An in vitro study of functional maturation of murine thymus cells.

Critical time of onset of thymus cell functions in ontogeny was studied in vitro. Collaborative function in an antibody response and ability to induce a graft-versus-host (GvH) response by murine thymocytes from different stages of ontogeny were investigated. Thymocytes from as early as 16-day mouse embryos were capable of collaborating in the antibody response to sheep-erythrocyte-antigen in vitro following 24 h of pretreatment with concanavalin A (con A). By contrast, maturation of thymus cell function as measured by competence to induce a graft-versus-host reaction, was first manifested by newborn thymus cells, and pretreatment with con A did not facilitate the maturation of this thymus cell function. Experiments to understand the effect of con A on the expression of cell surface antigens have also been reported. Con A-treated thymus cells of different ontogenic stages tested were less susceptible to killing by anti-theta serum than nontreated thymus cells; reverse was true with anti-H-2 serum. The significance of the differential susceptibility of con A-treated thymus cells to anti-sera treatment and the finding that mouse thymocytes can provide helper function as early as the 16th day of gestation have been discussed.     

Multilineage hemopoiesis induced by cloned stromal cells

Long-term hemopoiesis in culture depends upon the presence of an adherent layer composed of a variety of stromal cells. A subtype of endothelial-adipocytes from the bone marrow stroma (clone 14F1.1) was previously shown to induce long-term myelopoiesis and renewal of pluripotent stem cells. One of a series of stromal cell lines and clones from mouse thymus stroma (STAC-1.2) has now been found to support long-term hemopoiesis. These marrow- and thymus-derived stromal cell clones also have lymphopoietic activities: precursor T cells, or pre-B cells accumulated in co-cultures of thymus cells and the stromal clones, as indicated by cell surface markers, T cell receptor and immunoglobulin gene rearrangements. The predominance of a cell type in these cultures depended upon the serum used to supplement the medium. Recombinant interleukin 2 (IL-2) and the 14F1.1 clone synergistically promoted the proliferation of thymocytes, while a thymus hormone, THF-gamma 2, shifted the population to a relatively mature phenotype. It is proposed that one major function of stromal cells, whether from the bone marrow or thymus, is to restrain the maturation flow and preferentially support the accumulation of cells at early differentiation stages.     

The human thymic microenvironment. Phenotypic characterization of Hassall's bodies with the use of monoclonal antibodies

The human thymic microenvironment is important in promotion of T cell maturation, particularly during early stages of thymic ontogeny. Hassall's bodies (HB) are epithelial swirls in the human thymic medulla that are thought to be derived from endocrine medullary thymic epithelium. To study the ontogeny and function of various components of the human thymic microenvironment, we have produced four monoclonal antibodies (TE-8, TE-15, TE-16, and TE-19) that selectively reacted in thymus with HB. Antibodies TE-8 and TE-16 reacted with the cells forming the outer rim of the HB swirl. Antibody TE-19 reacted with the entire cellular portion of HB and with epithelial cells immediately surrounding HB. Granular foci in the cellular swirls of greater than 90% of HB reacted with antibody TE-15. During thymic ontogeny, the antigens defined by antibodies TE-8, TE-15, TE-16, and TE-19 were first detected in fetal thymus on HB beginning at 16 wk gestation, the age when HB morphologically appear in the thymus. Aberrant expression of the antigens corresponding to antibodies TE-8, TE-15, TE-16, and TE-19 was observed on thymic tissue from individuals with severe cellular immunodeficiency disease. In human skin, antibodies TE-8, TE-16, and TE-19 reacted with the stratum granulosum; antibody TE-15 reacted with the stratum corneum. Thus, with the use of antibodies TE-8, TE-15, TE-16, and TE-19, we have identified HB as antigenically distinct regions of endocrine thymic epithelium. Furthermore, we have shown that these anti-HB reagents also selectively react with epidermal keratinocytes in the terminal stages of keratinocyte maturation.     

T cell differentiation in the thymus

T lymphocytes arise in the thymus and seed to peripheral lymphoid organs as fully functional cells at the time of exit. In humans, the thymus begins to function very early in ontogeny and releases large numbers of T cells before the time of birth. However, the vast majority of developing thymocytes (>95%) die within the thymus as a result of stringent selection processes. Positive selection imposes self-MHC-restriction on thymocytes and dictates the MHC-restricted repertoire of post-thymic T cells. Negative selection results in deletion of autoreactive cells. Both types of selection depend on cell to cell contracts and on the presence of appropriate growth factors which are still largely undetermined. Cell to cell contacts occur between developing thymocytes and cells of the thymic microenvironment (accessory cells), and are mediated by several receptor/ligand interactions which subserve the function of establishing and stabilizing these contacts. Besides MHC-TCR interactions, adhesion molecules are important for thymocyte maturation, selection and activation, and for the export and peripheral homing of mature T cells produced in the thymus. Here we describe a novel integrin involved in thymocyte-thymic epithelial cell interactions.     

Differentiation of human T lymphocytes. I. Acquisition of a novel human cell surface protein (p80) during normal intrathymic T cell maturation

The thymus is thought to be the primary central lymphoid organ in which T cells mature. Although thymic cortical and medullary compartments are distinct histologically, few antigens have been described that are absolutely acquired during the presumed intrathymic maturation pathway from cortical to medullary thymocytes. In this paper, we describe the acquisition during human intrathymic T cell maturation of a novel protein (p80) defined by a monoclonal antibody (A1G3). Although the p80-A1G3 antigen is distributed throughout the body and is not T cell specific, our study demonstrates that expression of p80-A1G3 antigen in normal human thymus is associated with thymocyte functional maturity and location in the thymus medulla. Moreover, in contrast to other markers of mature human T cells, the p80-A1G3 cell surface protein is not expressed on T6+ cortical thymocytes, and, therefore, is absolutely acquired by medullary thymocytes during T cell maturation. Thus, the p80-A1G3 antigen and the A1G3 antibody provide a heretofore unavailable system for the study of molecular events that transpire during the maturation of thymocytes.     

Development and ontogeny of hamster T cell subpopulations

The Syrian hamster is unique among laboratory animals because products of class I MHC genes are monomorphic. Thus, this species may be a model in which to test the relationship between MHC polymorphism and the T cell antigen receptor repertoire. Recently, cytotoxic and helper T cell subpopulations have been distinguished on the basis of cell surface phenotype detected with monoclonal antibodies (mAb). We used these reagents (mAb 110 detects all peripheral T cells and mAb 38 detects cytotoxic T cells) to dissect and categorize thymic populations according to relative maturational status. The two mAb divide thymocytes into four subpopulations in the young adult. Two (110+ 38+, 110+ 38-) were peripheral-like and were housed in the medulla, exclusively; another subset (110- 38+) consisted almost entirely of TdT+ cortical thymocytes. The fourth subset (110- 38-), bearing neither marker, was heterogeneous and consisted mostly of medium-large-size thymocytes, including cells with an early phenotype (nuclear TdT+). Cells with the cortical phenotype proved to be the most sensitive to cortisone treatment, whereas those which expressed the medullary marker, 110, were most resistant. To ascertain the relationship between 110- and 110+ T lineage cells, we followed the appearance of the four thymic subpopulations during ontogeny of the hamster thymus. Adult-like thymic architecture (delineation of cortex and medulla) as well as the two 110- subsets were established before expression of 110 antigen was apparent in the thymus. However, lymphocytes bearing the 110 antigen were found in lymph nodes prior to thymus during ontogeny, concomitant with developing T cell function in peripheral tissue. This finding implies that cells lacking 110 antigen were exported from the thymus and subsequently acquired expression of the molecule in the periphery, and we suggest that acquisition of 110 antigen may be a stage of postthymic maturation. Although 110+ cells appeared to be the most mature subset by several criteria, all functional thymocytes of adults or neonates were not 110+. Thus, we conclude that the 110 marker is acquired after T cells reach functional maturity. Moreover, the response profile of isolated 38+ thymocytes was analogous to peripheral 38+ T cells, suggesting that the dichotomy of function detected with our mAb also occurs before acquisition of 110 antigen. We have modeled what is known about hamster T cell development into a hypothetical scheme.     

Amplification of the proliferative response to alloantigen by a factor present in an extract of syngeneic thymic lymphoid cells: demonstration of optimal conditions and target cell for factor activity.

A factor extracted from syngeneic thymic lymphoid cells (thymocytes) is shown to amplify the proliferative (MLC) response of syngeneic lymphoid cells to alloantigen in vitro. The optimal conditions for an effect of the thymus factor are quantitatively defined by kinetic and dose-response studies. Other variables that could potentially influence the activity of the thymus factor, such as the presence of 2-mercaptoethanol and the source of alloantigen, are identified. Factor activity can be recovered from semi-allogeneic thymocytes, as well as syngeneic thymocytes. The factor appears to predominantly effect the proliferative response of T cells localized in peripheral lymphoid organs. As such, this factor appears to be distinct from the variety of previously described factors derived from thymic reticuloepithelial elements that are thought to primarily induce the differentiation of T cell precursors found predominantly in bone marrow. Several possible mechanisms of action of this thymocyte-derived factor are considered.     

A spleen-derived maturational factor allows immature thymocytes, prepared as cells bearing low amounts of surface sialic acid, to become cytotoxic T cells

A population of immature mouse thymocytes bears low levels of surface sialic acid and can be separated from the more mature high sialic acid-bearing thymocytes by selective agglutination with the sialic acid-specific lectin, lobster agglutinin 1. These immature thymocytes do not proliferate in response to concanavalin A (Con A). They do not produce interleukin 2 (IL-2), do not provide T cell help to B cells for an in vitro antibody response, and as shown here, do not become cytotoxic T lymphocytes when polyclonally stimulated with Con A + IL-2. We describe here a spleen-derived maturational factor which stimulates these immature thymocytes, in the presence of Con A and IL-2, to become cytotoxic T lymphocytes. The maturational factor is a protein secreted by Con A-stimulated mouse or rat spleen cells; it is apparently neither interleukin 1, IL-2, interleukin 3, gamma-interferon, nor combinations of these cytokines, because these materials do not replace the maturational factor. The active material in Con A-stimulated mouse spleen cell supernatant was recovered from a G-75 column in the 33,000-48,000 m.w. range. These experiments suggest that within the lobster agglutinin 1-negative thymocyte population there are cells which can mature under the influence of a spleen-derived factor. It is possible that these cells represent the small subpopulation of immature cells destined to become immunocompetent peripheral T cells. On the other hand, the factor may be rescuing cells destined to die in the thymus.     

The myelopoietic inducing potential of mouse thymic stromal cells

The thymus has generally been considered as being solely involved in T cell maturation. In this study we have demonstrated that mouse thymic stroma can also support myelopoiesis. Bone marrow from mice treated with 5-fluorouracil was depleted of cells expressing Mac-1, CD4, and CD8 and incubated on lymphocyte-free monolayer cultures of adherent thymic stromal cells. After 7 days there was a marked increase in nonadherent cells, the majority of which were Mac-1+, FcR+, and HSA+. These proliferating bone marrow cells also expressed markers (MTS 17 and MTS 37) found on thymic stromal cells. Such cells were not found in thymic cultures alone, in bone marrow cultured alone, or on control adherent cell monolayers. Supernatants from the cultured thymic stroma, however, were able to induce these cell types in the bone marrow precursor population. Incubation of normal thymocytes with a monolayer of these in vitro cultivated Mac-1+, MTS 17+, MTS 37+ myeloid cells leads to selective phagocytosis of CD4+ CD8+ cells. Hence, this study demonstrates that the thymic adherent cells can induce myelopoiesis in bone marrow-derived precursor cells and provide a form of self-renewal for at least one population of thymic stromal cells. Furthermore, these induced cells are capable of selective phagocytosis of CD4+ CD8+ thymocytes and may provide one mechanism for the selective removal of such cells from the thymus.     

Correspondence between lectin-defined and surface antigen-defined cell subpopulations in the human thymus: its variation during ontogeny

In the thymus of children, congruent to 50% of cells are recognized both by peanut agglutinin and soybean agglutinin (PNA+, SBA+), congruent to 23% of cells are PNA-, SBA-, and 23% are PNA-, SBA+. This pattern of recognition was compared with the reactivity of these cells with monoclonal antibodies recognizing T cell differentiation antigens A 50 and a series (T3, T6, T8) that defines 3 discrete stages of T cell differentiation. Most PNA+, SBA+ display T6 and T8 but not T3 antigens; most PNA-, SBA+ display T3+ and A 50+ but not T6; and T3-, T6-, A 50- cells are PNA-, SBA-. Thus, there is a close correspondence between PNA+, SBA+ cells and the common (cortical) T3-, T6+ thymocytes; between PNA-, SBA+ cells and late (medullary) T3+, T6- thymocytes; and between PNA-, SBA- cells and early thymocytes. During ontogeny, although there are fewer PNA+ cells in the thymus, the proportion of T3+ cells, T6+ cells, and T3-, T6- cells showed no major modification as early as 16 wk.     

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.     

Expression of T cell receptors by thymocytes: in situ staining and biochemical analysis.

We have examined the in situ expression of T cell receptor (TCR) V beta 8 protein in murine thymus during ontogeny using the monoclonal antibody F23.1. Positive cells were first detected at day 15 of gestation (0.6%). By day 16 the frequency of positive cells increased dramatically (4.18%). From day 16 to day 17 positive cells doubled (8.17%). The first clusters of F23.1 positive cells were seen at day 17. In the cortex, positive cells decreased from 14% in the newborn mice to 9.8% in 8-week-old mice, whereas in the medulla the frequency remained unchanged at 20%. The antibody F23.1, as well as an antiserum raised against the constant region of the beta chain, immunoprecipitated receptor dimers from highly purified Lyt2+, L3T4+ thymocytes and from two thymic lymphomas of cortical phenotype which express full size alpha and beta mRNA. The receptor dimer could not be precipitated from Lyt2-, L3T4- thymocytes. The results are discussed with regard to intrathymic T cell repertoire selection.     

Proliferation and production of IL-2 and B cell stimulatory factor 1/IL-4 in early fetal thymocytes by activation through Thy-1 and CD3

To examine which cell surface molecules can operate as transducers of activation signals to early fetal thymocytes, we analyzed the ability of mAb to CD3 and Thy-1 to induce fetal thymocyte activation. Both proliferation and lymphokine secretion were used as measures of activation. We show that anti-CD3 antibodies induce activation of fetal thymocytes as early as day 13 of fetal thymus development, 2 days before CD3 can be detected by flow cytometry. In addition, an alternative activation signal can be delivered to fetal thymocytes through the Thy-1 molecule as early as it is expressed, i.e., day 13. Both CD3- and Thy-1-mediated activation of day 15 fetal thymocytes results in expansion of cells expressing a CD3-gamma delta receptor complex; no CD3-alpha beta receptor complex could be detected. IL-2 production induced by CD3- and Thy-1-induced activation of fetal thymocytes is evident at the 13th day of gestation. Finally, an additional lymphokine B cell stimulatory factor-1 (BSF-1)/IL-4 (so far known only to be produced by mature CD3- cells), is also produced by fetal thymocytes. The results demonstrate that at least two cell surface molecules, Thy-1 and CD3, can function as pathways of activation in fetal thymocytes, and that at least two lymphokines, IL-2 and BSF-1/IL-4, are produced upon activation. These findings may well reflect a role for the early appearance of CD3- cells in thymus ontogeny.     

The expression, function, and ontogeny of a novel T cell-activating protein, TAP, in the thymus

The TAP molecule is an allelic 12,000 m.w. membrane protein that participates in T cell activation. This report analyzes the expression, function, and ontogeny of this molecule in the thymus. TAP is expressed on a small subset (10 to 20%) of thymocytes which is distinct from its expression on a majority (70%) of peripheral T lymphocytes. In the adult thymus, the majority of the TAP-bearing thymocytes are cortisone-resistant, Thy-1+, TL-, J11D-, and PNA-, which localizes TAP expression to medullary thymocytes. Cortical thymocytes do not bear this determinant. Parallel functional studies demonstrated that TAP+ thymocytes are required for Con A and MLR responsiveness. Anti-TAP MAb plus PMA specifically induces proliferation of mature thymocytes comparable in magnitude to the Con A response. These results demonstrate that TAP expression defines the immunocompetent thymocyte compartment and, further, that this molecule is functional on these cells. The ontogeny of TAP expression was also analyzed. TAP is expressed early in fetal thymic development at a time when most T cell markers (except Thy-1 and the iL2-R) are absent. The small sub-population of adult L3T4- and Lyt-2- thymocytes, which resemble early fetal thymocytes, also express TAP. These early thymocytes are capable of being activated through the TAP molecule. The implications of these findings for T cell development and, in particular, the relationship of TAP to T cell receptor expression and acquisition of immunocompetence are discussed.     

Antigenic markers on mouse lymphoid cells: origin of cells mediating immunologic memory

Specific antisera were used for the purification of thymus dependent and thymus independent or bursa equivalent lymphoid cells in the mouse. Spleen cells from mice immune to sheep erythrocytes, a thymus dependent antigen, or to E. coli 055:B5 lipopolysaccharide, a thymus independent antigen, were treated with anti-θ (C3H) serum or anti-MBLA serum and complement prior to their adoptive transfer into lethally irradiated syngeneic recipients. Syngeneic thymocytes, bone marrow cells, or spleen cells from nonimmune donors were appropriately added to antiserum treated cells prior to transfer. The secondary response to these antigens was assayed in recipient spleens six days after cell transfer. The kinetics of the primary response to SRBC was investigated as to its effect on origin of specific hyper-reactive T or B lymphoid cells.The adoptive response to CPS originated in the B lymphoid cell population. Immunologic memory to CPS was demonstrated in recipients of immune cells, compared to recipients of normal cells, by a five fold increase in antibody forming cells.The IgM and IgG adoptive immune response to high doses of SRBC depended upon an increased number of specifically hyper-reactive T-lymphoid cells to facilitate cooperation between T and B lymphocytes. High doses of SRBC initially stimulated T cell memory but at 42 days after priming an increased number of specifically hyper-reactive B lymphoid cells were present.     

Cell proliferation and differentiation in the fetal and early postnatal mouse thymus

The relationships between cell proliferation and cell differentiation during thymus ontogeny were studied by labeling DNA-synthesizing thymocytes with bromodeoxyuridine and staining with antibodies against CD4, CD8, J11d, phagocytic glycoprotein 1, TCR V beta 8 chain, Thy-1, and IL-2R surface proteins. The development of the thymus was discontinuous, with two well defined growth periods from 13 days to 18 days of fetal life and from 3 days to 6 days after birth, and more progressive growth from day 8 to 2 wk. Cell proliferation started on fetal day 12, 1 day after the arrival of hemopoietic stem cells in the third branchial pouch. These cells were phagocytic glycoprotein 1-positive but IL-2R and Thy-1 negative. Thus, cell proliferation preceded IL-2R expression. Until day 15, CD4-8- thymocytes expanded without differentiation. Then CD4-8+ and CD4+8+ cells appeared; this induction was proliferation dependent and occurred on cells which had already lost IL-2R, but just after maximum expression of this receptor. During several days, the thymus remained of constant size (around 10(7) cells) and behaved like the steady state thymus. On day 3 after birth, expansion started again and was correlated with an increase in CD4-8- proliferation index and IL-2R expression. At the same time, the thymic subset capable of expansion without differentiation was again, transiently, detectable. These results suggest that the inflow of precursor cells into the thymus is permanent but transiently increased at several times during ontogeny. Moreover, the behavior of fetal CD4-8- cells does not appear radically different from that of adult precursors, but the actual difference resides in the variation of the relative proportion of CD4-8- cells at different maturation stages, as revealed by striking variations of IL-2R expression by cycling cells.     

Quantitative and functional expression of somatostatin receptor subtypes in human thymocytes

We recently demonstrated the expression of somatostatin (SS) and SS receptor (SSR) subtype 1 (sst1), sst2A, and sst3 in normal human thymic tissue and of sst1 and sst2A on isolated thymic epithelial cells (TEC). We also found an inhibitory effect of SS and octreotide on TEC proliferation. In the present study, we further investigated the presence and function of SSR in freshly purified human thymocytes at various stages of development. Thymocytes represent a heterogeneous population of lymphoid cells displaying different levels of maturation and characterized by specific cell surface markers. In this study, we first demonstrated specific high-affinity 125I-Tyr(11)-labeled SS-14 binding on thymocyte membrane homogenates. Subsequently, by RT-PCR, sst2A and sst3 mRNA expression was detected in the whole thymocyte population. After separation of thymocytes into subpopulations, we found by quantitative RT-PCR that sst2A and sst3 are differentially expressed in intermediate/mature and immature thymocytes. The expression of sst3 mRNA was higher in the intermediate/mature CD3+ fraction compared with the immature CD2+CD3- one, whereas sst2A mRNA was less abundant in the intermediate/mature CD3+ thymocytes. In 7-day-cultured thymocytes, SSR subtype mRNA expression was lost. SS-14 significantly inhibited [3H]thymidine incorporation in all thymocyte cultures, indicating the presence of functional receptors. Conversely, octreotide significantly inhibited [3H]thymidine incorporation only in the cultures of immature CD2+CD3- thymocytes. Subtype sst3 is expressed mainly on the intermediate/mature thymocyte fraction, and most of these cells generally die by apoptosis. Because SS-14, but not octreotide, induced a significant increase in the percentage of apoptotic thymocytes, it might be that sst3 is involved in this process. Moreover, sst3 has recently been demonstrated on peripheral human T lymphocytes, which derive directly from mature thymocytes, and SS analogs may induce apoptosis in these cells. Interestingly, CD14+ thymic cells, which are cells belonging to the monocyte-macrophage lineage, selectively expressed sst2A mRNA. Finally, SSR expression in human thymocytes seems to follow a developmental pathway. The heterogeneous expression of SSR within the human thymus on specific cell subsets and the endogenous production of SS as well as SS-like peptides emphasize their role in the bidirectional interactions between the main cell components of the thymus involved in intrathymic T cell maturation.     

Detection of a cell surface antigen common to a mouse myeloma and a population of mouse thymocytes.

A new antigen termed PTA (plasmocytoma thymus antigen) is described which occurs on 70--80% of mouse thymocytes of all mouse strains tested and on an IgG 2b producing BALB/c plasma cell tumor. PTA is detectable on mouse spleen and lymph node cells. It is absent from liver, brain, bone marrow, and antibody plaque forming cells. PTA is not related to theta antigen and is not detectable on rat thymocytes.     

Membrane molecules in induction of apoptosis of thymocytes by mouse thymic dendritic cells which express Fas ligands

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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.