The thymus gland: a target organ for growth hormone

Increasing evidence has placed hormones and neuropeptides among potent immunomodulators, in both health and disease. Herein, we focus on the effects of growth hormone (GH) upon the thymus. Exogenous GH enhances thymic microenvironmental cell-derived secretory products such as cytokines and thymic hormones. Moreover, GH increases thymic epithelial cell (TEC) proliferation in vitro, and exhibits a synergistic effect with anti-CD3 in stimulating thymocyte proliferation, which is in keeping with the data showing that transgenic mice overexpressing GH or GH-releasing hormone exhibit overgrowth of the thymus. GH also influences thymocyte traffic: it increases human T-cell progenitor engraftment into the thymus; augments TEC/thymocyte adhesion and the traffic of thymocytes in the lymphoepithelial complexes, the thymic nurse cells; modulates in vivo the homing of recent thymic emigrants, enhancing the numbers of fluroscein isothiocyanate (FITC)+ cells in the lymph nodes and diminishing them in the spleen. In keeping with the effects of GH upon thymic cells is the detection of GH receptors in both TEC and thymocytes. Additionally, data indicate that insulin-like growth factor (IGF)-1 is involved in several effects of GH in the thymus, including the modulation of thymulin secretion, TEC proliferation as well as thymocyte/TEC adhesion. This is in keeping with the demonstration of IGF-1 production and expression of IGF-1 by TEC and thymocytes. Also, it should be envisioned as an intrathymic circuitry, involving not only IGF-1, but also GH itself, as intrathymic GH expression is seen both in TEC and in thymocytes, and that thymocyte-derived GH could enhance thymocyte proliferation. Finally, the possibility that GH improve thymic functions, including thymocyte proliferation and migration, places this molecule as a potential therapeutic adjuvant in immunodeficiency conditions associated with thymocyte decrease and loss of peripheral T cells.     

Autonomous and extrinsic regulation of thymopoiesis in human immune system (HIS) mice

Human Immune System (HIS) mice represent a novel biotechnology platform to dissect human haematopoiesis and immune responses. However, the limited human T‐cell development that is observed in HIS mice restricts its utility for these applications. Here, we address whether reduced thymopoiesis in HIS mice reflects an autonomous defect in T‐cell precursors and/or a defect in the murine thymic niche. Human thymocyte precursors seed the mouse thymus and their reciprocal interactions with murine thymic epithelial cells (TECs) led to both T‐cell and TEC maturation. The human thymocyte subsets observed in HIS mice demonstrated survival, proliferative and phenotypic characteristics of their normal human counterparts, suggesting that the intrinsic developmental program of human thymocytes unfolds normally in this xenograft setting. We observed that exogenous administration of human IL‐15/IL‐15Rα agonistic complexes induced the survival, proliferation and absolute numbers of immature human thymocyte subsets, without any obvious effect on cell‐surface phenotype or TCR Vβ usage amongst the newly selected mature single‐positive (SP) thymocytes. Finally, when IL‐15 was administered early after stem cell transplantation, we noted accelerated thymopoiesis resulting in the more rapid appearance of peripheral naïve T cells. Our results highlight the functional capacity of murine thymic stroma cells in promoting human thymopoiesis in HIS mice but suggest that the “cross‐talk” between murine thymic stroma and human haematopoietic precursors may be suboptimal. As IL‐15 immunotherapy promotes early thymopoiesis, this novel approach could be used to reduce the period of T‐cell immunodeficiency in the post‐transplant clinical setting.     

Ongoing Dll4-Notch signaling is required for T-cell homeostasis in the adult thymus

The essential role of the Delta-like ligand 4 (Dll4)-Notch signaling pathway in T-lymphocyte development is well established. It has been shown that specific inactivation of Dll4 on thymic stromal cells during early post-natal development leads to a deregulation in T-cell differentiation. However, whether ongoing Dll4-Notch signaling is required for T-cell development in the adult thymus is unknown. The use of anti-Dll4 Abs allowed us to confirm and expand previous studies by examining the kinetics and the reversibility of Dll4-Notch signaling blockade in T-cell development in adult mice. We found that anti-Dll4 treatment reduced thymic cellularity after 7 days, as a consequence of a developmental delay in T-cell maturation at the pro-T-cell double negative 1 (CD4(-) CD8(-) c-kit(+) CD44(+) CD25(-) ) stage, leading to decreased numbers of immature double-positive (CD4(+) CD8(+) ) T cells without affecting the frequency of mature single positive CD4(+) and CD8(+) thymocytes, while promoting alternative thymic B-cell expansion. This cellular phenotype was similarly observed in both young adult and aged mice (>1.5 years), extending our understanding of the ongoing role for Dll4-Notch signaling during T-cell development in the adult thymus. Finally, after cessation of Dll4 Ab treatment, thymic cellularity and thymocyte subset ratios returned to normal levels, indicating reversibility of this phenotype in both adult and aged mice, which has important implications for potential clinical use of Dll4-Notch inhibitors.     

Polycomb group gene Bmi1 plays a role in the growth of thymic epithelial cells

Polycomb group gene Bmi1 plays an essential role in HSCs and the BM microenvironment. Recent reports also pointed to the importance of Bmi1 in thymocyte development. However, little is known about its role in the development of the thymic microenvironment. Here, we examined the function of Bmi1 in thymic epithelial cells (TECs) by using the engraftment of fetal thymus (FT) lobes under the kidney capsule. The engrafted Bmi1(-/-) FT lobes were clearly smaller and the number of thymocytes in these lobes was significantly decreased compared with control FT lobes. Analysis of the cell cycle status of TECs in the reconstituted lobes revealed that the reduction of thymus size in Bmi1(-/-) FT grafts was caused by less proliferation of TECs during the early expansion stage. Unlike cases with hematopoietic stem cells or thymocytes, the deletion of p16Ink4a and p19Arf could not restore the defects in Bmi1(-/-) TEC, indicating a distinct role for Bmi1 in TECs. In conclusion, epigenetic regulator polycomb group gene Bmi1 plays a role in the thymic microenvironment in a regeneration process by supporting TEC growth, and thereby contributes to the control of thymus size for T-cell growth in mice.     

CCRL1/ACKR4 is expressed in key thymic microenvironments but is dispensable for T lymphopoiesis at steady state in adult mice

Thymus colonisation and thymocyte positioning are regulated by interactions between CCR7 and CCR9, and their respective ligands, CCL19/CCL21 and CCL25. The ligands of CCR7 and CCR9 also interact with the atypical receptor CCRL1 (also known as ACKR4), which is expressed in the thymus and has recently been reported to play an important role in normal αβT‐cell development. Here, we show that CCRL1 is expressed within the thymic cortex, predominantly by MHC‐II^lowCD40^? cortical thymic epithelial cells and at the subcapsular zone by a population of podoplanin⁺ thymic epithelial cells in mice. Interestingly, CCRL1 is also expressed by stromal cells which surround the pericytes of vessels at the corticomedullary junction, the site for progenitor cell entry and mature thymocyte egress from the thymus. We show that CCRL1 suppresses thymocyte progenitor entry into the thymus, however, the thymus size and cellularity are the same in adult WT and CCRL1^?/? mice. Moreover, CCRL1^?/? mice have no major perturbations in T‐cell populations at different stages of thymic differentiation and development, and have a similar rate of thymocyte migration into the blood. Collectively, our findings argue against a major role for CCRL1 in normal thymus development and function.     

Nitric oxide regulates clonal expansion and activation-induced cell death triggered by staphylococcal enterotoxin B.

Increased interest has recently been focused on nitric oxide (NO) due to its several biological roles. Apart from being a potential antimicrobial defense and a mediator of autoimmune diseases, NO also appears to be a strong mediator of T-cell responses. In this report, we have characterized the effect of NO on T-cell function. For this purpose, we analyzed in vivo T-cell responses to the bacterial superantigen produced by Staphylococcus aureus, staphylococcal enterotoxin B (SEB), in mice treated with an NO donor (isosorbide dinitrate [ISO]). We show that ISO partially prevents SEB-triggered activation-induced cell death of spleen and lymph node CD4Vbeta8+ T cells but not of CD8Vbeta8+ T cells. SEB-promoted thymic deletion is not abolished by ISO; however, a rapid recovery of thymocyte numbers due to increased double-positive (DP) CD4+ CD8+ thymocyte proliferation was clearly observed in ISO-treated, SEB-injected mice but not in controls (untreated SEB-injected mice). It was also found that ISO inhibits the early SEB-induced cell proliferation (i.e., that found 12 h after SEB injection), accelerating the clonal anergy usually observed 3 days after SEB injection. Inhibition of T-cell proliferation by the NO donor does not appear to be due to inhibition of cytokine production. These results show that NO interferes with apoptosis and facilitates thymic proliferation of DP thymocytes, although it inhibits peripheral T-cell proliferation.     

Indirect presentation in the thymus limits naive and regulatory T‐cell differentiation by promoting deletion of self‐reactive thymocytes

Acquisition of T‐cell central tolerance involves distinct pathways of self‐antigen presentation to thymocytes. One pathway termed indirect presentation requires a self‐antigen transfer step from thymic epithelial cells (TECs) to bone marrow‐derived cells before the self‐antigen is presented to thymocytes. The role of indirect presentation in central tolerance is context‐dependent, potentially due to variation in self‐antigen expression, processing and presentation in the thymus. Here, we report experiments in mice in which TECs expressed a membrane‐bound transgenic self‐antigen, hen egg lysozyme (HEL), from either the insulin (insHEL) or thyroglobulin (thyroHEL) promoter. Intrathymic HEL expression was less abundant and more confined to the medulla in insHEL mice compared with thyroHEL mice. When indirect presentation was impaired by generating mice lacking MHC class II expression in bone marrow‐derived antigen‐presenting cells, insHEL‐mediated thymocyte deletion was abolished, whereas thyroHEL‐mediated deletion occurred at a later stage of thymocyte development and Foxp3⁺ regulatory T‐cell differentiation increased. Indirect presentation increased the strength of T‐cell receptor signalling that both self‐antigens induced in thymocytes, as assessed by Helios expression. Hence, indirect presentation limits the differentiation of naive and regulatory T cells by promoting deletion of self‐reactive thymocytes.     

T-cell receptor affinity in thymic development

Understanding the thymic processes that support the generation of functionally competent and self-tolerant lymphocytes requires dissection of the T-cell receptor (TCR) response to ligands of different affinities. In spatially segregated regions of the thymus, with unique expression of proteases and cytokines, TCR affinity guides a number of cell fate decisions. Yet affinity alone does not explain the selection paradox. Increasing evidence suggests that the 'altered peptide' model of the 1980s together with the affinity model might best explain how the thymus supports conventional and regulatory T-cell development. Development of new tools to study the strength of TCR signals perceived by T cells, novel regulatory T-cell transgenic mice, and tetramer enrichment strategies have provided an insight into the nature of TCR signals perceived during thymocyte development. These topics are discussed and support for the prevailing hypotheses is presented.     

Peptide antagonists that promote positive selection are inefficient at T cell activation and thymocyte deletion

We set out to determine whether thymocytes from T cell receptor (TCR) transgenic animals specific for a class I-restricted determinant from ovalbumin (OVA) showed the same fine specificity for antigen-driven deletion in single-cell suspension culture as required for mature T cell activation. The transgenic TCR is specific for the K^b-restricted peptide OVA_257-264 (SIINFEKL) which is known to have four TCR contact residues at position 1, 4, 6, and 7 from the crystal structure of this fragment in complex with K^b. OVA_257-264 analogs systematically substituted at each of these positions were assayed for their ability to promote immature double-positive thymocyte deletion or mature T cell activation of a cytotoxic T lymphocyte line derived from this transgenic mouse. In the absence of additional antigen-presenting cells, single-cell thymocyte suspensions showed that the specificity for double-positive thymocyte deletion and mature T cell activation was virtually identical, demonstrating a limited cross-reactivity with a number of variants having conservative substitutions at these exposed residues. These peptides were considerably more efficient at both thymic deletion and mature T cell activation than a number of non-conservative substitution analogs known to act as antagonists of OVA_257-264 and capable of selecting transgenic T cells in thymic organ culture. Therefore, both peripheral T cell activation and thymic deletion have an overall similar pattern of peptide specificity which differs from that required for positive selection. This suggests that a subset of major histocompatibility complex-presented peptides could promote positive selection without causing either thymic deletion or peripheral activation of those selected T cells.     

T-cell homeostasis in mice exposed to airborne xenobiotics

Many effects of environmental toxic agents contribute to the deregulation of immune system homeostasis. Here we demonstrate that the effect of airborne suspended matter (ASM) on the generation of mouse T cells is reversible. This reversal can be achieved by an active process that returns the T cells to homeostasis and does not result from the simple effect of ASM deprivation. An accelerated development of thymocytes and increased influx of T-cell progenitors to the thymus in mice exposed to environmental xenobiotics has been postulated. This hypothesis has been confirmed by parallel increases in the percentages of single-positive and triple-negative thymocytes. Enhanced expression of thymocyte surface markers related to positive selection has also been observed. The pathway of T-cell progenitor development is favoured in the bone marrow of mice exposed to ASM.     

T Cell Development in CD3-ζ Mutant Mice

Increasing evidence points to multiple pathways of T lymphocyte development. The well characterized thymus-dependent pathway gives rise to T cells bearing TCRαβ heterodimers and either CD4 or CD8αβ co-receptors. T cells of this lineage populate peripheral lymphoid compartments including lymph nodes, spleen, skin, and Peyer's patches. By comparison, factors which govern extrathymic T cell development are poorly understood. A variety of experiments have shown that intestinal intraepithelial lymphocytes (IELs) develop outside of the thymic environment, e.g., in the gut of nude, SCID, and β2m-/- mutant mice, and after transplanting bone marrow or fetal liver cells into irradiated thymectomized adult mice. This review focuses on the role of the CD3-ζ subunit in the development of both thymically and extrathymically derived T cells as determined by gene-targeting experiments in mice. Data from these and other T cell-related mutations continue to define crucial stages in thymocyte differentiation. Most interestingly, CD3-ζ mutant mice contain a unique population of intestinal IELs that develops independently of thymic selective processes and expresses a novel TCR/CD3 complex.     

Optimization of culture and storage conditions for an in vitro system to evaluate thymocyte phenotype and function

Studies on thymopoiesis are critical to the understanding of T-cell homeostasis as well as the host response to T-cell depletion. Various in vitro culture systems have been used in the study of thymocyte development; however it is unclear if current co-culture methods have been fully optimized. In this study in vitro suspension cultures have been re-evaluated and the optimal storage conditions for thymocytes have been established by evaluating various methods of storing/isolating thymic tissue and isolated thymocytes as well as the source of thymic epithelial cells (TEC). It was determined that thymocytes must be freshly isolated from whole thymic tissue and ideally stored at 4 degrees C prior to co-culture. Co-culture with either autologous or allogeneic TEC results in similar thymocyte subset distribution as well as interleukin-7 receptor-alpha (CD127) expression on these subsets. To evaluate the influence of the source of TEC on one aspect of thymocyte function the effect of IL-7 stimulation on the expression of CD127 was evaluated. IL-7 stimulation resulted in a downregulation of the expression of CD127 on all thymic subsets similar to that observed in circulating CD8+ T-cells. The effect of this was the same whether TEC were autologous or allogeneic. Optimizing culture techniques and facilitating the study of individual thymocyte subsets will lead to a better understanding of thymic function and development. It could also lead to therapeutic approaches that enhance immune recovery after T-cell depletion in HIV infection, bone marrow transplantation or following chemotherapy.     

Abp1在调节性T细胞的发育及功能中的作用

目的 探讨肌动蛋白连接蛋白1(actin-binding protein 1,Abp1)对调节性T细胞(Treg)发育及功能的影响.方法 通过流式细胞术检测野生型小鼠(WT组)和Abp1基因敲除小鼠(KO组)的胸腺、脾脏、浅表淋巴结及肠系膜淋巴结中T淋巴细胞及Treg细胞的比例、数量以及相关功能性分子的表达,并利用体外...     

The aged thymus shows normal recruitment of lymphohematopoietic progenitors but has defects in thymic epithelial cells

Aging is associated with reduced numbers of all thymocyte sub-populations, including early T-cell progenitors. However, it is unclear if this is due to inadequate recruitment of lymphohematopoietic progenitor cells (LPCs) to the aged thymus or to abnormal development of T cells within the thymus. We found that LPCs from young mice were recruited equally well to the thymi of young or aged mice and that thymic stromal cells (TSCs) from young and old mice expressed similar levels of P-selectin and CCL25, which are believed to mediate recruitment of LPCs to the adult thymus. However, the number of recruited thymocytes in old thymus was markedly reduced after two weeks, indicating that T-cell development or proliferation is defective in the aged thymus. We also found that LPCs from aged and young mice have similar capacities to seed a fetal thymus that was transplanted under the kidney capsule. Thymic epithelial cells (TECs) in aged mice had lower proliferative capacity and higher rate of apoptosis, compared with findings in young animals. In addition, immunofluorescence staining with antibodies to cortical and medullary TECs revealed that aged thymi had a disorganized thymic stromal architecture, combined with reduced cellularity of the medulla, and apoptosis of thymocyte sub-populations in the medullary microenvironment was increased, compared with that in young mice. We conclude that aging does not impair recruitment of LPCs to the thymus, but is characterized by abnormalities in thymic epithelial architecture, especially medullary TEC function that may provide sub-optimal support for thymic development of LPCs.     

EphrinB1-EphB signaling regulates thymocyte-epithelium interactions involved in functional T cell development

The Eph and ephrin families are involved in numerous developmental processes. Recently, an increasing body of evidence has related these families with some aspects of T cell development. In the present study, we show that the addition of either EphB2-Fc or ephrinB1-Fc fusion proteins to fetal thymus organ cultures established from 17-day-old fetal mice decreases the numbers of both double-positive (CD4(+)CD8(+)) and single-positive (both CD4(+)CD8(-) and CD4(-)CD8(+)) thymocytes, in correlation with increased apoptosis. By using reaggregate thymus organ cultures formed by fetal thymic epithelial cells (TEC) and CD4(+)CD8(+) thymocytes, we have also demonstrated that ephrinB1-Fc proteins are able to disorganize the three-dimensional epithelial network that in vivo supports the T cell maturation, and to alter the thymocyte interactions. In addition, in an in vitro model, Eph/ephrinB-Fc treatment also decreases the formation of cell conjugates by CD4(+)CD8(+) thymocytes and TEC as well as the TCR-dependent signaling between both cell types. Finally, immobilized EphB2-Fc and ephrinB1-Fc modulate the anti-CD3 antibody-induced apoptosis of CD4(+)CD8(+) thymocytes in a process dependent on concentration. These results therefore support a role for Eph/ephrinB in the processes of development and selection of thymocytes as well as in the establishment of the three-dimensional organization of TEC.     

Thymic heterotypic cellular complexes in gene-targeted mice with defined blocks in T cell development and adhesion molecule expression

Thymocytes form unique multicellular complexes with epithelial cells (thymic nurse cells, TNC) and rosettes (ROS) with macrophages, epithelial cells and dendritic cells. To investigate the role of differentiation checkpoints in the formation of the thymic heterotypic complexes in vivo, we used mutant mice which have genetically defined blocks at early and late stages of T cell development. We show that RAG-1^−/−, TCRβ^−/−, and p56^lck−/− mice lack thymocyte ROS formation with epithelial cells, macrophages, or dendritic cells. TNC formation was not affected by TCRβ and p56^lck gene mutations but partially decreased in RAG-1^−/− mice, indicating that TNC are the earliest thymocyte-stromal cell complexes formed in development, whereas ROS only appear after thymocytes have rearranged and expressed a functional TCRβ chain. Genetic blocks in CD8 lineage commitment (CD8^−/− and IFN regulatory factor-1^−/− mice) and positive and negative T cell selection (CD45^−/−, TCRα^−/−, and CD30^−/− mice) did not affect thymocyte-stromal cell complexes. Surprisingly, CD4^−/− mice, but not MHC class II^−/− mice, had significantly reduced numbers of TNC and ROS, in particular, a severe defect in ROS formation with thymic dendritic cells. The CD4^−/− block in ROS and TNC formation was rescued by the introduction of a human CD4 transgene. Moreover, we show that the adhesion receptors CD44 and LFA-1 cooperate in the formation of the thymic microenvironment. These results provide genetic evidence on the role of defined stages in T cell development and adhesion molecules on thymocyte/stromal cell interactions in vitro.     

The Wnt signaling antagonist Kremen1 is required for development of thymic architecture

Wnt signaling has been reported to regulate thymocyte proliferation and selection at several stages during T cell ontogeny, as well as the expression of FoxN1 in thymic epithelial cells (TECs). Kremen1 (Krm1) is a negative regulator of the canonical Wnt signaling pathway, and functions together with the secreted Wnt inhibitor Dickkopf (Dkk) by competing for the lipoprotein receptor-related protein (LRP)-6 co-receptor for Wnts. Here krm1 knockout mice were used to examine krm1 expression in the thymus and its function in thymocyte and TEC development. Krm1 expression was detected in both cortical and medullary TEC subsets, as well as in immature thymocyte subsets, beginning at the CD25+CD44+ (DN2) stage and continuing until the CD4+CD8+(DP) stage. Neonatal mice show elevated expression of krm1 in all TEC subsets. krm1(-/-) mice exhibit a severe defect in thymic cortical architecture, including large epithelial free regions. Much of the epithelial component remains at an immature Keratin 5+ (K5) Keratin 8(+)(K8) stage, with a loss of defined cortical and medullary regions. A TOPFlash assay revealed a 2-fold increase in canonical Wnt signaling in TEC lines derived from krm1(-/-) mice, when compared with krm1(+/+) derived TEC lines. Fluorescence activated cell sorting (FACS) analysis of dissociated thymus revealed a reduced frequency of both cortical (BP1(+)EpCAM(+)) and medullary (UEA-1(+) EpCAM(hi)) epithelial subsets, within the krm1(-/-) thymus. Surprisingly, no change in thymus size, total thymocyte number or the frequency of thymocyte subsets was detected in krm1(-/-) mice. However, our data suggest that a loss of Krm1 leads to a severe defect in thymic architecture. Taken together, this study revealed a new role for Krm1 in proper development of thymic epithelium.     

The effect of rapamycin on T cell development in mice

Rapamycin (RAPA) is a strong immunosuppressant with a chemical structure similar to that of FK506, although it acts by a mechanism different from both FK506 and cyclosporin A. The effect of RAPA on T cell development in mice was investigated in this study. RAPA caused significant thymic atrophy. The major histological change in the RAPA-treated thymus was thinning of the cortex. No other apparent damage in the cortex or medulla was observed. Consistent with these histological findings, in vivo thymocyte cycling was blocked by RAPA before the S phase, and the ex vivo and in vitro proliferation of the thymocytes was also strongly repressed by the drug. According to electron microscopy and DNA fragmentation assays, RAPA did not induce apoptosis. These results indicate that the repressed thymocyte proliferation is a major mechanism causing RAPA-induced thymic atrophy. Further, RAPA had no effect on thymocyte apoptosis induced by anti-CD3 or ionomycin, and the drug did not interfere with deletion of CD4⁺8⁺ thymocytes or peripheral Vβ6⁺ T cells induced by anti-CD3 or Mls-1^a, respectively. These data suggest that RAPA does not hamper the negative selection. There was a relative increase in the CD3^? fraction of the de novo developing CD4 and CD8 double-positive (DP) thymocytes in the RAPA-treated mice. Moreover, there were relative increases of the CD3^? fractions of the CD4 or CD8 single-positive (SP) cells in both the thymi and periphery. The generation of the CD3^? SP under the influence of RAPA could be used as a useful model for further study of the function and signal transduction of these CD3-defective SP cells.