Comparison of Abeta(b-/-), H2-DM(-), and CIITA(-/-) in second-set skin allograft rejection.

BACKGROUND: Responses against donor MHC antigens are the major contributor to allograft rejection. Currently, it is unclear whether both direct and indirect recognition pathways are necessary and/or sufficient for allograft rejection. Previously, we found donor MHC class II and H2-DM to have dramatic effects on cardiac allograft survival. METHODS: Here, we used H2-DM(-) mice, which express CLIP-MHC class II complexes, and CIITA(-/-) mice, which lack all class II proteins, to examine the role of direct and indirect recognition on skin allograft rejection. Recipients were primed with donor cultured keratinocytes and later tested for accelerated memory response by challenge with full-thickness tail skin grafts. RESULTS: As previously reported, Abeta(b-/-) grafts survived longer than wild-type grafts, while H2-DM(-) grafts were rejected as rapidly as wild-type grafts. Skin grafts deficient for both beta2m and H2-DM survived longer than grafts lacking only H2-DM, but not as long as Abeta(b-/-) grafts. Additionally, CIITA(-/-) grafts survived as long as Abeta(b-/-) grafts. CONCLUSIONS: The delayed rejection of Abeta(b-/-) compared to H2-DM(-) suggests that indirect recognition of surface-expressed donor MHC class II is sufficient to mediate rapid skin allograft rejection. The equivalent survival of CIITA(-/-) and Abeta(b-/-) grafts suggests that indirect presentation of donor class II molecules (Aalpha or Ebeta) present in Abeta(b-/-) but not CIITA(-/-) mice does not contribute to graft rejection. These results reveal a modest role for surface-expressed donor class II in primed keratinocyte rejection, but also reveal a dramatic contrast to the cardiac allograft system and indicate tissue/organ-specific mechanisms of rejection.     

Intrathymic immunomodulation in sensitized rat recipients of cardiac allografts: requirements for allorecognition pathways.

BACKGROUND: Intrathymic injection of alloantigen in the form of donor cells, soluble major histocompatibility complex (MHC) molecules, or MHC allopeptides induces donor-specific tolerance in a variety of acute allograft rejection models. We have previously shown that a single intrathymic injection of donor spleen cells into pre-sensitized rats abrogates accelerated (circa 24-hour) rejection and prolongs the survival of cardiac allografts to about 7 days. The present study was designed to investigate the mechanisms by which intrathymic administration of donor cells modifies the course of accelerated rejection. METHODS: Lewis RT1(1) (LEW) rats sensitized by transplantation with Wistar-Furth RT1(u) (WF) skin grafts received WF cardiac allografts 7 days later-a classic model of accelerated rejection. At the time of skin challenge, however, certain animals received intrathymic cell suspensions (either allogeneic or syngeneic) or donor-derived class I and/or class II MHC peptides. RESULTS: Control animals (sensitized by skin grafts but receiving no other treatment) rejected cardiac allografts within 24 hours. Intrathymic injection of WF splenocytes at the time of skin transplantation abrogated rejection at 24 hours and prolonged cardiac allograft survival to 6.6+/-0.6 days (p<0.001), whereas intrathymic administration of syngeneic (LEW) or allogeneic third party Brown Norway RT1(n) cells was ineffective in this regard. Intrathymic injection of gamma-irradiated donor cells marginally extended cardiac allograft survival to 3.0+/-0.9 days (p< 0.001), but the grafts were still rejected in an accelerated fashion. Intrathymic injection of donor-derived class I and/or class II MHC allopeptides at the same time period also failed to prolong cardiac allograft survival beyond 3 days. In the group receiving unmodified donor cells, elevated immunoglobulin M (IgM) and immunoglobulin G (IgG) allo-antibodies were found at the time of cardiac transplantation; this pattern was not observed with any other treatment. CONCLUSION: The superiority of non-modified donor spleen cells over gamma-irradiated donor cells or donor specific allopeptides in modifying the course of accelerated cardiac rejection suggests that direct allorecognition is the dominant pathway initiating rejection in sensitized transplant recipients. Marked alterations in the antidonor IgM and IgG responses are associated with successful abrogation of accelerated rejection by thymic immunomodulatory mechanisms.     

IL-4 deficiency prevents eosinophilic rejection and uncovers a role for neutrophils in the rejection of MHC class II disparate skin grafts

BACKGROUND: Acute rejection of MHC class II-disparate bm12 skin grafts by C57BL/6 recipient mice is characterized by massive graft infiltration by eosinophils, together with increased intragraft amounts of IL-4 and IL-5 mRNA. IL-5 blockade prevents the intragraft eosinophil infiltration and prolongs the survival of skin allografts. As the differentiation of T cell precursors into Th2 cells is largely driven by IL-4, we investigated the role of IL-4 in MHC class II-disparate allograft rejection. METHODS: We performed skin grafts from MHC class II incompatible bm12 mice into wild-type C57BL/6 mice (IL-4) or C57BL/6 IL-4 deficient mice (IL-4). Graft survival, in vitro T cell reactivity, and histology were compared. RESULTS: We observed that 50% of IL-4 mice rapidly rejected their bm12 allograft, whereas the other 50% retained their graft 60 days after transplantation. Histological examination of bm12 allografts retained by IL-4 mice showed a normal appearance with no inflammatory infiltrate and no eosinophils. Among IL-4 mice that acutely rejected their bm12 skin graft, we observed a dense polymorphonuclear infiltrate. The depletion of neutrophils significantly prolonged bm12 graft survival. CONCLUSIONS: Eosinophil infiltrates, typical of MHC class II disparate acute skin graft rejection, are critically dependent on the availability of IL-4. IL-4 mice reject MHC class II disparate skin grafts by a pathway of rejection where neutrophils play a direct causal role.     

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.     

Patterns of immune responses evoked by allogeneic hepatocytes: evidence for independent co-dominant roles for CD4+ and CD8+ T-cell responses in acute rejection.

INTRODUCTION: This is the first in a series of reports that characterizes immune responses evoked by allogeneic hepatocytes using a functional model of hepatocyte transplantation in mice. METHODS: "Donor" hepatocytes expressing the transgene human alpha-1-antitrypsin (hA1AT-FVB/N, H2q) were transplanted into C57BL/6 (H2b) or MHC II knockout (H2b) hosts treated with anti-CD4, anti-CD8, or a combination of anti-CD4 and anti-CD8 monoclonal antibodies (mAbs). Hepatocyte rejection was determined as a loss of circulating ELISA-detectable transgene product (hA1AT). In addition, some C57BL/6 mice underwent transplantation with FVB/N heterotopic cardiac allografts and were treated with anti-CD4 mAb. Cardiac allograft rejection was determined by palpation. Graft recipients were tested for donor-reactive alloantibodies and donor-reactive delayed-type hypersensitivity (DTH) responses. RESULTS: The median survival time (MST) of allogeneic hepatocytes in normal C57BL/6 mice was 10 days (no treatment), 10 days (anti-CD4 mAb), 14 days (anti-CD8 mAb), and 35 days (anti-CD4 and anti-CD8 mAbs). The MST of hepatocytes in B6 MHC class II knockout mice was 10 days (no treatment) and 21 days (anti-CD8 mAb). The MST of cardiac allografts was 11 days (no treatment) and >100 days (anti-CD4 mAb). Donor-reactive DTH responses were readily detected in both untreated and mAb-treated recipients. Donor-reactive alloantibody was barely detectable in untreated hosts. CONCLUSIONS: These studies demonstrate that allogeneic hepatocytes are highly immunogenic and stimulate strong cell-mediated immune responses by both CD4+ and CD8+ T cells, even when treated with agents that can cause acceptance of cardiac allografts. Indeed, CD4+ or CD8+ T cells seem to independently cause hepatocellular allograft rejection. Allogeneic hepatocytes evoked strong donor-reactive DTH responses but were poor stimuli for donor-reactive antibody production. This is an unusual pattern of immune reactivity in allograft recipients.     

The degree of phylogenetic disparity of islet grafts dictates the reliance on indirect CD4 T-cell antigen recognition for rejection

Cellular xenograft rejection involves a pronounced contribution of CD4 T-cells recognizing antigens in association with recipient MHC class II molecules. However, the requirement for such "indirect" antigen recognition for acute islet xenograft is not clear, especially as a function of the phylogenetic disparity between the donor and recipient species. In vitro studies show that C57BL/6 (B6) mouse T-cells respond directly to either allogeneic BALB/c or phylogenetically related xenogeneic WF rat stimulator cells while having undetectable responses to phylogenetically disparate porcine stimulator cells. Although all types of grafts rejected acutely in wild-type mice, this response demonstrated markedly differing dependence on host MHC class II antigen presentation, depending on the donor species. While BALB/c islet allografts were acutely rejected in B6 MHC class II-deficient (C2D) recipients, WF rat xenografts demonstrated marked prolongation in C2D hosts relative to wild-type recipients. Interestingly, neonatal porcine islet (NPI) xenografts uniformly survived long term (>100 days) in untreated C2D hosts despite transfer of wild-type CD4 T-cells, demonstrating that survival in C2D recipients was not secondary to a lack of CD4 T-cells seen in such mice. Taken together, these results show a marked hierarchy in the requirement for host MHC class II-restricted indirect pathway in the rejection of pancreatic islet grafts. Thus, while cellular rejection of porcine xenografts is generally quite vigorous, this pathway is relatively finite, displaying a major reliance on host MHC class II-dependent antigen presentation for acute rejection.     

A major role for host MHC class I antigen presentation for promoting islet allograft survival

The purpose of this study was to determine the role for CD8 T cells versus generalized MHC class I-restricted antigen presentation in islet allograft rejection and tolerance. Diabetic C57BI/6 (B6, H-2(b)) controls, C57BI/6 CD8-deficient (CD8 KO), or MHC class I-deficient C57BI/6 (beta 2m KO) recipients were grafted with allogeneic BALB/c (H-2(d)) islets. Islet allografts were acutely rejected in untreated B6, CD8 KO, and in beta 2m KO mice, indicating that neither CD8 T cells nor host MHC class I is required for allograft rejection. We then determined the efficacy of costimulation blockade in these same strains. Costimulation blockade with anti-CD154 therapy facilitated long-term islet allograft survival in both B6 and in CD8 KO recipients. However, anti-CD154 treated beta 2m KO recipients were completely refractory to anti-CD154 therapy; all treated animals acutely rejected islet allografts with or without therapy. Also, anti-NK1.1 treatment of wild-type B6 mice abrogated graft prolongation following anti-CD154 therapy. Taken together, results show a dramatic distinction between two forms of MHC class I-restricted pathways in allograft prolongation. Although anti-CD154-induced allograft survival was CD8 T-cell independent, an intact host MHC class I-restricted (beta 2m-dependent) pathway is nevertheless necessary for allograft survival. This pathway required NK1.1+ cells, implicating NK and/or NKT cells in promoting allograft prolongation in vivo.     

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.     

Lack of correlation between the induction of donor class I and class II major histocompatibility complex antigens and graft rejection

The induction of donor major histocompatibility complex (MHC) antigens on nonrejected and rejected rat renal allografts was compared at various times after transplantation in two strain combinations, DA-to-PVG and LEW-to-DA. Graft rejection was prevented by preoperative donor-specific blood transfusion (DST). Quantitative absorption analysis and immunohistology were performed using monoclonal antibodies specific for donor class I and class II MHC antigens. A significant increase in the expression of donor MHC antigens, both class I and class II, was demonstrated on nonrejected as well as rejected kidneys after transplantation. A kinetic analysis showed that induction of donor class I antigens was accelerated on the nonrejected grafts, and by day 5 the nonrejected kidneys showed increased expression of class I antigen when compared with the rejected grafts (a 37- vs. a 25-fold increase in expression). Increased expression of donor class I antigens persisted on the nonrejected grafts and was still detectable on long-term-surviving kidneys, 50 days after transplantation. The magnitude of class II antigen induction was similar on both rejected and nonrejected grafts (8-fold by 5 days after transplantation). Immunohistology demonstrated that class I and class II antigens were induced on identical structures in the kidney in both situations. In particular the vessel endothelia, which do not express class II antigens in normal kidney, become strongly positive in both rejected and nonrejected grafts 5 days after transplantation. Although renal allograft rejection is completely suppressed in rats given a single donor-specific blood transfusion before transplantation, graft survival cannot be explained by the lack of induction of donor MHC antigens. Donor MHC antigens are induced on these nonrejected kidney grafts, and therefore they could act as target molecules for the effector cells that mediate graft destruction. Thus the induction of donor MHC antigens on tissue allografts should not be considered as indicative of a rejection response resulting in graft destruction.     

Induction of indefinite survival of fully mismatched cardiac allografts and generation of regulatory cells by sarpogrelate hydrochloride

BACKGROUND: At initiation of the immunologic response, platelets rapidly release chemical mediators such as serotonin (5-hydroxytryptamine, [5-HT]) and cytokines. Sarpogrelate hydrochloride (SH), a selective 5-HT2-receptor antagonist, is used to treat patients with peripheral arterial disease. We investigated the effect of SH on the alloimmune response in a murine cardiac transplantation model. METHODS: CBA mice underwent transplantation of a C57BL/10 heart and received a short course of SH treatment. Survival of the allograft was recorded. An adoptive transfer study was performed to determine whether regulatory cells were generated. Immunohistochemistry studies of intercellular adhesion molecule 1 (ICAM-1), histological, cell-proliferation, and cytokine assessments were performed. RESULTS: Untreated CBA mice rejected C57BL/10 cardiac grafts acutely (median survival time [MST], 8 days). In mice given 10 mg/kg of SH, all allografts survived indefinitely (MST, >100 days); these mice also had significantly prolonged survival of donor-specific skin grafts but acute rejection of third-party skin grafts. Secondary CBA recipients given not only whole but also CD4 splenocytes from primary SH-treated CBA recipients with C57BL/10 cardiac allograft had indefinite survival of C57BL/10 hearts (MST, >100 days). SH inhibited upregulation of ICAM-1 on endothelial cells in the allografts. Graft acceptance and hyporesponsiveness were confirmed by the histological and cell-proliferation studies, respectively. Production of interleukin-4 and interleukin-10 from splenocytes of SH-treated transplant recipients increased compared to that from splenocytes of untreated recipients. CONCLUSION: SH induced indefinite survival of fully allogeneic cardiac allografts, generated CD4 regulatory cells, inhibited ICAM-1 expression in the allografts, and upregulated IL-4 and IL-10 production.     

Major histocompatibility complex semi-matching improves murine corneal allograft survival under oxidative macrophage dominancy

BACKGROUND: Corneal allograft rejection is mediated by a Th1-type response. Because major histocompatibility complex (MHC)-compatible allografts are the prerequisite for efficient graft survival by reducing the Th1 response, we explored a new strategy for the acceptance of (MHC+minor H)-disparate allografts. METHODS: N,N'-diacetyl-L-cystine dimethylester (NM2) reduces the intracellular glutathione content (icGSH) in antigen-presenting cells (APCs) and down-regulates Th1 responses. Therefore, we subconjunctivally (scj) injected NM2 into donor- and/or recipient mice on days 1, 4, and 7 before penetrating keratoplasty. C57BL/10, B10.D2, or CBF1 corneal allografts were then placed on neovascularized graft beds of BALB/c mice. Corneal grafting was also performed between CBF1 and B6C3F1 mice. RESULTS: The saline-injected controls rejected all allografts within 3 weeks. Minor H-only-disparate B10.D2 allografts survived indefinitely after the intraperitoneal (ip) (65.0%) and scj (71.4%) injection of NM2 (P<0.0001). MHC+minor H-disparate C57BL/10 allograft survival was prolonged only by scj injection of NM2 (median survival time [MST]=43.6+/-1.5, P<0.001); there was no indefinite allograft survival. Allelic-gene semi-matched CBF1 grafts survived indefinitely after ip (75.0%) or scj (86.6%) delivery of NM2 and 50% of the B6C3F1 grafts survived indefinitely only after scl NM2 injection; no control grafts survived (MST=18.9+/-1.1, P<0.0001). CONCLUSIONS: The local application of NM2 improved the survival of MHC-disparate allografts. Allelic-gene semi-matching, combined with the local induction of APCs with reduced icGSH, resulted in allograft survival comparable to the survival of MHC-matched grafts.     

The smell of Tokishakuyaku-san (TJ-23) induces generation of regulatory T cells and prolongation of survival of fully allogeneic cardiac grafts in mice

Oral administration of Tokishakuyaku-san (TJ-23), a Japanese herbal medicine, induces prolongation of cardiac allograft survival and generates regulatory cells in mice. Because herbal medicines usually have unique odor, and because smell is supposed to modulate the immune system, we examined whether the odor of TJ-23 induced prolonged allograft survival and regulatory cell generation. Naïve CBA mice (H2^k) and olfactory-dysfunctional CBA mice after a stereotaxic operation underwent transplantation of C57BL/6 (B6, H2^b) hearts, receiving fumigated water only or TJ-23 until rejection. Untreated or treated with water fumigation CBA mice rejected B6 cardiac grafts acutely (median survival times [MSTs], 7 and 8.5 days). When CBA mice were treated with fumigation of TJ-23, allograft survival was significantly prolonged (MST, 48 days). Olfactory-dysfunctional CBA mice treated with fumigation of TJ-23 rejected grafts acutely (MST, 7 days). Treatment with fumigation of TJ-23 also suppressed splenocytes proliferation and interferon-γ production. Secondary CBA recipients of whole splenocytes or CD4⁺ cells from primary TJ-23-treated CBA recipients of B6 cardiac allografts at 30 days after grafting showed prolonged survival of B6 hearts (MST, >60 days). Flow cytometry studies showed increased CD4⁺CD25⁺Foxp3⁺ regulatory cells in recipients given fumigation of TJ-23. In conclusion naïve but not olfactory-dysfunctional CBA mice treated with fumigation of TJ-23 displayed prolonged survival of fully allogeneic cardiac allografts and generation of regulatory cells.     

胸腺内注射可溶性异基因主要组织相容性复合物抗原诱导皮肤移植特异性耐受

用３ｍｏｌ／ＬＫＣｌ从Ｃ５７ＢＬ／６小鼠脾细胞提取可溶性主要组织相容性复合物（ＭＨＣ）抗原，注射到ＢＡＬＢ／Ｃ受体鼠胸腺内，诱导了成年小鼠对该异基因小鼠皮肤移植物的耐受。除在胸腺注射当天及第３天给予抗Ｔ细胞单克隆抗体外，不使用免疫抑制剂。实验组移植皮肤平均存活时间（ＭＳＴ）为８３天，对照组ＭＳＴ为１１天。诱导耐受的小鼠对第３供体的移植皮肤仍正常排斥（ＭＳＴ为１２天）。单向混合淋巴细胞反应，耐受小鼠脾脏淋巴细胞对特异供体的脾细胞无反应，对第３供体的脾细胞反应正常，对丝裂原刺激的增殖反应正常。显示诱导的耐受是供体特异性的，无非特异性免疫抑制。     

Survival of fetal skin grafts is prolonged on the human peripheral blood lymphocyte reconstituted-severe combined immunodeficient mouse/skin allograft model

BACKGROUND: Fetal tissue is considered to be immune privileged and is under extensive investigation as a source of tissue for transplantation. In this paper, we analyzed the immune properties of human fetal and neonatal skin before and after transplantation to severe combined immunodeficient (SCID) mice. Using a human peripheral blood mononuclear cell reconstituted SCID (huPBMC-SCID) mouse model of allograft rejection, we compared the immune response to transplanted fetal and neonatal skin. METHODS: We analyzed human fetal (55-122 days of gestation) and neonatal skin samples by routine histology and immunohistochemistry for the expression of (MHC class I and II antigens before and after transplantation to SCID mice. After transplantation, we injected the mice with huPBMCs and analyzed the survival of neonatal and fetal skin grafts both visually and microscopically. RESULTS: We detected no class II expression in fetal skin of all gestational ages and only weak class I expression after 89 days compared with abundant class I and II expression in neonatal skin before transplantation. When transplanted to SCID mice, fetal skin grafts differentiated and expressed class I and II, but the levels were lower than neonatal grafts. In mice injected with huPBMCs, rejection of neonatal grafts started on day 5, and by day 9 all grafts were rejected. In contrast, rejection of fetal skin grafts was significantly delayed. Rejection started on day 13 and was complete by day 23 (P<0.00005). Histology sections from the rejected grafts showed marked CD3+ T cell infiltration in the human skin with a sharp demarcation between the human and mouse skin, with no T-cell infiltration in the mouse skin. CD4+ and CD8+ T cells were present in the rejected sites in similar densities. CONCLUSIONS: Our results show that fetal skin differentiates and expresses increased amounts of MHC class I and class II antigens when transplanted to SCID mice. However, these levels are much lower than the levels found in neonatal skin. We demonstrate that the survival of human fetal skin allografts is markedly prolonged compared with that of neonatal skin grafts in the huPBMC-SCID mouse model. Our results support the hypothesis that low levels of MHC antigen expression lead to a delay in the rejection of fetal skin and further demonstrate the utility of the huPBMC-SCID mouse model to investigate the molecular and cellular mechanisms of the immune response to human fetal tissues.     

Presentation of donor major histocompatibility complex antigens by bone marrow dendritic cell-derived exosomes modulates allograft rejection

BACKGROUND: Dendritic cells secrete a population of "antigen-presenting vesicles," called exosomes, expressing functional class I and II major histocompatibility complex (MHC) and co-stimulatory molecules. The subcutaneous administration of syngeneic exosomes expressing tumor antigens has been shown to induce specific antitumor immune responses in vivo. The authors hypothesized that antigen presentation by exosomes, depending on the context of their administration, may induce tolerance rather than immunity. METHODS: The authors therefore tested the capacity of exosomes derived from donor bone marrow dendritic cells, given before transplantation, to modulate heart allograft rejection. RESULTS: The authors show here that donor type but not syngeneic exosomes induced a significant prolongation of allograft survival, with a few recipients having long-term graft survival. During the first week after transplantation, allografts from exosome-treated rats displayed a significant decrease in graft-infiltrating leukocytes and in the expression of interferon-gamma mRNA compared with allografts from untreated animals. Moreover, when tested in vitro, spleen CD4+ T cells from exosome-treated recipients displayed a significant decrease in anti-donor responses, suggesting a decrease in anti-donor T-cell responses. However, the authors also found that allogeneic donor-derived exosomes increased anti-donor MHC class II alloantibody production. CONCLUSIONS: The authors demonstrate an effect of allogeneic exosomes on the modulation of immune responses in vivo, suggesting that, like donor cells, exosomes can stimulate or regulate antigen-specific immune responses.     

Prolonged survival of heart allografts from p53-deficient mice

BACKGROUND: Acute rejection of the heart allograft is the major cause of heart failure in the first month after transplantation. Most studies on the prevention of acute rejection have concentrated on immune suppression of the recipients, whereas little is known about the effects of genetically manipulated donor organs on heart allograft survival. Herein, we describe a mouse model of heart allografts donated by p53-/- mice that can prolong the survival time of the grafts. METHODS: Hearts of p53-/- or p53+/+ C57BL/6J mice were grafted to the neck carotid artery and jugular vein of BALB/c mice using a cuff technique. The graft survival was observed daily. The hearts were analyzed using several techniques, including histology, immunofluorescence, terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling (TUNEL), and Western blot analysis. RESULTS: p53+/+ allografts ceased beating at 7.6+/-0.5 days, whereas p53-/- hearts were beating at 10.5+/-1.1 days after transplantation (P<0.01). Mean histological rejection scores were significantly lower in allografts donated by p53-deficient mice. Furthermore, apoptotic cells, determined by TUNEL and a reagent kit for detection of cardiac apoptosis, were of high numbers in the allograft sections from wild-type hearts but rare in p53-/- allografts (4.2+/-1.3 vs. 0.7+/-0.5/250x field). Immunofluorescence staining and Western blot analysis revealed that high levels of p53 and proapoptotic protein Bax were expressed in wild-type grafts but not p53-/- allografts. Interestingly, Bcl-2, an antiapoptotic protein, was abundant in cardiac allografts from p53-/- mice and almost undetectable in grafts from wild-type mice. CONCLUSIONS: Thus, p53 is involved in cardiac apoptosis induced by alloimmune reaction, and prolonged survival of heart allografts can be achieved when p53 is lacking.     

The role of class I and class II MHC antigens in the rejection of vascularized heart allografts in mice

We have examined the role of entire major histocompatibility complex (MHC) disparity, individual class II or class I alloantigens in the rejection of vascularized heart allografts. Our results demonstrate that entire MHC, as well as both class II and class I disparities, may induce acute heart graft rejection or severe and irreversible heart muscle destruction. However, in 1 of 2 combinations differing at class II and 1 of 5 differing at class I, hearts have shown a good function greater than 100 days postgrafting. Furthermore, each donor-recipient combination has demonstrated a unique pattern of heart allograft function as well as a degree of heart muscle damage. In conclusion, these data suggest that the rejection process depends upon multiple factors such as the immune-response-gene-regulated immunoresponsiveness of the recipient as well as the expression of alloantigens on heart grafts during the induction and effector phases of the immune response.     

Chronic cardiac allograft rejection in a rat model disparate for one single class I MHC molecule is associated with indirect recognition by CD4(+) T cells

T-cell mediated immune responses play a critical role in chronic allograft dysfunction. The complex nature of allograft rejection, particularly with respect to the vast repertoire of alloantigens and their mode of recognition by T cells, presents a major challenge for the design of well-controlled studies into the immunobiology of chronic rejection. The purpose of this study was to develop a rat model with restricted antigenic specificity that develops chronic rejection without any immunologic manipulation to study the T-cell response. PVG.1U allogeneic hearts disparate for one single class I antigen, RT.1A(u), were transplanted into PVG.R8 rat recipients. Grafts from PVG.R8 were used as syngeneic controls. Chronic rejection was studied by histological analysis of the grafted hearts at various time points posttransplantation (20-100 days). Donor specific alloreactive response was studied in a mixed lymphocyte reaction assay. All allografts survived more than 90 days and showed extensive evidence of chronic rejection, which was characterized by interstitial fibrosis, vasculitis, and occlusive myointimal thickening. Chronic rejection was evident by day 20 and most extensive by day 100 posttransplantation. In marked contrast, syngeneic grafts remained free of chronic lesions. Lymphocytes harvested from graft recipients showed a more vigorous proliferative response to allogeneic splenocytes as compared with that of lymphocytes from nai;ve animals. The proliferative response was primarily mediated by CD4(+) T cells recognizing the RT1.A(a) molecule via the indirect pathway. A single class I disparity in this model generates chronic rejection associated with potent CD4(+) T-cell responses induced by the indirect recognition pathway. The use of this antigenically restricted model may facilitate the design of well-controlled studies for the characterization of immune mechanisms responsible for chronic rejection.     

Immunohistological observations of rat fetal pancreas allografts transplanted into unmodified and cyclosporine-treated recipients

Administration of CsA (15 mg/kg/day) prolonged the survival of DA (RT1a) rat fetal pancreas transplanted to the renal subcapular site of both PVG (RT1c) and Lewis (RT1(1] recipients. Sections of fetal pancreas examined 40 days after transplantation into allogeneic CsA-treated recipients showed growth and development of the fetal pancreas tissue, and the presence of numerous insulin-containing islets. CsA treatment prevented the induction of MHC antigen within allografts. Whereas at day 4, both rejecting and CsA treated grafts showed donor class I MHC expression on duct epithelium and islet cells, only rejecting grafts displayed class I MHC induction on acinar cells. Rejecting grafts showed strong induction of class II MHC antigen expression on duct epithelium from day 4 onward but this was completely prevented by CsA treatment. Islet cells in both rejecting and CsA treated allografts remained class II-negative throughout. CsA also resulted in a reduction in the day 6 cellular infiltrate of allografts (median area leukocyte infiltrate reduced from 43% to 10%) with a marked decrease in the number of MRC OX-8-positive cells. These results show a favorable effect of CsA on rat fetal pancreas allografts with a reduction in MHC antigen expression within the graft and prolonged survival of insulin-rich endocrine tissue.     

Allogeneic versus xenogeneic immune reaction to bioengineered skin grafts

There are conflicting reports on the survival and immune reaction to allografts and xenografts of cultured skin substitutes (CSS). In this study, we investigated the allogeneic and xenogeneic responses to CSS of human keratinocytes and genetically engineered CSS expressing keratinocyte growth factor (KGF) that forms a hyperproliferative epidermis. CSS (control and KGF modified) and neonatal human foreskins were evaluated by immunohistochemistry for the expression of MHC class I and II. To study allograft rejection, grafts were transplanted to human peripheral blood mononuclear cell (huPBMC)-reconstituted SCID mice. To study xenograft rejection, grafts were transplanted to immunocompetent mice. Graft survival and immune reaction were assessed visually and microscopically. After transplantation, control CSS formed a normal differentiated epidermis, whereas KGF CSS formed a hyperproliferative epidermis. Control and KGF CSS expressed class I similar to neonatal foreskin, but did not express class II. In the allograft model, rejection of neonatal foreskins was between 5 and 9 days. In contrast, neither control nor KGF CSS was rejected by huPBMC-SCID mice. Histology showed dense mononuclear cell infiltration in human foreskins, with few, if any, mononuclear cells in control or KGF CSS. In contrast to the allogeneic reaction, CSS (control and KGF) were rejected in the xenograft model, but rejection was delayed (9-21 days) compared with neonatal skin (5-8 days). Humanized SCID mice rejected allografts of human neonatal foreskins, but did not reject control CSS or KGF CSS, even though the KGF CSS formed a hyperproliferative epidermis. Rejection of control and KGF CSS by immunocompetent mice in a xenograft model was comparable and their survival was significantly prolonged compared with neonatal skin. These results demonstrate that control CSS and hyperproliferative KGF CSS are less immunogenic than normal human skin and that sustained hyperproliferation of the epidermis does not accelerate rejection.