Characterization of extrathymic CD8 alpha beta T cells in the liver and intestine in TAP-1 deficient mice

TAP-1 deficient (-/-) mice cannot transport MHC class I antigens onto the cell surface, which results in failure of the generation of CD8+ T cells in the thymus. In a series of recent studies, it has been proposed that extrathymic T cells are generated in the liver and at other extrathymic sites (e.g. the intestine). It was therefore investigated whether CD8+ extrathymic T cells require an interaction with MHC class I antigens for their differentiation in TAP-1(-/-) mice. Although CD8+ thymically derived T cells were confirmed to be absent in the spleen as well as in the thymus, CD8 alpha beta+ T cells were abundant in the livers and intestines of TAP-1(-/-) mice. These CD8+ T cells expanded in the liver as a function of age and were mainly confined to a NK1.1-CD3int population which is known to be truly of extrathymic origin. Hepatic lymphocytes, which contained CD8+ T cells and which were isolated from TAP-1(-/-) mice (H-2b), responded to neither mutated MHC class I antigens (bm1) nor allogeneic MHC class I antigens (H-2d) in in vitro mixed lymphocyte cultures. However, the results from repeated in vivo stimulations with alloantigens (H-2d) were interesting. Allogeneic cytotoxicity was induced in liver lymphocytes in TAP-1(-/-) mice, although the magnitude of cytotoxicity was lower than that of liver lymphocytes in immunized B6 mice. All allogeneic cytotoxicity disappeared with the elimination of CD8+ cells in TAP-1(-/-) mice. These results suggest that the generation and function of CD8+ extrathymic T cells are independent of the existence of the MHC class I antigens of the mouse but have a limited allorecognition ability.     

T-cell receptor beta chain gene rearrangements: genetic markers of T-cell lineage and clonality

We have performed a series of investigations involving T-cell receptor beta chain (T beta) gene rearrangements in benign and malignant nonhematopoietic, B-cell, and T-cell proliferations. These studies provide the conceptual basis and the operational approach for the use of T beta gene rearrangements as markers of T-cell lineage, clonality, and differentiation, analogous to immunoglobulin gene rearrangements in B cells. Southern blot hybridization analysis for T beta gene rearrangements can now be utilized to identify and distinguish between non-T cells, polyclonal T cells, and monoclonal T cells. Determination of T beta gene rearrangements will play an important role in the further investigation and classification of T-cell neoplasia. However, the identification of a genetic marker of clonality for T cells has significant diagnostic and prognostic value as well. For example, determination of the T beta gene rearrangement unique to a particular malignant T-cell clone provides a specific genetic marker for that clonal T-cell proliferation. This genetic marker of the T-cell clone may provide a useful tool for monitoring the patient's therapeutic response and clinical course for early signs of relapse. Nonetheless, our studies demonstrate that the lineage specificity of immunoglobulin and T beta gene rearrangements is not absolute. It appears that only a multiparametric approach combining extensive monoclonal antibody immunophenotypic analysis, in vitro testing for functional help and suppression, and Southern blot hybridization analysis for immunoglobulin and T beta gene rearrangements allows the conclusive and unequivocal demonstration of the B- or T-cell derivation of all lymphoid neoplasms. Lymphoid malignancies that cannot be assigned to the B- or T-cell lineage following this extensive multiparametric analysis are exceedingly uncommon.     

The T-cell receptor alpha, beta and gamma polymorphism in Japanese

Polymorphism in the genes encoding the alpha (alpha), beta (beta) and gamma (gamma) chains of the human T-cell receptors was analyzed both in population and family studies. Against twelve unrelated Japanese, several out of the 15 restriction endonucleases tested, revealed restriction fragment length polymorphism. The segregation of the polymorphic fragments were confirmed among 15 members of three families. In most of the cases paternal and/or maternal haplotypes could be assigned. By testing the polymorphic enzymes among the random healthy Japanese, the frequency of each polymorphic fragment was then determined. Although the polymorphism found in this study was similar to that reported in Caucasians, some differences were observed. Such differences are discussed. The restriction fragment length polymorphism in both population and family studies, derived from alpha, beta and gamma chains of the T-cell receptor found in this report, might be useful markers for genetic analysis of the T-cell function in relation to immunological disorders.     

Expression profile and clonality of T-cell receptor beta variable genes in normal human endometrium

PROBLEM: In spite of their key immunological role, alphabeta+ T cells residing in endometrium have not been extensively explored. We analyzed here expression profile of TCRBV genes in normal human endometrium compared with peripheral blood. METHODS: Samples were taken from normal reproductive women. RT-PCR using BV-gene specific primers was performed on blood and endometrial samples. After blotting, hybridization with radiolabelled probe and autoradiography, relative expression of each TCRBV family was determined. Clonal expansions of the over-expressed genes were assessed by CDR3 length polymorphism. RESULTS: Only one gene (TCRBV7) was expressed significantly and two other genes marginally more in the endometrium compared with blood. All three TCRBV genes examined showed a rather restricted pattern in the endometrium in contrast to polyclonal patterns in the blood. CONCLUSION: Our results stress the similarities between T cells residing in different mucosal tissues and provide a basis for future investigations about endometrial T cells and their antigen specificities in gynecological problems.     

Superantigens and conventional antigens induce different responses in alpha beta T-cell receptor transgenic mice.

While superantigens such as staphylococcal enterotoxin B (SEB) have been shown to induce both clonal deletion and clonal anergy, it is still not known why tolerance rather than memory is induced. To address this issue, we tested the proliferative capacity of T cells from ovalbumin (OVA)-specific alpha beta T-cell receptor transgenic mice primed with either SEB emulsified in complete Freund's adjuvant (CFA) or with OVA peptide, the specific antigen, in CFA. By contrast cells from mice primed with SEB in CFA appeared to be anergic in that they were hyporesponsive to OVA peptide as well as to SEB. The anergic cells could respond to phorbol myristate acetate (PMA) and ionomycin, suggesting that a proximal signal transduction step was affected. Cells from transgenic mice primed with OVA peptide and CFA were not anergic and in fact displayed an enhanced response when they were challenged with OVA in vitro. Thus, when the two antigens are emulsified in CFA and then injected subcutaneously, they behave very differently: the superantigen SEB induces anergy whereas the conventional antigen OVA induces a memory type of response.     

Sensitization of T-cell receptor-alpha beta+ T cells recovered from long-term T-cell receptor downmodulation.

Although the survival of fully allogeneic skin grafts was prominently prolonged by adult thymectomy in anti-T-cell receptor-alpha beta monoclonal antibody (TCR-alpha beta mAb)-treated mice compared with that of non-adult thymectomized (ATX) mice, the skin allografts were eventually rejected. In the anti-TCR-alpha beta mAb-treated ATX mice, as shown in the present study, most of TCR-alpha beta+ cells were promptly activated on day 2 and then rapidly disappeared by day 7, but some TCR-alpha beta- Thy-1+ cells remained at that time. These TCR-alpha beta- Thy-1+ cells which have downmodulated their TCR-alpha beta expression may be refractory to depletion events by the mAb treatment. Although these downmodulated T cells re-expressed their TCR-alpha beta on day 50, they could not respond to stimuli via TCR such as TCR cross-linking or alloantigens. However, they recovered the reactivity to donor antigens on day 85. These results indicate that the downmodulated T cells by anti-TCR-alpha beta mAb treatment are long-lived and re-express their TCR-alpha beta at a late stage to be sensitized to donor antigen, which suggests that additional regimens may be required to get permanent, or very long-term, graft acceptance.     

Immunohistology of T cell differentiation in the thymus of H-Y-specific T cell receptor alpha/beta transgenic mice

We examined the immunohistological aspects of the H-Y specific T cell receptor (TcR) alpha/beta transgene expression in the thymus of male and female transgenic (Tg) mice. Virtually all thymocytes expressed the beta transgene in both the male and female thymus. Expression of accessory molecules (co-receptors) in Tg mice deviated from control mice. In the male Tg thymus, CD8 expression was either low or absent on both cortical and medullary thymocytes. In contrast, in the thymus of female mice, CD8+ cells were found both in the cortex and in the medulla. The majority of medullary thymocytes was bright CD8+. This is in clear contrast to the CD8 distribution in control B6 mice, where only a few percent of medullary cells are CD8+. Similarly, the proportion of cells expressing CD4 antigens was reduced in the cortex and medulla of the thymus from male Tg mice, as compared to the thymus of female Tg mice and B6 control mice. Comparative analysis of the stromal cell types of the thymic microenvironments in the three groups of mice revealed that the cortical thymic microenvironment of male Tg mice differed, compared to that of female Tg mice. In particular, the deep cortex showed a closely packed meshwork of epithelial reticular cells. Moreover, H-2Db molecules (which are the restricting elements for the Tg TcR alpha/beta) were abnormally expressed in the thymic cortex of male mice. The cortical microenvironment in female mice, on the other hand, appeared normal. Together, the data indicate that TcR alpha/beta transgene expression in male mice leads to an aberrant co-receptor expression in both cortical and medullary lymphoid cells as well as an abnormal composition of the cortical microenvironment. Both phenomena may be the consequence of "negative selection" of developing H-Y-specific T cells, as it occurs only in the male Tg thymus. The absence of the H-Y antigen, but presence of the restricting element H-2Db in the thymic cortex of female mice, leads to accumulation of CD8+ in the medulla, a phenomenon interpreted as "positive selection".     

T cell subset-specific expression of antigen receptor beta chains in alpha chain-transgenic mice.

A large number of V beta 8 gene-encoded cDNA were analyzed from peripheral CD4+ and CD8+ T cell subsets of T cell receptor (TcR) alpha chain-transgenic mice. This analysis demonstrates that a limited repertoire of TcR beta chains are co-expressed with the transgenic alpha chain. Most importantly, certain V beta 8-J beta combinations were found exclusively in one of the subsets and, in some cases, subset-specific differences were localized to the VDJ junctional region of the beta chain genes. In contrast, CD4-CD8- transgenic T cells, as well as CD4+ and CD8+ T cells from normal littermate controls, were found to express diverse beta chain repertoires. The present study suggests that beta chains with distinct structural characteristics are expressed in the CD4+ and CD8+ subsets, respectively. Moreover, the data suggest that the same structural constraints do not apply to the population of CD4-CD8- transgenic T cells.     

T-cell receptor V beta repertoire of L3T4+ regulatory T cells in anti-L3T4 antibody-induced tolerant NOD mice.

In ongoing studies, we have found that short-term administration of anti-L3T4 monoclonal antibodies (mAb) prevents the development of overt diabetes in non-obese diabetic (NOD) mice. In the present work, we asked whether L3T4+ T cells or Lyt-2+ T cells can suppress the diabetes in these mice. L3T4+ T cells or Lyt-2+ T cells were sorted using a magnetic cell sorter, then were transferred into cyclophosphamide-induced male NOD mice. We obtained evidence that the L3T4+ but not Lyt-2+ T cells did inhibit the diabetes, thereby indicating that the former can regulate diabetes in anti-L3T4 mAb-induced tolerant NOD mice. Further analysis on T-cell receptor (TCR) V beta genes on splenic T cells from anti-L3T4 mAb-treated NOD mice revealed that V beta 4-positive T cells expanded predominantly, while L3T4+ T cells represented heterogeneity of the TCR V beta gene, hence, V beta 4-positive Lyt-2+ T cells generate predominantly. Our findings suggest that both L3T4+ and Lyt-2+ T cells renew and function as regulatory cells, through clonotypic interaction in tolerant NOD mice.     

过氧化物酶体增殖剂激活受体α对小鼠T、B细胞发育的影响

目的研究过氧化物酶体增殖剂激活受体α(PPARα)与小鼠免疫系统功能和发育的关系。方法喂养含过氧化物酶体增殖剂(PP)的食物后,观察野生型C57Bl/6小鼠和PPARα缺陷型小鼠胸腺、脾脏的重量及胸腺细胞、脾细胞数量的变化。用抗小鼠CD3、CD4、CD8a、CD19、IgM或CD45R/220单克隆抗体(mAb)进行细胞免疫荧光染色后,用流式细胞术分析骨髓细胞、胸腺细胞和脾细胞的表型变化。用刀豆蛋白A(ConA)和脂多糖(LPS)分别刺激小鼠的脾细胞,用3H-TdR掺入法检测淋巴细胞增殖活性的变化。用RT-PCR检测小鼠骨髓、胸腺和脾脏中PPARαmRNA的表达。结果与野生型小鼠相比较,PP对PPARα缺陷型小鼠胸腺、脾脏的重量和细胞数,以及ConA和LPS刺激对淋巴细胞增殖反应的影响很小。PP可致野生型小鼠胸腺中CD4 CD8 T细胞数,骨髓中B220 B细胞总数和原/前B细胞数明显减少,但对PPARα缺陷型小鼠的上述T、B细胞亚群无显著影响。PPARαmRNA在小鼠胸腺和脾脏中呈低表达,在骨髓中不表达。结论PPARα在PP诱导的免疫调节中起主要作用,其可通过间接途径影响T、B细胞的发育。     

In vivo elimination of T cells expressing specific T-cell receptor V beta chains in mice susceptible to collagen-induced arthritis.

Type II collagen-induced arthritis (CIA) is believed to be dependent on T cells expressing a limited number of V beta chains. Two different methods were used to selectively eliminate T cells expressing a certain T-cell receptor (TcR) V beta chain in mouse strains susceptible to CIA. In vivo treatment with monoclonal anti-V beta 6 or anti-V beta 8.1,2 antibodies did not alter CIA, despite a reduction of the major part of the V beta 6+ or V beta 8.1,2+ lymph node cells (LNC), as measured by flow cytometric (FACS) analyses. The reduction was not due to complete elimination of V beta 6+ or V beta 8.1,2+ cells, since part of the V beta 6 and V beta 8.1,2 expressing cells returned later, even in mice that had been thymectomized first to prevent maturation of new T cells. In contrast, treatment with antibodies against CD4 efficiently abrogated development of CIA. In the (CBA x DBA/1J)F1 and the (BALB/c x DBA/1J)F1 mice, where M1s1a was combined with expression of I-E, the V beta 6+ LNC were deleted. In spite of the deletion, both F1 strains were highly susceptible to CIA.     

利用T细胞受体变异β基因谱系分析T细胞急性淋巴细胞白血病病人T细胞克隆性

目的:分析T细胞-急性淋巴细胞白血病(T-ALL)病人的T细胞克隆性。方法:利用RT-PCR方法分析6例T-ALL和10例正常人外周血单个核细胞中24个T细胞受体变异β(TCR Vβ)基因的CDR3长度,PCR产物再进一步进行基因扫描和序列分析。结果:3例病人的某些TCR Vβ亚家族T细胞呈单克隆或寡克隆性增殖,主要为Vβ2、3、6、9、21和24。其它3例及正常人均表现为多克隆性增殖T细胞。结论:部分T-ALL来自于TCR Vβ亚家族克隆性增殖T细胞。该方法有助于临床上检测微小残留病变。     

Molecular determination of T-cell receptor alpha and beta chain genotypes in human families

Polymorphism in genes encoding the alpha and beta chain of the human T cell receptor has been detected by Southern blot analysis. Genomic DNA samples were isolated from B lymphoblastoid cell lines derived from members of families, each family including at least one individual with a recombinant HLA haplotype. T cell receptor alpha and beta chain haplotypes could be assigned in the families on the basis of observed restriction fragment length polymorphism (RFLP). Polymorphism in the alpha chain gene was detected in BglII digests using an alpha chain probe that included the V, J, C, and 3' untranslated sequences. A probe consisting of only the constant region (C alpha) revealed no polymorphism indicating that the polymorphic fragment hybridized to V, J, or 3' untranslated sequences of the alpha chain. Polymorphism in beta chain genes was observed in BglII digested DNA samples using a probe that corresponds to the constant region (C beta). Polymorphic C beta restriction fragments of 10.0 and 9.2 kilobase segregated in six of the eight families studied. Recent structural data for the C beta region suggest that the polymorphic BglII site lies in the region 5' to the C beta 2 gene. These polymorphisms should serve as markers for alpha and beta chain complexes allowing genetic studies of these immunologically important gene families.     

T-cell development in T cell receptor alphabeta transgenic mice

The introduction of rearranged T cell receptor alpha and beta chain genes into transgenic mice results in a high frequency of expression of the introduced receptor on T cells. In three different systems, analyses of mice expressing transgenic T cell receptors specific for antigen plus MHC class I or class II molecules have demonstrated several important features of T cell development: (1) T cell receptor specificity for MHC class I or class II molecules determines the expression of CD8 versus CD4, respectively, on mature T cells; (2) T cell maturation in the thymus is dependent on expression of an MHC molecule recognized by the T cell receptor; (3)for class II specific receptors, appropriate MHC expression on thymic epithelial cells is sufficient to achieve positive selection of T cells; and (4) self-reactive T cells die or are killed in the thymus.     

Structural mutations in the constant region of the T-cell antigen receptor (TCR)beta chain and their effect on TCR alpha and beta chain interaction.

The region responsible for T-cell receptor (TCR)alpha and beta chain assembly has previously been shown to reside in their extracellular domains. In an attempt to delineate further the structural requirements for TCR alpha and beta chain assembly, chimeric TCR beta chains with increasing length of constant (C) region and mutant TCR beta chains with C-domain point mutations were constructed. Their ability to assemble with wild-type TCR alpha chain was evaluated in non-T (COS cells) or T cells. The results reveal that the C beta domain is the binding region to TCR alpha chain, whereas the intact variable (V), diversity (D) and joining (J) regions with a short C-domain of beta chain are not sufficient for the TCR alpha and beta chain assembly. The unique interchain disulphide bond between TCR alpha and beta chains is not required for the TCR alpha beta heterodimer formation.     

Early deletion and late positive selection of T cells expressing a male-specific receptor in T-cell receptor transgenic mice

The ontogeny of T cells in T-cell receptor (TCR) transgenic mice, which express a transgenic alpha beta heterodimer, specific for the male (H-Y) antigen in association with H-2Db, was determined. The transgenic alpha chain was expressed on about 10% of the fetal thymocytes on day 14 of gestation. About 50% of day-15 fetal thymocytes expressed both alpha and beta transchains and virtually all fetal thymocytes expressed the transgenic alpha beta heterodimer by day 17. The early expression of the transgenic TCR on CD4-8- thymocytes prevented the development of gamma delta cells, and led to accelerated growth of thymocytes and an earlier expression of CD4 and CD8 molecules. Up to day 17, no significant differences in T-cell development could be detected between female and male thymuses. By day 18 of gestation, the male transgenic thymus contained more CD4-8- thymocytes than the female transgenic thymus. The preponderance of CD4-8- thymocytes in the male transgenic thymus increased until birth and was a consequence of the deletion of the CD4+8+ thymocytes and their CD4-8+ precursors. By the time of birth, the male transgenic thymus contained half the number of cells as the female transgenic thymus. The deletion of autospecific precursor cells in the male transgenic mouse began only at day 18 of gestation, despite the fact that the ligand could already be detected by day 16. The preferential accumulation of CD4-8+ T cells, which expressed a high density of the transgenic TCR, occurred only after birth and was obvious in 6-week-old female thymus. These data support the hypothesis that the positive selection of T cells expressing this transgenic heterodimer may involve two steps, i.e., the commitment of CD4+8+ thymocytes to the CD4-8+ lineage following the interaction of the transgenic TCR with restricting major histocompatibility molecules, followed by a slow conversion of CD4+8+ thymocytes into CD4-8+ T cells. In normal mice, the precursors of CD4+8+ and single positive thymocytes have the CD4-8- CD3-J11d+ (or M1/69+) phenotype. Because of the early expression of the transgenic alpha beta heterodimer, this population was not detected in adult transgenic mice. All CD4-8- M1/69+ cells expressed the transgenic receptor associated with CD3 and could be readily grown in media containing T-cell lectins and interleukin 2.     

Homeostasis of alpha beta TCR+ T cells

Cytokines contribute to T cell homeostasis at all stages of T cell existence. However, the particular cytokine involved varies as T cells progress from a na?ve through an activated to a memory state. In many cases the important cytokines are members of the interleukin 2 subfamily of the short-chain type I cytokines. A case is made for the idea that the evolutionary divergence of the short-chain family allowed for concurrent divergence in leukocytes.     

Gamma/delta T cells and alpha/beta T cells differ in their developmental patterns of receptor expression and modulation requirements

Measurement of the cell surface levels of gamma/delta (TcR 1) and alpha/beta (TcR 2) T cell receptors in the chicken revealed that thymocyte subpopulations that express these receptor isotypes differ remarkably in their rates of receptor acquisition. Whereas TcR 1 expression was relatively high (greater than 10(4) sites per cell) beginning on day 12 of embryonic life, the initial levels of TcR 2 expression on embryonic thymocytes were relatively low (approximately 10(3) sites per cell) when first measurable on day 15, and increased gradually as a function of T cell maturation. In peripheral tissues, the TcR 1 cells also expressed higher receptor levels than did the TcR 2 cells, but the difference was only 2-3-fold. The TcR 2 receptors on immature T cells could be easily modulated by receptor cross-linkage, very much like immunoglobulin receptors on immature B cells. While the TcR 2 receptor modulation occurred within minutes, TcR 1 receptor modulation required several hours for completion, even in the embryonic thymus. The data indicate very different developmental programs for TcR 1 and TcR 2 expression, and suggest fundamental differences in clonal selection modes for the two T cell subpopulations.