Michaella E. Maloney

Indirect recognition of allopeptides promotes the development of cardiac allograft vasculopathy

Graft loss from chronic rejection has become the major obstacle to the long-term success of whole organ transplantation. In cardiac allografts, chronic rejection is manifested as a diffuse and accelerated form of arteriosclerosis, termed cardiac allograft vasculopathy. It has been suggested that T-cell recognition of processed alloantigens (allopeptides) presented by recipient antigen-presenting cells through the indirect pathway of allorecognition plays a critical role in the development and progression of chronic rejection. However, definitive preclinical evidence to support this hypothesis is lacking. To examine the role of indirect allorecognition in a clinically relevant large animal model of cardiac allograft vasculopathy, we immunized MHC inbred miniature swine with synthetic polymorphic peptides spanning the α1 domain of an allogeneic donor-derived swine leukocyte antigen class I gene. Pigs immunized with swine leukocyte antigen class I allopeptides showed in vitro proliferative responses and in vivo delayed-type hypersensitivity responses to the allogeneic peptides. Donor MHC class I disparate hearts transplanted into peptide-immunized cyclosporine-treated pigs not only rejected faster than unimmunized cyclosporine-treated controls (mean survival time = 5.5 +/−1.7 vs. 54.7 +/−3.8 days, P < 0.001), but they also developed obstructive fibroproliferative coronary artery lesions much earlier than unimmunized controls (<9 vs. >30 days). These results definitively link indirect allorecognition and cardiac allograft vasculopathy.

Induction of tolerance to heart transplants by simultaneous cotransplantation of donor kidneys may depend on a radiation-sensitive renal-cell population.

Background. To determine the mechanism by which cotransplantation of a donor kidney and heart allograft induces tolerance to both organs in miniature swine, we examined the renal elements responsible for tolerance induction. Methods. Recipients received 12 days of cyclosporine, and transplants were performed across a major histocompatibility complex (MHC) class I mismatch. Group 1 animals received heart transplants (n=5); group 2 animals received heart and kidney allografts with no other manipulation (n=4); group 3 animals received heart transplants and donor-specific renal parenchymal cells (n=4); group 4 animals received heart and kidney allografts from lethally irradiated donors (n=7); group 5 animals received irradiated hearts and nonirradiated kidneys (n=2); group 6 animals received nonirradiated hearts and peripheral blood leukocytes from swine MHC matched to recipients and becoming tolerant to donor antigen (n=2); group 7 animals received nonirradiated hearts and donor-specific peripheral blood monocyte cells (PBMC) (n=2). Results. Animals in group 1 developed vasculopathy and fulminant rejection by day 55. Animals in group 2 never developed vascular lesions. Parenchymal kidney cell infusion (group 3) did not prolong cardiac survival. Animals in group 4 developed arteriopathy by postoperative day (POD) 28. Group 5 recipients accepted allografts without vascular lesions. Adoptive transfer of leukocytes from tolerant swine (group 6) prolonged cardiac graft survival as much as 123 days, whereas donor PBMC infusion (group 7) did not affect cardiac survival or development of arteriopathy. Conclusions. Radiosensitive elements in kidney allograft may be responsible for tolerance induction and prevention of chronic vascular lesions in recipients of simultaneous heart and kidney allografts.

CTLA4Ig-Induced Linked Regulation of Allogeneic T Cell Responses

The mechanisms by which CTLA4Ig exerts its powerful immunomodulatory effects are not clear. We show here that CTLA4Ig can induce linked regulation of allogeneic porcine T cell responses in vitro. Naive miniature swine SLAdd T cells were rendered hyporesponsive to specific allogeneic Ag after coculturing with MHC-mismatched SLAcc stimulators in the presence of CTLA4Ig. These Ag-specific hyporesponsive T cells were subsequently able to actively inhibit the allogeneic responses of naive syngeneic T cells in an MHC-linked fashion, as the responses of naive SLAdd responders against specific SLAcc and (SLAac)F1 stimulators were inhibited, but allogeneic responses against a 1:1 mixture of SLAaa (Ia, IIa) and SLAcc (Ic, IIc) were maintained. This inhibition could be generated against either class I or class II Ags, was radiosensitive, and required cell-cell contact. Furthermore, the mechanism of inhibition was not dependent upon a deletional, apoptotic pathway, but it was reversed by anti-IL-10 mAb. These data suggest that CTLA4Ig-induced inhibition of naive allogeneic T cell responses can be mediated through the generation of regulatory T cells via an IL-10-dependent mechanism.

The effects of mycophenolate mofetil on cardiac allograft survival and cardiac allograft vasculopathy in miniature swine

Background. Chronic rejection, as manifested by cardiac allograft vasculopathy, remains the leading cause of late graft failure in heart transplant recipients. Despite recent clinical trials, the efficacy of mycophenolate mofetil in preventing human cardiac allograft vasculopathy remains controversial. We investigated whether mycophenolate mofetil would prevent cardiac allograft vasculopathy and prolong cardiac allograft survival in our well-established miniature swine model of heart transplantation. Methods. Hearts disparate at the major histocompatibility complex class I locus were heterotopically transplanted into miniature swine recipients treated with a 12-day course of mycophenolate mofetil (n 3) or cyclosporine A (n 3). Allograft survival, acute rejection, and chronic rejection were monitored in the two groups. Results. Hearts transplanted with 12 days of cyclosporine were rejected between 46 and 61 days, whereas two of the three hearts transplanted with mycophenolate mofetil remained beating beyond 120 days (p 0.02). At necropsy, there was a 4.9% mean prevalence of cardiac allograft vasculopathy in the mycophenolate mofetil group as compared with 16.6% in the cyclosporine group (p 0.03). Cardiac allograft rejection and vasculopathy in the cyclosporine-treated group was associated with prominent myocardial interferon- gene expression, a finding absent in two thirds of the mycophenolate mofetil-treated swine. Moreover, the mycophenolate mofetil-treated swine failed to develop IgM or IgG alloantibodies. Conclusions. A short course of mycophenolate mofetil resulted in a longer allograft survival than a similar course of cyclosporine. Moreover, mycophenolate mofetil reduced the prevalence of cardiac allograft vasculopathy as compared with cyclosporine-treated controls. The salutary effect of mycophenolate mofetil may be related to its ability to decrease interferon- expression in the myocardium and prevent the generation of alloantibodies. (Ann Thorac Surg 2005;80:1787‐93)

CTLA4Ig-induced linked regulation of allogeneic T cell responses

The mechanisms by which CTLA4Ig exerts its powerful immunomodulatory effects are not clear. We show here that CTLA4Ig can induce linked regulation of allogeneic porcine T cell responses in vitro. Naive miniature swine SLA(dd) T cells were rendered hyporesponsive to specific allogeneic Ag after coculturing with MHC-mismatched SLA(cc) stimulators in the presence of CTLA4Ig. These Ag-specific hyporesponsive T cells were subsequently able to actively inhibit the allogeneic responses of naive syngeneic T cells in an MHC-linked fashion, as the responses of naive SLA(dd) responders against specific SLA(cc) and (SLA(ac))F(1) stimulators were inhibited, but allogeneic responses against a 1:1 mixture of SLA(aa) (I(a), II(a)) and SLA(cc) (I(c), II(c)) were maintained. This inhibition could be generated against either class I or class II Ags, was radiosensitive, and required cell-cell contact. Furthermore, the mechanism of inhibition was not dependent upon a deletional, apoptotic pathway, but it was reversed by anti-IL-10 mAb. These data suggest that CTLA4Ig-induced inhibition of naive allogeneic T cell responses can be mediated through the generation of regulatory T cells via an IL-10-dependent mechanism.