CD4+ T cell recognition of a single discordant HLA-A2-transgenic molecule through the indirect antigen presentation pathway induces acute rejection of murine cardiac allografts.

To further define the role of indirect allorecognition, cardiac allografts from HLA-A2-transgenic (HLA-A2+) C57BL/6 mice were heterotopically transplanted into normal C57BL/6, CD4 T cell-knockout (KO) C57BL/6 mice, CD8 T cell-KO C57BL/6 mice, fully MHC-discordant BALB/c mice (allogeneic control), and HLA-A2+ C57BL/6 mice (syngeneic control). HLA-A2+ grafts were acutely rejected when transplanted into BALB/c mice (mean survival time: 10+/-0.8 days), normal C57BL/6 mice (mean survival time: 16.5+/-2.1 days) as well as CD8-KO mice (mean survival time: 12.8+/-1.3 days). Histopathological analysis revealed classical acute cellular rejection with moderate to severe diffuse interstitial CD4+ and CD8+ cellular infiltrates and significant intra-graft deposition of IgG and complement. In contrast, HLA-A2+ grafts were not rejected when transplanted into CD4-KO mice or HLA-A2+ mice. CD8-KO recipients treated with an anti-CD4 monoclonal antibody, but not with an anti-NK monoclonal antibody, failed to reject their allografts with prolonged administration of antibody (30 days). Spleen cells from mice rejecting HLA-A2+ allografts failed to lyse HLA-A2+ target cells indicating a lack of involvement of CD8+ T cells in the rejection process. In contrast, spleen cells from rejecting animals proliferated significantly to both HLA-A2+ cells and to a peptide derived from the HLA-A2 molecule. Development of anti-HLA-A2 antibodies was observed in all animals rejecting HLA-A2+ allografts. These results suggest that indirect allorecognition of donor MHC class I molecules leads to rejection of cardiac allografts and development of alloantibodies in this unique transplant model in which there is a single MHC discordance between donor and recipient.     

Rejection responses to allogeneic hepatocytes by reconstituted SCID mice, CD4, KO, and CD8 KO mice

INTRODUCTION: The purpose of the current study was to investigate the capacity of CD4+, CD8+, or non-T cells to independently initiate acute rejection of allogeneic hepatocytes using reconstituted SCID, CD4 or CD8 knockout (KO) recipient mice. METHODS: Allogeneic hepatocytes (FVB/N, H-2q) were transplanted into C57BL/6.SCID (H-2b), CD4 KO (H-2b), CD8 KO (H-2b), or beige/beige (H-2b) mice. SCID mice with functioning hepatocellular allografts subsequently received purified non-T cells (NTC), CD4+, or CD8+ splenocytes. Some mice were treated with anti-CD4, anti-CD8, and/or anti-nkl.1 mAb. Recipient mice were also assessed for donor-reactive delayed-type hypersensitivity (DTH) responses and donor-reactive alloantibody production. RESULTS: Median hepatocellular allograft survival time (MST) was 28 days in CD4+ reconstituted SCID mice and 14 days in CD8+ reconstituted SCID mice. SCID hosts reconstituted with NTC demonstrated indefinite hepatocellular allograft survival (>120 days). MST was 10 days in untreated beige/beige (NK cell deficient) mice. MST was 14 days in untreated, 35 days in anti-CD4 mAb treated, and 10 days in anti-nkl.1 mAb treated CD8 KO mice. MST was 10 days in untreated, 35 days in anti-CD8 mAb treated, and 7 days in anti-nk1.1 mAb treated CD4 KO mice. Donor-reactive DTH responses were not detected in reconstituted SCID mice, were minimal in CD4 KO mice, and were prominent in CD8 KO mice after rejection of allogeneic hepatocytes. Similarly, donor-reactive alloantibody, was not detected in CD4 KO hosts, but was readily detected in CD8 KO hosts. CONCLUSIONS: These studies show that both CD4+ and CD8+ T cells (but not host NTC) can independently initiate the rejection of allogeneic hepatocytes. While hepatocyte rejection by isolated CD4+ T cells is not surprising, rejection by CD8+ T cells (in the absence of CD4+ T cells) was unusual, and may explain the failure of "standard" immunosuppressive regimens to suppress acute rejection of allogeneic hepatocytes, as noted in prior studies. Furthermore, NK cells do not appear to be required for either CD4+ T cell or CD8+ T cell initiated hepatocyte rejection.     

Prolonged allograft survival in anti-CD4 antibody transgenic mice: lack of residual helper T cells compared with other CD4-deficient mice

BACKGROUND: Investigations of the role of CD4 T lymphocytes in allograft rejection and tolerance have relied on the use of mouse models with a deficiency in CD4 cells. However, in mice treated with depleting monoclonal antibody (mAb) and in MHC class II knockout (KO) mice, there are residual populations of CD4 cells. CD4 KO mice had increased CD4- CD8-TCRalphabeta+ helper T cells, and both strains of KO mice could reject skin allografts at the normal rate. In this study, transgenic mice with no peripheral CD4 cells were the recipients of skin and heart allografts. Results were compared with allograft survival in CD4 and MHC class II KO mice. METHODS: GK5 (C57BL/6 bml mice transgenic for a chimeric anti-CD4 antibody) had no peripheral CD4 cells. These mice, and CD4 and class II KO mice, received BALB/c or CBA skin or cardiac allografts. Some GK5 mice were treated with anti-CD8 mAb to investigate the role of CD8 cells in rejection. CD4 and CD8 cells were assessed by FACS and immunohistochemistry. RESULTS: BALB/c skin on GK5 mice had a mean survival time +/- SD of 24+/-6 days, compared with 9+/-2 days in wild-type mice. Anti-CD8 mAb prolonged this to 66+/-7 days. BALB/c skin survived 10+/-2 days on class II KO and 14+/-2 days on CD4 KO, both significantly less than the survival seen on GK5 recipients (P<0.001). BALB/c hearts survived >100 days in GK5 recipients and in wild-type recipients treated with anti-CD4 mAb at the time of grafting, in contrast to a mean survival time of 10+/-2 days in untreated wild-type mice. Immunohistochemistry revealed that long-term surviving heart allografts from the GK5 recipients had CD8 but no CD4 cellular infiltrate. These hearts showed evidence of transplant vasculopathy. CONCLUSIONS: The GK5 mice, with a complete absence of peripheral CD4 cells, provide the cleanest available model for investigating the role of CD4 lymphocytes in allograft rejection. Prolonged skin allograft survival in these mice compared with CD4 and MHC class II KO recipients was clearly the result of improved CD4 depletion. Nevertheless, skin allograft rejection, heart allograft infiltration, and vascular disease, mediated by CD8 cells, developed in the absence of peripheral CD4 T cells.     

Absence of host B7 expression is sufficient for long-term murine vascularized heart allograft survival

CD28 antagonists have been shown to promote long-term graft survival and induce donor-specific tolerance. In this study, the role of CD28/B7 costimulation and the relative importance of host versus donor B7 expression in allograft rejection was assessed in a murine abdominal vascularized heterotopic heart transplant model. Wild-type, CD28-deficient, or B7-1/B7-2-deficient C57BL/6 (B6) mice were grafted with allogeneic wild type or B7-1/B7-2-deficient hearts. The results demonstrate allogeneic heart grafts survive long-term in mCTLA4Ig-treated B6 and untreated B7-1/B7-2-deficient B6 recipients but not CD28KO B6 mice. B7-1/B7-2KO B6 recipients treated with anti-CD28 (PV-1) or recombinant human IL-2 rejected the heart transplants indicating that these mice are immunologically competent to reject grafts if costimulatory signals are supplied or bypassed. Finally, there was no difference in rejection between normal animals transplanted with wild-type versus B7-1/B7-2-deficient hearts. These results support a critical role for B7-expressing host antigen presenting cells in the rejection of heart allografts in mice and differences among B7KO and CD28KO animals.     

Role of CD4+ and CD8+ T cells in murine skin and heart allograft rejection across different antigenic desparities

The factors that influence the relative contribution of the T cell subsets to allograft rejection remain unclear. We compared skin and heart rejection in CD4 Knockout (KO), and CD8 KO mice across full-, minor-, and class II histocompatibility antigen (HA) mismatches. Skin allografts were rejected by either CD4+ or CD8+ T cells alone at any degree of antigenic mismatch. However, either the absence of CD4+ cells or a lesser degree of HA mismatch resulted in prolongation of graft survival. In contrast, fully allogeneic heart grafts were accepted in CD4 KO recipients, and minor HA mismatched heart grafts were accepted by both CD4 KO and CD8 KO mice. Thus, the T cell subsets required for allograft rejection are determined by the immunogenicity of the tissue transplanted. In the absence of CD8+ T cells, perforin and Fas ligand (FasL) but not granzyme B mRNA were detected in rejecting grafts. Thus, granzyme B is a CD8+ cytotoxic T lymphocyte (CTL)-specific effector molecule.     

Roles of CD4+ and CD8+ T cells in discordant skin xenograft rejection

An essential role of murine CD4+ T cells in immune reactivity and skin graft rejection in discordant xenogeneic combinations have been reported. Our study was conducted to further clarify the roles of CD4+ and CD8+ T cells in discordant skin xenograft rejection, by using CD4 and CD8 knockout [C57BL/6 Cr Slc (B6; H-2b) background] mice. When human skins were grafted on CD8 knockout mice or B6 mice, both hosts rejected human skin grafts within 12 days after grafting. By contrast, survival of human skin grafts was significantly prolonged in CD4 knockout mice (mean survival times=19.3+/-(SD) 1.6 days; median 19 days). Fully allogeneic C3H/He Slc (H-2k) skin grafts were rejected within 14 days in CD4 knockout mice, suggesting that non-CD4+ T cells in CD4 knockout mice were immunocompetent for allograft rejection. In spleens of these recipient mice, CD8+ T cells seemed to be activated 10 days after human skin grafting. Immunohistological analysis revealed the infiltration of CD8+ T cells at the site of transplanted human skin on CD4 knockout mice. To further examine the role of CD8+ T cells in CD4 knockout mice, human skin grafting was performed on day 0 followed by administration of anti-CD8 monoclonal antibody on days 0, 5, and 14. The administration of anti-CD8 monoclonal antibodies caused the significant prolongation of human skin graft survival. These results indicate the following two conclusions: (1) CD4+ T cells have an essential role in rejecting discordant human skin xenografts rapidly and (2) however, CD8+ T cells also are capable of rejecting discordant human skin xenografts.     

Interferon-gamma is necessary for initiating the acute rejection of major histocompatibility complex class II-disparate skin allografts.

BACKGROUND: Although interferon (IFN)gamma has immunostimulatory functions, it is not essential for the acute rejection of fully allogeneic grafts in mice. It is not known whether IFNgamma plays a critical role in the acute rejection of MHC class I- or MHC class II-disparate allografts. METHODS: We studied the survival of skin allografts transplanted from fully allogeneic (BALB/c), MHC class I-disparate (bml), or MHC class II-disparate (bm12) donors to C57BL/6 wild-type (IFNgamma+/+) and IFNgamma gene-knockout (IFNgamma-/-) recipients. We also investigated the in vitro responses of IFNgamma+/+ and IFNgamma-/- T cells to MHC class II-disparate splenocytes. RESULTS: We found that IFNgamma-/- recipients reject BALB/c and bml skin grafts at the same rate as IFNgamma+/+ mice but are not capable of rejecting bm12 skin. Despite the inability of IFNgamma-/- mice to reject bm12 skin grafts, IFNgamma-/- T cells displayed vigorous proliferation and cytotoxic responses when stimulated with bm12 splenocytes in vitro. Furthermore, priming IFNgamma-/- recipients with bm12 splenocytes enabled these mice to reject bm12 skin grafts at a normal rate and to mount a cutaneous delayed-type hypersensitivity response to the bm12 antigen. CONCLUSION: The data demonstrate that IFNgamma is not necessary for generating effector mechanisms associated with acute transplant rejection but that it is required for initiating alloimmune responses to MHC class II-disparate skin grafts.     

Multiple pathways in the rejection of skin grafts.

We have analyzed the ability of CD4+ and CD8+ T cells to cause rejection of skin grafts in an Ir gene high responder strain. (DA.RT1u x DA.RT1c)F1 B rats (thymectomized, lethally irradiated, reconstituted with fetal liver cells) were grafted with ear skin of the recombinant strain, DA.RT1rl. The only allogeneic difference was a single class I MHC antigen. The B rats, which do not reject these grafts due to the absence of T cells, were reconstituted at various time intervals after skin grafting with either unsorted lymph node cells (LNCs), CD4+, CD8+ or CD4+ and CD8+ T cells. Unsorted LNCs given any time after graft placement always caused rejection (MST = 15d). CD4+ cells alone never caused rejection (MST greater than 60d, n = 8). CD8+ cells alone caused rejection if given within 3 weeks of graft placement. Thereafter, CD8+ cells alone lost their ability to cause rejection (MST greater than 60d, n = 6). B rats with grafts in place more than 3 weeks, when CD8+ cells alone were ineffective, rejected their skin grafts when given both CD8+ and CD4+ cells. These data suggest that there may be two T cell pathways in skin graft rejection. The first requires only CD8+ cells and causes rejection of a recently placed graft. The second pathway requires both CD4+ and CD8+ cells to reject long-standing grafts in which donor antigen-presenting cells have been putatively depleted and, therefore, may be dependent on host antigen-presenting cells.     

CD4+ T-cell-independent rejection of corneal allografts

BACKGROUND: Several studies suggest that a significant number of corneal allografts undergo rejection in the absence of CD4 T cells. This study examined the role of CD4 T cell-independent mechanisms of corneal allograft rejection. METHODS: BALB/c corneal allografts were transplanted to C57BL/6 beige nude mice that received either CD8 or CD8 T cells from C57BL/6 CD4 knockout (KO) mice that had rejected BALB/c corneal allografts. Immune effector functions of CD8 or CD8 T cells from C57BL/6 CD4 KO mice were assessed using delayed-type hypersensitivity assays and Annexin V apoptosis assays respectively. RESULTS.: Both CD8 and CD8 T cells from CD4 KO corneal allograft rejector mice mediated corneal allograft rejection following adoptive transfer to nude mice. CD8 T cells, but not CD8 T cells, from CD4 KO mice adoptively transferred donor-specific DTH and induced apoptosis of BALB/c corneal endothelial cells in vitro. Apoptosis of BALB/c corneal endothelial cells was mediated by double negative (DN) T cells, as treatment of CD8 cells from CD4 KO mice with anti-Thy 1.2 plus complement abolished their effector function. CONCLUSION: The results support the proposition that CD4 T cell-independent rejection of corneal allografts can be mediated by either CD8 or CD8 T cells. The CD8 T cells represent a unique DN T cell population that might mediate rejection by either direct cytolysis or by inducing apoptosis of the donor corneal endothelium.     

Human Skin Xenograft Rejection in CD45 Exon-6 Knockout Mice: The Implication of Involvement of a Direct Pathway

The results of previous studies indicate that only CD4⁺ T cells generated via the indirect pathway play an essential role in causing discordant skin xenograft rejection. The present study was conducted in an attempt to clarify further the roles of effector T cells generated via direct pathways on discordant xenograft rejection using CD45 exon-6 knockout (CD45−/−; C57BL/6 (B6): H-2^b) mice. It has been strongly suggested that CD45 exon-6 knockout mice have profound impairment in T-cell functions via an indirect pathway. When human skin was grafted onto untreated normal C57BL/6 (B6; H-2^b) mice, rejection occurred within 12 days; however, in the CD45 exon-6 knockout mice, the grafts lasted for slightly longer as in fully allogeneic C3H (H-2^k) skin rejection, with a mean survival time ± SD of 19.4 ± 1.5 days and median survival times of 19 days. The difference in survival periods between the human and C3H skin grafts in the CD45 knockout mice was not statistically significant. Both CD4⁺ and CD8⁺ T cells seemed activated in the spleens of these CD45 exon-6 knockout mice 10 days after the human skin grafting. These results suggest that effector T cells generated via a direct pathway can cause discordant skin xenograft rejection, and that CD45 exon-6 knockout mice can generate effector T cells via a direct pathway to reject discordant skin xenografts, similarly to fully allogeneic skin allografts. Received: June 24, 1999 / Accepted: May 30, 2000     

Allograft Rejection in a New Allospecific CD4+ TCR Transgenic Mouse

The application of TCR transgenic mice to transplantation immunology is hampered by the limited lines available. Recently, we reported CD4+ T cell receptor (TCR) transgenic mice specific for I-Abm12 expressed on B6.C.H-2bm12 mice. Here, we characterized rejection of skin and vascularized cardiac allografts in these mice, which we term ABM (for anti-bm12). In vivo proliferative experiments reveal that all CD4 T cells in ABM mice react to bm12 antigens. Surprisingly, while ABM mice have accelerated (compared to B6 recipients) rejection of bm12 skin allografts, they, like B6 recipients, fail to acutely reject bm12 cardiac allografts. This is not due to lack of immunogenicity of bm12 hearts, as these grafts are acutely rejected by primed ABM recipients, although not by primed B6 recipients. Lastly, long-term surviving bm12 grafts in ABM recipients are relatively free from chronic rejection (compared with B6 recipients), which may be due to skewing of the CD4 repertoire towards direct alloreactivity, and consequent lack of CD4 mediated indirect allorecognition as evidenced by the lack of IgG deposition in those grafts. The results indicate that a complex interplay between responder frequency, priming and repertoire dictates the occurrence, or lack thereof, of acute and chronic rejection.     

CD8+ T cells produce RANTES during acute rejection of murine allogeneic skin grafts

BACKGROUND: Based on their chemoattractant properties, it is likely that chemokines play a role in recruiting alloantigen-primed T cells to allografts and in amplifying inflammation within the graft. The graft-infiltrating leukocytes producing specific chemokines remain largely unknown. METHODS: We tested the intragraft RNA expression of the chemokine RANTES (regulated on activation normal T expressed and secreted) and granzyme B during rejection of full thickness, allogeneic skin grafts by C57BL/6 mice. Grafts with different immunogenetic disparities were chosen to test expression when rejection was mediated by CD4+, CD8+, or both CD4+ and CD8+ T cells. RNA expression was also tested in purified CD4+ and CD8+ T cell populations from skin graft recipients. Immunohistology was performed on graft sections to test colocalization of RANTES protein and graft-infiltrating CD4+ and CD8+ T cells. RESULTS: Intra-allograft RANTES RNA expression was not observed during CD4+ T cell-mediated rejection. Expression of RANTES and granzyme B RNA was observed at low levels in purified populations of CD8+, but not CD4+, T cells from the spleen and lymph nodes of graft recipients beginning at day 7 after transplantation and increased thereafter. Intra-allograft RANTES protein was associated with a small number of graft-infiltrating CD8+ T cells but was also associated with endothelial cells and with many graft-infiltrating CD4+ T cells. CONCLUSIONS: CD8+ T cells produce RANTES during allogeneic skin graft rejection. In the allograft, the chemokine also colocalizes with CD4+ T cells that do not produce RANTES.     

Induction of hyperacute rejection of skin allografts by CD8+ lymphocytes

BACKGROUND: Second-set rejection is generally regarded as a phenomenon mainly mediated by humoral cytotoxic antibodies, although a few discordant data have been presented. In the reported experiments, we have taken advantage of the absence of production of specific cytotoxic alloantibodies contrasting with the normal development of transplantation cellular immunity, in two murine models: chimeric mice and RAG mice. METHODS: Chimeras (BALB/c-->CBA) were obtained by transplantation of 2x10(7) fetal liver cells from BALB/c (H-2d) mice to lethally irradiated CBA (H-2k) mice. After hyperimmunization with third-party C57/ BL6 (B6) (H-2b) skin transplants and with injections of 2x10(7) B6 spleen cells, antibody production, and skin graft survival were analyzed. To identify further the factors or cells responsible for accelerated rejection of B6 skin transplants in hyperimmunized chimeras, transfer experiments were carried out involving the injection of serum, whole spleen cells, spleen T cells, spleen CD8+ T cells or spleen CD4+ T cells from chimeras into BALB/c mice that had received 6 Gy irradiation. The recipient mice were then grafted with B6 skin. Similarly, the immunodeficient RAG mice were used to construct a model of recipient animals with anti-H-2d hyperimmunized B6 T cells in the total absence of antibody. RESULTS: In chimeras, anti-B6 cytotoxic antibodies were not detectable in any of hyperimmunized chimeric mice, yet accelerated rejection of B6 skin transplant occurred: a graft survival of 8.6+/-0.5 days (d), comparable to 8.9+/-0.8 d survival in CBA control mice subjected to the same hyperimmunization procedure, and significantly shorter than that in nonhyperimmunized (BALB/c-->CBA) chimeras (11.6+/-0.5 d) or in non-hyperimmunized CBA control mice (12.1+/-0.6 d). High titers of anti-B6 cytotoxic antibodies were present in the serum of hyperimmunized CBA control mice. In transfer experiments, the graft survival was over 14 d in mice treated with irradiation alone, with irradiation + serum or with irradiation + CD4+ T cells. It was significantly shorter in mice treated with irradiation + whole spleen cells, with irradiation + T cells or with irradiation + CD8+ T cells (8.9+/-0.8 d). Similarly, in immunodeficient RAG mice, reconstitution of the T cell compartment with T cells from hyperimmunized B6 mice led to accelerated rejection of BALB/c skin allografts (11.4+/-1.1 d vs. 18.8+/-0.8 d when T cells were provided by nonimmunized mice). In a second transfer of cells from these reconstituted RAG mice into naive RAG mice, CD8+ T cells were shown to induce accelerated rejection of skin allografts (12.0+/-0.6 d) whereas CD4+ T cells were much less efficient (16.5+/-0.1 d). CONCLUSION: These data indicate that T cells, and especially the CD8+ subset, can be responsible for second-set rejection in the absence of anti-donor antibodies in chimeric and RAG mouse models. These sensitized CD8+ T cells are also likely to play an important role in normal mice, in addition to that of cytotoxic antibodies.     

Allograft rejection in CD4+ T cell-reconstituted athymic nude rats--the nonessential role of host-derived CD8+ cells.

PVG-rnu/rnu nude rats reject fully allogenic renal (DA) and skin (BN, AO) allografts after the adoptive transfer of naive CD4+ T cells alone, but rejection is accompanied by the accumulation of many nude-derived CD8+ leukocytes within the graft. In addition, mononuclear cells infiltrating the rejecting renal grafts in these animals display cytotoxic activity in vitro against specific and third-party alloantigens. In this investigation we have treated CD4+ T cell-restored nude rats bearing renal or skin allografts with the mAb MRC OX8 to deplete the host of CD8+ cells. In vivo treatment with OX8 completely eliminated CD8+ cells from rejecting grafts of both kidney and skin, but it did not prevent graft rejection, nor did OX8 treatment abolish the cytotoxic effector cells found in nude rat spleen or in graft-infiltrating cells (GIC) of rejecting renal allografts. The nature of the cytotoxic activity was examined with anti-CD3 mAb 1F4, which was shown to block conventional CD8+ Tc killing in vitro but did not inhibit allogeneic target cell lysis by spleen cells from nude rats. The cytotoxic activity found in GIC of rejecting allografts was not inhibited by anti-CD3 mAb, suggesting that these cytotoxic effector cells were CD3-CD8- and were of extrathymic origin. We conclude that non-thymus-derived CD8+ GIC are not essential for allograft rejection in CD4+ T cell-restored nude rats.     

CD4+ T cells, without CD8+ or B lymphocytes, can reject xenogeneic skin grafts

Abstract: Previous experiments have shown that rejection of xenogeneic skin grafts by mice is particularly dependent on CD4⁺ T cells. There are two possible explantations for this finding: either 1) "help" provided by CD4⁺ T cells is essential for CD8⁺ T cell-, B cell-, or NK cell-mediated effector mechanisms of rejection, or 2) CD4⁺ cells are themselves responsible for rejection, perhaps by some nonspecific effector mechanism. To examine these two hypotheses, we transplanted pig skin onto SCID mice and then reconstituted the mice with selected subpopulations of lymphocytes. Mice that did not received CD4⁺ T cells were unable to reject their xenografts, whereas those receiving CD4⁺ cells could do so in the absence of CD8⁺ cells or B cells and even when additionally depleted of NK cells by treatment with anti-Asialo GM1 antibody. Additional experiments were performed both in vivo and vitro to confirm the absence in test mice of CD4⁺ or CD8⁺ and B lymphocytes, respectively. These results suggest that CD4⁺ T cells are not only necessary for rejection of xenogeneic skin grafts by mice, but that they can do so without CD8⁺ cells or B cells, and probably without NK cells. Since CD4⁺ cells in mice have been shown to recognize xenogeneic antigens indirectly, this suggests that a nonspecific effector mechanism may be involved in the rejection of xenografts. In these experiments allogeneic skin grafts behave quite differently as they could not be rejected by this mechanism.     

Effect of Inflammation on Costimulation Blockade-Resistant Allograft Rejection

Previously, we reported that allogeneic skin grafts were rapidly rejected by CD28 and CD40 ligand double deficient mice mediated by CD8⁺ T cells. These results indicated that some elements in addition to CD28- and CD40-mediated costimulation provide stimulatory signals for the activation of donor-specific CD8⁺ T cells. In this report, we investigated the role of inflammation associated with transplantation on costimulation-independent priming of CD8⁺ T cell during graft rejection. B6 RAG1 KO mice were transplanted with BALB/c-skin and adoptively transferred with syngeneic CD8⁺ T cells the same day or 50 days after transplantation. When blockade of CD28- and CD40-mediated costimulation failed to prevent acute rejection of freshly transplanted skin grafts, it efficiently delayed rejection of well-healed skin grafts. These results showed that factors associated with transplantation have essential roles in inducing costimulation blockade-resistant allograft rejection. Costimulation blockade failed to prevent acute graft-infiltration of NK cells and increasing expression of intragraft IL-12 and IL-15. These factors may trigger the graft-infiltration and priming of CD8⁺ T cells to induce costimulation blockade-resistant allograft rejection.     

Development of autoimmunity after skin graft rejection via an indirect alloresponse

BACKGROUND: T cell allorecognition occurs through direct contact with donor peptide: MHC complexes on graft cells and through indirect recognition of donor-derived determinants expressed by recipient MHC molecules. As both indirect allorecognition and autoantigen recognition are self-restricted, we hypothesized that chronic activation of indirectly primed T cells might result in determinant spreading to involve autoantigens, analogous to that which occurs during chronic autoimmune diseases. METHODS: We placed C57BL/6 MHC II knockout (B6 II-/-) skin grafts onto BALB/c SCID mice reconstituted with wild-type (WT) CD4+ T cells. Under these conditions the CD4+ cells could not recognize any antigen on the graft, but could respond through the indirect pathway. CD4+ cell-mediated rejection of WT B6 skin was studied to determine if autoreactivity was induced after direct allorecognition. Recall immune responses against donor- and self-stimulator cells were determined by ELISPOT and animals were tested for their ability to reject second isografts. RESULTS: WT allografts were rejected by day 14 although B6 II-/- grafts underwent delayed rejection over 4-5 weeks. CD4+ cells reisolated from the recipients of the MHC II-/- grafts, but not from the recipients of WT grafts, vigorously produced interferon-gamma and interleukin-2 in response to self, BALB/c stimulators. These autoreactive CD4+ T cells mediated rejection of a second isogenic BALB/c skin graft, demonstrating that the autoimmune response was pathogenic. CONCLUSION: Autoreactivity can develop after transplant rejection via the indirect pathway. Although the direct alloresponse is likely to be the driving force in acute graft rejection, posttransplantation induced autoimmune responses may be important elements of delayed or chronic rejection.     

CXC趋化因子受体6在小鼠心脏移植排斥反应中的表达及意义

目的 研究CXC趋化因子受体6(CXCR6)在同种异体小鼠心脏移植中的表达及CXC趋化因子配体16(CXCL16)与CXCR6相互作用对移植物存活时间的影响.方法 以野生型Balb/c小鼠(H-2d)为供者(同种移植组),或以野生型C57BL/6小鼠(H-2b)为供者(同系移植组),以野生型C57BL/6小鼠为受者分别行小鼠腹腔异位心脏移植.测定同系和同种移植组小鼠移植心脏CXCR6mRNA的表达,并测定受者脾脏CD8+T淋巴细胞CXCR6的表达.另制作小鼠同种异位心脏移植模型(Balb/c小鼠为供者,C57BL/6小鼠为受者),将其分为实验组和对照组,实验组受者移植当天至发生排斥反应时腹腔注射抗CXCL16抗体,对照组受者同期注射对照抗体.记录两组移植心脏存活时间.进行CD8+T淋巴细胞的细胞毒试验,即用Balb/c小鼠脾细胞免疫C57BL/6小鼠后,获取C57BL/6小鼠脾脏CD8+T淋巴细胞,将Balb/c小鼠脾细胞与C57BL/6小鼠CD8+T淋巴细胞混合培养,分别加入抗CXCL16抗体、小鼠IgG(对照抗体)和抗CD40L抗体.结果 同种移植组移植心脏中CXCR6 mRNA的表达以及脾脏CD8+T淋巴细胞上CXCR6的表达均高于同系移植组和正常对照组.抗CXCL16抗体对CD8+T淋巴细胞的细胞毒活性无影响.与对照组相比较,实验组小鼠移植心脏存活时间并未明显延长.结论 小鼠心脏移植排斥反应中CD8+T淋巴细胞CXCR6的表达上升,阻断CXCL16/CXCR6相互作用并不能延长移植心脏的存活时间.     

CXC趋化因子受体6在小鼠心脏移植排斥反应中的表达及意义

目的 研究CXC趋化因子受体6(CXCR6)在同种异体小鼠心脏移植中的表达及CXC趋化因子配体16(CXCL16)与CXCR6相互作用对移植物存活时间的影响.方法 以野生型Balb/c小鼠(H-2d)为供者(同种移植组),或以野生型C57BL/6小鼠(H-2b)为供者(同系移植组),以野生型C57BL/6小鼠为受者分别行小鼠腹腔异位心脏移植.测定同系和同种移植组小鼠移植心脏CXCR6mRNA的表达,并测定受者脾脏CD8+T淋巴细胞CXCR6的表达.另制作小鼠同种异位心脏移植模型(Balb/c小鼠为供者,C57BL/6小鼠为受者),将其分为实验组和对照组,实验组受者移植当天至发生排斥反应时腹腔注射抗CXCL16抗体,对照组受者同期注射对照抗体.记录两组移植心脏存活时间.进行CD8+T淋巴细胞的细胞毒试验,即用Balb/c小鼠脾细胞免疫C57BL/6小鼠后,获取C57BL/6小鼠脾脏CD8+T淋巴细胞,将Balb/c小鼠脾细胞与C57BL/6小鼠CD8+T淋巴细胞混合培养,分别加入抗CXCL16抗体、小鼠IgG(对照抗体)和抗CD40L抗体.结果 同种移植组移植心脏中CXCR6 mRNA的表达以及脾脏CD8+T淋巴细胞上CXCR6的表达均高于同系移植组和正常对照组.抗CXCL16抗体对CD8+T淋巴细胞的细胞毒活性无影响.与对照组相比较,实验组小鼠移植心脏存活时间并未明显延长.结论 小鼠心脏移植排斥反应中CD8+T淋巴细胞CXCR6的表达上升,阻断CXCL16/CXCR6相互作用并不能延长移植心脏的存活时间.

Abstract：

Objective To investigate the expression of CXCR6 in allograft rejection and effect of CXCL16/CXCR6 interaction on allograft survival Methods Intra-abdominal heterotopic heart transplantation was performed using wild type (WT) Balb/c mice (H-2d) (allogeneic) as donors or WT C57BL/6 mice (B6, H-2b) (syngeneic) as donors, and using WT B6 mice as recipients. The intragraft expression of CXCR6 and expression of CXCR6 in CD8+ T cells of the spleens from syngeneic and allogeneic recipients were examined. The allogeneic recipients were further divided into the experimental group (n = 5) and control group (n = 6) randomly. The experiment group and control group were injected with anti-CXCL16 mAb or control mAb respectively until rejection occurred. The cardiac allograft survival in experimental group and control group was evaluated. Results Rejected allografts showed higher expression of CXCR6 than syngeneic cardiac grafts. More importantly,expression of CXCR6 in CD8+ T cells was also up-regulated by allograft rejection. However, injection of anti-CXCL16 mAb could not inhibit cytotoxic activity of CD8+ T cells. Moreover, experimental group could not prolong the cardiac graft survival time as compared with control group. Conclusion Expression of CXCR6 in CD8+ T cells is up-regulated in allograft rejection.     

CXC趋化因子受体6在小鼠心脏移植排斥反应中的表达及意义

目的 研究CXC趋化因子受体6(CXCR6)在同种异体小鼠心脏移植中的表达及CXC趋化因子配体16(CXCL16)与CXCR6相互作用对移植物存活时间的影响.方法 以野生型Balb/c小鼠(H-2d)为供者(同种移植组),或以野生型C57BL/6小鼠(H-2b)为供者(同系移植组),以野生型C57BL/6小鼠为受者分别行小鼠腹腔异位心脏移植.测定同系和同种移植组小鼠移植心脏CXCR6mRNA的表达,并测定受者脾脏CD8+T淋巴细胞CXCR6的表达.另制作小鼠同种异位心脏移植模型(Balb/c小鼠为供者,C57BL/6小鼠为受者),将其分为实验组和对照组,实验组受者移植当天至发生排斥反应时腹腔注射抗CXCL16抗体,对照组受者同期注射对照抗体.记录两组移植心脏存活时间.进行CD8+T淋巴细胞的细胞毒试验,即用Balb/c小鼠脾细胞免疫C57BL/6小鼠后,获取C57BL/6小鼠脾脏CD8+T淋巴细胞,将Balb/c小鼠脾细胞与C57BL/6小鼠CD8+T淋巴细胞混合培养,分别加入抗CXCL16抗体、小鼠IgG(对照抗体)和抗CD40L抗体.结果 同种移植组移植心脏中CXCR6 mRNA的表达以及脾脏CD8+T淋巴细胞上CXCR6的表达均高于同系移植组和正常对照组.抗CXCL16抗体对CD8+T淋巴细胞的细胞毒活性无影响.与对照组相比较,实验组小鼠移植心脏存活时间并未明显延长.结论 小鼠心脏移植排斥反应中CD8+T淋巴细胞CXCR6的表达上升,阻断CXCL16/CXCR6相互作用并不能延长移植心脏的存活时间.