Anna Valujskikh

Decay-accelerating factor modulates induction of T cell immunity

Decay-accelerating factor (Daf) dissociates C3/C5 convertases that assemble on host cells and thereby prevents complement activation on their surfaces. We demonstrate that during primary T cell activation, the absence of Daf on antigen-presenting cells (APCs) and on T cells enhances T cell proliferation and augments the induced frequency of effector cells. The effect is factor D- and, at least in part, C5-dependent, indicating that local alternative pathway activation is essential. We show that cognate T cell–APC interactions are accompanied by rapid production of alternative pathway components and down-regulation of Daf expression. The findings argue that local alternative pathway activation and surface Daf protein function respectively as a costimulator and a negative modulator of T cell immunity and explain previously reported observations linking complement to T cell function. The results could have broad therapeutic implications for disorders in which T cell immunity is important.

Primed allospecific T cells prevent the effects of costimulatory blockade on prolonged cardiac allograft survival in mice.

Costimulatory blockade can induce long‐term allograft survival in naïve animals, but may not be as effective in animals with previously primed immune repertoires. We attempted to induce long‐term graft survival in B10.D2 recipients of B10.A cardiac allografts using donor‐specific transfusion (DST) plus anti‐CD40 ligand antibody (αCD40L). Recipients were either naïve mice, or mice previously primed to B10.A or third party alloantigens through engraftment and rejection of skin transplants. Untreated naïve mice rejected cardiac transplants by day 15 and contained a high frequency of primed, donor‐reactive T cells. Donor‐specific transfusion/αCD40L treatment of naïve animals induced long‐term graft survival associated with low frequencies of donor‐reactive T cells. Previous priming of donor‐specific T cells through rejection of B10.A, but not third party, skin grafts prevented the effects of DST/αCD40L on prolonging survival of B10.A hearts. Moreover, adoptive transfer of CD3+, CD4+ or CD8+ T cells from B10.A skin‐graft‐primed animals prevented the effects of DST/αCD40L. The data demonstrate that animals with immune repertoires containing previously primed, donor‐reactive T cells are resistant to the effects of costimulatory blockade. The findings have important implications for ongoing, costimulatory blockade‐based trials in humans, whose T‐cell repertoires are known to contain memory alloreactive T cells.

Cross-primed CD8+ T cells mediate graft rejection via a distinct effector pathway

To prevent bystander destruction of healthy host tissues, cytotoxic CD8+ T lymphocytes are fitted with specific receptors that direct their destructive forces specifically against chosen targets. We show here, however, that anti–H-Y monospecific, H-2b–restricted MataHari CD8+ T cells reject H-2k male skin grafts, with which they cannot directly interact. Such rejection is interferon-γ–dependent and only occurs if the recipient endothelium expresses H-2b. The findings suggest an alternate indirect effector pathway that requires processing and presentation of the donor H-Y antigen by recipient endothelium and have implications for both transplantation and autoimmune disease.

T Cells Primed by Leishmania major Infection Cross-React with Alloantigens and Alter the Course of Allograft Rejection

Alloreactive T lymphocytes can be primed through direct presentation of donor MHC:peptide complexes on graft cells and through indirect presentation of donor-derived determinants expressed by recipient APCs. The large numbers of determinants on an allograft and the high frequency of the alloreactive repertoire has further led to speculation that exposure to environmental Ags may prime T cells that cross-react with alloantigens. We sought to develop a model in which to test this hypothesis. We found that CD4+ T cells obtained from C57BL/6 (B6) mice that clinically resolved Leishmania major infection exhibited statistically significant cross-reactivity toward P/J (H-2p) Ags compared with the response to other haplotypes. B6 animals that were previously infected with L. major specifically rejected P/J skin grafts with second set kinetics compared with naive animals. Although donor-specific transfusion combined with costimulatory blockade (anti-CD40 ligand Ab) induced prolonged graft survival in naive animals, the same treatment was ineffective in mice previously infected with L. major. The studies demonstrate that cross-reactive priming of alloreactive T cells can occur and provide direct evidence that such T cells can have a significant impact on the outcome of an allograft. The results have important implications for human transplant recipients whose immune repertoires may contain cross-reactively primed allospecific T cells.

In Vivo Helper Functions of Alloreactive Memory CD4+ T Cells Remain Intact Despite Donor-Specific Transfusion and Anti-CD40 Ligand Therapy

Memory T cells have specific properties that are beneficial for rapid and efficient protection from pathogens previously encountered by a host. These same features of memory T cells may be deleterious in the context of a transplanted organ. Consistent with this contention is the accumulating evidence in experimental transplantation that previously sensitized animals are resistant to the effects of costimulatory blockade. Using a model of murine cardiac transplantation, we now demonstrate that alloreactive memory CD4+ T cells prevent long-term allograft survival induced through donor-specific cell transfusion in combination with anti-CD40 ligand Ab (DST/anti-CD40L). We show that memory donor-reactive CD4+ T cells responding through the direct or indirect pathways of allorecognition provide help for the induction of antidonor CD8+ T effector cells and for Ab isotype switching, despite DST/anti-CD40L. The induced pathogenic antidonor immunity functions in multiple ways to subsequently mediate graft destruction. Our findings show that the varied functions of alloreactive memory CD4+ T cells remain intact despite DST/anti-CD40L-based costimulatory blockade, a finding that will likely have important implications for designing approaches to induce tolerance in human transplant recipients.

T cells reactive to a single immunodominant self-restricted allopeptide induce skin graft rejection in mice.

Alloreactive T lymphocytes can respond to foreign MHC complexed with foreign peptides through the direct pathway of allorecognition and can additionally recognize allopeptides expressed in the context of recipient (self) MHC through the indirect pathway. To better elucidate how indirect pathway-responsive CD4(+) T cells mediate allograft rejection, we isolated and characterized a TH1 T cell line from BALB/c recipients of B10.A skin that responds to a defined immunodominant, self-restricted allopeptide, I-Abetak58-71. When transferred into BALB/c severe combined immunodeficiency recipients of B10.A skin allografts, this cell line specifically induced a form of skin graft rejection characterized by the presence of TH1 cytokines, macrophage infiltration, and extensive fibrosis. Recall immune responses and immunofluorescence of the rejecting skin revealed only the presence of the peptide-specific T cells within the recipient animals, with no evidence of a direct pathway alloresponse. These studies demonstrate that T cells reactive to a single self-restricted allopeptide can mediate a form of allogeneic skin graft rejection that exhibits characteristics of a chronic, fibrosing process.

Donor-Reactive CD8 Memory T Cells Infiltrate Cardiac Allografts Within 24-h Posttransplant in Naive Recipients

Normal immune responses stimulated by pathogenic and environmental antigens generate memory T cells that react with donor antigens and no currently used immunosuppressive drug completely inhibits memory T‐cell function. While donor‐reactive memory T cells clearly compromise graft outcomes, mechanisms utilized by memory T cells to promote rejection are largely unknown. In this study, we investigated how early endogenous memory cells infiltrate and express effector function in cardiac allografts. Endogenous CD8 memory T cells in nonsensitized recipients distinguish syngeneic versus allogeneic cardiac allografts within 24 h of reperfusion. CD8‐dependent production of IFN‐γ and CXCL9/Mig was observed 24 to 72 h posttransplant in allografts but not isografts. CXCL9 was produced by donor cells in response to IFN‐γ made by recipient CD8 T cells reactive to donor class I major histocompatibility complex (MHC) molecules. Activated CD8 T cells were detected in allografts at least 3 days before donor‐specific effector T cells producing IFN‐γ were detected in the recipient spleen. Early inflammation mediated by donor‐reactive CD8 memory T cells greatly enhanced primed effector T‐cell infiltration into allografts. These results suggest that strategies for optimal inhibition of alloimmunity should include neutralization of infiltrating CD8 memory T cells within a very narrow window after transplantation.

Lymphoid sequestration of alloreactive memory CD4 T cells promotes cardiac allograft survival.

Memory T cells specific for donor Ags present a unique challenge in transplantation. In addition to expressing robust immune responses to a transplanted organ, memory T cells may be resistant to the effects of immunosuppressive therapies used to prolong graft survival. In this study, we explore the possibility of controlling deleterious donor-reactive memory CD4 T cells through lymphoid sequestration. We showed that sphingosine 1-phosphate receptor-1 agonist FTY720 induces relocation of circulating memory CD4 T cells into secondary lymphoid organs. Lymphoid sequestration of these donor-reactive memory CD4 T cells prolonged survival of murine heterotopic cardiac allografts and synergizes with conventional costimulatory blockade to further increase graft survival. Despite limited trafficking, memory CD4 T cells remain capable of providing help for the induction of anti-donor CD8 T cell and alloantibody responses. Elimination of antidonor humoral immunity resulted in indefinite allograft survival proving the pathogenicity of alloantibody under these conditions. Overall, this is the first demonstration that FTY720 influences memory CD4 T cell trafficking and attenuates their contribution to allograft rejection. The data have important implications for guiding FTY720 therapy and for designing combinatorial strategies aimed at prolonging allograft survival in sensitized transplant patients with donor-specific memory T cells.

Frontiers in Nephrology: T Cell Memory as a Barrier to Transplant Tolerance

Immunologic memory, or the ability to respond more rapidly and effectively to the previously encountered pathogens, represents a fundamental feature of the adaptive immune system. Such memory functions are carried out by subsets of specialized memory cells that are long-lived as a population.

In remembrance of things past: memory T cells and transplant rejection.

Summary:  A cardinal feature of the adaptive immune response is its ability to generate long‐lived populations of memory T lymphocytes. Memory T cells are specific to the antigen encountered during the primary immune response and react rapidly and vigorously upon re‐encounter with the same antigen. Memory T cells that recognize microbial antigens provide the organism with long‐lasting protection against potentially fatal infections. On the other hand, memory T cells that recognize donor alloantigens can jeopardize the survival of life‐saving organ transplants. We review here the immunobiology of memory T cells and describe their role in the rejection of solid organ allografts.