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.     

T cell receptor expression on immature thymocytes with in vivo and in vitro precursor potential

Immature CD8-CD4- double-negative (DN) thymocytes differentiate intrathymically into CD8+CD4- and CD8-CD4+ thymocytes and migrate to the periphery. This differentiation proceeds through several intermediate phenotypic changes in the expression of CD8 and CD4. We have recently established the existence of a CD8loCD4lo cell population in murine thymus that can repopulate the irradiated thymus in vivo and differentiate rapidly in vitro to CD8+CD4+ double-positive (DP) cells. The CD8loCD4lo cells score as DN upon direct cytofluorometric analysis, yet are distinct from true DN cells by various criteria. Experimental evidence strongly suggests that they are descendants of true DN in the maturation pathway. In the experiments presented here, we further characterize this CD8loCD4lo thymocyte population. Northern blot and RNA protection analysis reveal that these cells transcribe full length mRNA for the T cell receptor (TcR)alpha chain, unlike the less mature interleukin 2 receptor-positive DN thymocytes. Surface expression of the TcR-associated CD3 molecule occurs on approximately 15% of these cells at low levels characteristic of immature cells. In the course of in vitro differentiation a vast majority (approximately 80%) of these cells convert to CD8+CD4+ and significant numbers of the brightly staining DP convertants (11%-34% on day 1 and 48%-68% on day 2) express immature levels of CD3. Our results indicate that CD8lo, CD4lo cells might be the first thymic subset to rearrange TcR alpha chain genes and express TcR alpha/beta heterodimer on the surface at levels characteristic of immature cells. Furthermore, the surface expression of TcR persists on the in vitro progeny of these thymocytes.     

T cell receptor-negative thymocytes from SCID mice can be induced to enter the CD4/CD8 differentiation pathway

In order to investigate the role of T cell receptor (TcR) expression in thymocyte maturation, we have analyzed thymocytes from C.B-17/SCID mice, which are unable to productively rearrange their antigen receptor genes and fail to express TcR. Despite this defect, SCID thymocytes are functional as they produce lymphokines and proliferate in response to a variety of stimuli. Phenotypic analysis revealed that thymocyte populations from young adult SCID mice resemble thymocyte populations from normal embryonic mice in that they are large, Thy-1.2+, CD4-, CD8-, TcR- and enriched in CD5lo, IL2R+ and Pgp1+ cells. However, other TcR- populations normally present in adult mice (i.e., CD4-CD8+ cells and CD4+CD8+ cells) are absent from the thymus of TcR- adult SCID mice. To understand the basis of the developmental arrest of TcR- SCID thymocytes at the CD4-CD8- stage of differentiation, we analyzed thymi from the occasional "leaky" SCID mouse which possesses small numbers of TcR+ thymocytes. We found that the presence of TcR+ cells within a SCID thymus was invariably associated with the presence of CD4+ and/or CD8+ SCID thymocytes. Interestingly, however, the CD4+/CD8+ SCID thymocytes were not themselves necessarily TcR+. That is, emergence of SCID thymocytes expressing CD4/CD8 was tightly linked to the presence of TcR+ cells within that SCID thymus, but the SCID thymocytes that expressed CD4/CD8 were not necessarily the same cells that expressed TcR. Finally, we found that the introduction into TcR- SCID mice of normal bone marrow cells that give rise to TcR+ cells within the SCID thymus promoted the differentiation of SCID thymocytes into CD4-CD8+ and CD4+CD8+ TcR- cells. These data indicate that TcR+ cells within the thymic milieu provide critical signals which promote entry of CD4-CD8-TcR- precursor T cells into the CD4/CD8 differentiation pathway. When applied to differentiation of normal thymocytes, these findings may imply a critical role for early appearing CD4-CD8- TcR (gamma/delta)+ cells in initiating normal thymic ontogeny.     

Kinetics of chicken embryonic thymocyte development in ovo and in organ culture.

Thymocyte development was monitored in an embryonic thymus organ culture system to establish a model in the chicken in which the functional nature of the thymic microenvironment could be assessed. Thymus lobes were removed from 10-day-old embryos and cultured for 2-10 days. Cell yield increased to a maximum in 4-8 days of culture with a corresponding decrease in average cell size. An initial thymocyte population of predominantly CD3-CD4-CD8- cells gave rise to all CD3/CD4/CD8-defined subpopulations in vitro, maintaining high levels of CD3-CD4-CD8+ and CD3+CD4-CD8+ cells and a low representation of CD3-CD4+CD8-, CD3+CD4+CD8-, CD3-CD4+CD8+ and CD3+CD4+CD8+ thymocytes. This is the first observation of a CD3-CD4+CD8- population in the chicken. Developmental kinetics of CD3+ cells were similar to that in the embryo, suggesting that the in vitro environment is sufficient to promote and maintain thymocyte maturation. Thymocytes of both the gamma delta and alpha beta T cell receptor (TcR) lineages developed in that order, confirming in ovo data and the lineage potential of the first wave of thymocyte precursors. One unusual finding was a relative accumulation of gamma delta TcR+ thymocytes in culture, incorporating all CD4/CD8 subsets, including a previously undetected population, CD4+CD8-. This may indicate a favorable developmental environment or simply a lack of normal cellular emigration. A detailed comparison with T cell development in the embryo demonstrated that the chicken thymus organ culture system reflects thymic events in ovo during a limited time period and thus should prove useful in the identification of functionally relevant thymic molecules.     

Patterns of membrane TcR alpha beta and TcR gamma delta chain expression by normal blood CD4+CD8-, CD4-CD8+, CD4-CD8dim+ and CD4-CD8- lymphocytes.

Enriched CD4+CD8-/CD4-CD8-, CD4-CD8+/CD4-CD8- and CD4-CD8- cell suspensions were prepared from normal peripheral blood by selective immunomagnetic depletion of monoclonal antibody-defined lymphocyte populations. Subsequent examination of these modified cell fractions by two-colour flow cytometry provided a means of determining the expression of membrane T-cell receptor (TcR)alpha beta and TcR gamma delta chains by both major (CD4+ and CD8+) and minor (CD3+CD4-CD8dim+ and CD3+CD4-CD8-) lymphocyte subpopulations. Normal CD4+CD8- lymphocytes were almost invariably (greater than 99%) TcR alpha beta+, whereas lymphocytes expressing membrane CD8, which could be further subdivided according to differences in fluorescent staining intensity into CD3+CD4-CD8+, CD3+CD4-CD8dim+ and CD3-CD4-CD8dim+ components, were characterized by distinct differences in patterns of TcR chain expression. In contrast to CD3+CD4-CD8+ cells, which were predominantly (99%) TcR alpha beta+, CD3+CD4-CD8dim+ lymphocytes showed a significant proportion (33%) of TcR gamma delta+ cells (natural killer-associated CD3-CD4-CD8dim+ cells were uniformly TcR-). The highest proportion (62%) of TcR gamma delta+ cells was associated with the CD3+CD4-CD8- fraction, but these studies also revealed that a significant minority of this population was TcR alpha beta+. Despite some evidence for normal inter-individual variation, further analysis of membrane CD8 fluorescent intensities confirmed clear differential relationships for TcR alpha beta and TcR gamma delta chain expression.     

Newly generated thymocytes are not refractory to deletion when the alpha/beta component of the T cell receptor is engaged by the superantigen staphylococcal enterotoxin B

It has been reported that, following the initial expression of the T cell receptor (TcR) alpha/beta, newly generated thymocytes pass through a developmental window characterized by ineffective coupling between the alpha/beta and CD3 components resulting in resistance to deletion (negative selection). However, we now provide evidence that the TcR alpha/beta on developing thymocytes is capable of delivering deletional signals in response to the superantigen staphylococcal enterotoxin B (SEB) as soon as the receptor is expressed. We also show that if TcR+ thymocytes are allowed to mature in organ cultures of embryonic thymus before SEB is added, they respond by proliferation giving rise to blast cells of CD4-CD8-, CD4+CD8- or CD4-CD8+ phenotypes.     

Evidence for major alterations in the thymocyte subpopulations in murine models of autoimmune diseases

Thymocytes can be divided into four major subpopulations: CD4+CD8+ (double-positive), CD4-CD8- (double-negative), CD4+CD8- (CD4+) and CD4-CD8+ (CD8+) cells. Recent studies have shown that T-cell development in the thymus progresses as: CD4-CD8(-)----CD4+CD8(+)----CD4+ or CD8+ cells. In the present study we investigated these and other subpopulations of thymocytes in autoimmune MRL(-)+/+, MRL-lpr/lpr, C57BL/6-lpr/lpr, BXSB and NZB mice before (1-month old) and after (4-6-months old) the onset of lymphadenopathy and autoimmune disease. All the autoimmune strains at one month of age and other H-2, sex and age-matched controls (C3H, DBA/2, and C57BL/6) demonstrated normal proportions of thymocyte subsets with approximately 75% double-positive cells, 5-7% double-negative cells, 11-15% CD4+ cells and 3-5% CD8+ cells. By 4-6 months of age, MRL(-)+/+ mice demonstrated a moderate increase in double-negative cells (approximately 13%) and a decrease in double-positive cells (approximately 46%). Interestingly, in the presence of the lpr gene, as seen in MRL-lpr/lpr mice, the double-negative cells increased to approximately 47% and the double-positive cells decreased to approximately 16%. In contrast, 4-6-month-old C57BL/6-lpr/lpr mice failed to demonstrate any alterations in the thymocyte subsets thereby suggesting that background genes, in addition to the lpr gene, played a role in the thymocyte differentiation. BXSB male mice with severe lymphadenopathy behaved very similarly to MRL-lpr/lpr mice, inasmuch as their thymus contained approximately 48% double-negative cells and only approximately 8% double-positive cells. In contrast to MRL-lpr/lpr and BXSB strains, NZB mice at 6 or 10 months of age had normal composition of thymocyte subsets. In MRL and BXSB animals, although there was a significant increase in CD4+ cells (approximately 23-33%), due to a consequent increase in CD8+ cells (approximately 11%), the ratio of CD4+:CD8+ cells remained 2-3:1, similar to that seen in normal mice. Furthermore, using the J11d marker expressed by the majority of the double-negative and all double-positive thymocytes but not by mature functional T cells, we confirmed the above findings and demonstrated further that MRL-lpr/lpr mice at 4-6 months of age had an increased percentage of J11d- double-negative cells and a decrease in J11d+ double-negative cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

TCR抗体诱导不成熟胸腺细胞亚群凋亡的敏感性研究

为比较小鼠不同胸腺细胞亚群对抗TCR抗体诱导凋亡的敏感性，用体外抗TCR抗体刺激分离胸腺细胞．BALB／c小鼠体内注射抗TCR抗体，FACS检测胸腺细胞。结果显示，CD4^ CD8^ DP胸腺细胞和CD4^-CD8^ CD3^-TCR-细胞对抗TCR抗体诱导的凋亡敏感，但CD4^-CD8^-CD3^-TCR-胸腺前体细胞自发凋亡率低，且抗TCR抗体诱导的凋亡．表明胸腺细胞对凋亡的敏感点产生于CD4^-CD8^ CD3^-TCR-细胞表达后，胸腺细胞的凋亡敏感性受发育调节。     

Different subpopulations of developing thymocytes are associated with adherent (macrophage) or nonadherent (dendritic) thymic rosettes.

Thymic rosettes (ROS), structures consisting of thymic lymphoid cells attached to a central stromal cell, were isolated from mouse thymus by collagenase digestion and unit-gravity elutriation. The ROS were then separated into those where the stromal cells were either macrophage-like (M-ROS) or dendritic cell-like (D-ROS), on the basis of the differences in adherence properties or in the level of MAC-1 surface antigen. The ROS were then dissociated and the thymocyte content analyzed by immunofluorescent staining and flow cytometry. M-ROS and D-ROS differed in thymocyte composition, although the major component of both was the CD4+CD8+ cortical thymocyte. D-ROS were enriched in thymocytes expressing high levels of surface T-cell antigen receptor (TcR) and the associated CD3 complex, and these included both CD4+CD8-CD3++ and CD4-CD8+CD3++ mature thymocytes. M-ROS were enriched in CD4-CD8- thymocytes and had a reduced content of thymocytes expressing high TcR-CD3 levels; they nevertheless contained some mature thymocytes, but only of the CD4+CD8-CD3++ category. Several lines of evidence indicated that the mature thymocytes in ROS were cells recently formed in the cortex, and were not from the medullary pool. ROS-associated mature thymocytes expressed lower levels of H-2K than free, mature thymocytes. The CD4+CD8+CD3++ subpopulation, believed to be a developmental intermediate between cortical thymocytes and mature T cells, was present in both ROS populations. Further, late intermediates leading to both mature T-cell categories were evident in D-ROS, but only those leading to CD4+CD8-CD3++ T cells were evident in M-ROS. The results are compatible with a role for ROS in TcR-specificity selection and in the final maturation steps in the thymic cortex.     

Enhancement of CD3-mediated thymocyte apoptosis by the cross-linkage of heat-stable antigen.

Heat-stable antigen (HSA) is a murine differentiating antigen that is expressed on both CD4-CD8- double-negative and CD4+CD8+ double-positive thymocytes but not CD4+ or CD8+ single-positive thymocytes. Effects of anti-HSA monoclonal antibody, R13, on thymocyte apoptosis induced by various stimulations were investigated by a single-cell suspension culture system. Immobilized R13 enhanced the CD3-mediated DNA fragmentation and killing of thymocytes but not the dexamethasone-induced or phorbol myristate acetate-induced killing of thymocytes. Immobilized R13 by itself could not induce thymocyte apoptosis. Soluble R13 enhanced CD3-mediated apoptosis when HSA and T-cell receptor (TCR)/CD3 were co-cross-linked by a cross-reactive secondary antibody. Even without the cross-reactive secondary antibody, soluble R13 enhanced CD3-mediated apoptosis, although a greater than 100-fold increase in the amount of R13 was needed to give a similar enhancement compared with immobilized R13. Neither R13 by itself nor R13 plus secondary antibody induced cytosolic calcium influx, whereas R13 enhanced CD3-mediated cytosolic calcium increase. These results suggest a functional role of HSA in promoting the activation-induced apoptosis of thymocytes and the involvement of HSA in negative selection.     

The organotin-induced thymus atrophy, characterized by depletion of CD4+ CD8+ thymocytes, is preceded by a reduction of the immature CD4- CD8+ TcR alpha beta-/low CD2high thymoblast subset.

Thymic changes in the rat induced by the thymus atrophy-inducing organotin compound di-n-butyltin dichloride (DBTC) were examined using FACS analyses. The number of CD4+CD8+ thymocytes was reduced by DBTC treatment from Day 2 onwards and reached minimum level on Days 4 and 5 after dosing. On these days the CD4-CD8- and both the CD4-CD8+ and CD4+CD8- subsets were not affected. On Day 2 we observed a reduced proportion of transferrin receptor (CD71)-positive CD4-OX44- cells, representing the cycling immature CD4-CD8+ cells, and of CD71+OX44- cells, representing the cycling CD4+CD8+ cells, but not of CD71+CD4-CD8- cells. When compared to controls, the FSChigh cell population of DBTC-treated rats contained less CD4-OX44- and OX44- cells, which were further characterized as CD2high and T-cell receptor (TcR)alpha beta- low. Moreover, fewer TcR alpha beta high cells were detected in the OX44- thymoblast subset of DBTC-treated rats. The number of CD4-CD8- thymoblasts appeared marginally decreased while the numbers of CD4+OX44+ cells, representing mature CD4+ cells, were not affected. These data indicate that DBTC causes a preferential initial depletion of immature CD4-CD8+CD2high TcR alpha beta-low thymoblasts. This initial event may result in a decreased formation of CD4+CD8+ thymoblasts and of small CD4+CD8+ thymocytes. These characteristics of the initially depleted subset indicate a specific anti-proliferative effect of DBTC and may give clues for the mechanism involved in the induction of thymus atrophy.     

CD45 isoform expression during T cell development in the thymus.

Various isoforms of leukocyte common antigen, or CD45, are expressed differentially on T cells at different stages of development and activation. We report studies on CD45 isoform expression on various subsets of human T cells using two- and three-color flow cytometry and cell depletion. Bone marrow cells that were depleted of CD3+ and HLA-DR+ cells were CD45RA-RO-. The earliest CD3-CD4-CD8-CD19- thymocytes were CD45RO- with 20%-30% CD45RA+ cells. The most prominent population of CD4+CD8+ double-positive thymocytes were CD45RA-RO+. Even the CD4+CD8+ blasts were greater than 90% CD45RO+. About 80% of single-positive thymocytes (CD4+CD8- or CD4-CD8+) were also CD45RO+. Only 4.3% of CD4+ and 18% of CD8+ single-positive thymocytes were CD45RA+. In contrast, cord blood T cells which represent the stage that immediately follows single-positive thymocytes, contained 90% CD45RA+ cells. Thus, in terms of CD45 isoform expression, single-positive thymocytes are more like double-positive cells than cord blood T cells. These results suggest the following sequence of CD45 isoform switching during T cell development: CD45RA-RO- or RA+RO- (double-negative thymocytes)----RA-RO+ (double-positive and most single-positive thymocytes)----RA+RO- (cord blood T cells), the last switch from CD45RO to CD45RA occurring as a final step of maturation in the thymus.     

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.     

Two differential pathways from double-negative to double-positive thymocytes.

Murine thymocytes are divided into four major populations on the basis of expression of CD4 and CD8 antigens. The bulk of evidence favours the view that CD4-CD8- cells can develop into CD4-CD8+ and CD4+CD8- cells via the CD4+CD8+ stage in the thymus. However, CD4-CD8+ and CD4+CD8- thymocyte subsets contain not only CD3+ mature cells but also CD3- immature cells, which seem to be intermediate cells between CD4-CD8- and CD4+CD8+ cells. Here we demonstrate mouse strain differences in the proportion of immature single-positive thymocyte subsets in thymus at the steady or developing state. In C3H mice, immature CD4+CD8- is dominant in proportion over CD4-CD8+ in foetal thymus and in donor-derived thymocytes at an early stage of bone marrow transplantation. On the other hand, immature CD4-CD8+ is dominant over CD4+CD8- during T-cell development in the case of B10.BR mice. An intermediate pattern was shown in the case of F1 mice. Both of these immature single-positive subsets gave rise to double-positive cells after 24 hr culture. These results suggest that there exist two distinct differential pathways; one is from CD4-CD8- cells to CD4+CD8+ cells via CD4-CD8+ cells, and another is via CD4+CD8- cells, and that an application of the 'CD8 pathway' or 'CD4 pathway' seems to be genetically destined by BM-derived cells but not by thymic stromal cells.     

Human thymocyte development in mouse organ cultures

A novel system to study human thymocyte development is described in which embryonic mouse thymic rudiments are seeded with human precursor cells in vitro. In these cultures human thymocytes proliferate extensively (greater than 20-fold increase in cell number) and mature, as evidenced by the accumulation of double and single positive (CD4+ and/or CD8+) cells. Data presented here suggest that the survival and ordered development of the mature human thymocytes in chimeric thymuses is dependent on human stromal elements. Immature CD4-CD8- human thymocytes failed to colonize or minimally recolonized mouse thymic lobes unless provided with high density (greater than 1.077 g/ml) human thymic cell fractions. These fractions contain multicellular complexes of epithelial/nurse cells, thymocytes, and dendritic cells/macrophages which dramatically enhanced the recolonizing capacity of purified CD4-CD8- thymocytes. The chimeric organ culture system described here provides not only a new approach for studying human T cell ontogeny but also a direct means for the future dissection of stromal interactions necessary for successful transition of precursor cells (CD4-CD8-) to immature double positive (CD4+CD8+) and mature single positive cells (CD4+ or CD8+) in the thymus.