Role of CD4(+)CD25(+) T regulatory cells in IL-2-induced vascular leak

T regulatory cells (CD4(+)CD25(+)) play an important role in the regulation of the immune response. However, little is known about the ability of T regulatory cells to regulate endothelial cell (EC) damage following activation of lymphocytes with IL-2. Therefore, in the current study, we examined the role of T regulatory cells and the subsequent T(h)1/T(h)2 bias in IL-2-mediated EC injury using the well-characterized C57BL/6 (T(h)1-biased) and BALB/c (T(h)2-biased) models. Following IL-2 treatment, BALB/c mice were less susceptible to IL-2-induced vascular leak syndrome (VLS) compared with C57BL/6 mice. Splenocytes from BALB/c mice displayed less cytotoxicity against ECs compared with those from C57BL/6 mice. Interestingly, BALB/c mice had significantly higher numbers of CD4(+)CD25(+) T regulatory cells, which proliferated more profoundly following IL-2 treatment, compared with CD4(+)CD25(+) T regulatory cells from C57BL/6 mice. In addition, T regulatory cells from naive BALB/c mice were more potent suppressors of anti-CD3 mAb-stimulated proliferation of T cells than similar cells from C57BL/6 mice. Depletion of T regulatory cells in both BALB/c and C57BL/6 mice led to a significant increase in IL-2-induced VLS. Together, the results from this study suggest that CD4(+)CD25(+) T regulatory cells play an important role in the regulation of IL-2-induced EC injury.     

Blocking of IL-6 signaling pathway prevents CD4+ T cell-mediated colitis in a T(h)17-independent manner

Naive CD4(+) T cells rapidly proliferate to generate effector cells after encountering an antigen and small numbers survive as memory T cells in preparation for future immunological events. In the present work, adoptive transfer of naive CD4(+) T cells into RAG2(-/-) mice caused the generation of memory-type effector T cells including T(h)1, T(h)2, T(h)17 and regulatory T cells, and eventually induced T cell-dependent colitis. We found here that blocking of the IL-6R with a specific mAb remarkably inhibited the CD4(+) T cell-mediated colitis in parallel with the inhibition of T(h)17 cell generation. However, the transfer of naive CD4(+) T cells prepared from IL-17(-/-) mice still induced severe colitis. At the effector phase, the mAb significantly inhibited IL-17 but not IFN-gamma production. The blockade of IL-6 signaling enhanced the generation of IL-4- and IL-10-producing CD4(+) T cells, and inhibited up-regulation of tumor necrosis factor -alpha mRNA expression in the colon. These findings clearly demonstrated that IL-6 is a critical factor for the induction of colitis by expansion of naive CD4(+) T cells in RAG2(-/-) mice. Thus, the IL-6-mediated signaling pathway may be a significant therapeutic target in T cell-mediated autoimmune diseases.     

A co-stimulatory molecule on activated T cells,H4/ICOS,delivers specific signals in T(h) cells and regulates their responses

We examined the co-stimulatory activity of H4/ICOS on murine activated CD4(+) T cells and found that the cross-linking of H4/ICOS enhanced their proliferation, in addition to raising IFN-gamma, IL-4 and IL-10 production to levels comparable to those induced by CD28. However, IL-2 production was only marginally co-stimulated by H4/ICOS. This distinct pattern of lymphokine production appears to be induced by a specific intracellular signaling event. Compared with CD28, H4/ICOS dominantly elicited the Akt pathway via phosphatidylinositol 3-kinase. In addition, mitogen-activated protein kinase family kinases were activated in different ways by CD28 and H4/ICOS. The strong phosphorylation of p46 c-Jun N-terminal kinase was observed upon CD28 co-stimulation, but was less potently induced by H4/ICOS. The strain diversity in the induction of H4/ICOS was recognized. The expression of H4/ICOS on BALB/c activated CD4(+) T cells was >6-fold higher compared with C57BL/6 activated CD4(+) T cells. Furthermore, BALB/c activated CD4(+) T cells exhibited more T(h)2-deviated lymphokine production as compared with C57BL/6 activated CD4(+) T cells and signaling through H4/ICOS during the primary stimulation of naive CD4(+) T cells promoted the generation of T(h)2 cells. Thus, the difference in H4/ICOS expression on activated CD4(+) T cells, which is regulated among the mouse strains, may also regulate the polarization of T(h) cells.     

A central role for IL-2 in fate determination of mature T cells--I: role in determining the Th1/Th2 profile in primary T cell cultures.

IL-2 signaling appears to play a significant role in enabling the synthesis of T(h)2 cytokines in an in vitro system for studying primary T cell responses. When T cells from C57BL/6J or BALB/c strains of mice were activated in vitro and re-stimulated through their TCR complex 48 h later, CD4(+) T cells producing the T(h)2 cytokines IL-4 and IL-10 were found only when IL-2 was present. IL-2 also enhanced IFN-gamma synthesis in C57BL/6J cells but not in BALB/c cells. By up-regulating production of anti-inflammatory T(h)2 cytokines during a primary response, IL-2 may play a critical role in limiting T(h)1-mediated responses.     

IL-2通过上调naive CD4+T细胞SOCS-3表达抑制CD4+T细胞的极化和增殖

目的 探讨IL-2预孵育naive CD4+T细胞后,对其极化(polarization)方向和增殖(proliferation)能力的影响.方法 用终浓度为50 U/ml的IL-2分别预孵育DOI 1.10 TCR转基因小鼠和C57BL/6N小鼠naYve CD+T细胞,在不同时间点用荧光实时定量PCR(real-time PCR)检测这两种细胞中SOCS-3(suppressor of cytokine signal-3)表达的变化.预孵育4 h后,洗去IL-2,分别加入卵清白蛋白(OVA)和灭活后的BALB/c脾细胞,在存在细胞因子IL-12或IL-4情况下共培养14 d后,用流式细胞仪检测TH1细胞活化和极化的标志IL-12R β1、IL-12Rβ2,对C57BL/6N小鼠nave CD4+2T细胞的极化中还榆测TH2极化的标志--细胞内IL-4的表达;同时将无IL-2预孵育的作为对照组.结果 IL-2预孵育后这两种鼠naive CD4+T细胞内的SOCS-3表达于6 h达高峰;在SOCS-3表达达高峰后分别给予特异性抗原和同种异基因抗原刺激,其向TH1方向的极化和增殖能力都受到明显的抑制(P<0.05).结论 IL-2预孵育naive CD+T细胞后,可以上调SOCS-3的表达;SOCS-3的上调表达可以抑制naive CD4+T细胞接受特异性抗原和同种异基因抗原刺激后向TH1方向的极化和增殖能力.     

Linkage analysis of the genetic determinants of T-cell IL-4 secretion, and identification of Flj20274 as a putative candidate gene

The activation-induced differentiation of naive CD4+ T cells generates functionally divergent type 1 helper T cells (Th1) or type 2 helper T cells (Th2) effector cell populations, characterized by secretion of Interferon (IFN)-gamma or Interleukin (IL)-4, respectively. Inappropriate generation of Th subsets may contribute to immune dysfunction. The decision to generate Th1/Th2 lineages is critically regulated by cytokines, such that IL-12 induces Th1 differentiation, while IL-4 induces Th2 differentiation. Genetic factors influence the pathway of Th differentiation, as displayed by the preferential generation of divergent Th populations by different inbred strains of mice. We employ two complementary genetic techniques to identify genes that regulate the default IL-4 secretion profiles of T cells from BALB/c and B6 mice. We performed a genome-wide linkage analysis of the progeny of a backcross between BALB/c and B6 mice to identify three loci, T-cell secretion of interleukin-4 (Tsi)1-3, on chromosomes 7, 19 and 15, respectively, which regulate in vitro T-cell IL-4 production. We have also employed mRNA representational difference analysis to isolate a gene, Flj20274, which is differentially expressed in T cells that secrete high levels of IL-4. Significantly, Flj20274 was mapped to the point of peak linkage within Tsi1 and is a strong candidate for Tsi1.     

Chronic exposure to superantigen induces regulatory CD4(+) T cells with IL-10-mediated suppressive activity

The repeated injection of bacterial superantigens (SAg), such as staphylococcus enterotoxin (SE) A or B, has been shown in mice to induce a state of unresponsiveness characterized by the lack of secretion of Th1 lymphokines, such as IL-2 and IFN-gamma, following subsequent SAg challenge. We made the observation, in vivo as well as in vitro, that unresponsiveness to SAg could be transferred from SEA- to SEB-reactive T cells (and reversibly from SEB- to SEA-specific T cells) in C57BL/6 mice but not in BALB/c mice. Since C57BL/6 mice, unlike BALB/c mice, possess TCR V(beta)3+ and V(beta)11+ T cells able to react with both SEA and SEB, we hypothesized that SAg-unresponsive V(beta)3(+) and V(beta)11+ T cells could mediate linked suppression of other SAg-reactive T cells. To analyze further this possibility, spleen cells from BALB/c mice made unresponsive to SEB were tested for their capacity to suppress the response of normal BALB/c cells to SEB. The production of both IFN-gamma and IL-2 following SEB stimulation was greatly impaired in co-cultures containing CD4(+) T cells, but not CD8(+) T cells, isolated from unresponsive animals. In vivo, the production of both IFN-gamma and IL-2 responses to SEB was dramatically reduced in animals adoptively transferred with unresponsive spleen cells. This suppression was abrogated in recipients injected with neutralizing anti-IL-10 antibodies. Moreover, in animals made unresponsive to SEB, SAg-reactive CD4(+) T cells were found to express high levels of CTLA-4, a molecule recently described to play an essential role in the suppressive function of regulatory T cells. Taken together these results demonstrate that the repetitive injection of SAg induces the differentiation of regulatory CD4(+) T cells capable of suppressing SAg-reactive naive T cells.     

Human CD4+ central and effector memory T cells produce IL-21: effect on cytokine-driven proliferation of CD4+ T cell subsets

IL-21 regulates certain functions of T cells, B cells, NK cells and dendritic cells. Although activated CD4(+) T cells produce IL-21, data identifying the specific CD4(+) T cell subsets that produce IL-21 are conflicting. In a previous study, mouse IL-21 message was detected in T(H)2, whereas human IL-21 (hIL-21) message was found in both T(H)1 and follicular helper T cells. To identify the IL-21-secreting cell populations in human, we established a hybridoma cell line producing an anti-hIL-21 mAb. Intracellular hIL-21-staining experiments showed that hIL-21 was mainly expressed in activated CD4(+) central memory T cells and in activated CD4(+) effector memory T cells, but not in activated CD4(+) naive T cells. Moreover, IL-21 was produced upon activation by some IFN-gamma-producing T(H)1-polarized cells and some IL-17-producing T(H)17-polarized cells, but not by IL-4-producing T(H)2-polarized cells. These results suggest that specific CD4(+) T cell populations produce IL-21. In the functional analysis, we found that IL-21 significantly enhanced the cytokine-driven proliferation of CD4(+) helper T cells synergistically with IL-7 and IL-15 without T cell activation stimuli. Taken together, IL-21 produced from CD4(+) memory T cells may have a supportive role in the maintenance of CD4(+) T cell subsets.     

Nasal tolerance induces antigen-specific CD4+CD25- regulatory T cells that can transfer their regulatory capacity to naive CD4+ T cells

The mucosal immune system is uniquely adapted to elicit immune responses against pathogens but also to induce tolerogenic responses to harmless antigens. In mice, nasal application of ovalbumin (OVA) leads to suppression of both T(h)1 and T(h)2 responses. This tolerance can be transferred to naive mice by CD4(+) T(r) cells from the spleen. Using the allotypic Ly5 system, we were able to demonstrate in vivo that T(r) cells not only suppress naive CD4(+) T cells, but also induce them to differentiate into T(r) cells. The effector function of these mucosal T(r) cells is not restricted by cytokine polarization, since T(r) cells from T(h)1-tolerant mice can suppress a T(h)2 response and vice versa. Transfer of splenic CD4(+)CD25(+) and CD4(+)CD25(-) T cell subsets from OVA-tolerized mice revealed that both subsets were equally able to suppress a delayed-type hypersensitivity response in acceptor mice. In contrast to the CD25(-) T cell subset, the CD25(+) cells were not specific for the antigen used for tolerization. Together, these findings demonstrate a role for CD4(+)CD25(-) T(r) cells in mucosal tolerance, which suppresses CD4(+) T cells in an antigen-specific fashion, irrespective of initial T(h)1/T(h)2 skewing of the immune response. This offers a major advantage in the manipulation of mucosal tolerance for the treatment of highly cytokine-polarized disorders such as asthma and autoimmune diseases.     

gamma(c) cytokines provide multiple homeostatic signals to naive CD4(+) T cells

Cytokines signaling through receptors sharing the common gamma chain (gamma(c)), including IL-2, IL-4, IL-7, IL-9, IL-15 and IL-21, are critical for the generation and peripheral homeostasis of B, T and NK cells. To identify unique or redundant roles for gamma(c) cytokines in naive CD4(+) T cells, we compared monoclonal populations of CD4(+) T cells from TCR-Tg mice that were gamma(c) (+), gamma(c) (-), CD127(-/-) or CD122(-/-). We found that gamma(c) (-) naive CD4(+) T cells failed to accumulate in the peripheral lymphoid organs and the few remaining cells were characterized by small size, decreased expression of MHC class I and enhanced apoptosis. By over-expressing human Bcl-2, peripheral naive CD4(+) T cells that lack gamma(c) could be rescued. Bcl-2(+) gamma(c) (-) CD4(+) T cells demonstrated enhanced survival characteristics in vivo and in vitro, and could proliferate normally in vitro in response to antigen. Nevertheless, Bcl-2(+) gamma(c) (-) CD4(+) T cells remained small in size, and this phenotype was not corrected by enforced expression of an activated protein kinase B. We conclude that gamma(c) cytokines (primarily but not exclusively IL-7) provide Bcl-2-dependent as well as Bcl-2-independent signals to maintain the phenotype and homeostasis of the peripheral naive CD4(+) T cell pool.     

Adoptive transfer of CD4+ T cells specific for subunit A of Helicobacter pylori urease reduces H. pylori stomach colonization in mice in the absence of interleukin-4 (IL-4)/IL-13 receptor signaling

Protection in the murine model of Helicobacter pylori infection may be mediated by CD4+ T cells, but the mechanism remains unclear. To better understand how protection occurs in this model, we generated and characterized H. pylori urease-specific CD4+ T cells from BALB/c mice immunized with Salmonella enterica serovar Typhimurium expressing H. pylori urease (subunits A and B). The CD4+ T cells were found to be specific for subunit A (UreA). Upon antigen-specific stimulation, expression of interleukin 4 (IL-4), IL-10, gamma interferon (IFN-gamma), and tumor necrosis factor alpha was induced. Immunocytochemical analysis showed that the majority of cells produced IFN-gamma and IL-10. Adoptive transfer of the UreA-specific CD4+ T cells into naive syngeneic recipients led to a threefold reduction in the number of bacteria in the recipient group when compared to that in the nonrecipient group. Stomach colonization was also reduced significantly after transfer of these cells into patently infected mice. Adoptive transfer of UreA-specific CD4+ T cells into IL-4 receptor alpha chain-deficient BALB/c mice indicated that IL-4 and IL-13 were not critical in the control of bacterial load. In addition, synthetic peptides were used to identify three functional T-cell epitopes present in subunit A which were recognized by the UreA-specific T cells. Analysis of H. pylori-specific cellular immune responses in recipient challenged and nonrecipient infected mice indicated a strong local restriction of the response in infected animals. The implications of these findings for the mechanism of protection and the development of peptide-based vaccination are discussed.     

Early in vitro priming of distinct T(h) cell subsets determines polarized growth of visceralizing Leishmania in macrophages

An in vitro priming system of murine naive splenocytes was established to investigate early immune responses to LEISHMANIA: chagasi, the agent of visceral leishmaniasis in the New World. Priming of splenocytes from resistant C3H and CBA or susceptible BALB and B10 mice with L. chagasi resulted in blast transformation and in proliferating parasite-specific CD4(+) T cells secreting a differential complement of cytokines (IFN-gamma and low IL-10 levels for resistant T cells; IFN-gamma, IL-4 and high IL-10 levels for susceptible T cells). After priming, intracellular parasite load was much higher in susceptible than in resistant-type splenocyte cultures. On the other hand, infection of purified splenic macrophages from either resistant or susceptible mice with live L. chagasi promastigotes, resulted in comparable parasite loads. Moreover, when early CD4(+) T cell priming in splenocyte cultures was disrupted with anti-CD4 mAb, polarized parasite growth was abolished, becoming comparable in resistant and susceptible cultures. Neutralizing IL-4 activity during splenocyte priming did not affect the final parasite load in susceptible cultures. However, neutralizing IL-10 activity markedly decreased parasite load in susceptible, but not in resistant splenic macrophages. These results suggest that IL-10 plays an important role in L. chagasi infection in susceptible hosts. The results also indicate that innate control of growth of a visceralizing LEISHMANIA: in splenic macrophages results from the ability to activate different CD4(+) T cell subsets.     

Leishmania major induces differential expression of costimulatory molecules on mouse epidermal cells

Levels of expression of costimulatory molecules have been proposed to influence the outcome of antigen-specific T cell priming. We found that Leishmania major selectively modulated the expression of costimulatory molecules on various populations of epidermal cells. B7.2 expression was down-regulated on Thy1.2+ epidermal cells (keratinocytes) from disease-resistant C3H mice, but not from disease-susceptible BALB/c mice. In addition, epidermal cells from BALB/c mice showed a down-regulation of B7.1 expression on NLDC 145+ Langerhans cells. In vitro T cell priming experiments, using syngeneic epidermal cells as antigen-presenting cells (APC), showed that the production of IFN-gamma was inhibited when either B7.1 or B7.2 signaling pathways were blocked. Blockade of B7.2, but not B7.1, significantly inhibited the ability of epidermal cells to induce IL-4 production from CD4+ T cells. In addition, C3H CD4+ T cells, which were unable to secrete detectable levels of IL-4 in cultures with syngeneic APC, were now able to secrete IL-4 following presentation of L. major antigens by congenic BALB/K epidermal cells. Conversely, C3H epidermal cells supported the priming of BALB/K CD4+ T cells for IL-4 production in vitro. Thus, the differential expression of B7 molecules on epidermal cells may not represent the sole factor governing the polarization of L. major-specific CD4+ T cells in vitro.     

Functional CD4+T cell subsets defined by expression of CD45RC and NTA260 antigens and age-associated polarization in murine lupus

Using two mAb, one specific to the alternative exon 6-dependentepitope of CD45 molecules(JH6.2) and one a natural thymocytotoxicautoantibody (NTA) with an unknown reactive epitope (NTA260),we subdivided splenic CD4⁺ T cells from 2-month-old BALB/c miceinto five phenotypically distinct subsets. CD45RC⁺NTA260^–(SI) cells were phenotypically analogous to CD4⁺ T cells predominatingin newborn mice and produced a significant amount of IL-2, butnot so IL-4, IL-10 or IFN- when stimulated with immobilizedanti-CD3 mAb in vitro. They appeared to consist mainly of naiveT_hP cells. The CD45RC⁺;NTA260⁺ (S II) subset also produced IL-2,but not other cytokines; however, the IL-2 levels produced weremuch higher than seen with the S I subset, thereby suggestingthe predominance of further maturated T_hP cells. The D45RC^–NTA260⁺(S III) subset mainly produced IL-4, IL-10, IFN- and less IL-2,and contained memory cells that helped the secondary antibodyresponse to a recall antigen, and hence contained T_h2 and probablya mixture of T_h0 and T_h1 cells. The CD45RC^–NTA260^–(S IV) subset was a poor responder to the immobilized anti-CD3mAb. The CD45RC^brightNTA260^dull(S V) subset consisted of a smallnumber of cells that were phenotypically analogous to activatedCD4⁺ T cells. While an age-associated decrease in the proportionof S I and less markedly in S II and in turn increase in S IIIsubsets of CD4⁺ T cells occurred in normal BALB/c mice, autoimmunedisease-prone (NZBxNZW)F₁ mice showed a marked age-associateddecrease in the proportion of not only S I, II but also IIIsubsets. As aged (NZBxNZW)F₁ mice carry CD4⁺ T helper cellsfor IgG anti-DNA antibody production, such age-associated polarizationto the S IV subset appears to be critical in the pathogeneslsof autoimmune disease in these mice.     

Th2-type granuloma development in acute murine schistosomiasis is only partly dependent on CD4+ T cells as the source of IL-4

Schistosome granulomas produce IL-4, important for Th2 granuloma expression. We defined the origins of IL-4 within these granulomas and the role of IL-4-producing CD4(+) T cells in Th2 granuloma development. Dispersed granuloma cells spontaneously produced IL-4 independently of T cells, whereas IL-5 production was T cell dependent. Granuloma IL-4 mRNA localized to the non-T cells and IL-5 to T cells. Granuloma CD4(+) T and NK cells, but not B cells produced IL-4 and IL-5 in vitro. B cell-/- mice generated Th2 granulomas that produced IL-4 and IL-5 normally. Granuloma eosinophils expressed no IL-4 or IL-5 mRNA. Granulomas in WWv mast cell-deficient mice lacked mast cells. The dispersed granuloma cells from WWv mice released IL-4 only after T cell stimulation, suggesting that mast cells influenced the constitutive component of IL-4 production. Rag-1 animals (T/B/NK T cell deficient) given schistosomiasis after reconstitution with splenocytes from naive mice produced Th2 granulomas. Mice reconstituted to create selective CD4(+) T cell IL-4 knockout animals developed eosinophilic granulomas that made IL-4. Thus, granulomas contain several cell types that produce IL-4. Mast cells are not needed to form Th2 granulomas, but influence IL-4 release. Th2 granuloma development in schistosomiasis is only partly dependent on IL-4-producing CD4(+) T cells.     

雷帕霉素对同种移植耐受模型CD4+CD25+ T细胞活性的影响

目的：研究雷帕霉素（Rapa）对同种移植耐受个体CD4^＋CD25^＋ T细胞体内负免疫调节作用的影响.方法：建立同种皮肤移植模型, 受体鼠术前预输注供体鼠脾细胞, 术后给予环孢素A（CsA）进行耐受诱导.移植后第14天提取耐受诱导模型鼠的T细胞, 经不同浓度Rapa和/或IL-2体外处理后, 混合淋巴细胞反应（MLR）确定T细胞特异增殖水平;流式细胞术（FCM）检测CD4^＋CD25^＋ T细胞比例变化;RT-PCR检测Foxp3 mRNA表达情况;ELISA检测细胞培养不同时间后上清中IL-10的变化.然后将Rapa和/或IL-2处理的T细胞过继转移给同种移植后的BALB/c-SCID鼠, 观察移植物存活状态.结果：CsA加供体脾细胞预先注射可明显延长小鼠移植皮片的存活期（P＜0.05）;移植耐受状态的T细胞经Rapa和/或IL-2体外处理后CD4^＋CD25^＋ T细胞比例升高、增殖水平明显降低、 Foxp3表达量明显增加;过继转输给同种移植SCID鼠后, 其移植皮片存活时间显著延长（P＜0.05）.结论：Rapa可体外扩增耐受诱导模型中CD4^＋CD25^＋ T细胞, 使CD4^＋CD25^＋ T细胞相关的Foxp3和IL-10明显升高, 过继免疫后, 小鼠同种移植物存活时间明显延长, 而低浓度IL-2可以协同Rapa的这一作用.     

Helper CD4+ T cells for IgE response to a dietary antigen develop in the liver

BACKGROUND: Although T-cell responses to food antigens are normally inhibited either by deletion, active suppression, or both of antigen-specific T cells, T helper cells for IgE response to a food antigen still develop by unknown mechanisms in a genetically susceptible host. OBJECTIVE: We determined the site at which those IgE helper T cells develop. METHODS: We administered ovalbumin (OVA) orally to DO11.10 mice and studied CD4+ T cells in Peyer's patches, the spleen, and the liver. Helper activity for IgE response was assessed by adoptively transferring those CD4+ T cells to naive BALB/c mice, followed by systemic immunization with OVA. RESULTS: OVA-specific CD4+ T cells were deleted by cell death in the liver and Peyer's patches of DO11.10 mice fed OVA. OVA-specific CD4+ T cells that survived apoptosis in the liver expressed Fas ligand and secreted IL-4, IL-10, and transforming growth factor beta(1). CD4+ T cells producing IFN-gamma were deleted in the liver by repeated feeding of OVA. On transfer of CD4+ T cells to naive mice and systemic immunization with OVA, a marked increase in OVA-specific IgE response developed only in the mice that received hepatic CD4+ T cells from OVA-fed mice, the effect of which was not observed in the recipients of hepatic CD4+ T cells deficient in IL-4. In addition, significant suppression of delayed-type hypersensitivity and IgG(1)/IgG(2a) responses to OVA was observed in the recipients of hepatic CD4+ T cells, and this suppression required Fas/Fas ligand interaction. CONCLUSION: Together, these results suggested that a food antigen might negatively select helper T cells for IgE response to the antigen by preferential deletion of T(H)1 cells in the liver.