Expression and function of interleukin-2 receptors on immature thymocytes

T-cell differentiation represents a unique system for studying mechanisms of lymphoid development because it occurs in a segregated site, the thymus, in which distinct subpopulations of thymocytes at various stages of differentiation can be defined on the basis of the differential expression of T-cell surface antigens as well as topography. There is particular interest in thymocyte differentiation because the genotype of radioresistant thymus cells influences the specificity repertoire of the pool of T cells that mature therein: that is, the major histocompatibility complex (MHC) antigens expressed by thymus cells bias the pool of maturing T cells towards recognition of antigens in the 'context' of the products of that MHC haplotype ('thymus education'; refs 1-3). Immature T cells with affinity for thymus MHC antigens are generally thought to undergo a stage of positive selection in the thymus. Here we report that 30% of cells in the least mature adult thymocyte subpopulation yet defined, as well as 50% of immature fetal thymocytes, express receptors for interleukin-2 (IL-2, the T-cell growth factor) without in vitro induction, and will proliferate vigorously in an IL-2-dependent fashion if provided with co-stimulating mitogen.     

CD4 expressed on earliest T-lineage precursor cells in the adult murine thymus.

A continuous but low input of stem cells or 'prothymocytes' is necessary to maintain T-cell development in the adult thymus, but the colonizing cell has not been characterized. Precursors of T cells have been found in the minor CD4-8- population of thymocytes, but even the earliest cells of this population already have partially rearranged T-cell antigen receptor (TCR) genes. We now demonstrate that the thymus contains a minute population of lymphoid cells similar in some but not all respects to bone marrow-derived haemopoietic stem cells. This population has TCR genes in a germline state. It gives a slow but extensive reconstitution of both alpha beta and gamma delta lineages on transfer into an irradiated thymus, with kinetics indicating that it includes the earliest intrathymic precursor cells so far isolated. Surprisingly, these cells express low surface levels of the mature T-cell marker CD4.     

Engagement of the CD4 molecule influences cell surface expression of the T-cell receptor on thymocytes

The intrathymic differentiation process by which precursor cells derived from the bone marrow develop into immuno-competent T lymphocytes is poorly understood. Most thymocytes express both CD4 and CD8 accessory molecules, yet little is known about either the function of these molecules or the responsiveness of the CD4+8+ double positive thymocytes that bear them. Here, we address the possibility that CD4 engagement influences T-cell receptor (TCR) expression on developing thymocytes. We engaged CD4 molecules on murine thymocytes by in vivo injection of an anti-CD4 monoclonal antibody, which reduced the surface expression of CD4 on CD4+ thymocytes. More importantly, CD4 engagement also affected TCR expression on CD4+ thymocytes, but the effect on CD4+8+ double positive and CD4+8- single positive thymocytes was very different. CD4+8+ thymocytes responded to CD4 engagement by dramatically increasing surface expression of TCR, whereas CD4+8- thymocytes decreased surface expression of TCR. These results demonstrate that the effect of CD4 engagement on TCR expression is dependent upon the developmental state of the responding thymocyte, and, most interestingly, results in increased TCR expression by double positive thymocytes.     

Transient expression of IL-2 receptor precedes the differentiation of immature thymocytes

The growth of mature T lymphocytes after activation by antigen is regulated by the binding and endocytosis of interleukin-2 (IL-2). In the thymus, approximately 50% of adult thymocytes that carry neither the CD4 nor the CD8 antigen and day 14-15 fetal CD4-8- thymocytes express receptors for IL-2(IL-2R). The CD4-8- (double-negative) subpopulation of thymocytes contains the precursors of cells that can differentiate along an unknown pathway into thymocytes bearing either CD8 or CD4, with the characteristics of mature T lymphocytes. The basis for IL-2R expression by double-negative thymocytes is unclear as they appear to lack a functional T-cell receptor/CD3 complex through which activation of peripheral T cells is mediated. The argument for a role for IL-2 in thymocyte differentiation has also been complicated by conflicting reports on the inability or capability of double-negative thymocytes to respond to IL-2 in vitro. At present, both the nature of the stimuli within the thymic micro-environment which induce IL-2R expression and its relevance to thymocyte differentiation are not known. We show here that the IL-2R-bearing subset has a greater potential to differentiate into phenotypically mature T lymphocytes than do IL-2R-negative thymocytes. In addition, progeny of IL-2R-negative donor cells transiently express IL-2R in the thymuses of adoptive hosts before generating CD8 and/or CD4-positive thymocytes. These results identify the IL-2R-positive cells as a more differentiated double-negative thymocyte subset on the pathway to mature T lymphocytes.     

CD4+ murine T cells develop from CD8+ precursors in vivo

The adult murine thymus contains four subpopulations of thymocytes defined by the T-cell surface antigens CD4 (L3T4) (a marker of helper T cells) and CD8 (Lyt2) (a marker of cytotoxic/suppressor T cells): CD4+8- and CD4-8+ (single positives), CD4+8+ (double positives) and CD4-8- (double negatives). To understand how T cells develop in the thymus, it is important to determine the lineage relationships among these subpopulations. In particular, the status of double positives, which make up approximately 80% of the total thymocyte population, has long been controversial. Some purpose that double positives are 'dead-end cells' that all die in the thymus, perhaps because they have been rejected by some selection process. Others suggest that, although most double positives die in the thymus, some develop into the more mature single positives that leave the thymus. The experiments presented here show that repeated injections of anti-CD8 monoclonal antibodies block the development of CD4+ cells, demonstrating that these cells develop from CD8+ precursors, probably double positive thymocytes, in vivo.     

Participation of CD4 coreceptor molecules in T-cell repertoire selection.

During thymocyte development, progenitor cells bearing both CD4 and CD8 coreceptor molecules mature into functional T lymphocytes that express these proteins in a mutually exclusive way. Although T-cell specificity is determined primarily by the structure of the T-cell antigen receptor (TCR) heterodimer, a developmentally regulated process acts to ensure that cells bearing class II-restricted TCRs are CD4+ and those bearing class I-restricted TCRs express only CD8. To investigate this maturation process, we have engineered transgenic mice in which CD4 is expressed in all thymocyte subsets and in all peripheral T cells. Peripheral CD4+8+ T lymphocytes from these mice react with both class I and class II alloantigens. Moreover, expression of the CD4 transgene disrupts the positive selection of doubly transgenic thymocytes bearing a class I-restricted TCR specific for the male (H-Y) antigen. Hence the CD4 coreceptor participates directly in T-cell repertoire selection.     

Expression of interleukin-2 receptors as a differentiation marker on intrathymic stem cells

The thymus is regarded as the primary site for T-cell lymphopoiesis, but very little is known about the lineage inter-relationships of cells within that organ. At least four subpopulations of mouse thymocytes can be defined on the basis of staining with monoclonal antibodies directed against the T-cell differentiation antigens Lyt-2 and L3T4 (ref. 2). Thus immunocompetent (medullary) thymocytes, like peripheral T cells, express either Lyt-2 (cytotoxic phenotype) or L3T4 (helper phenotype) but not both, whereas non-functional (cortical) thymocytes express both markers. In addition, a small subpopulation comprising 2-3% of cells in the thymus and expressing neither Lyt-2 nor L3T4 has recently been described. The latter cells have the properties of intrathymic 'stem cells' in that they are the first to appear in the embryonic thymus and at least some can be shown to give rise, both in vivo (ref. 4. and our unpublished data) and in vitro, to other thymocyte subpopulations. We show here that 50% of Lyt-2-/L3T4- cells in the adult thymus express receptors for the polypeptide growth hormone interleukin-2 (IL-2) whereas other cells in the thymus do not. Furthermore, immunohistochemical localization studies on frozen sections indicate a disperse distribution of IL-2 receptor-positive cells in both the cortex and medulla. These novel findings have potential implications in the context of current models of differentiation pathways within the thymus.     

Clonal deletion of immature CD4+8+ thymocytes in suspension culture by extrathymic antigen-presenting cells

One mechanism ensuring self tolerance of T cells is the clonal deletion of thymocytes bearing alpha beta T-cell receptors. The stage of thymocyte development at which the interaction with antigen-presenting cells (APCs) leads to deletion, however, has not been determined directly. Indirect evidence suggests that intrathymic APCs induce deletion of CD4+8+ thymocytes (which die by apoptosis) but deletion at less and more mature developmental stages has also been implied. It is also not clear if clonal elimination of thymocytes can be triggered by peripheral antigens carried on extrathymic APCs migrating through the thymus. Here we show antigen-specific induction of apoptosis in CD4+8+ thymocytes cultured in suspension, by thymic as well as splenic APCs. Thus the recognition of antigen by CD4+8+ thymocytes may lead to deletion, suggesting that this is the central mechanism of tolerance induction, which is not limited by the antigen-presenting ability of the thymic stroma.     

T-cell specificity for H-2 and Ir gene phenotype correlates with the phenotype of thymic antigen-presenting cells

Experiments with chimaeric animals have demonstrated that the H-2 restriction specificity and immune response (Ir) gene phenotype of the T cell is acquired during development in the thymus. The mechanism by which this process occurs is unclear. One level of obligate expression of H-2 and Ir gene products is on the surface of antigen-presenting cells (APCs) which come from bone marrow precursors. We have now examined the turnover of APCs in the thymuses of F1 leads to parent (P) radiation-induced bone marrow chimaeras and found that APCs of donor phenotype appear at about 2 months after reconstitution. If the peripheral T-cell population is depleted after this time, new T cells emerging from the parental thymus (containing F1 APCs) behaving like F1 T cells, suggesting that cells from the bone marrow can influence thymic-directed T-cell differentiation. The thymic APC is an attractive condidate to play such a part in the development of the T-cell repertoire.     

Expression of genes of the T-cell antigen receptor complex in precursor thymocytes

The antigen receptor on T lymphocytes has recently been characterized as a heterodimeric, transmembrane glycoprotein consisting of disulphide-linked alpha (acidic) and beta (basic) subunits of relative molecular mass (Mr) 40,000-45,000 each. The genes encoding these proteins have been cloned and shown to resemble immunoglobulin genes in both overall structure and the requirement for DNA rearrangement before expression. In humans, three additional proteins, termed the T3 complex, are found associated with the clonotypic receptor, and a role for T3 in receptor expression has been proposed. Despite these recent advances in characterizing the antigen receptor complex, there is as yet little understanding of T-cell maturation, particularly the stage of T-cell ontogeny at which the genes encoding the antigen receptor and its associated structures are expressed and assembled. In the adult, stem cells destined to differentiate into T cells arise in the bone marrow and migrate to the thymus, where T-cell precursors proliferate, develop a preference for recognizing antigens in the context of self MHC molecules and are released to the periphery. Recently, cells that have the properties of immature murine thymocytes have been isolated and described. We have now analysed these cells with a series of molecular probes and we describe three distinct patterns of T-cell antigen receptor gene rearrangements in developing thymocytes.     

Homing receptor-bearing thymocytes, an immunocompetent cortical subpopulation

Much of the differentiation of murine T cells takes place in the thymus, perhaps influenced by the operation of stringent selection mechanisms whose existence has been inferred from the high rate of thymocyte turnover in the absence of extensive emigration. The origin of those 1% of total thymocytes which leave the thymus and seed the peripheral lymphoid organs is obscure. Recent thymic emigrants are functionally and phenotypically mature, and the purported greater maturity of medullary relative to cortical thymocytes is often cited a evidence for the medullary origin of thymic emigrants, a suggestion not without its critics. To approach this question, we have now isolated a a subpopulation of thymocytes expressing high levels of a receptor that mediates the homing of blood-borne lymphocytes into peripheral lymph nodes. Surprisingly, this population of cells (1-3% of total thymocytes) is both cortical and immunocompetent, containing approximately half of all thymic cytolytic T-lymphocyte precursors. The combination of homing receptor expression and immunocompetence makes this cortical population ideally suited for emigration to peripheral lymphoid organs.     

胸腺内双阴胸腺细胞重建动态的数学模型

根据小鼠的胸腺细胞实验数据,建立了描述胸腺细胞（ｔｈｙｍｏｃｙｔｅ）发育过程的数学模型,该模型考虑了胸腺细胞与胸腺基质细胞（ｔｈｙｍｉｃ ｓｔｒｏｍａｌ ｃｅｌｌ,ＴＳＣ）之间的相互作用,能够模拟ＣＤ４－ＣＤ８－ＤＮ细胞重建动态及正常小鼠胸腺细胞的发育过程,研究表明,模型中的一些参数应该是含有时间延迟的,通过模型研究了胸腺细胞与ＴＳＣ之间亲和力在胸腺选择过程中的阳性与阴性选择中的差异,理论预言与实     

Does T-cell tolerance require a dedicated antigen-presenting cell?

Almost 30 years ago Burnet proposed that the immune system maintained self-tolerance by deleting autoreactive lymphocytes. Recently it has become clear that for T cells this step occurs in the thymus, where developing T cells first express their antigen-specific receptors. Here a T-cell which encounters its antigen disappears--if it is not dead, it at least stops expressing its receptors. In the periphery by contrast, encounter with antigen leads to activation and proliferation of the responding T-cell. There are two possible explanations for this difference. Either the antigen-presenting cells in the thymus are different from those in the periphery and instead of producing positive signals they directly or indirectly kill the thymocytes; or the T cells themselves are different, and like immature B cells, may die after encounter with antigen. We tested the first possibility and found that dendritic cells from spleen, which are the most potent activators of mature T cells, are also the most potent inactivators of young developing T cells. Thus it is not the antigen-presenting cell which determines whether a T-cell responds or dies, but the T-cell itself or its thymic environment.     

Isolation of cell lines possessing functional and serological properties resembling those of thymocyte precursors

Thymocytes develop from a committed haematopoietic progenitor, referred to as a prothymocyte. They are uniquely capable of migrating to and restoring the thymus of a lethally irradiated host, a property which has been exploited as a specific assay for these cells. Like other committed haematopoietic progenitors, prothymocytes are found only in small numbers in even the richest sources (0.05-1.0% of the nucleated cells in bone marrow). Purification has proved difficult both in terms of finding a suitable starting material and in the degree of enrichment achieved. We now report the isolation of cloned lines of cells with some of the serological and functional properties of prothymocytes. One of these lines has been in continuous culture for almost 2 years. When injected into irradiated recipients, cells from this line migrate to the thymus and there develop into cells which resemble normal cortical thymocytes.     

造血重建小鼠骨髓中成纤维细胞的起源

选择Y染色体特异的性别决定基因(Sry)作为新的细胞遗传标志,采用PCR技术对小鼠骨髓细胞重建造血的性能和造血重建小鼠骨髓中成纤维细胞的起源进行研究.将正常雄鼠骨髓细胞输注给经致死剂量射线照射的受体雌性小鼠,PCR技术检测结果表明,在活存小鼠的骨髓、脾脏、胸腺和淋巴结中均具有供体起源的细胞.而正常雄鼠或5-氟尿嘧啶处理的雄鼠骨髓细胞输注给受体雌性小鼠后,造血重建小鼠骨髓中的成纤维细胞则为受体起源.由此可见,小鼠骨髓中的成纤维细胞与造血细胞具有不同的起源.     

Differential expression of two distinct T-cell receptors during thymocyte development

The product of the T-cell receptor (TCR) gamma-gene has recently been found to be expressed on a subset of both peripheral cells and thymocytes. As an initial approach to understanding the role of this gamma-chain of TCR (TCR gamma) in T-cell development, we have studied the ontogeny of TCR expression at the protein level in the developing murine thymus. We show here that the first T3-associated TCR to be expressed in the developing thymus is a disulphide-linked heterodimer composed of a gamma-chain of relative molecular mass 35,000 (Mr 35K) and a 45K partner (termed TCR delta). This TCR gamma delta is first detected approximately two days before the appearance of cell-surface TCR alpha beta heterodimers. We report that N-glycosidase digestions reveal that all of the gamma-protein expressed on fetal thymocytes, as in adult CD4-8-(L3T4-, Lyt2-) thymocytes, bear N-linked carbohydrate side chains. The major gamma-gene transcribed in mature, alpha beta-bearing T cells (V gamma 1.2C gamma 2)encodes no N-linked glycosylation site so these results suggest that the fetal gamma delta receptor defines a distinct T-cell lineage whose development in the thymus precedes classical alpha beta-bearing cells.