Evidence that epidermal alloantigen Epa-1 is an immunogen for murine heart as well as skin allograft rejection

Epa-1 is a non-H-2 mouse alloantigen defined by MHC-restricted, CD8+ cytotoxic T cells. In vitro it is a strong determinant for the lysis of epidermal cells, fibroblasts, and macrophages but not lymphocytes, and in vivo it functions as a target for skin allograft rejection and cutaneous graft-versus-host reactions. Genetically, Epa-1 appears to be the nonpolymorphic manifestation of a loss mutation. The establishment of C3H.Epa-1 (Epa), an Epa-1+ congenic strain on the Epa-1- C3H/HeJ (C3H) inbred strain background, facilitated the investigation of the role of Epa-1 in skin and heart allograft rejection. C3H females and males rejected first-set Epa skin grafts with median survival times (MSTs) of 20 and 30 days, respectively. However, there was a strong factor of immunization, because all second-set skin allografts were rejected by hosts of both sexes within 10 days. In contrast, all Epa hosts of both sexes permanently accepted C3H skin allografts, consistent with Epa-1 arising from a loss mutation. C3H hosts of both sexes rejected primarily vascularized first-set Epa heart allografts in similar tempo to first-set Epa skin allografts, with MSTs of about 30 days. However, in contrast to the accelerated rejection of skin allografts, sensitized C3H hosts rejected Epa heart allografts in chronic fashion, with some transplants showing very prolonged survival. Thus, Epa-1 is a relatively strong determinant of skin allograft rejection but a weaker determinant of heart allograft rejection.     

Blocking of interleukin-2 production, but not the tissue destruction induced by cytotoxic T cells, by cyclosporine

Cytotoxic T lymphocytes generated against epidermal alloantigen-1 (Epa-1), a tissue-restricted, non-H-2 alloantigen that is a target-cell determinant of both skin allograft rejection and cutaneous graft-versus-host reactions, directly produce full-thickness ulcerative skin lesions in Epa-1+ mice. Anti-Epa-1 CTL also indirectly cause extensive damage of "innocent bystander" tissue when injected admixed with Epa-1+ target cells into the skin of Epa-1- hosts. Unlike the direct destruction of host tissue by CTL in "immune lymphocyte transfer reactions" (TrR), "bystander reactions" (ByR) apparently are initiated by the release of lymphokines that recruit host inflammatory cells to the injection site. Treatment of CTL with cyclosporine in vitro prevents their production of lymphokines like interleukin 2 but has no effect on cell-mediated cytotoxicity. However, little is known about the function of CsA-treated CTL in vivo. We confirmed the differential effect of CsA on CTL function in vitro with bulk-culture anti-Epa-1 CTL-CsA pretreatment of CTL abrogated IL-2 production but did not affect CMC. Moreover, we found that CsA pretreatment did not affect the ability of CTL to evoke TrR, nor did it significantly impair their ability to mediate ByR. Therefore, when CTL are treated with CsA in such a way that they lose their capacity to produce IL-2, their cytotoxic activity in vitro as well as their ability to directly and indirectly mediate tissue destruction in vivo are left intact. These results suggest that the ability of CTL to mediate allograft rejection is not dependent on their ability to produce IL-2 and that CMC plays a role in the rejection process.     

Mediation of skin allograft rejection in scid mice by CD4+ and CD8+ T cells.

We analyzed the role of CD4+ and CD8+ T cells in H-2-disparate skin allograft rejection in the mutant mouse strain C.B-17/Icr scid with severe combined immunodeficiency. On the day of skin allografting, scid mice were adoptively transferred with negatively selected CD4+ or CD8+ splenocytes from normal unsensitized C.B-17/Icr mice. These populations were obtained using a double-mAb--plus--complement elimination protocol using anti-CD4 or anti-CD8 mAb that resulted in no detectable CD4+ or CD8+ cells by FACS and negligible numbers of cytolytic T lymphocytes by limiting dilution analysis in anti-CD8 treated populations. Spleen cells were removed from grafted mice at the time of rejection and were tested in vitro for antidonor reactivity in several assays: mixed lymphocyte culture, cell-mediated lympholysis, and LDA for CTL and for IL-2-producing HTL. The presence of Thy 1.2+, CD4+, or CD8+ cells was determined by FACS. All control C.B-17 mice and scid mice adoptively transferred with nondepleted CD4+, and CD8+ cells rejected skin allografts with similar mean survival times (15.6 +/- 1.5, 18.8 +/- 3.4, 18.0 +/- 5.4, respectively), whereas control scid mice retain skin allografts indefinitely (all greater than 100 days). C.B-17 syngeneic grafts survived indefinitely in all groups. At the time of rejection, splenocytes from scid mice receiving CD4+ cells had negligible donor-specific cytotoxicity in CML and negligible numbers of CTL by LDA, but demonstrated a good proliferative response in MLC and IL-2-producing cells by LDA (frequency = 1/1764). There were no detectable CD8+ cells present by FACS analysis. Conversely, splenocytes from scid mice adoptively transferred with CD8+ cells had strong donor-specific cytotoxicity in CML (58.8% +/- 16.1%) and CTL by LDA (frequency = 1/3448), but no significant proliferation was detected in MLC. There were no detectable CD4+ cells by FACS, but there were small numbers of IL-2-producing cells by LDA (frequency = 1/10,204). These data demonstrate that CD4+ cells adoptively transferred into scid mice are capable of mediating skin allograft rejection in the absence of any detectable CD8+ cells or significant functional cytolytic activity. The adoptive transfer of CD8+ cells also results in skin allograft rejection in the absence of detectable CD4+ cells. The detection of small numbers of IL-2 secreting cells in these mice may indicate that CD(8+)-mediated allograft rejection in this model is dependent on IL-2-secreting CD8+ cells.     

Clonal analysis of the lymphoid cells mediating skin allograft rejection. Mediation of graft rejection in vivo by cloned Lyt-1+2- proliferative, noncytotoxic long-term cell lines

Studies were undertaken to elucidate the cellular basis of skin allograft rejection mediated by long-term cultured cell lines and clones. The adoptive transfer, in vivo, of in-vitro-sensitized cells, from B6AF1 anti B10.BR or from C57BL/6 anti DBA/2 cultures, and expanded eight-fold to ten-fold for one week in lectin-free interleukin 2 (LF-IL-2) were able to mediate specific skin allograft rejection. These same cells lost the ability to mediate accelerated skin graft rejection when they were expanded more than 100-fold during three weeks of culture in LF-IL-2 even though these cultures mediated high levels of specific in vitro cytotoxicity for the appropriate allosensitizing cells. When Lyt-2+ cells were depleted using monoclonal antibodies and complement prior to in vitro sensitization and expansion in LF-IL-2, these cells lines retained the ability to mediate skin allograft rejection in vivo when expanded more than 100-fold for three culture generations in vitro. These latter lines were greatly enriched for Lyt-1+2- cells and had little or no cytolytic activity, but they retained specific in vitro proliferative responses to the sensitizing alloantigen. Several Lyt-1-2+ cloned long-term lymphoid cell lines with high levels of specific cytolytic activity against the sensitizing alloantigen were derived and none was capable of mediating the accelerated rejection of skin grafts in vivo. However, cloned lymphoid cell lines that were phenotypically Lyt-1+2- and were capable of proliferating when in contact with specific alloantigen, but were not cytolytic, were capable of mediating the accelerated rejection of skin grafts in vivo both in irradiated mice and in nude mice. These studies demonstrate that skin allograft rejection can be mediated by Lyt-1+2- cell lines with specific in vitro proliferative activity to alloantigen although Lyt-1-2+ cell lines with cytolytic but not proliferative activity to alloantigen in vitro are ineffective in mediating graft rejection in vivo. Specific proliferative activity and no cytolysis appears to be a good in vitro correlate of the in vivo activity of long-term cultured cell lines.     

Evidence that large granular lymphocytes of donor origin mediate acute graft-versus-host disease

We have studied the phenotype of mononuclear cells infiltrating target organs of mice with acute graft-versus-host disease after bone marrow transplantation from H-2-identical donors. Infiltrating mononuclear cells with characteristics of large granular lymphocytes (LGL) were frequently found in close association with dead or dying epithelial cells in the skin, liver, and colon. The phenotype of these putative effector cells was Thy-1+, ASGM1+, Mac-1+, Lyt-1-, Lyt-2-, Ia-, which is characteristic of LGL. Differences in the Thy-1 allele between donor and host were used to demonstrate that these cells were of donor origin. Analysis of cytolytic function in GVHD splenocytes indicated high natural killer activity and low cytolytic T lymphocyte (CTL) activity. These findings suggest that an important effector cell in systemic acute graft-versus-host disease is a large granular lymphocyte of donor origin.     

Allograft tolerance induction in adult mice associated with functional deletion of specific CTL precursors

Rejection of H-2 class I bm 1 mutant skin allografts by B6 recipient mice is mediated by a population of CD8+ anti-bm1 cytotoxic T-lymphocytes that produces and consumes its own T helper factor in response to bm1 skin allografts (dual function CTL). Previously we have demonstrated that transfusion of allogeneic lymphocytes across an H-2 class I disparity induces specific long-lasting skin allograft survival. We now show that intravenous injection of allogeneic spleen cells across the bm1 mutant disparity results in a temporary decrease of donor-reactive CTLp in the spleen of recipient mice, lasting for approximately five weeks. The sponge matrix allograft model was used to show that allograft tolerance is caused by a specific functional clonal deletion of CTLp within the allograft. We propose that dual function CTL are vetoed by donor T cells, resulting in skin allograft tolerance.     

Regulatory function of human CD4+ cytolytic T lymphocytes.

Allograft rejection is mediated by both CD4+ and CD8+ T cells. The lytic function of the classic CD8+ cytolytic T lymphocytes (CTL) occurs through recognition of allogeneic major histocompatibility complex (MHC) class I on the surface of the graft. CD4+ CTL recognize MHC class II through a direct recognition pathway or an indirect pathway where MHC peptides are presented in the context of self MHC class II. Lytic CD4+ cells may destroy graft tissue or, we hypothesize, the indirect CD4+ T cell may down regulate CD8+ CTL by recognition of donor MHC peptides presented by self MHC class II expressed on CD8+ T cells. To define the role of CD4+ CTL in allograft outcome we used a CD4+ CTL that is MHC class II restricted, recognizing human leucocyte antigen (HLA)-A1 and HLA-B8 peptides in the context of HLA-DR4. This line (MDSxA1/B8) will lyse DR4+ B lymphoblastoid cells (LCL) pulsed with HLA-A1/B8 peptides (amino acids 60-84 of the alpha1 domain of the MHC class I molecule). These T cells will also lyse peptide-pulsed antigen-specific T cell clones, both CD4+ and CD8+, that express HLA-DR4. These clones must process and present the MHC class I peptides for recognition and lysis to occur. These results suggest a possible mechanism to explain allograft tolerance. Lytic CD4+ T cells, that recognize donor HLA peptides through an indirect antigen presentation pathway, down-regulate donor-specific CTL through peptide-specific lysis resulting in graft tolerance.     

Inhibition of rat skin allograft rejection by cyclosporine. In situ characterization of the impaired local immune response

Cyclosporine (CsA) is known to induce long-term survival of skin allografts, although the cellular mechanisms responsible for this effect are not well understood. To further define the effects of CsA-induced immunosuppression, we performed a morphological and immunohistological study of acute skin allograft rejection in the rat, comparing untreated and CsA-treated animals. Three significant differences were found between grafts in CsA-treated and untreated rats. First, CsA-allografts contained fewer MRC OX-8+ cytotoxic T cells than untreated allografts. Second, although the presence and numbers of infiltrating macrophages (W3/25+, W3/13- cells) was not influenced by CsA treatment, CsA treatment blocked expression of a macrophage membrane activation antigen, defined by the monoclonal antibody A1-3, which has previously been linked with development of macrophage procoagulant activity (PCA). Third, diminution in MRC OX-8+ lymphocytes and A1-3+ macrophages in CsA allografts was associated with an absence of the widespread thrombotic and necrotizing microvascular injury typical of acute rejection in untreated rats. We conclude that prolongation of skin allograft survival by CsA is related to its ability to prevent cell mediated injury to the endothelium of graft vessels, and possibly also to inhibition of macrophage PCA with consequent reduced thrombus formation.     

Skin allograft rejection by L3/T4+ and Lyt-2+ T cell subsets

The L3/T4+ and Lyt-2+ T-cell subsets can be depleted from mice, using selected monoclonal antibodies in vivo, at different times during rejection of, or priming to, allogeneic skin grafts. Although L3/T4+ cells are sufficient to reject skin grafts in naive Lyt-2-depleted mice, we show that Lyt-2+ cells can become involved, after an initial delay, in intact mice. Furthermore, these Lyt-2+ cells are primed to dominate the accelerated rejection of a normal secondary response. Mice depleted of L3/T4+ cells cannot be primed in this way, suggesting that priming of Lyt-2+ cells is dependent on help from L3/T4+ cells. However, in mice depleted of Lyt-2+ cells, priming for rapid rejection can be achieved, presumably via the L3/T4+ population. This suggests that the rejection of skin allografts in a given situation reflects different contributions of multiple effector mechanisms.     

Mobilization of T lymphocytes following cardiac transplantation. Evidence that CD4-positive cells are required for cytotoxic T lymphocyte activation, inflammatory endothelial development, graft infiltration, and acute allograft rejection.

Modified limiting dilution analysis (LDA) techniques were used to evaluate the mobilization of antigen-stimulated helper T lymphocytes (HTL) and cytotoxic T lymphocytes (CTL) following allogeneic heterotopic cardiac transplantation. These modified LDA techniques allow a quantitative comparison of T cells that have been stimulated by antigen in vivo versus unstimulated precursor T cells of the same antigen specificity. Endothelial changes associated with mononuclear cell infiltration of the transplant were studied using endothelia-specific monoclonal antibodies and immunohistochemistry. Early (day 3) infiltration of cardiac allografts was characterized by a prevalence of donor alloantigen-specific HTL over CTL. Immunohistology revealed that the day-3 infiltrate was associated with areas of differentiated vascular endothelium, located primarily in the subepicardial region. Though donor-specific precursor HTL and CTL were present in the peripheral lymphoid tissues and blood, very few of them had been stimulated at this early time. During the latter phases of the response (days 6-9), antigen-stimulated HTL and CTL were present in the rejecting heart with CTL dominating the response. Accumulation of large numbers of donor-specific CTL in the allograft correlated with extensive inflammatory endothelial development, myocyte destruction, and loss of graft function by day 9. Stimulated HTL and CTL were detectable in peripheral lymphoid tissues at days 6 and 9. In addition, a marked increase in the number of donor-specific precursor CTL, but not precursor HTL, was observed in the lymphoid tissues at the peak of the response. Depletion of class II MHC-restricted T cells by in vivo treatment with anti-CD4 mAb eliminated HTL activity in all lymphoid compartments assessed and markedly reduced the number of CTL infiltrating the allograft. In addition, no stimulated CTL were detectable in lymphoid tissues, and the number of precursor CTL was not increased. In anti-CD4-treated recipients, cardiac allografts remained functional with minimal histological evidence of rejection for at least 21 days. Though graft-associated inflammatory endothelia were absent in anti-CD4-treated recipients at day 6, endothelial differentiation was observed in day 21 allografts in anti-CD4-treated recipients. These observations indicate that inflammatory endothelial development may precede T cell infiltration and subsequent loss of the cardiac allograft function. Thus, CD4-positive HTL are required for (1) graft-associated inflammatory endothelial development; (2) CTL activation in peripheral lymphoid tissues; (3) CTL accumulation in allografted tissues; and (4) acute cardiac allograft rejection.     

The role of TDTH and Tc populations in organ graft rejection. I. Functional analysis of graft-infiltrating T cells

To analyze the role of T cell subpopulations in the rejection of organ allografts, we developed a new model for obtaining large numbers of graft infiltrating cells (GICs). We isolated W3/25+ Th/DTH and OX8+ Ts/c from vascularized, irradiated rat spleen allografts. W3/25+ GICs obtained from spleen allografts transplanted to normal recipients were highly effective in eliciting cardiac allograft rejection when transferred to sublethally irradiated recipients, however, the OX8+ subset was incapable of eliciting rejection. On the other hand, when OX8+ GICs were obtained from spleen allografts transplanted to previously immunized recipients, they were as efficient as the W3/25+ Th/DTH subset in eliciting cardiac allograft destruction. These results indicate that the W3/25+, OX8- T cell is required for the rejection of primary organ allografts, but that the rejection of a secondary allograft by an immune recipient may be mediated, independently, by both W3/25+ and OX8+ cells.     

An immunodominant minor histocompatibility alloantigen that initiates corneal allograft rejection

BACKGROUND: Murine orthotopic corneal allografts experience immune privilege and have good survival as compared with skin allografts. However, privilege is not complete, and some grafts are still rejected. Unexpectedly, corneas expressing minor histocompatibility (H) alloantigens are rejected at a higher rate than major histocompatibility complex (MHC) disparate grafts. We hypothesize that certain immunodominant minor H alloantigens are extremely immunogenic when expressed in corneal tissue, terminate ocular immune privilege, and initiate corneal allograft rejection. METHODS AND RESULTS: Corneal allograft survival and the role of CD4+ T cells and CD8+ T cells were examined in corneal transplants that expressed genetically defined minor H3 alloantigens. The H3 locus contains at least two minor H genes. H3a is presented by MHC class I and recognized exclusively by CD8+ T cells. H3b is presented by class II and recognized exclusively by CD4+ T cells. Congenic strains that differ from C57BL/10 at (1) H3a, (2) H3b, or (3) H3a+H3b were used for orthotopic corneal and skin transplants. Donor corneas expressing either H3a or H3a+H3b experienced immune privilege and survived longer than skin allografts. By contrast, donor corneas expressing H3b (recognized by CD4+ T cells) experienced vigorous rejection and were eliminated faster than skin allografts. CONCLUSION: There are minor H alloantigens that terminate ocular immune privilege and initiate corneal allograft rejection. These minor H alloantigens are more immunogenic when expressed in corneal tissue than when they are expressed in skin allografts.     

Cellular pathways for rejection of class-I-MHC--disparate skin and tumor allografts

We have investigated the relative roles of the Lyt-2+ and L3T4+ T lymphocyte subsets in rejection of class-I-MHC-antigen-disparate skin and tumor allografts. To deplete T cells in vivo, rat anti-Lyt-2 or anti-L3T4 monoclonal antibodies (mAb) were administered to adult-thymectomized (ATX) recipient mice prior to transplantation. BALB/c (H-2d) recipient mice rejected the Ia- Sarcoma I (Sa1) (H-2a) tissue culture-derived tumor after depletion of the L3T4+ T cell subset in vivo. In contrast, depletion of the Lyt-2+ T cell subset permitted lethal tumor growth in all recipient mice. To determine the role of particular T cell subsets in rejection of Ld class-I-MHC-antigen-disparate allografts, BALB/c skin was transplanted to BALB/c-H-2dm2 recipient mice. Skin grafts were rejected by control mice with a mean survival time (MST) of 14.5 days. The MST of skin grafts for mice treated with anti-L3T4 mAb was 16.6 days. In contrast, administration of anti-Lyt-2 mAb alone (MST = greater than 47 days) or together with anti-L3T4 mAb (MST = greater than 50 days) caused prolonged or indefinite graft survival in all recipient mice. Depletion of specific T cell subsets was confirmed by flow cytometric analysis and by analysis of T cell function in vitro. These results suggest that Lyt-2+ T lymphocytes are essential for rejection of class-I-MHC-disparate allografts; indirect presentation of alloantigen to L3T4+ T cells may not be necessary for rejection.     

The role of leucyl-leucine methyl ester-sensitive cytotoxic cells in skin allograft rejection.

Treatment of murine spleen cells (SpC) with L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) depletes L3T4(+) and Lyt2(+) cytotoxic T lymphocyte precursors and the capacity to generate lethal graft-versus-host disease in semiallogeneic class I + II MHC and multiple non-MHC-disparate recipient mice, whereas T helper cell function is preserved. In the present studies the role of Leu-Leu-OMe-sensitive CTL in skin graft rejection was examined. C57BL/6J (B6) mice were serially thymectomized, lethally irradiated, reconstituted with T cell-depleted bone marrow, and treated with intraperitoneal injections of anti-L3T4 and anti-Lyt2 monoclonal antibodies. These adult thymectomized, bone marrow-reconstituted, T cell-depleted (ATXBM, TCD) mice were unable to reject B6xDBA/2F1 (B6D2F1) skin grafts. When such ATXBM, TCD mice were reconstituted with 7 x 10(7) control B6 SpC, acute rejection of B6D2F1 skin was observed. When B6 donor SpC were Leu-Leu-OMe-treated prior to transfer to ATXBM, TCD mice, uniform rejection of B6D2F1 skin grafts was still observed, although a significant delay in the time to rejection was observed. More rigorous T cell depletion of ATXBM, TCD host mice by infusion of antithymocyte globulin did not prevent delayed rejection of B6D2F1 skin initiated by transfer of Leu-Leu-OMe-treated B6 SpC. Despite the lack of complete prevention of skin allograft rejection, Leu-Leu-OMe treatment of B6 donor cells prevented lethal GVHD even in thymectomized B6D2F1 recipients. Precursors of anti-B6D2F1-specific CTL were greatly reduced or undetectable in unreconstituted ATXBM, TCD mice or in irradiated B6D2F1 recipients of Leu-Leu-OMe-treated B6 SpC. By contrast, ATXBM, TCD recipients of Leu-Leu-OMe-treated B6 SpC were found to contain a population of anti-class I MHC-specific CTL precursors of host origin within 28 days of reconstitution. These findings have indicated a number of features of the cells involved in skin graft rejection. First, Leu-Leu-OMe-sensitive CTL play a major role in acute rejection of class I + II MHC and multiple non-MHC antigen-disparate skin grafts. Moreover, the thymus-independent expansion of host-derived CTL precursors in ATXBM, TCD mice reconstituted with syngeneic Leu-Leu-OMe-resistant T helper cells also appears to play a role in mediating rejection of allogeneic skin grafts.     

T cell subsets required for in vivo and in vitro responses to single and multiple minor histocompatibility antigens.

The requirement for helper T cells in the in vivo and in vitro T cell response to a diverse panel of minor histocompatibility antigens in mice was investigated. Target H antigens included: (a) multiple antigens distinguishing H-2-matched, inbred strains, and (b) single H antigens, including H-4, H-3, and the male-specific (H-Y) antigen. The involvement of helper T cells in skin allograft rejection and CTL priming was evaluated by pretreating graft recipients with anti-CD4 antibody. Anti-CD4 treatment had no effect on rejection of H-3- and H-4-incompatible skin grafts, but slowed rejection of male and BALB.B skin grafts. Comparable pretreatment with anti-CD4 antibody in vivo eliminated the priming of H-4-specific CTL, multiple B10.BR anti-CBA/J CTL, and all but a minor C57BL/6 anti-BALB.B CTL population. However, CTL specific for the two classes of H antigens, single and multiple minor H antigens, differed in their in vitro requirements for CD4+ helper T cells: (a) multiple antigen-specific CTL required CD4+ helper T cells for optimal expansion, and (b) CTL specific for single H antigens expanded in the absence of helper T cells. The CTL specific for all tested H antigens were CD8+ T cells. These results suggest that CD4+ helper T cells are not always required for effective skin allograft rejection or CTL expansion in vitro; the requirement for helper T cells is apparently dependent upon the identity of the stimulatory minor H antigen(s). This variable dependency contrasts with the evident requirement for helper T cells in the in vivo priming of CTL specific for minor H antigens.     

The Immunobiology of Inductive Anti-CD40L Therapy in Transplantation: Allograft Acceptance is Not Dependent Upon the Deletion of Graft-Reactive T Cells

CD40–CD40L costimulatory interactions are crucial for allograft rejection, in that treatment with anti‐CD40L mAb markedly prolongs allograft survival in several systems. Recent reports indicate that costimulatory blockade results in deletion of graft‐reactive cells, which leads to allograft tolerance. To assess immunologic parameters that were influenced by inductive CD40–CD40L blockade, cardiac allograft recipients were treated with multiple doses of the anti‐CD40L mAb MR1, which was remarkably effective at prolonging allograft survival. Acute allograft rejection responses such as IL‐2 producing helper cell priming, Th1 priming, and alloantibody production were abrogated by anti‐CD40L treatment. Interestingly, the spleens of mice bearing long‐term cardiac allografts following inductive anti‐CD40L treatment retained precursor donor alloantigen‐reactive CTL, IL‐2 producing helper cells, and Th1 in numbers comparable to those observed in naïve mice. These mice retained the ability to reject donor‐strain skin allografts, but were incapable of rejecting the original cardiac allograft, or a second donor‐strain cardiac allograft. Further, differentiated effector cells were incapable of mediating rejection following adoptive transfer into mice bearing long‐term allografts, suggesting that regulatory cell function, rather than effector cell deletion was responsible for long‐term graft acceptance. Collectively, these data demonstrate that inductive CD40–CD40L blockade does not result in the deletion of graft‐reactive T cells, but induces the maintenance of these cells in a quiescent precursor state. They further point to a tissue specificity of this hyporesponsiveness, suggesting that not all donor alloantigen‐reactive cells are subject to this regulation.     

Asialo GM1 positive CD8+ T cells induce skin allograft rejection in the absence of the secondary lymphoid organs

BACKGROUND: Secondary lymphoid organs are considered to be the only organs in which APCs and na?ve T cells interact to initiate adaptive immune responses. Aly/aly mice are autosomal recessive mutants of C57BL/6 mice, and lack lymph nodes and Peyer's patches. In this study, we investigated immune responses to skin allografts in splenectomized aly/aly mice, which lack secondary lymphoid organs completely, and examined the effect of anti-asialo GM1 (AsGM1) antibodies on these responses. METHODS: Skin allografts were transplanted to 1) heterozygous aly/+ mice, which had normal secondary lymphoid organs, 2) splenectomized aly/+ mice, 3) aly/aly mice, and 4) splenectomized aly/aly mice, with and without anti-AsGM1 antibody treatment. Graft survival time and alloreactive antibody production were investigated. RESULTS: Heterozygous aly/+ mice and splenectomized aly/+ mice rejected skin allografts acutely. Aly/aly mice also rejected skin allografts, but at a later time than aly/+ mice. Sixty percent of splenectomized aly/aly mice rejected skin allografts within 120 days. Serial administration of anti-AsGM1 antibodies prevented skin allograft rejection in splenectomized aly/aly mice during the same 120-day period of observation. After ceasation of anti-AsGM1 antibody treatment, skin allografts were rejected; we observed a simultaneous increase in AsGM1 expression on CD8+ T cells. Alloreactive antibodies were detected in both splenectomized aly/aly mice that rejected skin allografts and in splenectomized aly/aly mice that accepted skin allografts after treatment with anti-AsGM1 antibodies. CONCLUSIONS: Cytotoxic and humoral immune responses to skin allografts could be initiated despite the absence of secondary lymphoid organs. AsGM1+ cells were important effector cells in secondary lymphoid organ-independent skin allograft rejection.     

CD4+ T cells are critical for corneal, but not skin, allograft rejection

BACKGROUND: The relative contribution of CD4+ or CD8+ T cells in allograft rejection remains to be fully characterized. Some reports indicate that there is an absolute requirement for CD4+ T cells in allogeneic rejection, whereas others report that CD4-depleted mice are capable of rejecting certain types of allografts. METHODS: We compared the ability of CD4- knockout (KO), CD8- KO, and normal CD4+/CD8+ mice to reject allogeneic corneal or skin grafts. We also examined delayed-type hypersensitivity and CTL responses to donor alloantigens. RESULTS: Engraftment of C57BL/6 corneas to C.B6-(n5-7) CD4-KO mice resulted in significantly higher rates of acceptance (>85%) than either C.B6-(n5-7) CD8- KO (30%) or normal BALB/c mice (40%). Likewise, mean survival times for B6 skin grafts placed on C.B6-(n5-7) CD4- KO mice (29.2 +/- 3.5 days) were significantly increased over those of normal BALB/c mice (13.2 +/- 1 days), although most CD4- KO mice (70%) eventually reject their grafts. C.B6-(n5-7) CD4- KO mice that reject allogeneic grafts fail to develop a delayed-type hypersensitivity response, but they did demonstrate significantly greater cytotoxic T lymphocyte precursor (CTLp) frequencies than did CD4- KO mice that accepted such grafts or that were not grafted. CONCLUSIONS: This study indicates that mice lacking CD4+ T cells have a significantly impaired ability to reject corneal allografts, but are able, in most cases, to reject allogeneic skin grafts. Thus, in the absence of CD4+ T cells, the likely mechanism for rejection appears to involve the generation of CD8+ CTLs.     

Antigenicity of venous allografts.

With isolated exceptions, the clinical use of venous allografts has been disappointing. Considerable evidence indicates that allograft antigenicity plays a major role in the failure of venous allografts when used as arterial replacements. Recent reports suggest that DMSO-cryopreservation of venous allografts may reduce allograft antigenicity while preserving allograft viability. The present study examines the effect of modifications of vein allografts on subsequent allograft antigenicity. Skin grafts were transplanted from ACI to Lewis inbred strains of male rats. Primary skin graft rejection occurred in 9.0 +/- 1.0 days. Subcutaneous implantation of fresh inferior vena cava from ACI rate into Lewis rats resulted in subsequent skin graft rejection in 5.0 +/- 1.0 days, confirming the antigenicity of venous tissue. Cryopreservation of ACI inferior vena cava for seven days prior to implantation, with or without 15% DMSO, resulted in subsequent skin graft rejection in 5.0 +/- 1.0 days. Treatment of ACI inferior vena cava with 0.30% gluteraldehyde for 20 minutes prior to implantation in Lewis rats resulted in skin graft rejection in 9.0 +/- 1.0 days, the same time as a first set rejection. This study indicates that unmodified veins are normally antigenic and that this antigenicity is not eliminated by cryopreservation with or without DMSO. Gluteraldehyde treatment appears to reduce allograft antigenicity, but results in a nonviable graft. At the present time, there is no known way to reduce the antigenicity of viable venous allografts.