The origin of thymic CD4+CD25+ regulatory T cells and their co-stimulatory requirements are determined after elimination of recirculating peripheral CD4+ cells

Studies on the thymic ontogeny of naturally arising CD4(+)CD25(+) regulatory T cells (TR cells) are complicated by the contamination of recirculating cells from the periphery (both activated CD4(+) T and TR cells). We investigated TR cells in anti-CD4 antibody transgenic (Tg) (GK) mice that continuously deplete peripheral CD4 T cells but not thymocytes so that the generation of thymic TR cells and their developmental requirement can be accurately assessed. We show that in the thymuses of mice that lack peripheral CD4(+) cells, TR cells were present but were fewer in number compared with wild-type (WT) mice. Therefore, we show that peripheral TR cells do re-enter the thymus, comprising 20% of TR cells in the normal thymus. TR cells from both WT and GK mice expressed Foxp3 and GITR, and suppressed the proliferation of CD25(-)CD4(+) T cells. Furthermore, the co-stimulation requirements for TR generation were evaluated in mice with or without peripheral CD4 cells. Splenic TR cells in CD40L(-/-) mice and CTLA4Ig Tg mice were fewer compared with WT mice. Mice deficient in both co-stimulatory pathways had further reduction in splenic TR cells. Unlike the periphery, the reduction in thymic TR cells was only seen for CD40L(-/-) but not for CTLA4Ig Tg mice. Therefore, we found that the co-stimulation requirements for the thymic development of TR cells differed from those for peripheral homeostasis.     

A critical function for TGF-beta signaling in the development of natural CD4+CD25+Foxp3+ regulatory T cells

The molecular mechanisms directing the development of 'natural' CD4+CD25+Foxp3+ regulatory T cells (T(reg) cells) in the thymus are not thoroughly understood. We show here that conditional deletion of transforming growth factor-beta receptor I (TbetaRI) in T cells blocked the appearance of CD4+CD25+Foxp3+ thymocytes at postnatal days 3-5. Paradoxically, however, beginning 1 week after birth, the same TbetaRI-mutant mice showed accelerated expansion of thymic CD4+CD25+Foxp3+ populations. This rapid recovery of Foxp3+ thymocytes was attributable mainly to overproduction of and heightened responsiveness to interleukin 2, as genetic ablation of interleukin 2 in TbetaRI-mutant mice resulted in a complete absence of CD4+CD25+Foxp3+ cells from the thymus and periphery. Thus, transforming growth factor-beta signaling is critical to the thymic development of natural CD4+CD25+Foxp3+ T(reg) cells.     

CD8+ T Cells Induce Medullary Thymic Epithelium and CD4+CD8+CD25+ TCRβ− Thymocytes in SCID Mice

During T-cell development the transition in the thymus of CD4-CD8- double negative (DN) progenitor T cells into CD4+CD8+ double positive (DP) cells is dependent on the expression of a T-cell receptor (TCR)-beta-chain protein. In this study purified peripheral CD4+ and CD8+ T lymphocytes from the C.B-17 strain of mice were adoptively transferred into syngeneic, neonatal SCID mice, where donor cells resided at constant numbers in thymus from 2 weeks until 10 weeks post cell transfer. In the recipient thymus the CD8+ donor cells outnumbered the CD4+ cells by a factor of three to five and both subsets contained a large fraction of activated cells. During the late phase of treatment, CD8+ T cells induced high numbers of DP thymocytes in the SCID mice, a process accompanied by the maturation of medullary epithelial cells. Such thymic development in the SCID mouse was inhibited by coresiding CD4+ donor T cells. These results indicate a regulatory role by mature peripheral T cells on medullary epithelial growth and thymocyte development in the treated SCID mice.     

自身免疫调节因子(Aire)对CD4+ CD25+调节性T细胞产生的影响

目的：探讨自身免疫调节因子（Aire）基因是否影响调节性T细胞的产生。方法：应用流式细胞术和real-time PCR的方法分别分析了Aire^-/-鼠的胸腺细胞和脾脏外周T细胞的CD4^＋CD25^＋T细胞分布及Foxp3的表达。结果：与对照鼠相比，Aire^-/-鼠的胸腺细胞、脾脏淋巴细胞以及脾脏T细胞总数未发生显著变化；CD4^＋CD25^＋调节性T细胞数目以及脾脏T细胞Foxp3 mRNA表达无显著差异；成年鼠、3日龄和7日龄鼠的CD4^＋CD25^＋T细胞占总的CD4^＋T细胞的百分比在Aire^-/-鼠和相应对照鼠间并无显著差异。结论：结果表明Aire基因不影响CD4^＋CD25^＋调节性T细胞的产生。     

CD3+ T cells in severe combined immunodeficiency (scid) mice. VI. Rescue of scid-derived, IgM-producing B cells by transfer of CD4+ CD8- T cells from various lymphoid organs.

Intravenous injection of purified CD4+ CD8- T cells from thymus, spleen or lymph nodes of adult dm2 donor mice (H-2d, Ld-, IgMa) into young C.B-17 scid/scid (scid) mice (H-2d, Ld+, IgMb) partially and selectively reconstituted the splenic CD4+ T-cell compartment of recipient scid mice. This was demonstrated by cytofluorographic analyses, histological examinations, growing donor-derived CD4+ T-cell lines in vitro from spleens of transplanted scid mice, and serial passage of Ld-, CD3+CD4+CD8- T-cell lines through young scid recipients for more than 1 year. Host-derived IgMb appeared in sera of all CD4+ T-cell-transplanted young scid mice, while none of the sex- and age-matched, non-transplanted control scid mice was Ig+. B-cell leakiness was most efficiently induced by transfer of low numbers of adult CD4+ CD8- thymocytes: transfer of 10(3) purified CD4+ CD8- thymocytes efficiently rescued scid-derived B cells, while transfer of 2 x 10(7) non-fractionated thymocytes from the same donor mouse was inefficient. Serum antibodies of scid mice with T-cell-induced B-cell leakiness stained congenic 'double-positive' (CD4+ CD8+) thymocytes and immunoprecipitated protein bands with an apparent MW of 14,000, 28,000, 43,000, 65,000 and 80,000 from 125I-labelled thymocytes. These data indicate that repopulation of peripheral lymphoid organs with CD4+ T cells is always accompanied by partial co-reconstitution of the B-cell system, and raises the question of the interdependence of these two lymphocyte subsets.     

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.     

The role of self-peptides in the development of CD4+ CD25+ regulatory T cells

The thymus produces a unique lineage of cells known as CD4+ CD25+ regulatory T cells, and the exact processes leading to their development continue to be defined. Highly specific interactions between developing thymocytes and cognate self-antigens expressed by radioresistant elements in the thymus have been shown to drive CD4+ CD25+ regulatory-T-cell development. The self-peptide(s) that mediate thymic selection of CD4+ CD25+ regulatory T cells can also promote their expansion in the periphery, and self-peptides might also play a role in the conversion of CD4+ CD25- T cells into CD25+ regulatory T cells.     

CD4+ CD25+ FOXP3+ regulatory T cells from human thymus and cord blood suppress antigen-specific T cell responses

Activation of self-reactive T cells in healthy adults is prevented by the presence of autoantigen-specific CD4+CD25+ regulatory T cells (CD25+ Treg). To explore the functional development of autoantigen-reactive CD25+ Treg in humans we investigated if thymic CD25+ Treg from children aged 2 months to 11 years and cord blood CD25+ Treg are able to suppress proliferation and cytokine production induced by specific antigens. While CD4+CD25- thymocytes proliferated in response to myelin oligodendrocyte glycoprotein (MOG), tetanus toxoid and beta-lactoglobulin, suppression of proliferation was not detected after the addition of thymic CD25+ Treg. However, CD25+ Treg inhibited interferon (IFN)-gamma production induced by MOG, which indicates that MOG-reactive CD25+ Treg are present in the thymus. In contrast, cord blood CD25+ Treg suppressed both proliferation and cytokine production induced by MOG. Both cord blood and thymic CD25+ Treg expressed FOXP3 mRNA. However, FOXP3 expression was lower in cord blood than in thymic CD25+ T cells. Further characterization of cord blood CD25+ T cells revealed that FOXP3 was highly expressed by CD25+CD45RA+ cells while CD25+CD45RA- cells contained twofold less FOXP3, which may explain the lower expression level of FOXP3 in cord blood CD25+ T cells compared to thymic CD25+ T cells. In conclusion, our data demonstrate that low numbers of MOG-reactive functional CD25+ Treg are present in normal thymus, but that the suppressive ability of the cells is broader in cord blood. This suggests that the CD25+ Treg may be further matured in the periphery after being exported from the thymus.     

Patterns of dual lymphocyte development in co-cultures of foetal thymus and lymphohaemopoietic cells from young and old mice.

Patterns of lymphocyte development in the thymus were analysed, focusing on newly emigrating bone marrow (BM) and resident thymic cells. We co-cultured foetal (Day 15 of gestation) thymic explants (FT, C57BL/Ka, Thy-1.1), with BM cells from young (2-3 months) or old (24 months) syngeneic, Thy-1 congenic (C57BL/6J, Thy-1.2) mice. When the FT was severely depleted [treated with either 2-deoxyguanosine (dGua) or exposed to an irradiation dose of 20 Gy] BM-type T lymphocytes were dominant, regardless of BM donor age. When the FT was only partially depleted of its proper lymphoid cells (by exposure to 10 Gy), the lymphocytes which developed were from both BM and FT origins, yet the level of donor-type thymocytes from the young mice was higher than that of the old. Under these conditions the proportion of FT-derived double-positive CD4+ CD8+ (DP) cells was higher, and that of single-positive CD4- CD8+ cells was lower, than in the BM-derived cells, irrespective of the BM donor age. The proportions of old BM-derived DP cells were lower than in the young. Co-cultures of thymus cells from young and old mice with partially depleted FT explants resulted in similar proportions of CD4/CD8 subsets from both donor and FT origins, with the exception that in the presence of old-thymus cells there was an increase in the level of FT-type CD4- CD8+ cells. Patterns of T-cell differentiation in the thymus thus seem to be determined by newly emigrating cells and the resident thymocytes.     

Tracking ex vivo-expanded CD4+CD25+ and CD8+CD25+ regulatory T cells after infusion to prevent donor lymphocyte infusion-induced lethal acute graft-versus-host disease.

Donor bone marrow (BM)-derived CD4+ CD25+ regulatory T cells, maturing in the host thymus, are critical in inhibiting graft-versus-host disease (GVHD) after donor lymphocyte infusion (DLI) in murine BM chimeras. Data presented here demonstrate that fresh CD25+ cells isolated from donor-type mice can be expanded ex vivo by a variety of methods. Ex vivo-expanded CD4+ CD25+ and CD8+ CD25+ cells were potent suppressors of donor response to host alloantigens in mixed lymphocyte reaction assays. Both fresh and ex vivo-expanded CD4+ CD25+ cells persisted long-term in vivo and effectively prevented DLI-induced GVHD in CD25-/- BM chimeras. Importantly, co-infused CD4+ CD25+ cells with DLI cells migrated to peripheral lymphoid organs and survived long-term in DLI-treated CD25-/- chimeras, but not in DLI-treated CD25+/+ chimeras, indicating homeostatic control of CD25+ cells and an available niche required for their long-term persistence. Furthermore, maintenance of CD25 expression seemed necessary for suppressive function, because only the CD25+ cell fraction, but not the CD25- fraction isolated after adoptive transfer, was suppressive in vitro. Ex vivo-expanded CD8+ CD25+ cells weakly prevented GVHD, apparently because of a rapid disappearance of these cells after adoptive transfer. Taken together, these data suggest that the therapeutic use of ex vivo-expanded CD4+ CD25+ cells may be a feasible, nontoxic modality for controlling GVHD in the clinic. Because of strict homeostatic control, an available niche may be required for long-term persistence of infused regulatory T cells.     

Downregulated expression of Ly-6-ThB on developing T cells marks CD4+CD8+ subset undergoing selection in the thymus

Interaction of TCRs on CD4+CD8+ immature T cell with MHC-peptide complexes on stromal cells is required for positive and negative selection in the thymus. Identification and characterization of a subpopulation of CD4+CD8+ thymocytes undergoing selection in the thymus will aid in understanding the mechanisms underlying lineage commitment and thymic selection. Herein, we describe the expression of Ly-6 ThB on developing thymocytes. The majority of CD4+CD8+ thymocytes express Ly-6 ThB at high levels. Its expression is downregulated in a subset of CD4+CD8+ thymocytes as well as in mature CD4+CD8- and CD4-CD8+ T cells. More importantly, interaction of TCR/coreceptor with the self-MHC-peptide contributes to the downregulation of ThB expression on developing thymocytes. These findings indicate that downregulation of ThB on CD4+CD8+ thymocytes identifies a unique subset (CD4+CD8+ThBneg-low) of thymocytes that has received the initial signals for thymic selection but have not yet downregulated the CD4 and CD8 cell surface expression. In addition, these results also indicate that a high frequency (approximately 20-40%) of CD4+CD8+ immature thymocytes receive these initial signals during thymic selection.     

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".     

A novel CD3-J11d+ subset of CD4+CD8- cells repopulating thymus in radiation bone marrow chimeras

Sequential appearance of T cell subpopulations occurs in the thymus of irradiated AKR (H-2k, Thy-1.1) mice at an early stage after transplantation with bone marrow cells of C3H/HeN (H-2k, Thy-1.2) mice. The donor-derived thymocytes were first detected on day 8 after bone marrow reconstitution. Although most of the thymocytes were CD4-CD8- cells, an appreciable level of CD4+CD8- cells was detected in the thymus at this stage. The early appearing CD4+CD8- cells were a novel subset of thymocytes that were J11d+CD3-. From day 10 to day 21 the proportion of CD4+CD8-CD3-J11d+ cells decreased while the proportion of CD4+CD8+ cells and CD4+CD8-CD3+J11d- cells increased. The CD4+CD8-CD3- cells seem to diversify to form CD4+CD8+ thymocytes after short-term culture in vitro. These results suggested the existence of a differential pathway from CD4-CD8- cells to CD4+CD8+ cells via CD4+CD8- cells in thymus.     

Different role of Apaf-1 in positive selection,negative selection and death by neglect in foetal thymic organ culture

Apoptotic protease-activating factor 1 (Apaf-1) is a component of the apoptosome which is required for the activation of procaspase-9. As Apaf-1 knockout (KO) (Apaf-1-/-) mice die before birth, the role of Apaf-1 during thymic selection was investigated using 5 day foetal thymic organ culture (FTOC) of thymi obtained at gestational day 15. There was a lower ratio of CD4 single-positive (SP) to CD8 SP cells and decreased apoptosis of CD4+CD8+ (DP) thymocytes from Apaf-1-/- mice compared with wild-type. To determine if these defects resulted in increased production of neglected thymocytes, the Apaf-1-/- mice were crossed with the T-cell receptor (TCR)-alpha-chain KO mice. There was no difference in thymocyte development in the thymi of TCR-alpha-/-Apaf-1-/- and TCR-alpha-/-Apaf-1+/+ mice 5 days after FTOC. To determine if Apaf-1 is involved in apoptosis during death by negative or positive selection, FTOC of the thymus of Apaf-1-/- Db/HY TCR-alphabeta transgenic (Tg) mice was carried out. There was decreased apoptosis of the HY clonal-specific M33+ thymocytes and an increased percentage of the autoreactive CD8+M33+ thymocytes in male, but not female Apaf-1-/- Db/HY TCR Tg mice. Our data suggest that Apaf-1 is not involved in positive selection or death by neglect, but may have a partial role in negative selection during early thymic T-cell development.     

Bone marrow-derived progenitor T cells convey the origin of maturational arrest from CD4+CD8+ to CD4-CD8+ thymocytes in LEC mutant rats.

A mutant strain of rats, LEC, shows a novel arrest of T cell maturation from CD4+CD8+ to CD4+CD8- but not to CD4-CD8+ cells in the thymus. Transplantation of LEC rat fetal thymuses into the subcapsule of the kidney of athymic nude rats resulted in a normal maturation of thymocytes in the thymus graft. Furthermore, both single-positive thymocytes and peripheral lymph node T cells expressed T cell receptor alpha/beta antigen, and lymph node T cells acquired the ability to produce interleukin 2 upon mitogen stimulation. Transplantation of fetal thymuses from LEA rats, which express the same major histocompatibility complex haplotype as LEC rats, into LEC rat kidney subcapsule resulted in the maturational arrest from CD4+CD8+ to CD4+CD8- cells in the thymus graft. These data strongly suggest that bone marrow-derived progenitor T cells carry the cause of maturational arrest and that the thymic stroma of LEC rats has a normal potential to nurse thymocytes.     

A bone marrow-derived stroma cell line, ST2, can support the differentiation of fetal thymocytes from the CD4−CD8−double negative to the CD4+CD8+ double positive differentiation stage in vitro

T-cell precursors differentiate into mature T cells predominantly in the thymus. However, it has also been reported that T-cell precursors mature in extrathymic organs such as the liver, bone marrow, or intestines. In order to investigate the nature of the extrathymic microenvironment that supports T-cell maturation, we examined the effect of a bone marrow-derived stroma cell line, ST2, on T-cell precursors by using a reaggregate thymic organ culture (RTOC) system. We found that ST2 cells supported the differentiation of fetal thymocytes at day 14.5 of gestation from a CD4- CD8- double negative (DN) to a CD4+ CD8+ double positive (DP) differentiation stage in a manner similar to that observed in thymus. Anti-interleukin-7 receptor (IL-7R) and anti-c-kit antibodies blocked the growth of thymocytes in RTOC with ST2 cells, but did not inhibit the generation of DP thymocytes. These data indicate that a bone marrow-derived stroma cell, ST2, which supports B-cell differentiation, is also able to support T-cell development and may constitute one of the microenvironmental components for extrathymic T-cell development.     

Alterations during positive selection in the thymus of nackt CD4-deficient mice

The T-cell repertoire is shaped by the positive and negative selection of immature CD4(+) CD8(+) double positive (DP) thymocytes. Positive selection of DP T cells to the CD4(+) CD8(-) and CD4(-) CD8(+) simple positive (SP) lineages is a multistep process which involves cellular interactions between thymocytes and stromal cells. Mutant nackt (nkt/nkt) mice have been shown to have a deficiency in the CD4(+) CD8(-) T-cell subset both in the thymus and in the periphery. The present report suggests that nkt/nkt mice present alterations in early steps of positive selection because they show decreases in the percentages of CD69(+) and CD5(+) cells within the DP subset. Experiments involving bone marrow transfer and thymic chimeras demonstrate that the thymic epithelium of nkt/nkt mice is involved in the alterations registered during positive selection and dictates the ultimate fate of CD4(+) SP cells.     

Interferons alpha/beta inhibit IL-7-induced proliferation of CD4- CD8- CD3- CD44+ CD25+ thymocytes, but do not inhibit that of CD4- CD8- CD3- CD44- CD25- thymocytes.

Type 1 interferons (IFN-alpha/beta) have recently been shown to inhibit interleukin-7 (IL-7)-induced growth and survival of early B-lineage cells. The CD3- CD4- CD8- (triple negative; TN) thymocytes from normal mice strongly proliferated upon stimulation with IL-7 in suspension, culture. Such an IL-7-induced proliferation was suppressed by the addition of IFN-alpha/beta, but a fraction of the TN thymocytes still showed proliferation. The IL-7-induced growth of TN thymocytes from acid mice, which lack the CD44- CD25- subpopulation, was completely inhibited by the addition of IFN-alpha/beta. The IL-7 induced proliferation of CD4- CD8- thymocytes from T-cell receptor (TCR) transgenic mice, the majority of which are CD3+ CD44- CD25-, was resistant to IFN-alpha/beta-mediated suppression. In fetal thymus organ cultures (FTOC), the addition of IL-7 greatly increased the population of CD4- CD8- CD44+ CD25+ thymocytes and IFN-alpha/beta inhibited this IL-7-driven expansion. In contrast, the addition of IL-7 markedly decreased the percentages of CD4- CD8- CD3- CD44- CD25- cells, and IFN-alpha/beta reversed the effect and increased the subpopulations of CD44- CD25+ and CD44- CD25-. Finally, IFN-beta mRNA was found to be expressed in the thymus. The data suggest that type I interferons inhibit IL-7-driven proliferation of TN thymocytes, but do not block the normal differentiation process.     

Thymic Nurse Cells Support CD4^-CD8^＋ Thymocytes to Differentiate into CD4^＋CD8^＋ Cells

Thymic nurse cells （TNCs） represent a unique microenvironment in the thymus for T cell maturation. In order to investigate the role of thymic nurse cells during T cell differentiation, a TNC clone, RWTE-1, which formed a typical complex with fetal thymocytes in vitro was established from normal Wistar rat. Hanging drop culture method was applied to reveal the interaction between TNCs and thymocytes. Our result revealed that eighty percent of immature CD4^-CD8^＋ cells differentiated into CD4^＋CD8^＋ cells after a 12-hour hanging drop culture with RWTE-1. However, in a 12-hour culture of immature CD4^-CD8^＋ cells with or without RWTE-1 supernatant, only 30% of the cells differentiated into CD4^＋CD8^＋ cells spontaneously. This observation led to the conclusion that RWTE-1 cell has the capacity to facilitate immature CD4^-CD8^＋ thymocytes to differentiate into CD4^＋CD8^＋ T cells by direct interaction.     

Generation of alphabeta T-cell receptor+ CD4- CD8+ cells in major histocompatibility complex class I-deficient mice upon activation of the aryl hydrocarbon receptor by 2,3,7,8-tetrachlorodibenzo-p-dioxin

Gene-targeted mice lacking the beta2 microglobulin gene (beta2m-/- mice), and hence functional major histocompatibility complex (MHC) class I molecules, do not develop CD4- CD8+ cells. We show here that both in vitro and in vivo treatment with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), a trans-activating ligand of the endogenous aryl hydrocarbon receptor (Ah-R), bypasses the need for MHC class I molecules for selection into the CD4- CD8+ cell pool. When beta2m-/- dams were given a single dose of 50 microg of TCDD, approximately 13% of CD4- CD8+ thymocytes could be detected in their newborn pups. In TCDD-exposed fetal thymus organ cultures of beta2m-/- mice, approximately 35% CD4- CD8+ thymocytes were detectable. About 16% of these CD4- CD8+ cells bore the alpha beta T-cell receptor (TCR) and approximately 33% bore CD3. Only a minority of the CD8+ cells were heat-shock antigen positive. The cells possessed killing activity as shown using the 51Cr-release assay comprising gamma delta TCR- CD4- CD8+ thymocytes from 3 to 4-day-old b2m-/- mice. Thus, TCDD leads to a significant increase of mature CD4- CD8+ thymocytes in relative and absolute numbers. High numbers of CD4- CD8+ thymocytes developed also in organ cultures from thymi, lacking both MHC class I and class II molecules, exposed to TCDD. A 10-fold transient increase of Notch1 mRNA in thymocytes from fetal thymus organ culture, exposed for 4 days to TCDD, was detected in CD4+ CD8+ cells compared with controls. We suggest that TCDD affects thymic selection and directs the lineage commitment of CD4+ CD8+ thymocytes towards CD4- CD8+ cells, possibly via up-regulation of the Notch1 gene.