Cell components required for deletion of an autoreactive T cell repertoire

T cells become tolerant to self antigens during their development in the thymus. Clonal deletion of thymocytes bearing T cell receptor (TcR) which recognize self antigens is a major mechanism for generating tolerance. In the present study we have used allogeneic bone marrow (BM) chimeras, prepared with various combinations of mouse strains and focusing especially on expressions of I-E molecules and Mls-1a antigens on the cell surface, to investigate both immunohistochemically and by flow cytometry the cell components that contribute to the clonal deletion of T cells positive for V beta 6 TcR. The V beta 6 TcR expression is strongly associated with T cell recognition of both I-E and Mls-1a antigens. We found that I-E+ cells derived from donor BM (and thus not of recipient lineage) represented a primary requirement for deletion of Mls-1a-reactive thymocytes which bear V beta 6 TcR. Immunohistochemical analysis revealed that the donor-derived I-E+ cells were distributed mainly to the thymic medulla and that the V beta 6+ cells were eliminated from the thymic medulla between 2 and 3 weeks following BM transplantation. In contrast, Mls-1a+ cells of either donor or recipient origin might be responsible for the deletion, even though cortical epithelial cells appeared not to express Mls-1a antigens.     

Mouse autoreactive gamma/delta T cells. II. Molecular characterization of the T cell receptor.

A panel of dendritic epidermal T cell (DETC) lines, and hybridomas derived from them, has been shown to spontaneously secrete lymphokines in the absence of added stimuli, which suggests that these cells are autoreactive. These cell lines are characterized by the expression of a V gamma 1.1C gamma 4/V delta 6 type T cell receptor (TcR), but several of the DETC lines also express a second TcR. Sequence analyses of these gamma/delta TcR revealed that the gamma chains were identical and that the delta chains, while not identical, were quite restricted in diversity, indicating that these receptors may recognize a common or closely related group of antigens. Analysis of hybridomas derived from newborn thymocytes identified six hybridomas that spontaneously secrete lymphokines. Five hybrids expressed a V gamma 1.1C gamma 4/V delta 6 receptor and one hybrid a V gamma 1.1C gamma 4/V delta 4 receptor that had a close structural relationship to the DETC gamma/delta TcR associated with spontaneous lymphokine secretion. gamma/delta TcR of the C gamma 4 type expressed by splenic hybridomas that did not spontaneously secrete lymphokines revealed no such relationship. Curiously, like the DETC, several of the thymocyte hybridomas that spontaneously secreted lymphokines expressed a second TcR, V gamma 2C gamma 1 or V gamma 3C gamma 1, apparently in association with the same delta chain that paired with the C gamma 4 chain. The presence of spontaneous lymphokine-secreting gamma/delta T cells with such highly homologous TcR in both the thymus and skin suggests a thymic origin for the autoreactive DETC and that these cells recognize a common or closely related group of self-antigens.     

Developmental T cell receptor gene rearrangements: relatedness of the alpha/beta and gamma/delta T cell precursor.

To examine the relationships between T cell populations at various stages of development, T cell receptor (TcR) gene rearrangements were compared between the four murine populations of (a) early thymocytes, (b) early splenocytes, (c) adult thymocytes and (d) adult splenocytes. TcR alpha gene rearrangements were shown to progress from 5' to 3' regions of the J alpha locus and from 3' to 5' regions of the V alpha locus during the development of T cells in both the thymus and spleen. Thus, the gene rearrangement potentials of proximal genes varied with age, yielding a biased repertoire in the young vs. adult animal. As evidence that gamma/delta and alpha/beta gene rearrangements appeared concomitantly in individual precursors, it was found that: (a) multiple adult thymocytes bore alpha gene rearrangements on one chromosome and delta gene rearrangements on the homologous chromosome, and (b) V gamma 3-J gamma 1 rearrangements, prominent joins in the early gamma/delta T cell population, were also prominent in the early alpha/beta T cell subset. These data illustrate the non-random nature of the developmental TcR gene rearrangement and suggest that alpha/beta and gamma/delta T cell populations derive from related, if not identical, T cell precursor populations.     

Structural and serological heterogeneity of gamma/delta T cell antigen receptor expression in thymus and peripheral blood

Monoclonal antibodies (mAb) reactive against the gamma/delta T cell antigen receptor (TcR) have been used to characterize the distribution and structural properties of gamma/delta TcR-bearing lymphocytes in blood and thymus. Consistent with prior reports the TcR gamma/delta-1 and delta-1 mAb react with all gamma/delta TcR+ T lymphocytes in blood and thymus. By contrast the TCS-delta mAb was found only to react with a subset of the gamma/delta TcR-bearing T cell population. Several lines of evidence suggest that this reagent preferentially reacts with the V delta 1 gene product. Using these reagents, it was observed that gamma/delta TcR+ T lymphocytes comprise 4.6 +/- 3.5% (range 1.0-16.3%) of peripheral blood lymphocytes. However, analysis of peripheral blood from normal adult donors revealed that in 29 of 32 the TCS-delta (possibly V delta 1)-bearing cells comprised less than 30% of the total gamma/delta-TcR+ population. Biochemical analysis demonstrated that the predominant form of the gamma/delta TcR in adult peripheral blood is a disulfide-linked heterodimer, indicating preferential use of the C gamma 1 gene. The delta TcR chain from these TcR-gamma/delta-1+/TCS-delta- T cells was remarkably basic in charge, as analyzed by nonequilibrium pH gradient electrophoresis. By contrast with peripheral blood the majority of freshly isolated and interleukin 2-cultured gamma/delta TcR+ thymocytes were predominantly TcR-gamma/delta-1+/TCS-delta +, and preferentially expressed V delta 1. Moreover, both disulfide-bonded and nondisulfide-bonded gamma/delta TcR heterodimers were expressed in all thymuses examined and both forms were contained within the TCS-delta + thymic subset. Similar to recent findings in the mouse, these studies suggest a possible bias in the structural form of gamma/delta TcR based on tissue location.     

Presence of CD8 alpha-CD8 beta-positive TcR gamma/delta thymocytes in the fetal murine thymus and their in vitro expansion with interleukin-7.

Several groups have described that a low percentage of in vitro cultured T cell receptor (TcR) gamma/delta cells express CD8. Contrary to TcR alpha/beta cells, however, CD8 on these TcR gamma/delta cells was shown to be a CD8 alpha homodimer. We describe here that addition of interleukin-7 (IL-7) to a short-term in vitro culture of fetal day 14 thymic lobes in an organ culture system or of fetal day 18 fetal thymocytes in cell suspension yields CD8 beta-positive TcR gamma/delta cells. This is not the result of IL-7-induced expression of CD8 beta on previously CD8 beta-negative cells. It is due to IL-7-induced expansion of CD8 alpha-CD8 beta-positive TcR gamma/delta cells which are shown to be present in the starting fetal thymocyte cell population.     

Ti gamma A + delta TCS1+ T cells in human thymus. Analysis of the T cell receptor.

TcR1+ T cells in peripheral blood have been shown to express in an exclusive fashion either the Ti gamma A or the delta TCS1 epitope. Here, we characterize a subset of TcR1+ T cells in fresh thymus co-expressing the Ti gamma A and delta TCS1 epitopes. TcR1dim and TcR1bright clones can be distinguished. Biochemical and molecular studies on both types of clones generated from these thymocytes reveal a unique T cell receptor structure characterized by the use of a V gamma 9/C gamma 2-encoded 55-kDa gamma chain nondisulfide linked to a V delta 1-encoded delta chain.     

CD5− dendritic epidermal T cells are derived from CD5+ precursor cells

Murine Thy-1⁺, TcR Vγ3/Vδ⁺ dendritic epidermal T cells (DETC) differ from most other T cell subsets by the absence of CD4 and CD8 antigens as well as the lack of CD5 expression. To see whether negativity for those antigens is an intrinsic feature of a given T cell population or if such triple-negative T cells go through a maturational stage where they express these antigens, we determined the phenotype of TcR Vγ3⁺ fetal thymocytes which are the precursor cells of DETC. We found that TcR Vγ3⁺ fetal thymocytes phenotypically differ from mature DETC in that they are CD5⁺, mostly CD8⁺ and partly CD4⁺. The injection of fetal thymic suspensions containing TcR Vγ3⁺/CD5⁺ (but not TcR Vγ3⁺/CD5^?) thymocytes into Thy-1-disparate athymic nude mice resulted in the appearance of donor-type TcR Vγ3⁺/CD5^? dendritic cells in the recipients' epidermis, indicating that TcR Vγ3⁺ thymocytes are indeed the precursors of CD5^? DETC. Tracing CD5 expression on DETC precursors during their intrathymic maturation and their migration to the fetal skin, we found that (i) the earliest DETC precursor cells as defined by TcR Vγ3 expression express high levels of CD5 antigen (day 15 of gestation), (ii) after day 16 of gestation 70% of TcR Vγ3⁺ thymocytes express high and 30% express intermediate levels of CD5, (iii) TcR Vγ3⁺ cells in the fetal blood express low levels of CD5, (iv) the first TcR Vγ3⁺ cells entering the epidermis express very low levels of this antigen and (v) TcR Vγ3⁺ epidermal cells later than day 19 of gestation are CD5^?. A similar down-regulation of CD5 expression on DETC precursors was also noted when TcR Vγ3⁺ cells were cultured in vitro. Even the addition of PMA and ionomycin, which up-regulates CD5 expression on TcR α/β-bearing thymocytes and lymph node T cells, could not prevent down-regulation on DETC precursors. The described cell system may serve as a useful tool in further experiments aimed to clarify the function of the CD5 glycoprotein as well as the mechanism(s) regulating its expression.     

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.     

Restitution of the thymus in lethally irradiated mice after transplantation of syngeneic or allogeneic bone marrow

The early restitution of the thymus of bone marrow chimeras was investigated by the immunoperoxidase technique using monoclonal antibodies against Thy-1 and Lyt-1, Lyt-2, Lyt-3. Within two weeks, normal thymus histology was restored in mice which received untreated syngeneic BM or syngeneic or allogeneic BM pretreated with SAL (specificed antilymphocytic serum). Irradiation depleted the thymic cortex of small Thy-1+, Lyt-1+2+3+ cells but did not affect a medullary population of medium sized weakly stained Thy-1+, strongly stained Lyt-1+ cells. Preceded by the appearance of an increasing number of large Thy-1+, Lyt-1- blasts (days 2 and 4), the thymic cortex was repopulated (beginning on day 6) by smaller Thy-1+ cells which acquired Lyt-1, Lyt-2 and Lyt-3 though, obviously not in a strictly sequential manner. Simultaneously, the medullary radioresistant cells disappeared, nd the medulla was subsequently repopulated (beginning on day 8) by thymocytes of a mature phenotype. Early restitution of the thymus in radiation control mice was similar to the bone marrow chimeras. The results indicate that the histological restitution of the thymus originates substantially from radioresistant precursors of host origin. Graft-versus-host reaction induced by untreated allogeneic bone marrow cells prevented normal thymic restitution. A delayed localized cortical repopulation with small Thy-1+, Lyt-1+2+3+ cells, progressive destruction of thymic architecture and almost no restoration of the medullary immunocompetent thymocytes were noted. T cell differentiation obviously was seriously affected by the injuries to the thymic microenvironment due to alloreactive T cells.     

Cytokine Production and Responsiveness of Fetal T-Cell Receptor Vγ3 Thymocytes

The aim of this study was to examine the cytokine production and cytokine responsiveness of the first T-cell receptor (TcR) positive cells that appear in the murine fetal thymus, namely TcR V gamma 3 cells. It is shown that IL-2-cultured fetal TcR V gamma 3 thymocytes were capable of producing IL-3, GM-CSF, TNF-alpha and IFN-gamma upon TcR triggering. IL-2, IL-4, IL-5 and IL-6 could not be detected. With regard to cytokine responsiveness, TcR V gamma 3 cells proliferated to a high extent when high concentrations of rIL-2 were added. rIL-4 or rIL-7 alone, but not rIL-1 alone, were capable of inducing a modest proliferation of TcR V gamma 3 thymocytes. When combined with low concentrations of IL-2, a synergistic effect could be observed with IL-1, IL-4 or IL-7. It is shown that the synergistic effect of IL-2 with IL-4 was mainly due to induction of IL-2 receptor expression. The synergistic effect of IL-2 and IL-7 on the proliferation of TcR V gamma 3 cells could only be partially inhibited by anti-IL-2 receptor MoAb, and this antibody had no effect on the IL-2 + IL-1 cultures. These observations can explain the extensive proliferation of TcR V gamma 3 thymocytes during fetal life and they indicate that TcR V gamma 3 thymocytes have the potential to play a functional role during fetal thymus development.     

DL4‐mediated Notch signaling is required for the development of fetal αβ and γδ T cells

T‐cell development depends upon interactions between thymocytes and thymic epithelial cells (TECs). The engagement of delta‐like 4 (DL4) on TECs by Notch1 expressed by blood‐borne BM‐derived precursors is essential for T‐cell commitment in the adult thymus. In contrast to the adult, the earliest T‐cell progenitors in the embryo originate in the fetal liver and migrate to the nonvascularized fetal thymus via chemokine signals. Within the fetal thymus, some T‐cell precursors undergo programmed TCRγ and TCRδ rearrangement and selection, giving rise to unique γδ T cells. Despite these fundamental differences between fetal and adult T‐cell lymphopoiesis, we show here that DL4‐mediated Notch signaling is essential for the development of both αβ and γδ T‐cell lineages in the embryo. Deletion of the DL4 gene in fetal TECs results in an early block in αβ T‐cell development and a dramatic reduction of all γδ T‐cell subsets in the fetal thymus. In contrast to the adult, no dramatic deviation of T‐cell precursors to alternative fates was observed in the fetal thymus in the absence of Notch signaling. Taken together, our data reveal a common requirement for DL4‐mediated Notch signaling in fetal and adult thymopoiesis.     

T cell receptor repertoire of gamma delta cells generated from the 14-day embryonic mouse thymus.

Whole, undisrupted 14 day mouse fetal thymus lobes cultured in the presence of 10 U/ml IL-2 generate a heterogeneous population of gamma delta-expressing T cells. Phenotypic analysis has shown that the majority of gamma delta T cells in such cultures stain with the anti-V gamma 3-specific mAb 536. To investigate the V gamma T-cell receptor diversity of cultured fetal thymocytes, cDNA was prepared and amplified using the polymerase chain reaction. The DNA fragments obtained were subsequently cloned and sequenced and compared with those obtained from fresh and organ-cultured 14 day fetal thymus lobes. Results obtained tend to support a positive selection model of gamma delta T cell differentiation.     

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.     

Ontogeny of the response of mouse thymocytes to interleukin 1 and interleukin 2.

In the present report we demonstrate that the in vitro proliferative response of the newborn thymocytes to interleukin (IL) 1 and IL 2, which is remarkably stronger than the adult thymocyte response, is associated with a considerable increase of CD4-CD8- cells expressing a gamma/delta T cell receptor (TcR). By polymerase chain reaction analysis we show that the V gamma gene segment usage in the adult and newborn responding cells reflects the developmentally regulated expression of the V gamma gene segments, suggesting that the increase in TcR gamma/delta+ cells results from the polyclonal expansion of pre-existing clones. Surprisingly, although the fetal thymocyte populations contain higher numbers of TcR gamma/delta+ cells than the adult and newborn ones, the highest proliferative response to IL 1 and IL 2 is obtained with the newborn thymocytes. Non mutually exclusive hypotheses are discussed to explain these results.     

Diversity of novel recombining elements suggests developmentally programmed expression of the T cell receptor alpha/delta locus.

During fetal ontogeny, the first wave of gamma delta T lymphocytes appears in the thymus at day 14 of gestation assembling predominantly T cell receptors (TcR) with V gamma 3 and V delta 1. To identify V delta gene segments that are transcribed at day 16, subsequent to the first wave of V delta 1 expression, delta chain cDNA was amplified by the anchored polymerase chain reaction with single-sided specificity for C delta. Unexpectedly, most of the cDNA clones do not contain V gene segments. In some cDNA clones an alternative splice from the leader exon to the C delta exon has deleted the whole variable region exon. In other cDNA clones, multiple non-V-like elements are juxtaposed to the D delta 2 and J delta 1 gene segments. A large number of these diverse elements appear to be rearranged in fetal thymocytes, bringing V alpha gene segments located upstream of the recombining element into proximity to the J alpha locus. It is proposed that these rearrangements make irreversible the commitment to the TcR alpha beta lineage and determine a programmed read out of different clusters of V alpha gene segments.