Human thymic epithelial cells inhibit IL-15- and IL-2-driven differentiation of NK cells from the early human thymic progenitors

T/NK progenitors are present in the thymus; however, the thymus predominantly promotes T cell development. In this study, we demonstrated that human thymic epithelial cells (TEC) inhibit NK cell development. Most ex vivo human thymocytes express CD1a, indicating that thymic progenitors are predominantly committed to the T cell lineage. In contrast, the CD1a(-)CD3(-)CD56(+) NK population comprises only 0.2% (n = 7) of thymocytes. However, we observed increases in the percentage (20- to 25-fold) and absolute number (13- to 71-fold) of NK cells when thymocytes were cultured with mixtures of either IL-2, IL-7, and stem cell factor or IL-15, IL-7, and stem cell factor. TEC, when present in the cultures, inhibited the increases in the percentage (3- to 10-fold) and absolute number (3- to 25-fold) of NK cells. Furthermore, we show that TEC-derived soluble factors inhibit generation of NK-CFU and inhibit IL15- or IL2-driven NK cell differentiation from thymic CD34(+) triple-negative thymocytes. The inhibitory activity was found to be associated with a 8,000- to 30,000 Da fraction. Thus, our data demonstrate that TEC inhibit NK cell development from T/NK CD34(+) triple negative progenitors via soluble factor(s), suggesting that the human thymic microenvironment not only actively promotes T cell maturation but also controls the development of non-T lineage cells such as the NK lineage.     

Thymocyte LFA-1 and thymic epithelial cell ICAM-1 molecules mediate binding of activated human thymocytes to thymic epithelial cells.

We have investigated the binding in vitro of activated thymocytes to thymic epithelial (TE) cells, and studied the effect of up-regulation of TE cell surface intracellular adhesion molecule 1 (ICAM-1) and HLA-DR by IFN-gamma on the ability of TE cells to bind to both resting and activated human thymocytes. TE cell binding to activated and resting thymocytes was studied by using our previously described suspension assay of TE-thymocyte conjugate formation. We found that activated mature and immature thymocytes bound maximally at 37 degrees C to IFN-gamma-treated ICAM-1+ and HLA-DR+ TE cells and this TE-activated thymocyte binding was inhibited by antibodies to LFA-1 alpha-chain (CD11a) (68.1 +/- 5.6% inhibition, p less than 0.01) and ICAM-1 (73.9 +/- 7.7% inhibition, p less than 0.05). Neither anti-HLA-DR antibody L243 nor anti-MHC class I antibody 3F10 inhibited IFN-gamma-treated TE binding to activated thymocytes. As with antibodies to LFA-3 and CD2, antibodies to LFA-1 and ICAM-1 also inhibited PHA-induced mature thymocyte activation when accessory signals were provided by TE cells in vitro. Finally, LFA-1 and ICAM-1 were expressed early on in human thymic fetal ontogeny in patterns similar to those seen in postnatal thymus. Taken together, these data suggest that resting mature and immature thymocytes bind to TE cells via the CD2/LFA-3 ligand pair, whereas activated thymocytes bind via both CD2/LFA-3 and LFA-1/ICAM-1 ligand systems. We postulate that IFN-gamma produced intrathymically may regulate TE expression of ICAM-1 and therefore potentially may regulate TE cell binding to activated thymocytes beginning in the earliest stages of human thymic development.     

The role of LFA-1/ICAM-1 interactions during murine T lymphocyte development.

We have examined the expression and function of the cell adhesion molecules LFA-1 (CD11a/CD18), ICAM-1 (CD54), and ICAM-2 in murine fetal thymic ontogeny and in the adult thymus. On fetal days 14 and 15, 40 to 50% of thymocytes coexpress high levels of LFA-1 and ICAM-1, as determined by flow cytometry. By day 16, more than 90% of fetal thymocytes are LFA-1+ ICAM-1hi, and all IL-2R+ cells are located in this population. Although LFA-1 expression remains unchanged thereafter, ICAM-1 expression appears to be differentially regulated in different thymocyte subpopulations, with CD4+8+ cells being ICAM-1lo and CD4-8- thymocytes remaining ICAM-1hi. ICAM-2 surface expression is dull on both fetal and adult thymocytes. Surprisingly, the expression of ICAM-1 is differentially up-regulated on T cells having a mature phenotype in thymus and in peripheral lymphoid organs, with CD8+ T cells bearing the highest amount of surface ICAM-1. Addition of anti-ICAM-1 or anti-LFA-1 antibodies to fetal thymic organ cultures results in the impaired generation of CD4+8+ cells. These results indicate that LFA-1/ICAM-1 interactions facilitate murine thymic development and suggest that cell adhesion molecules mediate important events in T cell differentiation.     

IL-1, IL-4, and IFN-gamma differentially regulate cytokine production and cell surface molecule expression in cultured human thymic epithelial cells.

We investigated the response of purified and cloned human thymic epithelial cells (TEC) to IL-1, IL-4, and IFN-gamma stimulation in vitro. IL-1 alpha strongly up-regulated the production of granulocyte-macrophage CSF (GM-CSF), granulocyte CSF (G-CSF), IL-6, and IL-8, as measured by specific immunoenzymetric assays and by increased steady state mRNA levels. IL-4 or IFN-gamma did not induce these cytokines in TEC but in a sustained and dose-dependent manner down-regulated the IL-1-induced GM-CSF protein and mRNA levels. Only IFN-gamma, and not IL-4, suppressed the IL-1-induced G-CSF and IL-8 production, as shown at both the protein and mRNA levels. The inhibition was dose dependent, sustained for at least 96 h, and more pronounced for G-CSF than for IL-8. In contrast, both IL-4 and IFN-gamma enhanced the IL-1-induced IL-6 production. IL-4 and IFN-gamma had additive effects to increase IL-6 secretion and to more completely suppress the IL-1-induced GM-CSF. Analyses of cell surface molecules showed that intercellular adhesion molecule 1 (ICAM-1) expression on TEC was increased by IL-1 or IFN-gamma. IL-4 slightly down-regulated constitutive ICAM-1 levels but did not significantly modify the levels of expression induced by either IL-1 or IFN-gamma. MHC class II expression was induced by IFN-gamma but not by IL-1 or IL-4. The combination of IL-1 and IL-4 with IFN-gamma did not alter the levels of class II MHC Ag induced by IFN-gamma. In conclusion, TEC cytokine production and cell surface molecule expression are differentially regulated via a complex cytokine network. Our data suggest that developing T cells provide, in part, the signals controlling the function of their supporting stroma.     

Synergistic effect of IL-2, IL-12, and IL-18 on thymocyte apoptosis and Th1/Th2 cytokine expression

In the periphery, IL-18 synergistically induces the expression of the Th1 cytokine IFN-gamma in the presence of IL-12 and the Th2 cytokines IL-5 and IL-13 in the presence of IL-2. Although the expression of these cytokines has been described in the thymus, their role in thymic development and function remains uncertain. We report here that freshly isolated thymocytes from C57BL/6 and BALB/c mice stimulated in vitro with IL-2-plus-IL-18 or IL-12-plus-IL-18 produce large amounts of IFN-gamma and IL-13. Analysis of the thymic subsets, CD4(-)CD8(-) (DN), CD4(+)CD8(+), CD4(+)CD8(-), and CD4(-)CD8(+) revealed that IL-18 in combination with IL-2 or IL-12 induces IFN-gamma and IL-13 preferentially from DN cells. Moreover, DN2 and DN3 thymocytes contained more IFN-gamma(+) cells than cells in the later stage of maturation. Additionally, IL-18 in combination with IL-2 induces CCR4 (Th2-associated) and CCR5 (Th1-associated) gene expression. In contrast, IL-18-plus-IL-12 specifically induced CCR5 expression. The IL-2-plus-IL-18 or IL-12-plus-IL-18 effect on IFN-gamma and IL-13 expression is dependent on Stat4 and NF-kappaB but independent of Stat6, T-bet, or NFAT. Furthermore, IL-12-plus-IL-18 induces significant thymocyte apoptosis when expressed in vivo or in vitro, and this effect is exacerbated in the absence of IFN-gamma. IL-12-plus-IL-18-stimulated thymocytes can also induce IA-IE expression on cortical and medullary thymic epithelial cells in an IFN-gamma-dependent manner. Thus, the combination of IL-2, IL-12, and IL-18 can induce phenotypic and functional changes in thymocytes that may alter migration, differentiation, and cell death of immature T cells inside the thymus and potentially affect the Th1/Th2 bias in peripheral immune compartments.     

Expression and function of the UM4D4 antigen in human thymus

UM4D4 is a newly identified T cell surface molecule, distinct from the Ag receptor and CD2, which is expressed on 25% of peripheral blood T cells, resting or activated. Monoclonal anti-UM4D4 is mitogenic for T cells and T cell clones. Since alternative activation pathways independent of Ag/MHC recognition may be important in thymic differentiation, the expression and function of UM4D4 was examined in human thymus. UM4D4 was found on the surface of 6% of thymocytes. All thymocyte subsets contained UM4D4+ cells but expression was greatest on thymocytes that were CD1- (12%), CD3+ (11%) and especially CD4-CD8- (18%). CD3+CD4- CD8- cells, most of which bear the gamma delta-receptor, were greater than or equal to 50% + for UM4D4. Moreover, anti-UM4D4 was comitogenic for thymocytes together with PMA or IL-2. Anti-UM4D4 also reacted strongly with a subset of thymic epithelial cells in both cortex and medulla. Dual color fluorescence microscopy, with anti-UM4D4 and antibodies to other thymic epithelial Ag, showed UM4D4 expression on neuroendocrine thymic epithelium but not on thymic fibrous stroma. Thus, UM4D4 is expressed on, and represents an activation pathway for, a subset of thymic T cells. In addition, this determinant, initially identified as a novel T cell activating molecule, is broadly expressed by neuroendocrine thymic epithelium. Although the function of UM4D4 on the thymic epithelial cells is not yet clear, it is possible that UM4D4 represents a pathway for the functional activation of a subset of the thymic epithelium as well as a subset of thymocytes, thus playing a dual role in T cell differentiation.     

Ligand binding to the LFA-3 cell adhesion molecule induces IL-1 production by human thymic epithelial cells.

We have shown that human thymic epithelial (TE) cells produce IL-1 alpha, IL-1 beta, and TE cells bind to thymocytes by CD2 and LFA-1 molecules on thymocytes and LFA-3, ICAM-1 on TE cells. We investigated whether ligand binding to LFA-3 on human TE cells can modulate TE cell IL-1 production. First, we investigated the ability of human thymocytes to regulate IL-1 release by TE cells. Both autologous and allogenic emetine-treated thymocytes when cultured with TE cells augmented IL-1 release by TE cells. The augmentation of IL-1 release was cell density dependent. Inasmuch as the interaction between thymocytes and TE cells is mediated in part by CD2 molecules on thymocytes and LFA-3 molecules on TE cells we next determined the effect on IL-1 release of ligand binding (anti-LFA-3 mAb TS2/9) to TE cell surface LFA-3. Purified anti-LFA-3 mAb augmented IL-1 release in a concentration-dependent fashion. The anti-LFA-3-mediated augmentation of IL-1 release required both new protein and RNA synthesis as shown by the ability of cycloheximide and actinomycin-D to inhibit augmentation of IL-1 production by TE cells, and by direct quantitation of IL-1 alpha and IL-1 beta mRNA by Northern blot analysis. Both F(ab)'2 and Fab' fragments of anti-LFA-3 mAb augmented IL-1 alpha and IL-1 beta mRNA production, indicating that monovalent binding to cell surface LFA-3 was sufficient to provide the inducing signal. The identification of LFA-3, the cell surface ligand for thymocyte CD2 molecules, as a molecule via which TE cell-derived cytokine production may be regulated suggests a mechanism at the cell surface by which direct TE cell-thymocyte interaction might result in the triggering of local IL-1 release within the human thymic microenvironment.     

MHC non-restricted, CD95-independent apoptosis of immature thymocytes induced by thymic epithelial cells

The interaction of thymocytes with thymic epithelial cells in the absence of an exogenous antigen was studied in vitro. Thymic, but not splenic epithelial cells induced apoptosis of thymocytes. A thymic epithelial cell line (TEC) induced apoptosis of thymocytes but not of splenic T-cells. The target population for TEC-induced death were immature CD4(+)8(+) (double positive), but not mature single positive thymocytes. TEC also induced DNA fragmentation in day 18 foetal thymocytes, most of which are CD4(+)8(+) cells. Radiation leukemia virus (RadLV)-transformed thymic lymphoma clones expressing various phenotypes reflected this sensitivity, in that a CD4(+)8(+)3(+) clone apoptosed by thymic epithelial cells or TEC. Other, single positive or double negative clones were resistant. Thymocytes from C3H (H-2(k)), C57BL/6 (H-2(b)) and Balb/C (H-2(d)) mice apoptosed equally in response to either C57BL/6 thymic epithelial cells or TEC (H-2(b) x H-2(d)). Likewise, thymocytes from MRLIpr((-/-)) and B6Ipr((-/-)) mice, which do not express CD95 were also apoptosed by TEC.The data suggest that thymic epithelial cells induce MHC non-restricted, Fas-independent apoptosis of immature thymocytes. This response may reflect a mechanism through which thymocytes expressing TcR with no affinity to self MHC/peptide complexes are eliminated.     

Induction of thymocyte proliferation by supernatants from a mouse thymic epithelial cell line

The thymic stroma plays a critical role in the generation of T lymphocytes by direct cell-to-cell contacts as well as by secreting growth factors or hormones. The thymic epithelial cells, responsible for thymic hormone secretion, include morphologically and antigenically distinct subpopulations that may exert different roles in thymocyte maturation. The recent development of thymic epithelial cell lines provided an interesting model for studying thymic epithelial influences on T cell differentiation. Treating mouse thymocytes by supernatants from one of TEC line (IT-76M1), we observed an induction of thymocyte proliferation and an increase in the percentages of CD4-/CD8- thymocytes. This proliferation was largely inhibited when thymocytes were incubated with IT-76M1 supernatants together with an anti-thymulin monoclonal antibody, but could be enhanced by pretreating growing epithelial cells by triiodothyronine. We suggest that among the target cells for thymulin within the thymus, some putative precursors of early phenotype might be included.     

Murine dendritic cells derived from myeloid progenitors of the thymus are unable to produce bioactive IL-12p70

Dendritic cells (DC) are present at low density in the thymus where they mediate negative selection of self-reactive thymocytes. Previous reports suggest that thymic DC (TDC) are a single population of lymphoid-related DC. In this study, we documented the presence in the adult mouse thymus of an additional population of TDC exhibiting a myeloid phenotype (CD11c(+) CD8alpha(-) CD11b(+)). This population, which can be purified, represented approximately 20% of the total TDC and differs from the population of lymphoid TDC (CD11c(+) CD8(+) CD11b(-)) by its incapacity to produce IL-12p70 under double stimulation by LPS and anti-CD40. Furthermore, using an original culture system allowing expansion of DC from myeloid progenitors, we demonstrated that DC exhibiting a similar myeloid phenotype can be derived from a common DC/macrophage progenitor resident in the adult mouse thymus. We found that, in contrast with myeloid splenic DC expanded in the same conditions, these cultured TDC were unable to produce IL-12p70 under double stimulation by LPS and anti-CD40 or LPS and IFN-gamma. Thus, our results suggest that 1) adult mouse thymus contains at least two phenotypically and functionally distinct populations of DC; and 2) cultured myeloid DC derived from thymus and spleen differ by their ability to produce IL-12p70. The mechanisms underlying the differences in IL-12-secreting capacities of the cultured splenic and thymic DC are under current investigation.     

Differential expression and regulation of cyclooxygenase isozymes in thymic stromal cells

Prostaglandins (PGs) are lipid-derived mediators of rapid and localized cellular responses. Given the role of PG in supporting thymic T cell development, we investigated the expression of the PG synthases, also known as cyclooxygenases (COX)-1 and -2, in the biosynthesis of PGs in thymic stromal cell lines. The predominant isozyme expressed in cortical thymic epithelial cells was COX-1, while COX-2 predominated in the medulla. IFN-gamma up-regulated expression and activity of COX-2 in medullary cells, in which COX-2 was expressed constitutively. In contrast, IFN-gamma down-regulated COX-1 activity, but not expression, in cortical cells. Stromal cells support T cell development in the thymus, although the mediators of this effect are unknown. Selective inhibition of COX-2, but not COX-1, blocked the adhesion of CD4+CD8+ and CD4+CD8- thymocytes to medullary cell lines. No effect of the inhibitors was observed on the interactions of thymocytes with cortical epithelial lines. These data further support the differential regulation of COX-1 and COX-2 expression and function in thymic stromal cells. PGs produced by COX-2 in the medullary thymic stroma may regulate the development of thymocytes by modulating their interaction with stromal cells.     

Altered T cell differentiation and Notch signaling induced by the ectopic expression of keratin K10 in the epithelial cells of the thymus

Transgenic mice expressing hK10 under the keratin K5 promoter display several alterations in the epidermis including decreased cell proliferation, and reduced susceptibility to tumor development. Given that K5 promoter is also active in the epithelial cells of the thymus, we explored the possible alterations of the thymus because of K10 transgene expression. We found severe thymic alterations, which affect not only the thymic epithelial cells (TEC), but also thymocytes. We observed altered architecture and premature thymus involution in the transgenic mice associated with increased apoptosis and reduced proliferation of the thymocytes. Interestingly, prior to the development of this detrimental phenotype, thymocytes of the transgenic mice also displayed altered differentiation, which is aggravated later on. Molecular characterization of this phenotype indicated that Akt activity is reduced in TEC, but not in thymocytes. In addition, we also observed altered expression of Notch family members and some of their ligands both in TEC and T cells. This produces reduced Notch activity in TEC but increased Notch activity in thymocytes, which is detectable prior to the disruption of the thymic architecture. In addition, we also detect altered Notch expression in the epidermis of bK5hK10 transgenic mice. Collectively the present data indicate that keratin K10 may induce severe alterations not only in a cell autonomous manner, but also in neighboring cells by the modulation of signals involved in cell-cell interactions.     

A novel cofactor produced by a thymic epithelial cell line: promotion of proliferation of immature thymic lymphocytes by the presence of interleukin-1 and various mitogens

Three thymic epithelial cell lines (TEC1C5, TEC1-4, and TEC2-3) were established from the thymus of newborn C57BL/6 mice. TEC1C5 was revealed to be an interleukin (IL)-1 producing cell line. TEC1-4 produced a cofactor to promote proliferation of double negative (CD4-8-) thymic lymphocytes by the presence of IL-1. Production of the same cofactor was also seen in TEC2-3, but only when it was cultured by the presence of indomethacin. The chemical analysis of the TEC1-4 culture supernatant by ion-exchange column and sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the factor was approximately 35 kDa in molecular weight. The present study revealed that a factor produced by TEC1-4 acted as a cofactor to promote the proliferation of immature T cells stimulated by IL-1 and various mitogens and was considered to be a new one in terms of molecular weight.     

Identification of CD25+ gamma delta T cells as fetal thymus-derived naturally occurring IL-17 producers

We previously reported that resident gammadelta T cells in the peritoneal cavity rapidly produced IL-17 in response to Escherichia coli infection to mobilize neutrophils. We found in this study that the IL-17-producing gammadelta T cells did not produce IFN-gamma or IL-4, similar to Th17 cells. IL-17-producing gammadelta T cells specifically express CD25 but not CD122, whereas CD122(+) gammadelta T cells produced IFN-gamma. IL-17-producing gammadelta T cells were decreased but still present in IL-2- or CD25-deficient mice, suggesting a role of IL-2 for their maintenance. IFN-gamma-producing CD122(+) gammadelta T cells were selectively decreased in IL-15-deficient mice. Surprisingly, IL-17-producing gammadelta T cells were already detected in the thymus, although CD25 was not expressed on the intrathymic IL-17-producing gammadelta T cells. The number of thymic IL-17-producing gammadelta T cells was peaked at perinatal period and decreased thereafter, coincided with the developmental kinetics of Vgamma6(+) Vdelta1(+) gammadelta T cells. The number of IL-17-producing gammadelta T cells was decreased in fetal thymus of Vdelta1-deficient mice, whereas Vgamma5(+) fetal thymocytes in normal mice did not produce IL-17. Thus, it was revealed that the fetal thymus-derived Vgamma6(+) Vdelta1(+) T cells functionally differentiate to produce IL-17 within thymus and thereafter express CD25 to be maintained in the periphery.     

Parathyroid hormone-related peptide (hPTHrP) and parathyroid hormone-related peptide receptor type 1 (PTHR1) expression in human thymus.

Parathyroid hormone-related peptide (hPTHrP) is expressed in human tissues and regulates cellular proliferation, differentiation, and apoptosis by an autocrine/paracrine loop. In rodent thymus, both parathormone and parathyroid hormone-related peptide (PTHrP) are expressed by thymic epithelial cells (TECs). The present study demonstrated by RT-PCR and immunohistochemistry that hPTHrP and parathyroid hormone-related peptide receptor type 1 (PTHR1) were expressed in human thymus at both RNA and protein levels. hPTHrP was expressed mainly in the thymic medulla by epithelial (cytokeratin-positive), mature dendritic (CD40+/86+) and plasmacytoid interleukin (IL)-3Ralpha1 cells. This protein was also present in some cells forming Hassall's bodies and a few subcapsular and cortical TECs. PTHR1 was expressed by scattered subcapsular and cortical TECs and by rare TECs in the medulla. Thymocytes did not express either hPTHrP or PTHR1. Primary cultures of human TECs revealed the presence of both hPTHrP and PTHR1 mRNAs, confirming the capacity of TECs to synthesize both peptides. Moreover, synthetic (1-39) hPTHrP peptide administered on cultured TECs induced the expression of IL-6 mRNA, suggesting that hPTHrP can regulate thymic functions by inducing in TECs the expression of IL-6, which is involved in the development and maturation of thymocytes.     

Positive regulation of CXCR4 expression and signaling by interleukin-7 in CD4+ mature thymocytes correlates with their capacity to favor human immunodeficiency X4 virus replication

The emergence of X4 human immunodeficiency virus type 1 (HIV-1) variants in infected individuals is associated with poor prognosis. One of the possible causes of this emergence might be the selection of X4 variants in some specific tissue compartment. We demonstrate that the thymic microenvironment favors the replication of X4 variants by positively modulating the expression and signaling of CXCR4 in mature CD4(+) CD8(-) CD3(+) thymocytes. Here, we show that the interaction of thymic epithelial cells (TEC) with these thymocytes in culture induces an upregulation of CXCR4 expression. The cytokine secreted by TEC, interleukin-7 (IL-7), increases cell surface expression of CXCR4 and efficiently overcomes the downregulation induced by SDF-1 alpha, also produced by TEC. IL-7 also potentiates CXCR4 signaling, leading to actin polymerization, a process necessary for virus entry. In contrast, in intermediate CD4(+) CD8(-) CD3(-) thymocytes, the other subpopulation known to allow virus replication, TEC or IL-7 has little or no effect on CXCR4 expression and signaling. CCR5 is expressed at similarly low levels in the two thymocyte subpopulations, and neither its expression nor its signaling was modified by the cytokines tested. This positive regulation of CXCR4 by IL-7 in mature CD4(+) thymocytes correlates with their high capacity to favor X4 virus replication compared with intermediate thymocytes or peripheral blood mononuclear cells. Indeed, we observed an enrichment of X4 viruses after replication in thymocytes initially infected with a mixture of X4 (NL4-3) and R5 (NLAD8) HIV strains and after the emergence of X4 variants from an R5 primary isolate during culture in mature thymocytes.     

Peripheral CD4+ lymphocytes derived from fetal versus adult thymic precursors differ phenotypically and functionally

There is growing evidence that the differentiation processes in the fetal and adult thymus are not identical. However, there is little information on whether these developmental differences influence the properties of mature cells that exit the thymus and seed peripheral lymphoid organs. We have addressed this issue by comparing the development of Ag-specific Th1/Th2 function by fetal vs adult thymic derived CD4(+) cells in the same adoptive adult hosts. Host mice were irradiated and transplanted with 14- to 15-day fetal thymic lobes from Thy-1 congenic mice. Ag (keyhole limpet hemocyanin)-specific Th1/Th2 responses of fetal-derived (donor) or adult-derived (host) CD4(+) cells were analyzed by ELISA following primary or secondary immunization. Fetal-derived cells produced up to 10-fold more of both Th1 (IFN-gamma) and Th2 (IL-4) cytokines than did adult-derived cells. Comparisons of the IL-4:IFN-gamma ratios showed that the responses of fetal-derived cells were Th2-skewed in an Ag dose-dependent manner. At low doses of Ag, the fetal-derived ratio was approximately 5 times higher than the adult-derived ratio. As the Ag dose was increased, the differences between the ratios of the fetal- and adult-derived responses were minimized. These relative responses were established initially during the primary effector phase but were maintained for weeks, into the memory phase of the immune response. Importantly, fetal-derived CD4(+) cells showed these properties whether the fetal thymic precursors matured within the fetal or adult thymic microenvironment. These results demonstrate that cells arising from fetal thymic precursors are functionally different both qualitatively and quantitatively from adult-derived cells.     

Phenotypic and functional characterization of human thymic stromal cell lines.

To establish new tools for studying human thymic stromal cells, we transfected adherent cells from a human postnatal thymus using a plasmid encoding SV40 large T antigen. Among the cell lines obtained, we characterized four epithelial cell lines (LT-TEC1 to LT-TEC4) and one thymic myoid cell line (MITC). Several morphological, functional and phenotypic differences were observed between these 2 cell types. Epithelial cells were heterogeneous and larger than myoid cells. Untreated LT-TEC lines expressed MHC class I, ICAM-1 and LFA-3 antigens and not MHC class II antigens, similarly to primary thymic epithelial cells (PTEC), while MITC line expressed only class I and LFA-3 antigens. After IFN-gamma treatment, MHC class II and ICAM-1 antigens were markedly upregulated in LT-TEC lines but not in MITC, indicating the absence or a dysfunction of regulatory factors in MITC line. Myoid cells expressed mRNA for all the subunits of the acetylcholine receptor (AChR) while epithelial cells expressed only the alpha, beta and epsilon subunits. Strikingly, LT-TEC produced much more C-C chemokines and IL-6 than MITC cells, while these latter produced higher levels of IL-8 and TNF-alpha. Altogether, these results reveal phenotypic and functional differences between these two stromal cell types, suggesting a potential involvement of myoid cells in the thymic function.     

Identification of MiR-205 As a MicroRNA That Is Highly Expressed in Medullary Thymic Epithelial Cells

Thymic epithelial cells (TECs) support T cell development in the thymus. Cortical thymic epithelial cells (cTECs) facilitate positive selection of developing thymocytes whereas medullary thymic epithelial cells (mTECs) facilitate the deletion of self-reactive thymocytes in order to prevent autoimmunity. The mTEC compartment is highly dynamic with continuous maturation and turnover, but the genetic regulation of these processes remains poorly understood. MicroRNAs (miRNAs) are important regulators of TEC genetic programs since miRNA-deficient TECs are severely defective. However, the individual miRNAs important for TEC maintenance and function and their mechanisms of action remain unknown. Here, we demonstrate that miR-205 is highly and preferentially expressed in mTECs during both thymic ontogeny and in the postnatal thymus. This distinct expression is suggestive of functional importance for TEC biology. Genetic ablation of miR-205 in TECs, however, neither revealed a role for miR-205 in TEC function during homeostatic conditions nor during recovery from thymic stress conditions. Thus, despite its distinct expression, miR-205 on its own is largely dispensable for mTEC biology.