. Markers of bone turnover and leptin were studied using commercially available kits. RESULTS: Leptin correlated with the percentage of body fat, trunk fat, lean body mass, serum creatinine, and urea. Insulin growth factor binding protein 1 was negatively related to waist-hip ratio and global and trunk fat, whereas BMD of the lumbar spine was correlated with the daily dose of prednisone, azathioprine, cyclosporine trough levels, serum calcium, as well as osteoprotegerin level. CONCLUSIONS: Leptin levels are associated with graft function and body fat in kidney allograft recipients. Leptin is not related to nutritional status, BMD, or bone metabolism in kidney allograft recipients, but is associated with the current dosage of immunosuppressants and the serum calcium.     

Interleukin‐33 prolongs allograft survival during chronic cardiac rejection

Interleukin‐33 (IL‐33) stimulates the generation of cells and cytokines characteristic of a Th2 immune response. We examined the effects of IL‐33 on allografted heart tissue in a chronic cardiac rejection model, including analysis of the peripheral myeloid and lymphoid compartments. B6.C‐H2bm12/KhEg hearts were transplanted into MHC class II‐mismatched C57Bl/6J mice; IL‐33 was administered daily. Cells from allografts and spleens were isolated for flow cytometry and cultured for cytokine production; some tissues were used for immunohistochemistry. Animals treated with IL‐33 showed significantly longer allograft survival, which was associated with a distinct cytokine profile produced by graft‐infiltrating cells. Proinflammatory IL‐17A production was decreased with IL‐33 treatment, while increased levels of IL‐5, IL‐10, and IL‐13 were observed. After IL‐33 therapy, flow cytometry showed a direct induction of CD4⁺ Foxp3⁺ Treg, whereas the number of B220⁺ CD19⁺ B cells, and circulating, as well as allograft deposited, alloantibodies was reduced. Following IL‐33 treatment, a significant decrease in graft‐infiltrating CD11b^highGr1^high granulocytes coincided with a significant increase in CD11b^highGr1^intermediate myeloid‐derived suppressor cells (MDSC). In conclusion, IL‐33 treatment in the setting of chronic rejection promotes the development of a Th2‐type immune response that favors MDSC and Treg expansion, reduces antibody‐mediated rejection (AMR), and ultimately, prolongs allograft survival.     

CD11b is a novel alternate receptor for CD154 during alloimmunity

Antagonism of the CD154/CD40 pathway is a highly effective means of inducing long‐term graft survival in preclinical models. Using a fully allogeneic murine transplant model, we found that CD154 blockade was more effective in prolonging graft survival than was CD40 blockade, raising the possibility that CD154 binds a second receptor. To test this, we queried the impact of CD154 antagonism in the absence of CD40. Data indicated that anti‐CD154 functioned to reduce graft‐infiltrating CD8⁺ T cells in both WT and CD40^?/? hosts. Because it has recently been reported that CD154 can ligate CD11b, we addressed the impact of blocking CD154‐CD11b interactions during transplantation. We utilized a specific peptide antagonist that prevents CD154 binding of CD11b but has no effect on CD154‐CD40 interactions. CD154:CD11b antagonism significantly increased the efficacy of anti‐CD40 in prolonging allograft survival as compared to anti‐CD40 plus control peptide. Mechanistically, CD154:CD11b antagonism functioned to reduce the frequency of graft‐infiltrating CD8⁺ T cells and innate immune cells. These data therefore demonstrate that blocking CD154 interactions with both CD40 and CD11b is required for optimal inhibition of alloimmunity and provide an explanation for why CD40 blockers may be less efficacious than anti‐CD154 reagents for the inhibition of allograft rejection.     

Circulating mitochondria in organ donors promote allograft rejection

The innate immune system is a critical regulator of the adaptive immune responses that lead to allograft rejection. It is increasingly recognized that endogenous molecules released from tissue injury and cell death are potent activators of innate immunity. Mitochondria, ancestrally related to bacteria, possess an array of endogenous innate immune‐activating molecules. We have recently demonstrated that extracellular mitochondria are abundant in the circulation of deceased organ donors and that their presence correlates with early allograft dysfunction. Here we demonstrate the ability of mitochondria to activate endothelial cells (ECs), the initial barrier between a solid organ allograft and its host. We find that mitochondria exposure leads to the upregulation of EC adhesion molecules and their production of inflammatory cytokines and chemokines. Additionally, mitochondrial exposure causes dendritic cells to upregulate costimulatory molecules. Infusion of isolated mitochondria into heart donors leads to significant increase in allograft rejection in a murine heterotopic heart transplantation model. Finally, co‐incubation of human peripheral blood mononuclear cells with mitochondria‐treated ECs results in increased numbers of effector (IFN‐γ⁺, TNF‐α⁺) CD8⁺ T cells. These data indicate that circulating extracellular mitochondria in deceased organ donors may directly activate allograft ECs and promote graft rejection in transplant recipients.     

Recipient Myd88 Deficiency Promotes Spontaneous Resolution of Kidney Allograft Rejection

The myeloid differentiation protein 88 (MyD88) adapter protein is an important mediator of kidney allograft rejection, yet the precise role of MyD88 signaling in directing the host immune response toward the development of kidney allograft rejection remains unclear. Using a stringent mouse model of allogeneic kidney transplantation, we demonstrated that acute allograft rejection occurred equally in MyD88-sufficient (wild-type [WT]) and MyD88^−/− recipients. However, MyD88 deficiency resulted in spontaneous diminution of graft infiltrating effector cells, including CD11b⁻Gr-1⁺ cells and activated CD8 T cells, as well as subsequent restoration of near-normal renal graft function, leading to long-term kidney allograft acceptance. Compared with T cells from WT recipients, T cells from MyD88^−/− recipients failed to mount a robust recall response upon donor antigen restimulation in mixed lymphocyte cultures ex vivo. Notably, exogenous IL-6 restored the proliferation rate of T cells, particularly CD8 T cells, from MyD88^−/− recipients to the proliferation rate of cells from WT recipients. Furthermore, MyD88^−/− T cells exhibited diminished expression of chemokine receptors, specifically CCR4 and CXCR3, and the impaired ability to accumulate in the kidney allografts despite an otherwise MyD88-sufficient environment. These results provide a mechanism linking the lack of intrinsic MyD88 signaling in T cells to the effective control of the rejection response that results in spontaneous resolution of acute rejection and long-term graft protection.     

The association of IgA deficiency but not IgG or IgM deficiency with a reduced patient and graft survival following liver transplantation.

Recipients of solid organ allografts require lifelong immunosuppression in order to prevent graft rejection and to maintain graft function. In general, such immunosuppression greatly impairs the cellular immune system, as this level of the immune system is principally responsible for self and non-self recognition. The consequences of allograft transplantation in terms of patient and graft survival when transplants are given to individuals who have a preexisting humoral immune deficiency characterized by a deficiency of the serum levels of one or more of the major Ig classes have not yet been reported. From February 1, 1981 through December 31, 1990, a total of 43 adult patients with a deficiency of 1 or more Ig classes received a ABO-matched liver allograft at this institution. This sample represents 2.5% of a total of 1684 adults transplanted during this interval. These 43 liver graft recipients could be divided into 3 major groups based upon the presence of an IgG, IgM, or IgA deficiency. IgG deficiencies were defined as levels less than 50 mg/dl. Patient and graft survival for the IgA-deficient group was significantly reduced (P less than 0.04 and P less than 0.009, respectively) compared with both the IgG- and IgM-deficient groups. The latter two groups did not differ from controls without an Ig deficiency for these same two endpoints. The major causes of death in the IgA-deficient group were sepsis and opportunistic infection. A third of the deaths in the IgA-deficient group occurred in the perioperative period (first 30 days) while greater than 50% of the deaths occurred within the first 3 months, and all deaths occurred before the first year. Based upon these data, the following conclusions can be made: (1) serum IgA deficiency but not IgG or IgM deficiency is associated with an increased post-OLTx death and graft loss rate; (2) the majority of these deaths are due to sepsis or an opportunistic infection; and (3) most of the deaths occur early. These data suggest that recognition of a deficiency of IgA prior to organ grafting necessitates meticulous attention to the prevention of infection in the immediate perioperative period if patient and graft survival of these patients is to be improved.     

Interleukin‐17 positive cells accumulate in renal allografts during acute rejection and are independent predictors of worse graft outcome

Interleukin‐17 (IL‐17) plays an important role in the regulation of cellular and humoral immune responses. Recent studies suggest a role for IL‐17 in transplantation. Our study investigated whether quantifying IL‐17⁺ cells in renal transplant biopsies during acute rejection could have additional prognostic value for better stratifying patients at risk for nonresponsiveness to anti‐rejection therapy and future graft dysfunction. Forty‐nine renal biopsies with acute rejection were double immunostained and quantitatively analyzed for IL‐17 and CD3 (IL‐17⁺ T‐lymphocytes), tryptase (IL‐17⁺ mast cells) or CD15 (IL‐17⁺ neutrophils). Total IL‐17⁺ cell count correlated with total percentage of inflamed biopsy and estimated GFR during rejection. Most IL‐17⁺ cells were mast cells and neutrophils. We could hardly find any IL‐17⁺ T‐lymphocytes. IL‐17⁺ mast cells correlated with interstitial fibrosis/tubular atrophy (IF/TA). None of the IL‐17⁺ cell counts had an additional prognostic value for response to anti‐rejection treatment. Multivariate analysis correcting for C4d positivity and time from transplantation to biopsy showed that total IL‐17⁺ cell count independently predicts graft dysfunction at the last follow‐up, which was validated in an independent cohort of 48 renal biopsies with acute rejection. We conclude that intragraft IL‐17⁺ cell count during acute allograft rejection could have an additional value for predicting late graft dysfunction.     

In Vivo Function of Immune Inhibitory Molecule B7‐H4 in Alloimmune Responses

B7 ligands deliver both costimulatory and coinhibitory signals to the CD28 family of receptors on T lymphocytes, the balance between which determines the ultimate immune response. Although B7‐H4, a recently discovered member of the B7 family, is known to negatively regulate T cell immunity in autoimmunity and cancer, its role in solid organ allograft rejection and tolerance has not been established. Targeting the B7‐H4 molecule by a blocking antibody or use of B7‐H4^?/? mice as recipients of fully MHC‐mismatched cardiac allografts did not affect graft survival. However, B7‐H4 blockade resulted in accelerated allograft rejection in CD28‐deficient recipients. B7‐1/B7‐2‐double‐deficient recipients are truly independent of CD28/CTLA‐4:B7 signals and usually accept MHC‐mismatched heart allografts. Blockade of B7‐H4 in these mice also precipitated rejection, demonstrating regulatory function of this molecule independent of an intact CD28/CTLA‐4:B7 costimulatory pathway. Accelerated allograft rejection was always accompanied by increased frequencies of alloreactive IFN‐γ‐, IL‐4‐ and Granzyme B‐producing splenocytes. Finally, intact recipient, but not donor, B7‐H4 is essential for prolongation of allograft survival by blocking CD28/CTLA4:B7 pathway using CTLA4‐Ig. These data are the first to provide evidence of the regulatory effects of B7‐H4 in alloimmune responses in a murine model of solid organ transplantation.     

Prevention of Chronic Rejection with Immunoregulatory Cells Induced by Intrathymic Immune Modulation with Class I Allopeptides

Intrathymic immune modulation with RT1.A^a allopeptides in the PVG.R8‐to‐PVG.1 U rat strain combination leads to long‐term survival of cardiac allografts. This regimen, however, does not induce transplantation tolerance, since most long‐surviving allografts undergo chronic rejection. We investigated recipients with chronic rejection for donor‐specific immune nonresponsiveness and immunoregulatory cells as possible mechanisms responsible for long‐term graft survival. There was a significant reduction in the proliferative response of T cells from long‐term allograft recipients to donor alloantigens as compared with that of naïve T cells. Adoptive transfer of splenocytes from intrathymically manipulated primary long‐term graft survivors into minimally irradiated secondary hosts resulted in indefinite survival of > 80% of allografts, providing evidence for immunoregulatory cells. Secondary recipients had total absence of donor‐reactive cellular and humoral responses. Immunoregulation was also transferable from secondary to tertiary graft recipients. More importantly, there was a significant reduction in the incidence of chronic rejection in secondary hosts (> 85%) and complete prevention of acute and chronic rejection in tertiary hosts. This study demonstrates that intrathymic immunomodulation with class I allopeptides results in the generation of immunoregulatory cells that do not block chronic rejection in primary hosts where they develop, but prevent both acute and chronic allograft rejection when adoptively transferred into secondary and tertiary recipients.     

Dominant regulation of long‐term allograft survival is mediated by microRNA‐142

Organ transplantation is often lifesaving, but the long‐term deleterious effects of combinatorial immunosuppression regimens and allograft failure cause significant morbidity and mortality. Long‐term graft survival in the absence of continuing immunosuppression, defined as operational tolerance, has never been described in the context of multiple major histocompatibility complex (MHC) mismatches. Here, we show that miR‐142 deficiency leads to indefinite allograft survival in a fully MHC mismatched murine cardiac transplant model in the absence of exogenous immunosuppression. We demonstrate that the cause of indefinite allograft survival in the absence of miR‐142 maps specifically to the T cell compartment. Of therapeutic relevance, temporal deletion of miR‐142 in adult mice prior to transplantation of a fully MHC mismatched skin allograft resulted in prolonged allograft survival. Mechanistically, miR‐142 directly targets Tgfbr1 for repression in regulatory T cells (T_REG). This leads to increased T_REG sensitivity to transforming growth factor – beta and promotes transplant tolerance via an augmented peripheral T_REG response in the absence of miR‐142. These data identify manipulation of miR‐142 as a promising approach for the induction of tolerance in human transplantation.     

Graft produced interleukin-6 functions as a danger signal and promotes rejection after transplantation

BACKGROUND: Interleukin (IL)-6 is a pleiotropic cytokine that functions in both the innate and adaptive immune responses. However, the role of IL-6 in allograft rejection remains poorly understood. METHODS: In this study, we demonstrate a critical role for graft-produced IL-6 in allograft rejection in a murine model of cardiac allograft transplantation. RESULTS: The results show that IL-6-deficient grafts transplanted into allogeneic wild-type recipients have significantly prolonged survival, approximately three times the survival time of wild-type controls. In contrast, allogeneic cardiac transplants into IL-6-deficient recipients do not have prolonged graft survival, indicating that donor graft cells are the relevant source of IL-6. Our investigation of potential mechanisms shows that graft-produced IL-6 promotes the activation of peripheral CD4 and CD8 T cells. Furthermore, we show that IL-6 deficiency prolongs graft survival only in the presence of CD25+ T cells that have a phenotype consistent with regulatory T cells. Interestingly, IL-6 production by the graft is triggered by antigen-independent innate immune mechanisms. CONCLUSIONS: Thus, our results suggest the paradigm that graft rejection versus tolerance is determined by a balance between the activation of effector T cells versus immune suppression by regulatory T cells, and that after transplantation, IL-6 functions as a systemic danger signal that overcomes constitutive immune suppression mediated by regulatory T cells and promotes the activation of effector T cells.     

Mast cells contribute to the induction of ocular mucosal alloimmunity

Beyond their historical role as the effector cells in allergic disorders, mast cells have been implicated in regulating both innate and adaptive immune responses. Possessing considerable functional plasticity, mast cells are abundant at mucosal surfaces, where the host and external environments interface. The purpose of this study was to evaluate the contribution of mast cells to allograft rejection at the ocular surface. Using a well‐characterized murine model of corneal transplantation, we report that mast cells promote allosensitization. Our data show mast cell frequencies and activation are increased following transplantation. We demonstrate that mast cell inhibition (a) limits the infiltration of inflammatory cells and APC maturation at the graft site; (b) reduces allosensitization and the generation of Th1 cells in draining lymphoid tissues; (c) decreases graft infiltration of alloimmune‐inflammatory cells; and (d) prolongs allograft survival. Our data demonstrate a novel function of mast cells in promoting allosensitization at the ocular surface.     

Allergic Conjunctivitis Renders CD4+ T Cells Resistant to T Regulatory Cells and Exacerbates Corneal Allograft Rejection

Allergic diseases rob corneal allografts of immune privilege and increase immune rejection. Corneal allograft rejection in BALB/c allergic hosts was analyzed using a short ragweed (SWR) pollen model of allergic conjunctivitis. Allergic conjunctivitis did not induce exaggerated T‐cell responses to donor C57BL/6 (B6) alloantigens or stimulate cytotoxic T lymphocyte (CTL) responses. Allergic conjunctivitis did affect T regulatory cells (Tregs) that support graft survival. Exogenous IL‐4, but not IL‐5 or IL‐13, prevented Treg suppression of CD4⁺ effector T cells isolated from naïve mice. However, mice with allergic conjunctivitis developed Tregs that suppressed CD4⁺ effector T‐cell proliferation. In addition, IL‐4 did not inhibit Treg suppression of IL‐4Rα^?/? CD4⁺ T‐cell responses, suggesting that IL‐4 rendered effector T cells resistant to Tregs. SRW‐sensitized IL‐4Rα^?/? mice displayed the same 50% graft survival as nonallergic WT mice, that was significantly less than the 100% rejection that occurred in allergic WT hosts, supporting the role of IL‐4 in the abrogation of immune privilege. Moreover, exacerbation of corneal allograft rejection in allergic mice was reversed by administering anti‐IL‐4 antibody. Thus, allergy‐induced exacerbation of corneal graft rejection is due to the production of IL‐4, which renders effector T cells resistant to Treg suppression of alloimmune responses.     

IL‐17 Deficiency Attenuates Allograft Injury and Prolongs Survival in a Murine Model of Fully MHC‐Mismatched Renal Allograft Transplantation

IL‐17 is a pro‐inflammatory cytokine implicated in the pathogenesis of inflammatory and autoimmune diseases. However the role of IL‐17 in renal allograft rejection has not been fully explored. Here, we investigate the impact of IL‐17 in a fully MHC‐mismatched, life‐sustaining, murine model of kidney allograft rejection using IL‐17 deficient donors and recipients (IL‐17^?/? allografts). IL‐17^?/? allografts exhibited prolonged survival which was associated with reduced expression of the Th1 cytokine IFN‐γ and histological attenuation of acute and chronic allograft rejection, as compared to wild‐type allograft recipients. Results were confirmed in WT allograft recipients treated with an IL‐17 blocking antibody. Subsequent experiments using either donors or recipients deficient in IL‐17 showed a trend towards prolongation of survival only when recipients were IL‐17^?/?. Administration of a depleting anti‐CD25 antibody to IL‐17^?/? recipients abrogated the survival advantage conferred by IL‐17 deficiency, suggesting the involvement of a CD4⁺CD25⁺ T cell regulatory mechanism. Therefore, IL‐17 deficiency or neutralization was protective against the development of kidney allograft rejection, which may be mediated by impairment of Th1 responses and/or enhanced protection by Tregs.

     

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

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