Gamma delta T cells expressing CD8 or CD4low appear early in murine foetal thymus development.

Three-colour flow cytometry was used to study the distribution of TCR gamma delta+ cells among CD4+CD8-, CD4-CD8+, CD4+CD8+, and CD4-CD8- cell populations during thymic development. Thymocytes were obtained either directly from embryos at different stages of gestation (ex vivo) or from organ cultures maintained in vitro. In both cases, TCR gamma delta+ cells were found predominantly among the double negative (CD4-CD8-) and CD8 single positive subsets. These cells were actively dividing as demonstrated by 7 amino actinomycin D (7AAD) labelling. A small population of TCR gamma delta+ cells expressing low levels of CD4 was identified early and transiently (days 15-18) during development, but this subset was rare in the adult thymus. In newborn mice, adult mice, and late during organ culture, TCR gamma delta+ cells were found mainly within the CD4-CD8- compartment of thymocytes, although a minor population of CD8+ cells (5-10%) bearing gamma delta receptor was routinely observed. In contrast, few gamma delta cells were contained among the CD4+CD8+ subset at any timepoint studied. These data highlight differences between the ontogeny of alpha beta and gamma delta cells in the thymus, and suggest that a CD4+CD8+ intermediate may not be a requisite for the intrathymic differentiation of murine gamma delta T cells.     

Expression and role of interleukin-2 receptor beta chain on CD4-CD8- T cell receptor alpha beta+ cells [corrected]

Using anti-murine interleukin-2 receptor beta chain (IL-2R beta) monoclonal antibody (mAb), we have examined the expression of IL-2R beta on murine thymocyte subpopulations. We found that it was constitutively expressed on 1%-4% of thymocytes in an almost mutually exclusive fashion with IL-2R alpha. The expression of IL-2R beta is developmentally regulated. While it is expressed mainly on T cell receptor gamma delta+ (TcR gamma delta+) cells during fetal age, the major subpopulation expressing IL-2R beta in adult mouse shifts to CD4-CD8-TcR alpha beta+ thymocytes. A considerable portion of CD4-CD8- TcR alpha beta+ cells in other organs, including spleen, bone marrow and liver, was also found to express IL-2R beta. In fetal thymus organ culture, the above thymocyte subset was induced to expand in response to exogeneous IL-2, and the expansion was inhibited by addition of anti-IL-2R beta mAb, suggesting that IL-2R beta is functional in this subpopulation. However, in vivo blockade of the IL-2/IL-2R pathway with the mAb did not exert any effects on the appearance of CD4-CD8- TcR alpha beta+ cells both in the thymus and the periphery. This indicates that the development of CD4-CD8- TcR alpha beta+ cells is not solely controlled by IL-2 but also by other complex elements.     

Human T cell receptor gamma delta + T cells.

TCR gamma delta + T cells represent a minority of CD3+ T cells in many species including man. The molecular structure of the TCR gamma and delta loci in man is well understood. The gamma and delta loci contain V, D, J and C gene segments. These segments do not rearrange randomly but in a coordinated, ordered fashion during thymic development. Therefore, the structure of gamma and delta genes of early fetal TCR gamma delta + thymocytes differ drastically from those in postnatal TCR gamma delta + thymocytes. In contrast to postnatal TCR gamma delta + thymocytes, early fetal-TCR gamma delta + produce substantial levels of IL-4 and IL-5 and the possibility is discussed that the early fetal TCR gamma delta + cells are involved in development of TCR gamma delta + cells. In man, unlike in mouse, no preferential homing of early fetal TCR gamma delta + cells has been observed so far. Mature human peripheral TCR gamma delta + cells can recognize a great variety of cell surface antigens including 'classical' and 'non-classical' MHC antigens, immunoglobulins and other undefined antigens. In addition, TCR gamma delta + can recognize bacterial products. So far, no class of antigens has been defined that is preferentially recognized by TCR gamma delta + T cells and the function of these cells remains elusive.     

Delineation of chicken thymocytes by CD3-TCR complex, CD4 and CD8 antigen expression reveals phylogenically conserved and novel thymocyte subsets.

To further define the relationship between thymocyte subsets and their developmental sequence, multi-parameter flow cytometry was used to determine the distribution of the CD3-TCR complex and the accessory molecules CD4 and CD8 on chicken thymocytes. As in mammals, adult thymocytes could be subdivided into CD3-, CD3lo, and CD3hi staining populations. CD4 and CD8 distribution on such populations revealed the presence of CD3-CD4+CD8- and CD3-CD4-CD8+ thymocytes, putative precursors to CD4+CD8+ cells, detectable in the adult and at high frequency during ontogeny. Of particular interest was the existence of CD3lo expression on CD4+CD8- and CD4-CD8+, and in some instances, on CD4-CD8- thymocytes. Such phenotypes are not easily detectable in the mammalian thymus but were readily observed in both adult and embryonic chicken thymus from 16 days of embryogenesis. Further analysis of the TCR lineage of these CD3lo cells revealed that they were essentially all of the alpha beta TCR type. Mature CD3hi thymocytes were found within the CD4+CD8+ and CD4+CD8- and CD4-CD8+ subsets. Both alpha beta and gamma delta TCR lineage thymocytes were detected within all CD4- and CD8-defined subsets, thus identifying novel thymocyte subsets in the chicken thymus, namely alpha beta TCR+CD4-CD8- and gamma delta TCR+ CD4+CD8- cells. Hence, this analysis of chicken thymocytes, while confirming the phylogenically conserved nature of the thymus, has revealed novel T cell subsets, providing further insight into the complexity of mainstream thymocyte maturation pathways.     

Analysis of clones derived from human CD7+CD4-CD8-CD3- thymocytes.

The differentiation of human thymocyte precursors was studied by analysis of clonal progeny of CD4-CD8-CD3- (triple negative or TN) thymocytes. Using a culture system of phytohemagglutinin, IL-2, and irradiated allogeneic lymphoid feeder cells, we found that 48% of clones (104 total) derived from TN thymocyte suspensions were TCR gamma delta cells, 12% of clones were TCR alpha beta cells, and 34% were CD16+CD3- cells. Importantly, 6% of clones were novel subsets of CD4+CD8-CD3- or CD4-CD8+CD3- thymocytes. The majority of TCR alpha beta, TCR gamma delta, and CD16+CD3- clones expressed low levels of CD4. Molecular analysis of freshly isolated TN- thymocytes prior to in vitro culture demonstrated that up to 40% of cells had TCR gamma, delta, and beta gene rearrangements, but were negative in indirect immunofluorescence assays for cytoplasmic TCR delta and beta. These data provide evidence at the clonal level for the presence of precursors of the TCR alpha beta and TCR gamma delta lineages in the human TN thymocyte pool. Moreover, a substantial proportion of freshly isolated human TN thymocytes had already undergone TCR gene rearrangement prior to in vitro culture. Whether these precursors of the TCR alpha beta and TCR gamma delta lineages mature from cells already containing TCR gene rearrangements into sTCR+ cells or differentiate in vitro from cells with TCR genes in germline configuration remains to be determined. Nonetheless, these data demonstrate that the predominant clone types that grow out of human TN thymocytes in vitro are TCR gamma delta and NK cells.     

Human intrathymic T cell differentiation

The human thymus develops early on in fetal gestation with morphologic maturity reached by the beginning of the second trimester. Endodermal epithelial tissue from the third pharyngeal pouch gives rise to TE3+ cortical thymic epithelium while ectodermal epithelial tissue from the third pharyngeal cleft invaginates and splits during development to give rise to A2B5/TE4+ medullary and subcapsular cortical thymic epithelium. Fetal liver CD7+ T cell precursors begin to colonize the thymus between 7 and 8 weeks of fetal gestation, followed by rapid expression on thymocytes of other T lineage surface molecules. Human thymic epithelial cells grown in vitro bind to mature and immature thymocytes via CD2 and CD11a/CD18 (LFA-1) molecules on thymocytes and by CD58 (LFA-3) and CD54 (ICAM-1) molecules on thymic epithelial cells. Thymic epithelial cells produce numerous cytokines including IL1, IL6, G-CSF, M-CSF, and GM-CSF--molecules that likely are important in various stages of thymocyte activation and differentiation. Thymocytes can be activated via several cell surface molecules including CD2, CD3/TCR, and CD28 molecules. Finally, CD7+ CD4-CD8- CD3- thymocytes give rise to T cells of both the TCRab+ and TCR gd+ lineages.     

Identification of αβ and γδ T Cell Receptor-Positive Cells

Two lineages of T lymphocytes bearing the CD3 antigen can be defined on the basis of the nature of the heterodimeric receptor chain (alpha beta or gamma delta T cell receptor (TCR) expressed. Precise identification of alpha beta and gamma delta TCR+ cells is essential when studying the tissue distribution and function of these different T cells. In immunofluorescence studies gamma delta TCR+ cells have been identified as CD3+WT-31- or CD3+CD4-CD8- cells. However, this may not be the optimal procedure because gamma delta TCR+ cells are weakly WT-31+, and some are CD8+. The aim of this study was to evaluate a panel of monoclonal antibodies (MoAb) directed against different chains of the TCR-T3 complex for a more precise identification of alpha beta+ and gamma delta TCR+ cells in flow cytometric studies. We found that the MoAb anti-Ti-gamma A and delta-TCS-1, recognizing the TCR-gamma and the TCR-delta chain respectively, only reacted with a subpopulation of gamma delta TCR+ cells, whereas another TCR-delta chain recognizing MoAb anti-TCR-delta 1 reacted with all gamma delta TCR+ cells. All MoAb reported to belong to the CD3 group reacted with both alpha beta TCR+ and gamma delta TCR+ cells as expected. Our results indicate that all gamma delta TCR+ cells can be identified with the MoAb anti-TCR-delta 1. Because no MoAb recognizing the TCR-alpha or TCR-beta chains at the cell surface of intact cells are yet available, we suggest that alpha beta TCR+ cells could be identified as CD3+ anti-TCR-delta 1-cells.     

Human thymic epithelium and T cell development: current issues and future directions

The human thymus develops early in fetal gestation with morphologic maturity reached by the beginning of the second trimester. TE3+ cortical thymic epithelium is most likely derived from endodermal third pharyngeal pouch, while A2B5/TE4+ medullary and subcapsular cortical thymic epithelium is likely derived from third pharyngeal cleft ectoderm. Fetal liver and yolk sac CD7+, CD4-, CD8-, surface(s) CD3- T cell precursors begin to colonize the thymus between 7 and 8 weeks of fetal gestation, followed by rapid expression of other T lineage surface molecules on developing thymocytes. CD7+, CD4-, CD8-, sCD3- thymocytes give rise to T cells of both the TCR alpha beta and TCR gamma delta lineages. Human thymic epithelial cells produce numerous cytokines including IL1, IL6, TGF alpha, leukemia inhibitory factor (LIF), M-CSF, G-CSF and GM-CSF- molecules that likely play important roles in multiple stages of thymocyte selection, activation and differentiation. Important areas for future research on human thymic epithelium include study of lymphoid and non-lineage differentiation potentials of CD7+, CD4-, CD8-, sCD3- T cell precursors in response to TE-cell produced cytokines, study of the triggering signals of cytokine release within the thymic microenvironment, and study of TCR-MHC mediated TE-thymocyte interactions.     

Dissociation of signal transduction via Thy-1 and CD3 antigens in murine T cells

To understand the proliferation/differentiation of immature thymocytes which have not express T cell antigen receptor (TCR), we studied whether Thy-1 has signal-transducing capacity. Thy-1+ CD3-TCR- cells including thymocytes from BALB/c embryos and SCID mice and nude mouse splenic cells did not show proliferative responses in the culture with anti-Thy-1 (G7) plus phorbol myristate acetate (PMA), whereas Thy-1+ CD3+ cells from normal thymus or spleen did show a response to them. Since Thy-1-mediated activation is suggested to require co-expression of the CD3-TCR complex, we compared the T cell proliferative response in mature T cells stimulated with anti-Thy-1 (G7) and anti-CD3-epsilon (2C11). Under the presence of PMA or IL-2, accessory cell-depleted splenic T cells were cultured with G7 or 2C11. PMA augmented the proliferative response of splenic T cells cultured with G7 much more than that with 2C11. IL-2, however, showed reciprocal effect on the proliferation of G7 and 2C11-treated splenic T cells. These data suggest that signals triggered via Thy-1 and CD3-epsilon may provide a distinct intracellular pathway for T cell activation.     

Gamma delta T cell receptor-positive cells of the human gastrointestinal mucosa: occurrence and V region gene expression in Heliobacter pylori-associated gastritis, coeliac disease and inflammatory bowel disease.

T cells expressing the gamma delta heterodimer of the T cell receptor (TCR) were studied with respect to their occurrence and expression of gamma delta TCR variable region (V) genes in the normal gastrointestinal mucosa and in a variety of inflammatory conditions. In controls, gamma delta TCR+ cells were a minority population confined to the epithelial compartment of stomach, small bowel and colonic mucosae. Unlike in the periphery, gastro-intestinal gamma delta TCR+ intraepithelial lymphocytes (IEL) were mainly V delta 1+ (89.98 +/- 17.70%); few were V delta 2+ (6.04 +/- 13.8%) or V gamma 9+ (11.38 +/- 10.73%). All gamma delta TCR+ IEL were CD5low; nearly half were CD8+ and the remainder were CD4-CD8- 'double negatives'. There was no significant change from normal in percentages of gamma delta TCR+ IEL in H. pylori-associated gastritis, Crohn's disease and ulcerative colitis. However, in coeliac disease, gamma delta TCR+ IEL were elevated from 2.54% (+/- 1.71) in controls to 29.6% (+/- 16.1) in untreated patients (P less than 0.001) and 18.5% (+/- 7.2) in treated patients (P less than 0.001) and more were CD4-CD8-. Otherwise, gamma delta TCR+ IEL phenotypes were little changed: the majority remained V delta 1+V delta 2-V gamma 9- and all were CD5low. These data suggest that increased gamma delta TCR+ IEL are not a generalized response to intestinal inflammation or to stress proteins, although the typical V delta 1+V delta 2-V gamma 9- CD5low phenotype is retained.     

Decreases in alpha beta T cell receptor negative T cells and CD8 cells, and an increase in CD4+ CD8+ cells in active Hashimoto''s disease and subacute thyroiditis.

We examined peripheral lymphocyte subsets in patients with autoimmune thyroid disease, or subacute thyroiditis, in the active stage when possible. During destructive thyrotoxicosis arising from alpha beta T cell receptor (TCR) negative T (WT31-CD3+) cells and CD8 (CD4-CD8+) cells decreased and those of CD4+CD8+ cells increased slightly, resulting in proportional increases in CD4 (CD4+CD8-) cells, non-T, non-B (CD5-CD19-) cells, and the CD4/CD8 cell ratio. Changes were similar in active subacute thyroiditis. During stimulative thyrotoxicosis in active Graves' disease, the numbers of such T lymphocyte subsets were not changed, but only the number of CD5+ B (CD5+CD19+) cells increased markedly, resulting in proportional decreases in total T (CD3+) cells, alpha beta+ TCR T (WT31+CD3+) cells, CD8 cells, and non-T, non-B cells. A serial study of some of the patients showed opposite changes in alpha beta TCR- T cells, the CD4/CD8 cell ratio, and CD5+ B cells between the active stages of Graves' and Hashimoto's diseases. alpha beta TCR- T cells were mostly gamma delta TCR+ T (IIF2+ CD3+) cells in these patients. These data suggest that alpha beta TCR-T (gamma delta TCR+ T), CD8, and CD4+ CD8+ cells are important in thyroid destruction in Hashimoto's disease and subacute thyroiditis, and that CD5+ B cells are important in thyroid stimulation in Graves' disease.     

NOD小鼠胸腺细胞TCR介导的信号通路缺陷

目的 进一步研究NOD小鼠T细胞应答改变机理。方法 用抗TCR抗体、ConA激活NOD小鼠胸腺细胞，分析TCR介导的信号通路的水平。结果 与Balb／c小鼠胸腺细胞相比，抗TCR抗体诱导的增殖应答较弱，与年龄及NOD胸腺CD4^ CD8^-和CD4^-CD8^ SP细胞有关；rIL-2能部分恢复对TCR抗体应答的缺乏。NOD小鼠对PMA IONO和PMA anti—TCR-mAb应答正常，但对anti-TCRmAb IONO应答缺乏。结论 与年龄有关的NOD小鼠胸腺细胞对TCR抗体应答的缺乏与T细胞激活时上游PKC信号通路的缺乏有关。     

Evidence for the early recruitment of T-cell receptor gamma delta+ T cells during rat listeriosis.

We have previously reported that heat-shock protein (hsp) 60-reactive T-cell receptor (TCR)gamma delta+ T cells appear in the peritoneal cavity during the early stage of infection with Listeria monocytogenes in mice. In this study, we examined the kinetics of TCR gamma delta+ T cells during listeriosis in F344 rats by flow cytometry using a V65 monoclonal antibody (mAb) directed to a constant determinant of rat TCR gamma delta chains. TCR gamma delta+ T cells significantly increased in the peritoneal cavity on day 6 and then decreased by day 10 after infection, in parallel with the kinetics of hsp60 expression in the peritoneal macrophages during listeriosis in F344 rats. Most of the early appearing TCR gamma delta+ T cells were of the CD4- CD8 alpha beta+ CD5+ lymphocyte function-associated antigen (LFA)-1 alpha high CD45RC- interleukin-2 receptor (IL-2R) alpha- phenotype, although a significant fraction of the TCR gamma delta+ T cells expressed CD8 alpha only. The increase in TCR gamma delta+ T cells during listeriosis was prominent in F1 (F344 x Lewis) rats but only marginal in Lewis rats, which was correlated with the expression level of hsp 60 in the peritoneal macrophages. The peritoneal TCR gamma delta+ T cells in naive F344 rats appeared to proliferate significantly in response to recombinant hsp 60 (rhsp 60) derived from Mycobacterium bovis bacillus Calmette-Guérin (BCG). These results imply that the early appearance of hsp 60-reactive TCR gamma delta+ T cells during listerial infection can be generalized across species.     

Phenotypical and Functional Characterization of Double-Negative (CD4-CD8-) αβ T-Cell Receptor Positive Cells from an Immunodeficient Patient

We have characterized CD4-CD8- double-negative (DN) alpha beta TCR+ T cells from a patient with immunodeficiency, lymphocytosis, lymphadenopathy, and hepatosplenomegaly. The majority of peripheral blood lymphocytes were DN alpha beta TCR+ T cells as evaluated by FACS and biochemical analysis. The DN T cells showed the following phenotype: alpha beta TCR+, gamma delta TCR-, CD2+, CD3+, CD4-, CD5+, CD7-, CD8-, CD16-, CD25-, CD26-, CD28+, CD45RO-, CD45RA+, CD57+, and HLA-DR+. Both southern blot analysis of TCR genes and FACS analysis applying a panel of V beta and V alpha monoclonal antibodies (MoAbs) indicated a polyclonal T-cell expansion. Thymic biopsy showed normal histology, whereas lymph node biopsy samples showed altered histological and immunohistological patterns with markedly expanded paracortical areas containing the DN T cells of the same phenotype as found in peripheral blood T cells. In functional studies, the DN T cells showed a profoundly reduced proliferative response upon stimulation with mitogens as well as MoAbs against the TCR/CD3 complex, CD2, and CD28, respectively. Addition of exogenous interleukin-2 (IL-2) only minimally augmented the proliferative response. In contrast, the addition of a combination of Ca2+ ionophore and phorbol 12-myristate 13-acetate (PMA) restored the proliferative response of the DN T cells to almost normal levels. This observation strongly suggests that the protein kinase C activity of the DN T cells was intact, but that the normal mechanism for transmembrane signal transduction was impaired in these unusual DN T cells.     

Pathogenic autoantibody-inducing gamma/delta T helper cells from patients with lupus nephritis express unusual T cell receptors.

In previous work, we found that only 59 (15%) of 396 "autoreactive" T cell clones derived from five patients with lupus nephritis had the ability to selectively augment the production of pathogenic anti-DNA autoantibodies and the majority (49/59) of those autoimmune T helper (Th) clones were CD4+. Surprisingly, 7 of those Th clones were CD4-/CD8- and gamma/delta TCR+, capable of augmenting the production of pathogenic anti-DNA autoantibodies up to 125-fold. The gamma/delta Th clones responded in a MHC-nonrestricted manner to some endogenous autoantigen associated with heat shock proteins (HSP60) on the lupus B cells. The gamma/delta TCR genes expressed by 4 of these Th clones were amplified and sequenced here. Three of the 4 Th clones, each from a different lupus patient, expressed a gene from the V gamma 1 subgroup. Moreover, 2 of the Th clones expressed V delta 5, and the others V delta 1 or V delta 3. These TCRs are rarely expressed by peripheral blood gamma/delta T cells of normal adult humans. The predominant gamma/delta T cells in human peripheral blood express V gamma 2 (V gamma 9) and V delta 2 TCR genes, including HSP-responsive T cells. None of the lupus Th clones expressed this combination of TCR genes. In addition, some of these pathogenic autoantibody-inducing Th clones from the lupus patients had limited diversity and few N-nucleotide additions in their gamma/delta TCR junctional regions (CDR3), thus resembling fetal gamma/delta thymocytes early in ontogeny.     

bcl-2 transgene expression promotes survival and reduces proliferation of CD3-CD4-CD8- T cell progenitors

Proliferative expansion and apoptotic cell death play prominent roles in T cell development. The molecular control of cell cycle progression and apoptosis appear to be inter-connected since the Bcl-2 protein can inhibit apoptosis and slow cell cycle progression in cortical thymocytes and mature T cells, particularly during the transition from the quiescent state into the cell cycle. Here the impact of bcl-2 transgene expression on CD3-CD4-CD8- T cell progenitors was assessed. Bcl-2 enhanced the survival of these progenitors at all of the four major differentiation stages, CD25- CD44+ (pro-T1), CD25 + CD44+ (pro- T2), CD25 + CD44- (pro-T3) and CD25-CD44- (pro-T4). However, it reduced cell cycling and slowed turnover only in the pro-T4 subset. From an analysis of bcl-2 transgenic mice expressing a TCR transgene or bearing a mutation in the scid or rag-1 gene we conclude that Bcl-2 inhibits proliferation only of T cell progenitors that are activated via the pre- TCR, not those stimulated via c-Kit and the IL-7 receptor.      

Characterization and Expression of the Human T Cell Receptor-T3 Complex by Monoclonal Antibody F101.01

A murine monoclonal antibody (MoAb) F101.01 reacting with the T cell receptor (TCR)-T3 complex is presented. Immunohistological studies showed that F101.01 specifically stains T-zone lymphocytes in lymph nodes, tonsils, and splenic tissue. Two-colour immunofluorescence and flow cytometry demonstrated co-expression of the antigen defined by F101.01 and the pan-T cell antigens defined by CD2, CD3, CD5, and CD7 antibodies. Cells stained with CD4 and CD8 antibodies were both included in the F101.01-positive population, whereas CD16-positive natural killer cells (NK), B cells (CD19 and CD20), and myeloid cells (CD13 and CD33) were excluded. The target antigen of F101.01 co-modulated with the CD3-defined antigen (T3) and the TCR recognized by the MoAb WT-31. CD3 antibody and WT-31 both blocked binding of F101.01. F101.01 precipitated the TCR-T3 complex from lysates of 125I-labelled peripheral blood mononuclear cells (PBMC) and HPB-ALL, when the lysate was prepared with a detergent (digitonin) that conserves the TCR-T3 complex. FACS analysis of T cells from a patient with a T cell immunodeficiency demonstrated that delta-TCS-1-CD3+CD4+ and delta-TCS-1-CD3+CD8+ cells were brightly F101.01+, whereas a large subpopulation of delta-TCS-1+CD3+CD4-CD8- cells were weakly F101.01+. We conclude that F101.01 recognizes a conformational epitope of the TCR-T3 complex and that it reacts with the alpha beta TCR-T3 and the gamma delta TCR-T3 complexes with different intensities.