CD28-B7 T-cell co-stimulatory blockade potentiates the effects of intrathymic immunomodulation in sensitized graft recipients

Apoptotic cell death during accelerated rejection in sensitized rat recipients of cardiac allografts

Accelerated rejection due to host sensitization to major histocompatibility complex antigens is a critical problem in clinical organ transplantation in patients who have previously received an organ transplant, experienced acute rejection episodes, received blood transfusions, or been pregnant. The precise pathologic mechanisms underlying accelerated rejection have not been characterized. Herein, we describe apoptosis during T- and B-cell-driven accelerated rejection of cardiac allografts in presensitized recipients. In an established accelerated rejection model, Lewis rats were sensitized to skin grafts from Wistar-Furth rats; after 7 days, they received Wistar-Furth hearts. These grafts were rejected within 24 hours posttransplantation compared with 10 days in nonsensitized recipients (acute rejection, n = 5). Apoptosis was observed during accelerated rejection of cardiac allografts but not in naïve recipients of hearts, as demonstrated at DNA laddering and TUNEL (terminal deoxynucleotide transferase-mediated deoxyuridine triphosphate nick-end labeling) assay. Apoptosis was discovered as a thus far unknown effector mechanism in accelerated cardiac transplant rejection that accompanies combined cellular and humoral immune alloreactivity. Apoptotic cell death in accelerated rejection and the cascade of upstream and downstream events leading to or resulting from this process should be considered critical steps in the pathogenesis of accelerated rejection.

Anti-CD28 monoclonal antibody therapy prevents chronic rejection of renal allografts in rats

The effects of a signaling anti-CD28 mAb (JJ319), which interferes with the CD28-B7 T cell costimulation pathway thought to be involved in the development of chronic rejection of organ transplants, was investigated. Functional, morphologic, and molecular changes in rat renal allografts were examined up to 24 wk after placement. Control Lewis rats, recipients of F344 kidneys, received a single dose of a nonspecific mouse mAb intravenously on the day of transplantation (group 1). Group 2 animals were given anti-CD28 mAb in similar fashion. Group 3 animals were treated with a short course of cyclosporin A (CsA), and group 4 received both anti-CD 28 mAb and CsA. The majority (>95%) of animals in groups 2, 3, and 4 survived throughout the follow-up, compared with 28% in group 1 (P < 0.001). Group 2 and 4 recipients produced negligible proteinuria, whereas group 1 controls developed progressively increasing proteinuria after 4 wk and group 3 animals developed proteinuria by 24 wk. Allografts in groups 2 and 4 were morphologically unremarkable at 24 wk. Kidneys of group 1 animals rapidly developed changes of acute rejection, and those that survived long-term showed extensive glomerulosclerosis and interstitial fibrosis. Changes of early chronic rejection were noted in group 3 grafts. By reverse transcriptase-PCR, expression of representative inflammatory factors interferon-gamma and interleukin-10 were significantly elevated at 24 wk only in the surviving group 1 animals. A single dose of a signaling anti-CD28 mAb administered at transplantation or in combination with a short course of CsA significantly prolonged recipient survival, normalized function, and preserved the morphology of renal allografts in an established model of chronic rejection. These data support an important role for T cell costimulation in the evolution of the chronic process.

Intrathymic immunomodulation and the "infectious" tolerance pathway in allograft recipients

BACKGROUND

We have previously shown that >75% of LEW cardiac allografts survive indefinitely in BUF rats pretreated at Day -21 intrathymically (IT) with donor alloantigen in conjunction with a single intravenous dose of ALS. Spleen cells can adoptively transfer the tolerant state to new cohorts of test recipients. This study was designed to analyze cellular and humoral events contributing to the "infectious" tolerance pathway in this model.

METHODS

Spleen cells (25 x 10(6)) harvested from BUF recipients bearing long-term cardiac allografts were injected intravenously into lightly irradiated (450 R) secondary BUF rats, followed 24 h later by transplantation of LEW of ACl hearts. Cardiac allografts were then analyzed serially by reverse transcription polymerase chain reaction for Th1 and Th2 cytokine gene expression. Donor-specific IgM and IgG alloantibody responses in host serum were screened by flow cytometry.

RESULTS

Transfer of regulatory spleen cells harvested between Days 80 and 140 from tolerant hosts induced tolerance to heart grafts in a donor-specific manner. In the early posttransplant period, selective sparing of Th2 cytokines was noted. Adoptively transferred hosts showed overall depression of IgM, but a vigorous IgG1 and IgG2a alloantibody response.

CONCLUSION

IT + ALS-induced tolerance can be transferred in a donor-specific "infectious" manner to new cohorts of engrafted recipients. The development of tolerance is nontemporally bound, and associates with an early Th2-type immune deviation at the graft site. The elevated levels of T cell-dependent IgG1 and IgG2 may interfere with the antigen reactivity and alloresponsive effector functions, contributing to graft acceptance in the "infectious" tolerance pathway.

Induction of immunologic tolerance for transplantation

In the second half of the 20th century, the transplantation of replacement organs and tissues to cure disease has become a clinical reality. Success has been achieved as a direct result of progress in understanding the cellular and molecular biology of the immune system. This understanding has led to the development of immunosuppressive pharmaceuticals that are part of nearly every transplantation procedure. All such drugs are toxic to some degree, however, and their chronic use, mandatory in transplantation, predisposes the patient to the development of infection and cancer. In addition, many of them may have deleterious long-term effects on the function of grafts. New immunosuppressive agents are constantly under development, but organ transplantation remains a therapy that requires patients to choose between the risks of their primary illness and its treatment on the one hand, and the risks of life-long systemic immunosuppression on the other. Alternatives to immunosuppression include modulation of donor grafts to reduce immunogenicity, removal of passenger leukocytes, transplantation into immunologically privileged sites like the testis or thymus, encapsulation of tissue, and the induction of a state of immunologic tolerance. It is the last of these alternatives that has, perhaps, the most promise and most generic applicability as a future therapy. Recent reports documenting long-term graft survival in the absence of immunosuppression suggest that tolerance-based therapies may soon become a clinical reality. Of particular interest to our laboratory are transplantation strategies that focus on the induction of donor-specific T-cell unresponsiveness. The basic biology, protocols, experimental outcomes, and clinical implications of tolerance-based transplantation are the focus of this review.