The cellular basis of cardiac allograft rejection. IX. Ratio of naïve CD4+CD25+ T cells/CD4+CD25- T cells determines rejection or tolerance

Na?ve CD4+ T cells are central to allograft rejection, but include 3-10% CD4+CD25+ T cells that induce and maintain immune tolerance. Whether increasing the ratio of CD4+CD25+ T cells can inhibit rejection and induce tolerance is not known. This study examined the effects that na?ve CD4+CD25+ and CD4+CD25- T cells have on rejection of MHC incompatible PVG cardiac allografts in whole body irradiated DA rats. The ratio of CD4+CD25+ T cells to CD4+CD25- T cells was increased to examine if this delayed rejection. CD4+CD25- T cells alone restored near first set rejection time of 8-10 days and were significantly faster than unfractionated CD4+ T cells which nearly always took over 10 days to effect rejection. Enriched CD4+CD25+ T cells, either fresh or cultured with IL-2 and donor alloantigen, did not restore rejection. Admixing na?ve CD4+CD25+ T cells with CD4+ T cells at a ratio of 1:10 prevented graft destruction by rejection. Na?ve CD4+CD25+ T cells, either fresh or cultured with IL-2 and donor alloantigen, at a ratio of 1:1, prevented significant episodes of rejection and grafts survived >300 days. These grafts had large areas of normal myocardium but had some foci of CD4+, CD8+ and CD25+ cellular infiltration. This study found CD4+CD25- T cells were the principal mediators of rejection and na?ve CD4+CD25+ T cells partially inhibited the CD4+CD25- T cells in unfractionated CD4+ T cells. Increasing the ratio of na?ve CD4+CD25+ to CD4+CD25- T cells inhibited rejection allowing grafts to survive indefinitely and may induce transplant tolerance, without a need for long-term immunosuppression.     

Transfer of allograft specific tolerance requires CD4+CD25+T cells but not interleukin-4 or transforming growth factor-beta and cannot induce tolerance to linked antigens

BACKGROUND: The mechanisms by which CD4+T cells, especially CD4+ CD25+T cells, transfer allograft specific tolerance are poorly defined. The role of cytokines and the effect on antigen-presenting cells is not resolved. METHODS: Anti-CD3 monoclonal antibody (mAb) therapy induced tolerance to PVG heterotopic cardiac transplantation in DA rats. Peripheral CD4+T cells or CD4+ CD25+ and CD4+ CD25-T cell subsets were adoptively transferred to irradiated DA hosts grafted with PVG heart grafts. For specificity studies, tolerant CD4+T cells were transferred to hosts with Lewis or (PVGxLewis)F1 heart grafts. Cytokine mRNA induction and the requirement for interleukin (IL)-4 and transforming growth factor (TGF)-beta in the transfer of tolerance was assessed. RESULTS: CD4+T cells transferred specific tolerance and suppressed na?ve CD4+T cells capacity to effect rejection of PVG but not Lewis grafts. (PVGxLewis)F1 grafts had a major rejection episode but recovered. Later these hosts accepted PVG but not Lewis skin grafts. Adoptive hosts restored with tolerant or na?ve cells had similar levels of mRNA expression for all Th1 and Th2 cytokines and effector molecules assayed. Transfer of tolerance by CD4+T cells was not blocked by mAb to IL-4 or TGF-beta. CD4+ CD25-T cells from either na?ve or tolerant hosts effected rejection. In contrast neither tolerant nor na?ve CD4+ CD25+T cells restored rejection. CONCLUSIONS: Specific tolerance transfer required CD4+ containing CD4+ CD25+T cells. An inflammatory response with induction of mRNA for Th1 and Th2 cytokines plus cytotoxic effector molecules occurred, but IL-4 and TGF-beta were not essential. Inhibition of antigen presenting cells was not the sole mechanism as there was no linked tolerance.     

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.     

Tolerance to rat heart grafts induced by intrathymic immunomodulation is mediated by indirect recognition primed CD4+CD25+ Treg cells

BACKGROUND: In a rat model (PVG.R8-to-PVG.1U) disparate for one class I antigen, RT.1Aa, we previously demonstrated that intrathymic immunomodulation with donor antigens resulted in prolonged survival of cardiac allografts that underwent chronic rejection. However, long-term survivors developed a regulatory cell population that prevented both acute and chronic rejection when adoptively transferred into secondary graft recipients. The purpose of this study was to characterize these regulatory cells with particular emphasis on CD4+CD25+ Treg cells. METHODS: Spleens, lymph nodes, and peripheral blood lymphocytes of secondary tolerant recipients were characterized using antibodies to various T cell markers in flow cytometry. In vitro MLR and in vivo adoptive transfer experiments were conducted to investigate the involvement of CD4+CD25+ T cells in the observed tolerance. The presence of various cytokines in the sera of graft recipients and MLR culture supernatants was tested using ELISA. RESULTS: Tolerant recipients compared with naive rats had substantially higher percentages of CD4+CD25+ T cells in the spleen (28+/-3% vs. 11+/-5%) and blood (23+/-6% vs. 9+/-4%). Tolerant animals also had higher levels of serum IL-10 than naive and rejecting animals. CD4+CD25+ T cells from secondary long-term graft survivors inhibited donor-specific proliferative responses in vitro that was associated with high IL-10 production. Importantly, depletion of CD4+CD25+ T cells from splenocytes of tolerant rats abrogated their ability to transfer tolerance to tertiary graft recipients. CONCLUSIONS: Our data demonstrate that cardiac allograft tolerance in this model is mediated by CD4+CD25+ Treg cells primed by indirect recognition and is associated with high levels of IL-10.     

Targeting acute allograft rejection by immunotherapy with ex vivo-expanded natural CD4+ CD25+ regulatory T cells

BACKGROUND: Natural CD4CD25 regulatory T (Treg) cells have been implicated in suppressing alloreactivity in vitro and in vivo. We hypothesized that immunotherapy using ex vivo-expanded natural Treg could prevent acute allograft rejection in mice. METHODS: Natural CD4+ CD25+ Treg were freshly purified from naive mice via automated magnetic cell sorter and expanded ex vivo by anti-CD3/CD28 monoclonal antibody (mAb)-coated Dynabeads. Suppression was assayed in vitro by mixed lymphocyte reaction and in vivo by targeting cardiac allograft rejection. Survival of Treg or effector T (Teff) cells after adoptive transfer in vivo was tracked by flow cytometry and all allografts were examined by histology and immunohistochemistry. RESULTS: By day nine in culture, 26.6+/-5.3-fold of expansion was achieved by co-culture of fresh natural Treg with anti-CD3/CD28 mAb-coated Dynabeads and interleukin-2. Ex vivo-expanded Treg exerted stronger suppression than fresh ones towards alloantigens in vitro and prevented CD4 Teff-mediated but only delayed CD4+/CD8+ Teff-mediated heart allograft rejection in Rag-/- mice. Long-term surviving allografts showed no signs of acute or chronic rejection with graft-infiltrating Treg expressing CD25 and FoxP3. Infused Treg persisted and expanded long-term in vivo and trafficked through the peripheral lymphoid tissues. CD25 expression was dynamic in vivo: maintained CD25 expression on Treg was indicative for the preservation of allosuppression, while significantly enhanced CD25 expression on CD4+ effector T cells was most likely associated with T-cell expansion and graft rejection. CONCLUSIONS: Therapeutic use of ex vivo-expanded natural CD4+ CD25+ Treg may be a feasible and nontoxic modality for controlling allograft rejection or perhaps inducing allograft tolerance.     

利用RNA干扰诱导产生的CD8+CD28-抑制性T淋巴细胞的免疫学特性

目的 探讨通过RNA干扰技术诱导产生的CD8+ CD28-抑制性T淋巴细胞(Ts细胞)的免疫学特性.方法 取SD大鼠骨髓,培养分离树突状细胞(DC),设计、合成主要组织相容性复合物(MHC)Ⅰ类小片段干扰RNA(siRNA),以MHC Ⅰ siRNA转染DC.先以Wistar大鼠肠系膜淋巴组织液刺激转染MHCI siRNA的DC,然后将DC与从SD大鼠脾脏分离得到的CD8+T淋巴细胞共同培养,通过磁珠法分离出Ts细胞.分别在由SD大鼠脾脏淋巴细胞(反应细胞)和Wistar大鼠肠系膜淋巴组织细胞(刺激细胞)组成的混合淋巴细胞培养体系中加入数量不等的Ts细胞,检测反应细胞增殖情况;分别以Wistar大鼠肠系膜淋巴组织细胞和卵白蛋白(OVA)刺激SD大鼠脾脏淋巴细胞,然后再按不同比例加入Ts细胞,检测各组脾脏淋巴细胞的增殖情况;在由SD大鼠脾脏淋巴细胞、Wistar大鼠肠系膜淋巴组织液和Ts细胞组成的混合淋巴细胞培养体系中加入可溶性重组白细胞介素2(rrIL-2),观察IL-2对Ts细胞功能的影响;采用实时定量聚合酶链反应(PCR)测定Ts细胞中转化生长因子β(TGF-β和γ干扰素(IFN-γ)mRNA的表达,流式细胞仪和实时PCR检测Ts细胞上CD25分子的表达.结果 Ts细胞对SD大鼠脾脏淋巴细胞和Wistar大鼠肠系膜淋巴组织细胞之问的混合淋巴细胞反应(MLR)具有抑制作用,但对于SD大鼠脾脏淋巴细胞和OVA之间的MLR则无抑制作用.在SD大鼠脾脏淋巴细胞、Wistar大鼠肠系膜淋巴组织液和Ts细胞组成的混合淋巴细胞培养体系中加入rrIL-2后,SD大鼠脾脏细胞的增殖并无明显增加(P＞0.05).与CD8+CD28+T淋巴细胞和CD8+ T淋巴细胞比较,Ts细胞的TGF-β和IFN-γ mRNA的表达量明显升高(P＜0.01,P＜0.05),而CD25的表达量明显降低(P＜0.05).结论 采用经MHC I siRNA干扰的DC能够诱导CD8+T淋巴细胞产生CD8+ CD28-Ts细胞;Ts细胞在体外具有免疫抑制特性,其免疫抑制作用不被外源性IL-2所逆转,且其免疫调节作用具有抗原特异性.     

Regulation of transplant arteriosclerosis by CD25+CD4+ T cells generated to alloantigen in vivo

BACKGROUND: CD25+CD4+ regulatory T cells have been shown to suppress alloimmunity in various experimental settings. Here, we hypothesized that alloantigen-reactive regulatory T cells would reduce the severity of transplant arteriosclerosis. METHODS: CD25+CD4+ T cells from CBA mice that were pretreated with C57BL/6 (B.6) blood (donor-specific transfusion, DST) and nondepleting anti-CD4 Ab (YTS 177) were cotransferred with na?ve CBA CD25-CD4+"effector" T cells into CBA-rag-/- mice. These animals received aorta transplants from B.6 CD31-/- donors. CBA wild-type recipients of B.6 aorta grafts were pretreated with 177/DST directly. Some animals received 6x10(5) CD25+CD4+ T cells from pretreated mice to augment regulation on day -1. Grafts were harvested on day 30. RESULTS: Luminal occlusion of the graft caused by neointima formation was 29.3+/-19.4% (n=5) after transfer of effector T cells only. Co-transfer of CD25+CD4+ regulators reduced occlusion significantly (2.4+/-3.3%, n=3; P=0.009). This effect was partially abrogated in the presence of a CTLA4 blocking Ab (11.1+/-4.7%, n=4; P=0.008). Pretreating immunocompetent CBA recipients of B.6 aortic allografts with 177/DST did not reduce transplant arteriosclerosis significantly (43.0+/-15.7%, n=5 vs. 56.6+/-16.8%, n=5; 177/DST vs. controls; P=0.22). However, when pretreated primary CBA recipients received an additional transfer of 6 x 10(5) CD25+CD4+ T cells procured from other mice pretreated with 177/DST before transplantation, luminal occlusion of the graft was markedly reduced (33.0+/-7.6%, n=5; P=0.002). CONCLUSION: Regulatory T cells generated in vivo to alloantigen can prevent CD25-CD4+ T-cell-mediated transplant arteriosclerosis. In immunocompetent recipients, these cells have potential to be used as cellular immunotherapy to control transplant arteriosclerosis.     

RNA干扰树突细胞主要组织相容性复合物1表达后诱导抑制性T细胞对小肠移植耐受的影响

目的探讨RNA干扰树突细胞（Dc）组织相容性复合物1（MHC-1）表达后获得的CD8＋CD28-抑制性T细胞（Ts）对小肠移植免疫耐受的的影响。方法通过siRNA干扰DC MHC—I表达后,诱导获得CD8^＋CD28^-Ts。建立由Wistar大鼠移植到SD大鼠的小肠移植模型36例,随机分为A组（转染实验组）、B组（未转染组,注射普通T细胞）和C组（移植对照组,注射生理盐水）。术后14d,每组各随机挑选6例,取移植大鼠小肠和血液标本行移植小肠组织病理学检查．并检测移植大鼠血清TGF-β、IFN-γ水平及回肠黏膜Na^＋-K^＋-ATP酶活性,观察移植大鼠的存活时间。结果术后第14天,A组移植大鼠血清中TGF—β和IFN-γ表达水平高于B、C组（P〈0．05）。A组大鼠肠黏膜Na^＋-K^＋-ATP酶活性为（6．3±1．0）kU／g,明显高于B组的（3．6±0．9）kU／g和C组的（2．9±1．3）kU／g（P〈0．05）。A组移植小肠病理Parks评分分级明显低于B组和C组（P〈0．05）。A、B和C组移植后大鼠中位生存时间分别为32．0、17．5和21．0d,A组存活时间明显优于B组和C组（P〈0．05）。结论将RNA干扰DCMHC—I表达所获得的CD8^＋CD28^-Ts过继小肠移植大鼠．可以减轻移植大鼠的损伤程度．抑制免疫排斥反应．     

Combination of donor-specific blood transfusion with anti-CD28 antibody synergizes to prolong graft survival in rat liver transplantation

Donor-specific blood transfusion (DST) has been shown to effectively induce tolerance to certain allografts. In addition, it is well known that blockade of costimulatory signals reduces the ability of T cells to respond to alloantigens, prolonging allograft survival in some transplant models. We assessed the effects of single or multiple DSTs in the absence or presence of anti-CD28 monoclonal antibodies (mAbs) on graft function and host survival in rat liver transplantation (LTx). Fully MHC-mismatched adult male Dark Agouti (DA) and Lewis (LEW) rats were used as donors and recipients, respectively. Heparinized DA blood was administered to na?ve LEW rats 7 days before LTx [DST(-7d)], 14 and 7 days before LTx [DST(1 x 2)], twice a week for 2 weeks prior to LTx [DST(2 x 2)] and once a week for 4 weeks prior to LTx [DST(1 x 4)]. For some experiments, two different monoclonal antibodies (mAb) to rat CD28 (JJ316 and JJ319) were administered in combination with some DST treatments. We found that DST administration induced a time- and dose-dependent increase in host survival. Treatment of LEW rats with JJ316 or JJ319 mAb alone failed to prolong graft survival over untreated rats; however, the combination of DST(1 x 2) with JJ316 or JJ319 mAb induced indefinite survival at 100 days following surgery. We found that this protective effect was associated with increased numbers of splenic CD4+ CD45RC- but not CD4+ CD25+ foxp3+ T-cells in long-term survivors. Our data suggest that the combination of suboptimal DST with CD28 mAb induces donor-specific tolerance that correlates with enhanced numbers of regulatory T-cells.     

Spontaneous allograft tolerance in B7-deficient mice independent of preexisting endogenous CD4+CD25+ regulatory T-cells

BACKGROUND: Acute cardiac allograft rejection requires host, but not donor, expression of B7-1/B7-2 costimulatory molecules. However, acute cardiac rejection requires direct antigen presentation by donor-derived antigen presenting cells to CD4 T-cells and does not require indirect antigen presentation to CD4 T-cells. Given this discrepancy in the literature and that the consequence of allograft exposure in B7-deficient mice is unknown; the goal of the study was to examine the antidonor status of allografted B7-1/B7-2-deficient hosts. METHODS: C57Bl/6 B7-1/B7-2-/- mice were grafted with heterotopic BALB/c hearts. Recipients bearing long-term surviving allografts were used to examine the status of antidonor reactivity in vitro and in vivo. Tolerance was examined in vivo through adoptive transfer of splenocytes from graft-bearing animals to secondary immune-deficient Rag-1-/- hosts bearing donor-type or third-party cardiac allografts and by regulatory T-cell depletion with anti-CD25 antibody. RESULTS: When transferred to B7-replete Rag-1-/- recipients, cells from na?ve B7-1/B7-2-/- mice readily initiated cardiac allograft rejection. However, splenocytes transferred from long-term allograft acceptor B7-1/B7-2-/- hosts failed to reject donor-type hearts but acutely rejected third-party allografts. In addition, such cells did not reject (donorxthird-party) F1 allografts. Finally, in vivo depletion of regulatory T-cells did not prevent long-term acceptance. CONCLUSIONS: Results demonstrate that B7-deficient T-cells are capable of acute cardiac allograft rejection in a B7-replete environment. Importantly, results also show that B7-deficient hosts do not simply ignore cardiac allografts, but rather spontaneously develop transferable, donor-specific tolerance and linked suppression in vivo. Interestingly, this tolerant state does not require endogenous CD4+CD25+ regulatory T-cells.     

Adoptive transfer of transplantation tolerance mediated by CD4+CD25+ and CD8+CD28- regulatory T cells induced by anti-donor-specific T-cell vaccination

Previous studies have shown that vaccinating rodents with anti-donor-specific T cells significantly prolonged allograft survival; however, the putative mechanism of the tolerance remains unclear. In this study, we used the model of heterotopic heart transplantation between the C57BL/6 donor mice and BALB/c recipient mice vaccinated with anti-donor (C57BL/6) or anti-third party (C3H)-specific T cells to determine whether T cells prolong survival of mouse heart allografts and which cells were involved in induction of allograft tolerance. We observed that the mean survival time (MST) of C57BL/6 heart grafts in BALB/c mice vaccinated with anti-C57BL/6 specific T cells (43.1 +/- 4.7 days) was prolonged from that in untreated BALB/c mice (9.5 +/- 1.1 days) or BALB/c mice receiving anti-C3H-specific T cells (10.4 +/- 1.9 days). These results suggested that alloantigen-specific T-cell vaccination significantly prolonged cardiac allograft survival. The CD4+CD25+ or CD8+CD28- T cells purified from splenocytes of BALB/c mice vaccinated with anti-donor-specific T cells proliferated markedly in response to irradiated anti-C57BL/6-specific T cells in vitro. Adoptive transfer of these CD4+CD25+ or CD8+CD28- T cells to na?ve syngenic mice significantly prolonged the survival of heart allografts. These data suggested that anti-donor-specific T-cell vaccination induced development of CD4+CD25+ or CD8+CD28- regulatory T cells, which in turn mediated allogeneic-specific tolerance.     

Pretransplant donor peripheral blood mononuclear cells infusion induces transplantation tolerance by generating regulatory T cells

BACKGROUND: It was suggested that maintenance of tolerance to organ transplantation may depend on the formation of T regulatory cells. METHODS: Lewis (LW) rats were made tolerant to a Brown Norway kidney by pretransplant donor peripheral blood mononuclear cells (PBMC) infusion. At greater than 90 days after transplantation, lymph node cells (LN) and graft-infiltrating leukocytes (GIL) alloreactivity was tested in mixed lymphocyte reaction (MLR), coculture, and transwell experiments. GIL phenotype was analyzed by FACS. mRNA expression of cytokines and other markers was analyzed on CD4+ T cells from LN. The tolerogenic potential of tolerant cells in vivo was evaluated by adoptive transfer. RESULTS: Tolerant LN cells showed a reduced proliferation against donor stimulators but a normal anti-third-party alloreactivity. In coculture, these cells inhibited antidonor but not antithird-party reactivity of na?ve LN cells. Interleukin (IL)-10 and FasL mRNA expression was up-regulated in tolerant CD4+ T cells, but an anti-IL-10 monoclonal antibody (mAb) only partially reversed their inhibitory effect. Immunoregulatory activity was concentrated in the CD4+ CD25+ T-cell subset. In a transwell system, tolerant T cells inhibited a na?ve MLR to a lesser extent than in a standard coculture. Regulatory cells transferred tolerance after infusion into na?ve LW recipients. CD4+ T cells isolated from tolerized grafts were hyporesponsive to donor stimulators and suppressed a na?ve MLR against donor antigens. CONCLUSIONS: Donor-specific regulatory T cells play a role in tolerance induction by donor PBMC infusion. Regulatory activity is concentrated in the CD4+ CD25+ subset and requires cell-to-cell contact. Regulatory CD4+ T cells accumulate in tolerized kidney grafts where they could exert a protective function against host immune response.     

Infectious tolerance mediated by CD8+ T-suppresor cells after UV-B-irradiated donor-specific transfusion and rat heart transplantation

AIMS: CD8+CD28- human T-suppressor cells (Ts), which can be generated in vitro, act directly on APC rendering them tolerogenic to unprimed and primed CD4+ T cells. The aim of this study was to investigate the possibility that CD8+ T cells mediate the induction of tolerance in a heart transplantation model in rodents. MATERIALS AND METHODS: Blood from Lewis rats was UV-B-irradiated and transfused into ACI recipients on days -21, -14, and -7 before heart allograft transplantation on day 0. CD4(+) and CD8(+) T cells were positively selected from ACI rats, which had tolerated Lewis heart allografts for more than 100 days and were adoptively transferred to naive ACI rats pretreated (day -1) with gamma irradiation. These ACI rats underwent transplantation with Lewis hearts 24 hours after adoptive transfer of putative T-suppressor cells. RESULTS: Adoptive transfer of CD8(+) T cells from tolerant ACI to naive ACI rats significantly prolonged Lewis heart mean allograft survival time (MST +/- SD) to 69 +/- 13 days as compared with 15 +/- 1 and 14 +/- 1 days in animals adoptively transferred with CD4+ T cells or untreated controls, respectively (P < .001). Similarly, adoptive transfer of CD8(+) T cells from secondary ACI recipients to naive syngeneic animals also significantly prolonged survival of heart allografts to MST +/- SD of 72 +/- 4 for CD8(+) and 15 +/- 4 days for CD4(+) T cells (P < .001). CONCLUSIONS: These data demonstrate that allogeneic tolerance induced in ACI recipients by treatment with UV-B-irradiated blood from Lewis donors is mediated by CD8+ T-suppressor cells.     

CD4+ CD25+ Tr细胞与大鼠肝移植自发免疫耐受关系的研究

目的研究CD4^＋CD25^＋Tr细胞及其相关基因Foxp3与大鼠肝移植自发免疫耐受的关系。方法双袖套法建立大鼠原位肝移植模型;密度梯度离心法分离肝内淋巴细胞;免疫磁性分离法（MACS）分选CD4^＋CD25^＋Tr细胞,流式细胞术（FCM）检测所得细胞纯度。体外细胞增殖试验研究CD4^＋CD25^＋Tr细胞的免疫抑制作用。Western蛋白印迹法检测CD4^＋CD25^＋Tr细胞Scurfin蛋白表达。结果自发耐受组大鼠移植肝内CD4^＋CD25^＋Tr细胞含量显著高于急性排斥组。混合淋巴细胞反应中,LEW大鼠的脾细胞比DA大鼠自身的脾细胞更能刺激CD4^＋CD25^＋T细胞的增殖。CD4^＋CD25^-T细胞能抑制CD4^＋CD25^-T细胞的增殖,当加入外源性IL-2（200U／ml）时,该抑制作用被逆转。结论转录因子Foxp3介导的CD4^＋CD25^＋Tr细胞的免疫抑制作用可能是诱导大鼠肝脏移植自发免疫耐受的机制之一。     

Infiltration of tumor-reactive transforming growth factor-beta insensitive CD8+ T cells into the tumor parenchyma is associated with apoptosis and rejection of tumor cells

BACKGROUND: TGF-beta is a potent immunosuppressant. High levels of TGF-beta produced by cancer cells have a negative inhibition effect on surrounding host immune cells and leads to evasion of the host immune surveillance and tumor progression. In the present study, we report a distinct ability of tumor reactive, TGF-beta-insensitive CD8+ T cells to infiltrate into established tumors, secrete relevant cytokines, and induce apoptosis of tumor cells. METHODS: CD8+ T cells were isolated from the spleens of C57BL/6 mice, which were primed with irradiated mouse prostate cancer cells, the TRAMP-C2 cells. After ex vivo expansion, these tumor reactive CD8+ cells were rendered TGF-beta-insensitive by infection with a retroviral (MSCV)-mediated dominant negative TGF-beta type II receptor (TbetaRIIDN). Control CD8+ cells consist of those transfected with the GFP-only empty vector and na?ve CD8+ T cells. Recipient mice were challenged with a single injection of TRAMP-C2 cells 21 days before adoptive transfer of CD8+ T cells was performed. Forty days after the adoptive transfer, all animals were sacrificed. The presence of pulmonary metastases was evaluated pathologically. Serial slides of malignant tissues were used for immunofluorescent staining for different kinds of immune cell infiltration, cytokines, and apoptosis analysis. RESULTS: Pulmonary metastases were either eliminated or significantly reduced in the group receiving adoptive transfer of tumor-reactive TGF-beta-insensitive CD8+ T cells (3 out of 12) when compared to GFP controls (9 out of 12), and na?ve CD8+ T cells (12 out of 12). Results of immunofluorescent studies demonstrated that only tumor-reactive TGF-beta-insensitive CD8+ T cells were able to infiltrate into the tumor and mediate apoptosis when compared to CD4+ T cells, NK cells, and B cells. A large amount of cytokines such as perforin, nitric oxide, IFN-gamma, IL-2, TNF-alpha were secreted in tumor tissue treated with tumor-reactive TGF-beta-insensitive CD8+ T cells. No immune cells infiltration and cytokine secretion were detected in tumor tissues treated with na?ve T cells and GFP controls. CONCLUSIONS: Our results demonstrate the mechanism of anti-tumor effect of tumor-reactive TGF-beta-insensitive CD8+ T cells that adoptive transfer of these CD8+ T cells resulted in infiltration of these immune cells into the tumor parenchyma, secretion of relevant cytokines, and induction of apoptosis in tumor cells. These results support the concept that tumor-reactive TGF-beta-insensitive CD8+ T cells may prove beneficial in the treatment of advanced cancer patients.     

A Significant Expansion of CD8 CD28 T-Suppressor Cells in Adult-to-Adult Living Donor Liver Transplant Recipients

Background

The appearance of human regulatory CD8⁺ CD28⁻ T-suppressor (Ts) cells has been associated with a reduced need for maintenance immunosuppression in cadaveric heart- kidney transplant recipients and pediatric liver-intestine transplant recipients. However, few data are available in adult-to-adult living donor liver transplantation (A-A LDLT).

Materials and Methods

To study the population of CD8⁺ CD28⁻ Ts cells in A-A LDLT, we performed flow cytometry on whole blood specimens obtained from 20 transplant recipients, 18 end-stage liver disease patients, and 20 normal controls. Meanwhile, we measured the trough levels of immunosuppressants and monitored graft function in transplant recipients. We retrospectively reviewed the clinical data of the 20 recipients.

Results

A significant expansion of CD8⁺ CD28⁻ Ts cells was observed among recipients of A-A LDLT as compared with a disease control group (P = .000) or healthy individuals (P = .000). All recipients were free of acute cellular rejection episodes. During the follow-up period, no grafts were lost due to acute or chronic rejection.

Conclusion

Expansion of CD8⁺ CD28⁻ Ts cells in A-A LDLT seemed to be associated with a decreased occurrence of acute or chronic rejection and sustained good graft function. Based on our low dosages of immunosuppressants for recipients of A-A LDLT, we suggest that this strategy may promote expansion of CD8⁺ CD28⁻ Ts cells, which can conversely maintain the low immunosuppressant dosages.     

Superagonistic CD28 Antibody Induces Donor‐Specific Tolerance in Rat Renal Allografts

The ultimate goal of organ transplantation is to establish graft tolerance where CD4+CD25+FOXP3+ regulatory T (Treg) cells play an important role. We examined whether a superagonistic monoclonal antibody specific for CD28 (CD28 SA), which expands Treg cells in vivo, would prevent acute rejection and induce tolerance using our established rat acute renal allograft model (Wistar to Lewis). In the untreated or mouse IgG‐treated recipients, graft function significantly deteriorated with marked destruction of renal tissue, and all rats died by 13 days with severe azotemia. In contrast, 90% of recipients treated with CD28 SA survived over 100 days, and 70% survived with well‐preserved graft function until graft recovery at 180 days. Analysis by flow cytometry and immunohistochemistry demonstrated that CD28 SA induced marked infiltration of FOXP3+ Treg cells into the allografts. Furthermore, these long‐surviving recipients showed donor‐specific tolerance, accepting secondary (donor‐matched) Wistar cardiac allografts, but acutely rejecting third‐party BN allografts. We further demonstrated that adoptive transfer of CD4+CD25+ Treg cells, purified from CD28 SA‐treated Lewis rats, significantly prolonged allograft survival and succeeded in inducing donor‐specific tolerance. In conclusion, CD28 SA treatment successfully induces donor‐specific tolerance with the involvement of Treg cells, and thus the therapeutic value of this approach warrants further investigation and preclinical studies.     

Aggressive skin allograft rejection in CD28-/- mice independent of the CD40/CD40L costimulatory pathway.

CD28-/- mice have been utilized to study the role of B7/CD28 and B7-CTLA4 interactions. There is evidence that CTLA4 ligation may be critical for tolerance induction. The aim of the current study is to further investigate rejection responses of CD28-/- mice and to define the role of B7-CTLA4 interactions in the absence of the CD40 and CD28 pathways. Balb/c skin allografts were transplanted onto C57BL/6 (B6) wild type or CD28-/- mice treated with anti-CD40L, CTLA4-Ig, or combination blockade. To investigate the cellular mechanism of rejection in CD28-/- recipients, mice were treated with anti-CD4 or anti-CD8 antibodies prior to treatment with costimulation blockade. The fluoroscein dye CFSE was utilized to study T cell expansion in vivo. Surprisingly, treatment of B6 CD28-/- mice with CTLA4-Ig alone (MST 12d), anti-CD40L alone (MST 13d), or combined blockade (MST 13d) had no effect on allograft survival compared to untreated B6 CD28 mice (MST 11d). CD28-/- recipients depleted of CD4+ cells and treated with CTLA4-Ig, anti-CD40L, or combination blockade also did not have prolonged survival compared with untreated mice (MST 10d). In contrast, CD28-/- recipients depleted of CD8+ cells had markedly prolonged allograft survival when treated with either anti-CD40L alone (MST 49d) or with combination blockade (MST 57d). Studies utilizing CFSE demonstrated that CD28-/- CD8+ T cells are not defective in in vivo proliferation responses compared with wild type CD8 cells. Thus, CD28-/- CD8+ T cells are responsible for aggressive rejection responses of CD28-/- mice independent of the CD40 pathway. In addition, CD40L blockade does not result in CD4+ T cell tolerance in CD28 recipients, despite an intact B7-CTLA4 pathway.     

Transfer of "infectious" cardiac allograft tolerance induced by donor-specific transfusion

BACKGROUND: "Infectious tolerance" has been defined as the tolerance induced in a new recipient by the adoptive transfer of cells from a recipient accepting an allograft after anti-CD4 and anti-CD8 monoclonal antibody treatment. A clear understanding of the mechanisms responsible for graft acceptance after donor-specific blood transfusion (DST) has remained elusive. We examined the development and "infectious" nature of immunologic changes resulting in indefinite survival of LEW to DA rat cardiac allografts after DST alone without the need for antibody. METHODS: One hundred x 10(6) LEW splenocytes (SC) as DST were injected intravenously into DA recipients 7 days before LEW cardiac transplantation. Subsequently, 100 x 10(6) SC harvested from a DA recipient 30, 60, or 100 days after graft acceptance were adoptively transferred into lightly gamma-irradiated (450 rad) na?ve DA recipients 24 hours before a second LEW cardiac allograft. Subsequent graft function was determined. RESULTS: Adoptive transfer of SC from the DST-treated DA rats 30 days after LEW heart transplant acceptance into na?ve gamma-irradiated DA rats failed to transfer tolerance to LEW cardiac allografts. However, SC from DA rats bearing LEW hearts for more than 60 days induced indefinite tolerance to all LEW hearts. This infectious tolerance could be adoptively transferred again to a second DA recipient. CONCLUSIONS: DST-generated regulatory cells can downregulate na?ve lymphocytes to promote allograft acceptance. This tolerance can be expanded and serially transferred to a subsequent na?ve cardiac recipient.