Cytotoxic T-cell elimination during anti-CD4-induced rat liver acceptance and rapid replacement of functional graft antigen-presenting cells.

In previous studies, we showed that primed T cells were eliminated in long-term survival Wistar Furth (WF) recipient rats with spontaneously accepted Lewis (LEW) liver graft and that the grafted liver lost the ability to elicit rejection reaction early after liver transplantation. We hypothesized that the same phenomenon may be observed in tolerant animals after immunosuppression in a rejector rat strain combination (WF-->LEW). Furthermore, we proposed the repopulation of liver allograft with host antigen-presenting cells rapidly after transplantation. Recipient LEW rats that underwent anti-CD4 therapy accepted the WF liver allografts after a transient rejection reaction. In tolerant animals, alloreactive CD8 T cell precursors were present, but primed T cells were absent. Intraperitoneal challenge with grafted WF liver homogenates obtained from recipient LEW rats on day 4 after transplantation did not induce transient rejection responses in long-term survival recipient LEW rats, a finding that differed from the results of experiments using normal WF liver homogenates. However, challenge with grafted WF liver homogenates, similar to those of normal LEW liver homogenates, induced rejection responses in long-term survival recipient WF rats with LEW liver allograft. Flow cytometric analysis confirmed that most of nonparenchymal cells in the grafted WF liver were recipient (LEW) genotype. These observations showed that the deletional mechanism of effector T cells also is observed in this setting, and professional donor antigen-presenting cells are replaced by those of recipient genotype within the graft during the early phase of transplantation.     

CD4 T-Cell Regulation of Cytotoxic T Cells During the Induction Phase of Liver-Induced Spontaneous Tolerance in Rats

Purpose To check for in vivo CD4 T-cell-mediated inhibition of the immune response in rats with spontaneously accepted liver transplants.Methods Using the Lewis to Wistar Furth rat strain combination, we performed transient in vivo depletion of CD4 T-cells by anti-CD4 monoclonal antibodies (mAb) after liver transplantation. We used the CTL assay to detect primed T cells. We also retransplanted a grafted donor liver, parked for 3 days, into a secondary naive recipient rat.Results When Lewis rat livers were transplanted into the recipient Wistar Furth rats, the grafts suffered an early immune attack, followed by spontaneous acceptance without immunosuppression. However, giving anti-CD4 mAb to the recipients at the time of grafting prolonged the acute rejection reaction. Furthermore, giving anti-CD4 therapy on postoperative days (PODs) 21 and 35, but not on PODs 56 and 100, induced transient liver damage in recipients overcoming acute rejection. No primed T cells were detected by the CTL assay in the recipient rats within 2 months after transplantation. Meanwhile, the retransplanted liver had no ability to elicit an immune attack.Conclusions CD4 T cells seemed to downregulate the effector function of T cells, but not T-cell proliferation in this model.     

The role of Foxp3+ regulatory T cells in liver transplant tolerance

The liver has long been considered a tolerogenic organ that favors the induction of peripheral tolerance. The mechanisms underlying liver tolerogenicity remain largely undefined. In this study, we characterized Foxp3-expressing CD4+ CD25+ regulatory T cells (Treg) in liver allograft recipients and examined the role of Treg in inherent liver tolerogenicity by employing the mouse spontaneous liver transplant tolerance model. Orthotopic liver transplantation was performed from C57BL/10 (H2b) to C3H/HeJ (H2k) mice. The percentage of CD4+ CD25+ Treg was expanded in the liver grafts and recipient spleens from day 5 up to day 100 posttransplantation, associated with high intracellular Foxp3 and CTLA4 expression. Immunohistochemistry further demonstrated significant numbers of Foxp3+ cells in the liver grafts and recipient spleens and increased transforming growth factor beta expression in the recipient spleens throughout the time courses. Adoptive transfer of spleen cells from the long-term liver allograft survivors significantly prolonged donor heart graft survival. Depletion of recipient CD4+ CD25+ Treg using anti-CD25 monoclonal antibody (250 microg/d) induced acute liver allograft rejection, associated with elevated anti-donor T-cell proliferative responses, CTL and natural killer activities, enhanced interleukin (IL)-2, interferon-gamma, IL-10, and decreased IL-4 production, and decreased T-cell apoptotic activity in anti-CD25-treated recipients. Moreover, CTLA4 blockade by anti-CTLA4 monoclonal antibody administration exacerbated liver graft rejection when combined with anti-CD25 monoclonal antibody. Thus, Foxp3+ CD4+ CD25+ Treg appear to underpin spontaneous acceptance of major histocompatability complex- mismatched liver allografts in mice. CTLA4, IL-4, and apoptosis of alloreactive T cells appear to contribute to the function of Treg and regulation of graft outcome.     

Lympho-myeloid chimerism achieved by spleen graft of green fluorescent protein transgenic rat in a combined pancreas transplantation model (TI03-029)

BACKGROUND: Multilineage chimerism is a promising strategy to induce donor-specific tolerance. Because the beneficial effect of splenic grafting on tolerance induction is well known, we studied long-term hematopoietic chimerism and the fate of donor-derived cells after allogenic pancreas/spleen transplantation. METHODS: Green fluorescent protein (GFP) transgenic (Tg) Wistar rats were donors and combined pancreas/spleen transplantation (PST) or pancreas transplantation (PT) alone was performed on recipient LEW rats. Graft survival was compared between these two groups and the fate of donor-derived GFP(+) cells was analyzed by flow cytometry. In this system, the donor-derived cells were clearly defined as having lymphocytic or granulocytic lineage by cell size. T-cell subsets of GFP(+) and GFP(-) cells in long graft-surviving rats were also characterized. RESULTS: The survival period of the grafted pancreas in PST rats was significantly longer than that of PT rats (P<0.001). Three of seven PST rats survived >250 days. The chimeric level of donor-derived GFP(+) cells in the recipient peripheral blood was markedly higher in PST rats. In rats with long-surviving grafts, overall peripheral blood chimerism was more than 5%, and both lymphocytes and granulocytes generated from the grafted spleen were stable. T-cell subsets in the recipient LEW rats varied according to the type of cells. CD4(+)CD8(+) subsets decreased in the GFP(+) cells and CD4(-)CD8(+) subsets increased in the GFP(-) (LEW) cells. CONCLUSION: We confirmed the combination effect of the grafted spleen on pancreatic graft survival. Donor lymphocytic and granulocytic lineages were generated in the recipients with long-surviving graft. It suggested that multilineage chimerism was often induced by the spleen graft and protected the pancreatic graft against rejection for a long period.     

Cytotoxic T-cell response following mouse liver transplantation is independent of the initial site of T-cell priming

BACKGROUND: Liver transplantation in the mouse results in systemic induction of tolerance. The underlying mechanisms may also account for the persistence of chronic liver infections. It has therefore been hypothesized that antigen (Ag) presentation within the liver by nonprofessional antigen-presenting cells (APC) leads to incomplete T-cell activation, ultimately resulting in tolerance induction. We tested this hypothesis in an orthotopic mouse liver transplantation model. METHODS: Mouse liver transplantation was used to manipulate antigen presentation in major histocompatibility complex (MHC)-disparate donor and recipient strains. The effect of restricted Ag presentation was studied using CD8+ T-cell receptor transgenic OT-I cells. Transgenic OT-I cells were activated by injection of their cognate peptide antigen SIINFEKL, which could be presented by the MHC class I of only one of the mouse strains. Depending on the strain combination, Ag presentation was restricted to either the transplanted liver itself, the recipient (excluding the transplanted liver), or systemically throughout the recipient. Extrahepatic Ag presentation by passenger leukocytes was eliminated by using donors of chimeric bone marrow. RESULTS: OT-I cells encountering antigen only in the transplanted liver were activated, underwent extensive proliferation, and developed effector functions, based on IFN-gamma production and in vivo cytotoxicity assays. This T-cell activation and differentiation within the liver was comparable to animals with systemic Ag presentation and to animals with absent hepatic-parenchymal Ag presentation. CONCLUSIONS: The restricted presentation of antigen in the liver showed no immunosuppressive effect on activation of CD8+ T cells. In contrast, the liver may be an excellent priming site for naive CD8+ T cells.     

Exhaustive differentiation of alloreactive CD8+ T cells: critical for determination of graft acceptance or rejection

BACKGROUND: The precise role that CD8+ T cells play in the rejection and acceptance of different types of allograft is unclear and has been shown to vary between donor-recipient combinations. METHODS: The response of adoptively transferred CD8+ T cells reactive to the donor alloantigen H2Kb was examined after transplantation of H2Kb liver, kidney, and heart grafts in mice. RESULTS: After transfer of 6 x 10(6) alloreactive CD8+ T cells to T-cell depleted syngeneic mice spontaneous long-term acceptance of liver grafts was observed, whereas kidney and heart grafts were acutely rejected. Within 5 days of liver transplantation, we found that the entire H2Kb-reactive T-cell pool was stimulated to proliferate and differentiate into memory or effector cells that were detectable within lymphoid tissues as well as the liver graft itself. However, despite the generation of effector or memory T cells, liver allografts were accepted, which correlated with the exhaustion or deletion of such cells. In contrast, although activation and proliferation of H2Kb-reactive CD8+ T cells was observed after transplantation of heart or kidney grafts, unactivated, H2Kb-reactive CD8+ T cells were still present in the spleen even long term. Interestingly, differences in the effector function of liver and kidney graft infiltrating donor-reactive CD8+ T cells were not detected after adoptive transfer into immunodeficient mice, despite a reduction in Th1-type cytokines within liver grafts. CONCLUSIONS: The rapid and extensive initial activation and differentiation of donor-reactive CD8+ T cells that occurs after liver transplantation leads to clonal exhaustion or deletion of the alloreactive CD8+ T-cell repertoire resulting in spontaneous tolerance induction.     

Infusion of Lin- bone marrow cells results in multilineage macrochimerism and skin allograft tolerance in minimally conditioned recipient mice

Donor-specific immunological tolerance using high doses of donor bone marrow cells (BMC) has been demonstrated in mixed chimerism-based tolerance induction protocols; however, the development of graft versus host disease (GVHD) remains a risk. In the present study, we demonstrate that the infusion of low numbers of donor Lin(-) bone marrow cells (Lin(-) BMC) 7 days post allograft transplantation facilitates high level macrochimerism induction and graft tolerance. Full-thickness BALB/c skin allografts were transplanted onto C57BL/6 mice. Mice were treated with anti-CD4 and anti-CD8 mAbs on day 0, +2, +5, +7 and +14 along with low dose busulfan on day +5. A low dose of highly purified Lin(-) BMC from BALB/c donor mice was infused on day +7. Chimerism and clonal cell deletion were evaluated using flow cytometry. Donor-specific tolerance was tested by donor and third-party skin grafting and mixed leukocyte reaction (MLR). Lin(-) BMC infusion with minimal immunosuppression led to stable, mixed, multilineage macrochimerism and long-term allograft survival (>300 days). Mixed donor-recipient macrochimerism was observed. Donor-reactive T cells were clonally deleted and a 130% increase in CD4(+)CD25(+)Foxp3(+) regulatory T cells (Tregs) was observed in the spleen. Tolerant mice subsequently accepted second donor, but not third-party (C3H), skin grafts and recipient splenocytes failed to react with allogeneic donor cells indicating donor-specific immunological tolerance was achieved. We conclude that the infusion of donor Lin(-) BMC without cytoreductive recipient conditioning can induce indefinite survival of skin allografts via mechanisms involving the establishment of a multilineage macrochimeric state principally through clonal deletion of alloreactive T cells and peripherally induced CD4(+)Foxp3(+) Tregs.     

Adoptive transfusion of ex vivo donor alloantigen-stimulated CD4(+)CD25(+) regulatory T cells ameliorates rejection of DA-to-Lewis rat liver transplantation

BACKGROUND: Adoptive transfusion of splenocytes from long-term survivors of a tolerance model of rat orthotopic liver transplantation can induce acceptance of liver allografts in a rejection model preconditioned with donor gamma-irradiation before liver transplantation. Recent studies suggest that the regulatory T cells (Treg cells) in splenocytes from long-term survivors play an important role in the induction of liver graft tolerance, but this observation was made from a rejection model preconditioned with donor gamma-irradiation; little is known about the role of Treg cells in liver graft rejection using a naive rejection model. In this study, we examined the therapeutic potential of CD4(+)CD25(+) Treg cells in a naive rejection model of rat liver transplantation. METHODS: Freshly isolated or ex vivo alloantigen-stimulated CD4(+)CD25(+) Treg cells (1 x 10(6) cells) from naive Lewis RT(1) (LEW) rats were adoptively transferred into another LEW rat on days 1 and 7 after liver transplantation from a Dark Agouti RT1(a) (DA) rat. Recipients were treated with or without oral tacrolimus (FK506) (0.1 mg/kg/day) from days 1 to 7 after transplantation. For ex vivo alloantigen-stimulation, CD4(+)CD25(+) Treg cells from LEW rats were cocultured with mitomycin C-treated DA (donor alloantigen specific) or Brown Norway (BN)(RT1(n), third party) splenocytes for 72 hours. Ex vivo alloantigen-specific CD4(+)CD25(-) T-cell proliferation responses were assessed with fresh and stimulated CD4(+)CD25(+) Treg cells. RESULTS: Freshly isolated, donor alloantigen-stimulated and third-party alloantigen- stimulated CD4(+)CD25(+) Treg cells suppressed antigen-specific CD4(+)CD25(-) T-cell proliferation ex vivo, and adoptive transfusion of these 3 kinds of CD4(+)CD25(+) Treg cells prolonged survival of the liver allografts. The group transfused with the donor alloantigen-stimulated CD4(+)CD25(+) Treg cells had the greatest mean survival among the 3 groups (fresh Treg cells, 21 +/- 2 days, n = 6; third-party alloantigen-stimulated Treg cells, 20 +/- 2 days, n = 6; donor alloantigen-stimulated Treg cells, 30 +/- 2 days, n = 6). When combined with short-term tacrolimus administration, adoptive transfusion of donor antigen-stimulated Treg cells induced the greatest survival time in recipients (greater than 60 days; n = 6). CONCLUSION: Adoptive transfusion of ex vivo donor alloantigen-stimulated CD4(+)CD25(+) Treg cells combined with short-term tacrolimus treatment may represent a new strategy for preventing rejection after liver transplantation.     

Addition of cyclophosphamide to T-cell depletion-based nonmyeloablative conditioning allows donor T-cell engraftment and clonal deletion of alloreactive host T-cells after bone marrow transplantation

BACKGROUND: Bone marrow (BM) chimerism has been shown to have a beneficial effect on allograft survival. We recently found that production of donor T-cells was highly correlated with induction of tolerance in minimally conditioned chimeras. In the present studies, we demonstrate that nonmyeloablative conditioning and BM cell infusion modulate innate and adaptive host immune responses. METHODS: Chimeras were generated by bone marrow transplantation (B10.BR to B10). Recipients were preconditioned with T-cell depleting antibodies and total body irradiation with or without cyclophosphamide. Donor-specific tolerance was tested by skin grafting. RESULTS: Transfer of tolerant splenocytes to immunocompetent secondary recipients did not transfer tolerance, nor did infusion of tolerant CD4+/CD25+ T-cells into chimeras without donor T-cell production, demonstrating that linked suppression is an unlikely mechanism in tolerance induction in the context of BM cell infusion. The addition of a single dose of cyclophosphamide to the conditioning enhanced engraftment and tolerance. This was associated with production of donor T-cells and effective clonal deletion, and a significant reduction in activated recipient plasmacytoid dendritic cells (pDC) and natural killer (NK) cells. Chimeras without donor T-cell production that eventually lost their chimerism did not generate an antidonor humoral response, whereas unconditioned controls infused with similar numbers of BM cells did, indicating that infusion of donor BM cells into conditioned recipients induced immune deviation for adaptive B-cell immunity, preventing sensitization to major histocompatibility complex (MHC) alloantigens. CONCLUSIONS: These results demonstrate that recipient T-cells, pDC, and NK cells contribute to the host barrier for establishing chimerism, implicate deletional tolerance as the mechanism for total body irradiation-based nonmyeloablative conditioning for BM transplantation, and show a beneficial effect of BM cells in preventing sensitization to MHC alloantigens.     

Direct versus Indirect Allorecognition: Visualization of Dendritic Cell Distribution and Interactions During Rejection and Tolerization

Interactions of donor and recipient dendritic cells (DCs) with CD4+ T cells determine the alloantigenic response in organ transplantation, where recipient T cells respond either directly to donor MHC, or indirectly to processed donor MHC allopeptides in the context of recipient MHC molecules. The present study evaluates donor and recipient alloantigen-presenting DC trafficking and their interactions with CD4+ T cells in the lymph nodes (LNs) and the spleen under tolerogenic treatment with anti-CD2 plus anti-CD3 mAb compared with untreated rejecting conditions. CX3CR1(GFP) BALB/c (I-A(d)) donor hearts were transplanted into C57BL/6 (I-A(b)) mice and quantification of donor DC direct (GFP+ or I-A(d+)) and recipient DC indirect (YAe+) trafficking and interactions with host CD4+ T cells was performed by fluorescent microscopy. Our data indicate that although both direct and indirect interactions between CD4+ T cells and donor and recipient DCs occur shortly after engraftment, only indirect presentation persists in the LN, but not the spleen, of tolerized recipients. These data suggest that distinct anatomic lymphoid compartments play a critical role in peripheral tolerance induction and maintenance, and persistent indirect presentation to CD4+ T cells within the LNs is an important process during tolerization.     

近交系大鼠肝移植自发免疫耐受模型的建立及其CD8+CD28-T细胞的作用

目的建立近交系大鼠原位肝移植自发免疫耐受模型,并研究CD8+CD28- T细胞在自发免疫耐受形成中的作用.方法双袖套法建立原位肝移植模型;流式细胞技术检测CD8+CD28- T抑制细胞含量变化;利用补体细胞毒和免疫磁珠方法分离CD8+CD28- T细胞,通过体外混合淋巴细胞反应验证其抑制功能.结果我们成功建立了BN(供体)LEW(受体)原位肝移植自发免疫耐受模型,并发现自发免疫耐受模型大鼠脾脏CD8+CD28- T细胞含量(23.7%±7.2%)显著高于正常大鼠(5.4%±1.5%)和急性排斥组大鼠(6.0%±1.3%),而且,分离纯化后的自发免疫耐受组大鼠脾脏CD8+CD28- T细胞可以抑制混合淋巴细胞反应的增殖,但急性排斥组大鼠脾脏CD8+CD28- T细胞无抑制功能.结论 BN(供体)LEW(受体)原位肝移植模型为自发免疫耐受;脾脏CD8+CD28- T细胞作为一种T抑制细胞,在自发免疫耐受的形成过程中具有重要作用.     

Mechanisms Involved in the Establishment of Tolerance Through Costimulatory Blockade and BMT: Lack of Requirement for CD40L-Mediated Signaling for Tolerance or Deletion of Donor-reactive CD4+ Cells

We have previously shown that high levels of multiline-age mixed hematopoietic chimerism and systemic T-cell tolerance can be achieved in mice without myeloablation through the use of anti-CD40L and costimulatory blockade alone (plus CTLA4Ig) or with recipient CD8 depletion and allogeneic bone marrow transplantation. Chimeric mice permanently accept donor skin grafts (> 100 days), and rapidly reject third-party grafts. The mechanisms by which costimulatory blockade facilitates the engraftment of allogeneic hematopoietic cells have not been defined. To further understand the in vivo mechanisms by which the administration of anti-CD40L mAb facilitates the engraftment of donor bone marrow and rapidly tolerizes CD4+ T cells, we analyzed the establishment of chimerism and tolerance in CD40L -/- mice. We demonstrate here that anti-CD40L mAb treatment is required only to prevent CD40L/CD40 interactions, and that no signal to the T cell through CD40L is necessary for the induction of CD4+ tolerance. Peripheral deletion of donor-reactive CD4+ T cells occurs rapidly in CD40L -/- mice receiving bone marrow transplantation (BMT), indicating that this deletion in the presence of anti-CD40L is not due to targeting of activated CD4+ cells by the antibody. Complete CD4+ cell tolerance is observed by both skin graft acceptance and in vitro assays before deletion is complete, indicating that additional mechanisms play a role in inducing CD4+ T-cell tolerance as the result of BMT in the presence of CD40/CD40L blockade.     

调节性CD4+T细胞在大鼠自发肝移植耐受中的作用

目的 探讨在肝移植的自发耐受模型中，调节性CD4^＋T细胞的免疫抑制作用机制。方法 利用近交系大鼠从Lewis（LEW）到Wistar Furth（WF）的肝移植组合，对移植后不同时期的宿主注射抗CD4的单克隆抗体（Anti-CD4mAb），然后抽血检测丙氨酸氨基转氨酶（ALT）的动态变化；并结合细胞毒性T淋巴细胞（CTL）试验了解宿主脾细胞中T细胞亚群的动态改变。结果 对肝移植自然生存的宿主注射Afiti—CD4mAb后，术后第21天、42天均能够诱导出肝损害（排斥反应），但第56天、100天以上的则未能诱导出来，且该损害能被抗CD8单克隆抗体阻断。另外CTL试验显示宿主的脾细胞中，初始型CTL前体细胞在移植56d后未能检测出来。结论 在自发性肝耐受模型中。宿主术后早期存在由CD4^＋T细胞介导的下调原始效应性T细胞的作用机制。     

Induction of stable chimerism and transplantation tolerance to rat islet and heart allografts by ultraviolet-B modulation of bone marrow cells.

Ultraviolet-B irradiation (UV-B) (700 J/m2) of BM cells prior to transplantation into lethally gamma-irradiated (1050 rads) allogeneic rats prevents the development of GVHD and results in stable chimerism. This study was developed to determine if UV-B modulation of BMT is useful for preconditioning recipients for the induction of tolerance to donor islets and heart allografts. Lethally irradiated Lewis rats that received UV-B irradiated (700 J/m2) WF BMT (10(8) BM cells) demonstrated stable chimerism without any evidence of GVHD. The stable Lewis chimeras were made diabetic with streptozotocin (STZ) at 28-35 days after BMT and subdivided into 3 experimental groups that received 1000-1200 islets from WF, Lewis, or BN (third-party), respectively. The results showed that group I diabetic Lewis chimeras accepted permanently (greater than 300 days) BM donor WF islets and became normoglycemic. When 3 of 6 Lewis chimeras transplanted with WF islets were rechallenged with WF hearts 60 days after islet grafts, they accepted both islets and cardiac allografts permanently (greater than 240 days). Similarly, the remaining 3 animals accepted Lewis cardiac allografts permanently, thus indicating tolerance to both donor and recipient alloantigens. Group II diabetic chimeras accepted permanently (greater than 300 days) recipient (Lewis) islets. In contrast, group III chimeras rejected acutely (7-8 days) third-party (BN) islets. However, when these animals that rejected BN islets and again became diabetic were retransplanted with BM donor-type (WF) islets, they became permanently normoglycemic (greater than 200 days). This finding emphasizes the specificity of the induction of tolerance in this model and the apparent lack of organ-specific sensitization. To define the underlying mechanism of tolerance, in vivo adoptive transfer of 10(8) spleen cells to naive Lewis or WF recipients, obtained from tolerant Lewis chimeras carrying donor islets and heart allografts, showed no prolongation of cardiac allografts in the unmodified syngeneic hosts, thus questioning the role of suppressor mechanisms in the tolerant rats. Furthermore, cells from the tolerant chimeras that showed no mixed lymphocyte reaction (MLR) response to Lewis or; WF alloantigens failed to suppress anti-Lewis and anti-WF MLR-response in coculture MLR. These results suggest that tolerance to donor alloantigens in the UV-B BMT model is most likely due to selective elimination of anti-BM donor helper or effector cell precursors (clonal deletion) rather than induction of suppressor cell activity. This study demonstrates that this relatively simple and effective approach to modulation of T cells in BM treatment may be potentially useful in the induction of tolerance to donor organs.     

Effect of immunosuppressants on T-cell subsets observed in vivo using carboxy-fluorescein diacetate succinimidyl ester labeling

BACKGROUND: The in vivo effects of immunosuppressants on T cells are classically determined using animal models of organ transplantation. These methods are technically difficult and time consuming. A simple in vivo method is needed for screening new immunosuppressants. METHODS: Donor mouse spleen cells were labeled with a fluorescent dye, carboxy-fluorescein diacetate succinimidyl ester (CFSE), and then injected into the blood of recipient severe combined immunodeficiency mice. Three days after the injection, spleen cells of the recipient mice were isolated and the proliferating alloreactive T cells were analyzed by flow cytometry. RESULTS: In control recipient mice, 50% of the T cells were proliferating, consisting of both CD4+ and CD8+ T cells. In cyclosporine- or FK506-treated mice, T-cell proliferation was suppressed in the CD4 subset but not in the CD8 subset. On the contrary, T-cell proliferation was significantly reduced in the CD8 subset but not in the CD4 subset in recipient mice treated with rapamycin. CONCLUSION: The present mouse model using carboxy-fluorescein diacetate succinimidyl ester labeling is simple and fast. It is useful for screening new immunosuppressants and for examining the effect on T-cell subsets.     

全身照射预处理供体对异基因大鼠肝移植的作用及对受体内CD4~+CD25~+调节性T细胞的影响

目的 探讨全身照射(TBI)预处理诱导大鼠肝移植术后急性排斥反应的发生机制,及CD4~+ CD25~+调节性T细胞的变化在诱导免疫耐受中的作用.方法 以雄性Lewis、DA大鼠为供、受体,随机分为正常对照组、同种肝移植组、自发免疫耐受组、急性排斥反应组.观察各组受体的生存时间及生存率,检测受体术后外周血中ALT、TB含量、Foxp3~+ CD4~+ CD25~+ 调节性T细胞和T细胞亚群上GITR的表达,检测受体术后第14天移植肝的病理变化和受体脾脏CTL杀伤活性.结果 自发免疫耐受组,术后经历短暂排斥反应最终获得免疫耐受并长期存活.急性排斥反应组,在术后第17～21天死亡,与其他组相比,外周血血清中ALT、TB含量明显升高,而Foxp3~+ CD4~+ CD25~+调节性T细胞比例明显降低.TBI预处理大鼠供肝致受体外周血中CD3~+ CD4~+ T细胞上GITR表达降低,CD3~+CD8~+T细胞上GITR表达增加,提高CTL的杀伤活性.结论 通过TBI清除供体大鼠肝移植物中携带的旁路淋巴细胞,致受体外周血中Foxp3~+ CD4~+ CD25~+调节性T细胞表达降低,而使CD3~+ CD8~+T细胞上GITR表达增加,共同诱导大鼠肝移植术后急性排斥反应发生和耐受障碍.     

Examination of the mechanisms responsible for tolerance induction after intrathymic inoculation of allogeneic bone marrow.

OBJECTIVE: This study examined the immunologic mechanism(s) responsible for the induction of transplantation tolerance in rats pretreated with intrathymic inoculation of donor strain bone marrow. SUMMARY BACKGROUND DATA: Induction of unresponsiveness may involve deletion and/or inactivation of donor-reactive T-cell precursors maturing in a thymus harboring donor alloantigen or generation of regulatory/suppressor cells. It was reasoned that, if unresponsiveness is caused by deletion of alloreactive clones, the presence of additional thymic tissue devoid of donor alloantigen permits normal maturation of T-cells and, thus, prevents induction of tolerance. However, if unresponsiveness were primarily mediated by regulatory/suppressor cells, the presence of noninoculated thymic tissue should not affect the induction of tolerance. METHODS: Three strategies were used to define the cellular basis of cardiac and islet allograft survival in WF recipients of intrathymic LEW donor bone marrow as follows: (1) inoculation of bone marrow either into the native thymus and/or into an ectopic thymus, (2) limiting dilution analyses of the frequency of precursor cytotoxic T-lymphocytes (CTLp), and (3) adoptive transfer to syngeneic secondary hosts. RESULTS: Inoculation of bone marrow into only one lobe of the native thymus and/or into an ectopic thymus did not promote consistent survival of subsequent LEW cardiac allografts. Tolerant hosts displayed significant reductions in CTLp frequencies against donor alloantigens. Adoptive transfer of spleen cells from tolerant WF hosts harboring long-standing cardiac allografts led to permanent survival of LEW cardiac allografts in all secondary recipients. However, transfer of spleen cells from WF animals that received intrathymic LEW bone marrow (but no cardiac allograft) did not promote survival of LEW cardiac allografts in naive secondary hosts. CONCLUSIONS: These results indicate that the unresponsive state after intrathymic inoculation of bone marrow cells is primarily mediated by deletion and/or inactivation of donor-specific T-cell precursors maturing in a chimeric thymus. The demonstration by adoptive transfer studies of putative regulatory/suppressor cells suggested an important role for the persistence of donor alloantigen (supplied by a vascularized allograft) in the maintenance of the unresponsive state.