Characterization of CD4+ CD8alphaalpha+ and CD4-CD8alphaalpha+ intestinal intraepithelial lymphocytes in rats

Intestinal intraepithelial lymphocytes (i-IEL) of aged rats comprise CD4+CD8alphaalpha+ and CD4-CD8alphaalpha+ T cells expressing TCR alphabeta. In the present study, we compared characteristics between CD4+CD8alphaalpha+ and CD4-CD8alphaalpha+ i-IEL, which were purified by a cell sorter from the i-IEL of 6-month-old Lewis rats. Most of the CD4+CD8alphaalpha+ i-IEL were of the CD44(hlgh) phenotype, while CD4-CD8alphabeta+ i-IEL were CD44(low). Vbeta usage in the CD4-CD8alphaalpha+ i-IEL was much diversified, while CD4+CD8alphaalpha+ i-IEL showed a skewed Vbeta repertoire. The CD4+CD8alphaalpha+ i-IEL but not the CD4-CD8alphaalpha+ i-IEL proliferated in response to syngeneic spleen cells, which was partially inhibited by addition of anti-MHC class I mAb. The CD4+CD8alphaalpha+ i-IEL produced IFN-gamma and IL-2 but no IL-4 or transforming growth factor (TGF)-beta in response to syngeneic spleen cells, while CD4-CD8alphaalpha+ i-IEL produced abundant levels of TGF-beta but no IL-2, IFN-gamma or IL-4. CD4+CD8alphaalpha+ i-IEL proliferated in response to exogenous IL-2 but not to IL-15, while CD4-CD8alphaalpha+ i-IEL could respond to IL-15 as well as IL-2. These results suggest that a significant fraction of CD4+CD8alphaalpha+ i-IEL belongs to Th1-type T cells capable of responding to self-MHC class I, while CD4-CD8alphaalpha+ i-IEL are a unique population with a diversified Vbeta repertoire that respond to IL-15 in rats.     

Age-associated increase in number of CD4+CD8+ intestinal intraepithelial lymphocytes in rats.

A significant number of CD4+CD8+ T cells were detected in intestinal intraepithelial lymphocytes (IEL) of various strains of rats including Wistar, WKA, BN, LEW and F344. The site of the CD4+CD8+ population in IEL increased with age in all strains we examined. Most IEL bearing CD8 expressed no CD5 antigen in young rats, while all CD4+CD8+ IEL and some of CD8+ IEL in aged rats were of CD5+CD45RB- phenotype. In germ-free Wistar rats, age-associated increase in the number of CD4+CD8+CD5+ IEL was not evident, indicating that stimulation by the intestinal microflora was important for expansion of the CD4+CD8+CD5+CD45RB- IEL. Aged athymic F344 nude rats contained appreciable numbers of CD4+ IEL and CD8+ IEL but few CD4+CD8+ IEL, suggesting that the CD4+CD8+ IEL may be derived from thymus-dependent populations. Unlike a majority of CD4+CD8+ thymocytes bearing a low intensity of CD3/T cell receptor (TcR) alpha/beta, the CD4+CD8+ T cells in IEL expressed a high intensity of CD3/TcR alpha/beta on their surface. The CD4+CD8+ IEL appear to contribute to the spontaneous proliferation of the IEL in aged rats as assessed by tritiated thymidine incorporation after in vitro culture with medium only. These results suggest that with aging a unique CD4+CD8+ IEL may expand at a local site of the intestine under the influence of intestinal microflora and may contribute to the first line of defense against various pathogens in the epithelium.     

CD2 expression on murine intestinal intraepithelial lymphocytes is bimodal and defines proliferative capacity

The CD2 molecule is normally expressed on nearly all murinelymphocytes, and is co-stimulatory in T cell activation viathe antigen receptor (TCR). A naturally occurring T lymphocytepopulation that is bimodal for CD2 expression was found in theintestinal intraepithelial lymphocytes (IEL). TCRß⁺IEL contain CD2^– and CD2⁺ cells of approximately equalproportion, while TCR⁺ IEL are predominantly CD2^–. Theproliferative response of IEL to stimulation with an anti-CD3mAb or with PMA plus ionomycin co-segregated with CD2 expression;the CD2⁺ subset proliferated vigorously under these conditionswhile the CD2^– subset was much less responsive. The respondingCD2⁺ IEL contained both TCRß⁺ and TCR⁺ cells. However,activation of the CD2^– IEL with anti-CD3 mAb resultedin only the expansion of TCR⁺ IEL, while activation with PMAplus ionomycin did not promote expansion of either the TCRß⁺or the TCR⁺ IEL. These findings parallel observations in theautoimmune lpr mouse, where massive numbers of peripheral TCRß⁺CD4^–CD8^–T cells that lack CD2 expression are also hyporesponsive tomltogenic stimulation. The apparent energy of CD2^–TCRß⁺IEL, as well as CD2^– T cells from lpr mice, demonstratesthat the absence of CD2 on TCRß⁺ T lymphocytes co-segregateswith nonresponsiveness.     

Interactions between peripheral blood CD8 T lymphocytes and intestinal epithelial cells (iEC)

Intestinal intraepithelial lymphocytes (iIEL) are primarily CD8 cells and most of them have a CD28^? phenotype, the phenotype of effector cytotoxic T cells. We asked whether the predominance of CD8⁺ CD28^? T cells in the gut may result from peripheral blood T cells preferentially migrating to the iIEL compartment and adhering to iEC. Compared with CD4 cells, adhesion of resting CD8⁺ T cells to iEC cell lines was significantly higher. Adhesion could be blocked with a MoAb to gp180, a molecule expressed on iEC which is known to interact with CD8/lck. No significant difference in the level of adhesion was observed between CD8⁺ CD28⁺ and CD8⁺ CD28^? T cells. Thus CD8 cells may preferentially migrate to the iIEL compartment, but loss of CD28 expression could occur in situ after migration. Consistent with this hypothesis, the CD8⁺ CD28^? cells became enriched after co-culturing T cells with iEC cell lines and primary iEC. Induction of the CD8⁺ CD28^? phenotype in cord blood and adult T cells was observed in co-cultures with iEC and also with mitogens and superantigens. In the latter case, CD28 down-modulation was seen specifically in the Vβ subset targeted by the superantigen, indicating that loss of CD28 expression is a direct result of T cell receptor (TCR)-mediated stimulation. The combined results suggest that CD8⁺ CD28^? T cells are antigen experienced T cells, and that they may have a survival advantage in the presence of gut epithelial cells in vitro. This may contribute to the predominance of CD8⁺ CD28^? T cells in the iIEL compartment.     

Failure of T cell receptor V beta negative selection in murine intestinal intra-epithelial lymphocytes.

The intestinal intra-epithelial lymphocytes (IEL) are divided into several subsets on the basis of expression of T cell receptor (TCR) alpha beta and gamma delta, intensity of Thy-1 expression and expression of Lyt-3 chain. To investigate the differentiation pathway of the IEL, we examined the repertoire of V beta segments of T cells in the IEL in BALB/c (H-2d, MIs-1b2a) or AKR/J (H-2k, MIs-1a2b) mice. Among freshly isolated IEL, an appreciable number of T cells bearing V beta 3 or V beta 11, which recognize MIs-2a- or MHC IE-encoded molecules respectively, were detected in BALB/c mice. Similarly, in AKR/J mice, IEL contained appreciable levels of V beta 6-bearing T cells. V beta 3- or V beta 11-bearing T cells in the IEL in BALB/c mice increased to a significant level when incubated with staphylococcal enterotoxin A which specifically stimulates V beta 3- and V beta 11-bearing T cells. Most of IEL without clonal deletion expressed Lyt-2 but not Lyt-3 antigens. Such T cells were hardly detected in other organs, including liver. Our results indicate that TCR alpha beta-bearing intestinal IEL that have not undergone negative selection may have differentiated outside the thymus, presumably at a local site of the intestine and can respond normally to the signal via their TCR.     

CD3−CD8+ intestinal intraepithelial lymphocytes (IEL) and the extrathymic development of IEL

Present evidence suggests that a majority of murine CD3⁺ intraepithelial intestinal lymphocytes (IEL) are extrathymically derived T cells and that these extrathymically derived IEL phenotypically express the CD8 homodimer (CD8αα). Recently, CD3^? IEL have been reported to express the recombination activating gene (RAG-1), suggesting that precursors to extrathymically derived CD3⁺CD8⁺αα IEL exist on the intestinal epithelium. To study in detail whether these CD3^? IEL can develop into CD3⁺CD8⁺αα IEL, we analyzed the CD3^? IEL subset and found that it can be separated into two subsets, namely CD3^?CD8^? and CD3^?CD8⁺ IEL. We show that (1) CD3^?CD8^? IEL are mostly small, non-granular and phenotypically Pgp-1⁺ IL-2R⁺ B220^?, while CD3^?CD8⁺ IEL are mostly large, granular and phenotypically Pgp-1^? IL-2R⁺ B220⁺, (2) CD3^?-CD8⁺ IEL express the RAG-1 gene, and (3) CD3^?CD8^?, CD3^?CD8⁺ and CD3⁺CD8⁺αα IEL, respectively, appear sequentially in normal ontogeny and in bone marrow-reconstituted thymectomized radiation chimeras. In the latter, virtually all CD3⁺CD8⁺αα IEL expressed the γδ T cell receptor (TCR), but not the αβ TCR. From this and what is presently known about T cell development, we propose that CD3^?CD8⁺ IEL are an intermediate in extrathymic IEL development and that the development of extrathymically derived IEL occurs at the intestinal epithelium from CD3^?CD8^? to CD3^?CD8⁺ to CD3⁺(γδ TCR)CD8⁺αα.     

Intestinal intraepithelial lymphocytes preferentially repopulate the intestinal epithelium

We have used C.B-17 severe combined immune deficiency (SCID)mice to study the repopulation of intestinal intraepithelialcells in these mice. We have found that intestinal intraepitheliallymphocytes (IELs) injected into SCID mice preferentially repopulatethe intestinal epithelium. About 5 weeks after injection wecan detect significant numbers of IEL in repopulated SCID mice.Repopulation occurs in {small tilde}70% of the injected miceand the amount of recovered cells per mouse is variable. Therecovered cells are of donor-type origin and exhibit a typicalIEL phenotype. The donor-type T lymphocytes that can sometimesbe found in other organs of IEL-repopulated SCID mice are generallyof low number. They are not stained with antibodies againstIEL-specific markers and their phenotypes appear to be moretypical for T cells normally found in these sites. In contrast,the intestinal epithelium of SCID mice cannot be efficientlyrepopulated with lymphocytes using cells of other organs includingthymocytes, Peyer's patch lymphocytes, and bone marrow cells.From our data we conclude that intestinal IELs are confinedto the intestinal epithelium and possibly contain a precursor-typecell that preferentially regenerates cells of its own population.     

免疫磁珠负性分离纯化小鼠脾脏CD8+ T细胞

目的 探讨小鼠脾脏CD8 T细胞的免疫磁珠负性分选方法,并对分选后所得细胞进行纯度、活力及功能检测.方法 以免疫磁珠负性分选法从小鼠脾脏细胞中分离CD8 T细胞,流式细胞术检测所得细胞的纯度,台盼蓝检测细胞活力并用ConA刺激检测增殖能力. 结果 经过流式细胞仪测定免疫磁珠负性分选后的小鼠脾脏CD8 T细胞纯度达到(91.6±3.6)%,台盼兰染色细胞活力为(94.9±3.2)%,ConA刺激72 h后有(56.3±1.7)%的细胞增殖.结论 免疫磁珠负性分选法能够分选出高纯度的CD8 T细胞,并且不影响分选靶细胞的细胞活力和功能.     

Proliferative properties of murine intestinal intraepithelial lymphocytes (IEL): IEL expressing TCR alpha beta or TCR tau delta are largely unresponsive to proliferative signals mediated via conventional stimulation of the CD3-TCR complex.

Murine intestinal intraepithelial lymphocytes (IEL) were studied for their capacity to proliferate in vitro following stimulation of the T cell receptor (TCR)-associated CD3 epsilon molecule, or upon direct stimulation of the TCR complex itself. Although IEL consisted primarily of CD3+ T cells which included activated cytotoxic T lymphocytes as demonstrated in CD3- and TCR-mediated redirected cytotoxic assays, IEL displayed minimal proliferative responses following stimulation with anti-CD3, anti-TCR alpha beta, or anti-TCR tau delta monoclonal antibodies under soluble conditions, or under conditions which effect membrane cross-linking, including the addition of accessory cells to IEL cultures. The lack of proliferation induction could not be overcome by stimulation of IEL in the presence of T cell-dependent cytokines, phorbol ester, or interleukin-4. Moreover, unlike splenic T cells, stimulation of IEL failed to result in expression of interleukin-2 receptor, further demonstrating an inability of IEL to respond to exogenous proliferative signals. This study is the first to examine the proliferative potential of murine IEL following direct CD3 or TCR stimulation. The findings described here: (i) identify an important functional distinction between intestinal IEL and other peripheral alpha beta or tau delta T cells which generally respond well to proliferative signals mediated through the CD3-TCR complex, and (ii) demonstrate that on murine IEL the CD3-TCR complex can discriminate signals of lytic activity from those of cell proliferation.     

Functionally active CD8alphabeta+ TCRgammadelta intestinal intraepithelial lymphocytes in athymic nu/nu mice

Murine intestinal intraepithelial lymphocytes (IEL) encompass a high proportion of TCRgammadelta cells. A vast majority of these TCRgammadelta IEL express CD8alpha, but not CD8beta (CD8alphaalpha homodimer), and are considered to develop in intestinal epithelial layers independently of a functional thymus. Here we show that TCRgammadelta cells expressing both CD8alpha and CD8beta (CD8alphabeta heterodimer) appear in athymic nu/nu mice, although their appearance is random. The IEL comprising CD8alphabeta(+) TCRgammadelta cells expressed pronounced cytolytic and IFN-gamma-producing activities after TCRgammadelta ligation, which were markedly stronger than activities of IEL lacking CD8alphabeta(+) TCRgammadelta cells. Purified CD8alphabeta(+) TCRgammadelta cells expressed strong cytolytic activities and produced large quantities of IFN-gamma after TCR engagement. CD8alphabeta(+) TCRgammadelta cells were also identified among IEL from euthymic C57BL/6 mice, although their abundance varied among individual animals. However, cytolytic and IFN-gamma-producing activities in euthymic C57BL/6 mice were markedly lower than those in athymic nu/nu mice. Our findings suggest that CD8alphabeta(+) TCRgammadelta cells can develop in the intestine independently of a functional thymus/thymic epithelial cells and that they perform biological functions in situ.     

Functionality of CD4+ and CD8+ T cells from tonsillar tissue

For many years, tonsillectomy has been used routinely in children to treat chronic or recurrent acute tonsillitis. Palatine tonsils are secondary lymphoid organs and the major barrier protecting the digestive and respiratory tracts from potential invasive microorganisms. They have been used as sources of lymphoid tissue; however, despite the hundreds of papers published on tonsillectomy, no studies addressing the functionality of the CD4(+) and CD8(+) T cells from chronically infected tonsils have yet been published. The aim of this study was to analyse the functionality of the CD4(+) and CD8(+) T cells with respect to tonsillar tissue. We used an affordable approach to measure the frequency of antigen-specific CD4(+) T cells, the direct ex-vivo cytotoxicity of CD8(+) T cells, memory T cell phenotype, cytokine profile and DC phenotype. Our results demonstrate that CD4(+) and CD8(+) T cells from tonsillar tissue are totally functional, as shown by their ability to produce cytokines, to degranulate and to differentiate into effector-memory T cells.     

Newly recruited intraepithelial Ly6A+CCR9+CD4+ T cells protect against enteric viral infection

1. Download : Download high-res image (215KB)
2. Download : Download full-size image

     

CD8+ suppressor-mediated regulation of human CD4+ T cell responses to glutamic acid decarboxylase 65

Although potentially autoreactive T cells are present even in healthy subjects, most individuals do not develop autoimmune disease. It has been well demonstrated that CD4+ CD25+ regulatory T cells play a significant role in controlling the expansion of autoreactive T cells in the periphery. However, some healthy individuals exhibit measurable responses to self peptide even in the presence of CD4+ CD25+ regulatory cells. This article describes the regulation of human CD4+ T cell responses to glutamic acid decarboxylase 65 (GAD65), an autoantigen implicated in type-1 diabetes, by autologous CD8+ suppressor T cells. In cells cultured from healthy individuals, the inclusion of autologous CD8+ T cells at physiological levels resulted in a dramatic decrease in the magnitude of in vitro CD4+ T cell responses to GAD65 peptide. Based on transwell experiments, the observed suppression was cell contact-dependent. However, antibody blocking studies indicated that suppression was mediated by IL-10. Cell fractionation studies suggested that CD8+ suppressor T cells originate from the CD45RA+ CD27- population. The suppression of CD4+ T cell responses to GAD65 in healthy individuals raises the possibility that CD8+ suppressor T cells play an important role in controlling potentially autoreactive T cells in the general population.     

MHC class II-independent CD25+ CD4+ CD8alpha beta+ alpha beta T cells attenuate CD4+ T cell-induced transfer colitis

CD4+ alpha beta T cell populations that develop in mice deficient in MHC class II (through 'knockout' of either the Aalpha, or the Abeta chain of the I-A(b) molecule) comprise a major 'single-positive' (SP) CD4+ CD8- subset (60-90%) and a minor 'double-positive' (DP) CD4+ CD8alpha beta+ subset (10-40%). Many DP T cells found in spleen, mesenteric lymph nodes (MLN) and colonic lamina propria (cLP) express CD25, CD103 and Foxp3. Adoptive transfer of SP but not DP T cells from Aalpha(-/-) or Abeta(-/-) B6 mice into congenic RAG(-/-) hosts induces colitis. Transfer of SP T cells repopulates the host with only SP T cells; transfer of DP T cells repopulates the host with DP and SP T cells. Anti-CD25 antibody treatment of mice transplanted with DP T cells induces severe, lethal colitis; anti-CD25 antibody treatment of mice transplanted with SP T cells further aggravates the course of severe colitis. Hence, regulatory CD25+ T cells within (or developing from) the DP T cell population of MHC class II-deficient mice control the colitogenic potential of CD25- CD4+ T cells.     

CD4+ T-cell help amplifies innate signals for primary CD8+ T-cell immunity

CD8⁺ T cells provide an important component of protection against intracellular infections and cancer. Immune responses by these T cells involve a primary phase of effector expansion and differentiation, followed by a contraction phase leading to memory formation and, if antigen is re-encountered, a secondary expansion phase with more rapid differentiation. Both primary and secondary phases of CD8⁺ T-cell immunity have been shown to depend on CD4⁺ T-cell help, although during certain infections the primary phase is variable in this requirement. One explanation for such variability relates to the strength of associated inflammatory signals, with weak signals requiring help. Here, we focus on our studies that have dissected the requirements for help in the primary phase of the CTL response to herpes simplex virus, elucidating intricate interactions and communications between CD4⁺ T cells, various dendritic cell subsets, and CD8⁺ T cells. We place our studies in the context of others and describe a simple model of help where CD40 signaling amplifies innate signals to enable efficient CD8⁺ T-cell expansion and differentiation. This model facilitates CTL induction to various different agents, without altering the qualitative innate signals that direct other important arms of immunity.     

Late postnatal expansion of self-reactive CD8alphaalpha+ intestinal intraepithelial lymphocytes in mice

The intestinal epithelium is unique in that it harbors auto-reactive T cells largely absent from the peripheral TCR repertoire in normal mice. Intestinal intraepithelial lymphocytes (IEL) expressing self-reactive TCR are mostly CD8alphaalpha+ cells in adult H-Y TCR RAG(-/-) male mice homozygous for the restricting MHC I allele, H-2D(b). By contrast, in male mice heterozygous for the restricting and non-restricting MHC I allele, H-2D(d) (MHC F(1), H-2D(b/d)), IEL are composed of CD8alphabeta and CD8alphaalpha+ T cells. Here we demonstrate that IEL in the immediate postnatal period of MHC homozygous male mice were mostly CD8(-) T cells, while IEL in MHC F(1) male mice were CD8(-) and CD8alphabeta+ T cells. Regardless of the MHC I configuration and the ability to support positive selection of CD8alphabeta+ cells in the thymus, the expansion of CD8alphaalpha+ IEL was a late postnatal event that followed a reduction in CD8(-) IEL. Furthermore, although in vivo treatment with the specific peptide antigen resulted in an earlier accumulation of activated IEL, the expansion of CD8alphaalpha+ IEL remained inefficient until late in postnatal life. Finally, as CD8(-) IEL stimulated with TCR agonists in vitro, acquired expression of CD8alphaalpha, we propose that CD8alphaalpha+ IEL derive from CD8(-) IEL intermediates. Whether CD8(-) IEL are CD8alphabeta-lineage cells that escape deletion in the thymus or are T cells targeted to the intestine from the thymus because of the early and high level TCR transgene expression in this model, is not clear. The signals required for the expansion of CD8alphaalpha+ IEL are however, incomplete in the immediate postnatal intestine. Determining the factors required for the expansion or retention of CD8alphaalpha+ IEL bearing high affinity, self-specific TCR will further elucidate the in vivo role of these T cells in intestinal homeostasis and perhaps, autoimmunity.     

Circulating CD4+CD8+ T lymphocytes in patients with Kawasaki disease

We serially monitored cell surface antigen expression on mononuclear cells in peripheral blood isolated from patients with Kawasaki disease (KD), and found, for the first time, that a markedly increased number of CD4⁺CD8⁺ T lymphocytes was present in some of the patients (11 of the 24 cases). The cases of five of these 11 patients were complicated with coronary artery lesion (CAL); the 13 patients with normal numbers of CD4⁺CD8⁺ T lymphocytes did not have CAL. The patients' age, sex and grade of systemic inflammation evaluated by peripheral leucocyte count and serum C-reactive protein levels were not correlated to the number of CD4⁺CD8⁺ T lymphocytes. Other cell surface antigen characteristics of the CD4⁺CD8⁺ T lymphocytes included CD3⁺, CD45RA⁺, CD45RO⁺, CD16^?, and HLA-DR⁺. These results indicate that the surface antigen characteristics of the KD peripheral blood examined were the same as those of Epstein–Barr virus infection without CD45RA⁺. These findings provide useful information for the analysis of the pathogenesis of KD.     

Activated CD4+ CD25+ T cells suppress antigen-specific CD4+ and CD8+ T cells but induce a suppressive phenotype only in CD4+ T cells

CD4(+) CD25(+) regulatory T cells are increasingly recognized as central players in the regulation of immune responses. In vitro studies have mostly employed allogeneic or polyclonal responses to monitor suppression. Little is known about the ability of CD4(+) CD25(+) regulatory T cells to suppress antigen-specific immune responses in humans. It has been previously shown that CD4(+) CD25(+) regulatory T cells anergize CD4(+) T cells and turn them into suppressor T cells. In the present study we demonstrate for the first time in humans that CD4(+) CD25(+) T cells are able to inhibit the proliferation and cytokine production of antigen specific CD4(+) and CD8(+) T cells. This suppression only occurs when CD4(+) CD25(+) T cells are preactivated. Furthermore, we could demonstrate that CD4(+) T-cell clones stop secreting interferon-gamma (IFN-gamma), start to produce interleukin-10 and transforming growth factor-beta after coculture with preactivated CD4(+) CD25(+) T cells and become suppressive themselves. Surprisingly preactivated CD4(+) CD25(+) T cells affect CD8(+) T cells differently, leading to reduced proliferation and reduced production of IFN-gamma. This effect is sustained and cannot be reverted by exogenous interleukin-2. Yet CD8(+) T cells, unlike CD4(+) T cells do not start to produce immunoregulatory cytokines and do not become suppressive after coculture with CD4(+) CD25(+) T cells.     

雷公藤甲素对诱导CD4+、CD8+T细胞凋亡的作用

目的 探讨雷公藤甲素对ＣＤ４＾＋、ＣＤ８＾＋Ｔ细胞凋亡的作用。方法 分离后的正常人外周血ＣＤ４＾＋、ＣＤ８＾＋Ｔ细胞在外培养条件下,加入雷公藤甲素处理,然后用３末端脱氧核苷酸基（ＴｄＴ）介导的ｄＵＴＰ缺口末端标记（ＴＵＮＥＬ）检测凋亡细胞。结果 雷公藤甲素处理后ＣＤ４和ＣＤ８＾＋细胞凋亡率比对照组显著增加,但ＣＤ４＾＋、ＣＤ８＾＋Ｔ细胞凋亡率则针显著差别。结论 雷公藤甲素诱导诱活化的ＣＤ４＾＋、Ｃ