Isolation of murine thymic epithelium and an improved method for its propagation in vitro

Culture of Mouse Thymic Epithelial Cells in Serum-Free Medium

Primary cell culture systems are widely used as a valuable method for analyzing the biological functions of specific cells in vitro. Recently, various serum-free primary cell culture methods have been developed that do not involve the use of animal serums. Since the thymus is comprised of many cell types, such as thymocytes, thymic epithelial cells, macrophages, and fibroblasts, thymic epithelial cells must be isolated for their functional analysis in vitro. This chapter describes the detailed protocol for the selective primary culture of thymic epithelial cells using defined serum-free medium.

Control of the thymic medulla and its influence on αβT-cell development

The thymus is a primary lymphoid tissue that supports the generation of αβT cells. In this review, we describe the processes that give rise to the thymus medulla, a site that nurtures self-tolerant T-cell generation following positive selection events that take place in the cortex. To summarize the developmental pathways that generate medullary thymic epithelial cells (mTEC) from their immature progenitors, we describe work on both the initial emergence of the medulla during embryogenesis, and the maintenance of the medulla during postnatal stages. We also investigate the varying roles that receptors belonging to the tumor necrosis factor receptor superfamily have on thymus medulla development and formation, and highlight the impact that T-cell development has on thymus medulla formation. Finally, we examine the evidence that the thymic medulla plays an important role during the intrathymic generation of distinct αβT-cell subtypes. Collectively, these studies provide new insight into the development and functional importance of medullary microenvironments during self-tolerant T-cell production in the thymus.

Autoimmune regulator initiates the expression of promiscuous genes in thymic epithelial cells

The expression of peripheral antigens in the thymus, known as promiscuous gene expression, has been implicated in T cell tolerance and autoimmunity. Here we identified thymic epithelial cells (TECs) as the main cell type that expresses a diverse range of tissue-restricted antigens (TRAs). The TECs of a common autoimmune (non-obese diabetic [NOD]) mouse model express much lower levels of an autoimmune regulator (Aire) and TRAs than normal (Balb/c) TECs. Transfection of an Aire plasmid led to increased levels of TRA expression in cultured TECs from Balb/c and NOD mice; an increase that was enhanced by the presence of thymocytes. These data show that Aire initiates promiscuous gene expression in TECs, and that this function might be under thymocyte control.

Medium calcium concentration determines keratin intermediate filament density and distribution in immortalized cultured thymic epithelial cells (TECs)

Isolation and culture of thymic epithelial cells (TECs) using conventional primary tissue culture techniques under conditions employing supplemented low calcium medium yielded an immortalized cell line derived from the LDA rat (Lewis [Rt1l] cross DA [Rt1a]) that could be manipulated in vitro. Thymi were harvested from 4-5-day-old neonates, enzymically digested using collagenase (1 mg/ml, 37 degrees C, 1 h) and cultured in low calcium WAJC404A medium containing cholera toxin (20 ng/ml), dexamethasone (10 nM), epidermal growth factor (10 ng/ml), insulin (10 mug/ml), transferrin (10 mug/ml), 2% calf serum, 2.5% Dulbecco's Modified Eagle's Medium (DMEM), and 1% antibiotic/antimycotic. TECs cultured in low calcium displayed round to spindle-shaped morphology, distinct intercellular spaces (even at confluence), and dense reticular-like keratin patterns. In high calcium (0.188 mM), TECs formed cobblestone-like confluent monolayers that were resistant to trypsinization (0.05%) and displayed keratin intermediate filaments concentrated at desmosomal junctions between contiguous cells. Changes in cultured TEC morphology were quantified by an analysis of desmosome/membrane relationships in high and low calcium media. Desmosomes were significantly increased in the high calcium medium. These studies may have value when considering the growth conditions of cultured primary cell lines like TECs.

Prss16 is not required for T-cell development

PRSS16 is a serine protease expressed exclusively in cortical thymic epithelial cells (cTEC) of the thymus, suggesting that it plays a role in the processing of peptide antigens during the positive selection of T cells. Moreover, the human PRSS16 gene is encoded in a region near the class I major histocompatibility complex (MHC) that has been linked to type 1 diabetes mellitus susceptibility. The mouse orthologue Prss16 is conserved in genetic structure, sequence, and pattern of expression. To study the role of Prss16 in thymic development, we generated a deletion mutant of Prss16 and characterized T-lymphocyte populations and MHC class II expression on cortical thymic epithelial cells. Prss16-deficient mice develop normally, are fertile, and show normal thymic morphology, cellularity, and anatomy. The total numbers and frequencies of thymocytes and splenic T-cell populations did not differ from those of wild-type controls. Surface expression of MHC class II on cTEC was also similar in homozygous mutant and wild-type animals, and invariant chain degradation was not impaired by deletion of Prss16. These findings suggest that Prss16 is not required for quantitatively normal T-cell development.

Cathepsin L: critical role in Ii degradation and CD4 T cell selection in the thymus

Degradation of invariant chain (Ii) is a critical step in major histocompatibility complex class II-restricted antigen presentation. Cathepsin L was found to be necessary for Ii degradation in cortical thymic epithelial cells (cTECs), but not in bone marrow (BM)-derived antigen-presenting cells (APCs). Consequently, positive selection of CD4+ T cells was reduced. Because different cysteine proteinases are responsible for specific Ii degradation steps in cTECs and BM-derived APCs, the proteolytic environment in cells mediating positive and negative selection may be distinct. The identification of a protease involved in class II presentation in a tissue-specific manner suggests a potential means of manipulating CD4+ T cell responsiveness in vivo.

Thymic epithelial cell culture

Culture of epithelial cells from the thymus of children and laboratory animals has been used for more than two decades to evaluate both the nature of these cells and their importance in the selection and maturation of functional T cells. Especially by the use of serum-free cultures and by establishment of cell lines from cultured thymic epithelial cells (TEC), it has been possible to obtain basic information on morphology of subpopulations of TEC, including surface determinants of importance for interactions with T-cell precursors, and on the repertoire of cytokines secreted by different types of TEC. The available information, obtained by co-culture of pre-T cells and TEC, on the effects of TEC on the fate of pre-T cells suggests that cultured TEC/TEC lines are able both to secrete needed cytokines for T-cell development, and to deliver signals needed for T-cell selection. In vivo results showing cross-talk between TEC and T cells indicate that more careful evaluation of interactions between well-defined subtypes of cultured TEC and co-cultured subpopulations of pre-T cells (as well as macrophages/dendritic cells) will be of importance in evaluation of the function of the thymus.

Peptide contributes to the specificity of positive selection of CD8+ T cells in the thymus

Mice deficient in the gene encoding the peptide transporter associated with antigen processing (TAP1) have drastically reduced levels of surface expression of MHC class I molecules and few CD8+ T cells. Addition of class I binding peptides to cultured fetal thymi from TAP1 mutant mice invariably allowed the rescue of class I expression, while only some of these peptides promoted the positive selection of CD8+ T cells, which were polyclonal and specific for the peptide-MHC complex. A nonselecting peptide was converted to a mixture of selecting peptides when the residues involved in the interaction with TCRs were altered. A mixture of self-peptides derived from C57BL/6 thymi induced positive selection of CD8+ T cells at concentrations that gave relatively low class I surface expression. The implication of these observations is that self-peptides determine, in part, the repertoire of specificities exhibited by CD8+ T cells.

Culture and characterization of thymic epithelium from autoimmune NZB and NZB/W mice

Autoimmune NZB and NZB/W mice display early abnormalities in thymus histology, T cell development, and mature T cell function. Abnormalities in the subcapsular/medullary thymic epithelium (TE) can also be inferred from the early disappearance of thymulin from NZB. It has also been reported that NZB thymic epithelial cells do not grow in culture conditions that support the growth of these cells from other strains of mice. In order to study the contribution of TE to the abnormal T cell development and function in NZB and NZB/W mice, we have devised a culture system which supports the growth of TE cells from these mice. The method involves the use of culture vessels coated with extracellular matrix produced by a rat thymic epithelial cell line. TEA3A1, and selective low-calcium, low-serum medium. In addition TEA3A1 cells have been used as an antigen to generate monoclonal antibodies specific for subcapsular/medullary TE. These antibodies, as well as others already available, have been used to show that the culture conditions described here select for cells displaying subcapsular/medullary TE markers, whereas markers for cortical TE and macrophages are absent.

Short-term cultivation of murine thymic epithelial cells in a serum-free medium

Thymic epithelial cells were grown in defined medium without unknown serum factors and without concurrent growth of other cell types. Thymic tissue was obtained from 1- to 4-wk-old mice, disaggregated, and incubated in a mixture of collagenase-dispase-DNAse. The resulting organoids were seeded on collagen-coated flasks. The culture medium consisted of DME-F12 with low or high concentration of Ca2+ supplemented with insulin, epidermal growth factor, cholera toxin, hydrocortisone, and transferrin. Under these conditions, explants attached to the substrate within 2 d, and expanding epithelioid monolayer islets emerged from the organoids during the following days. [3H]Thymidine incorporation revealed a growth fraction of the cells close to 5%. By omitting either epidermal growth factor, insulin, or cholera toxin from the medium, pronounced reduction in sizes of islets and in [3H]thymidine incorporation was found. Throughout the culture period, the islets appeared as continuous sheets of polygonal cells. The epithelial nature of the expanding cell islets was confirmed by demonstration of cytokeratins and of desmosomes. Ultrastructural evaluation of early cultures revealed clusters of epithelial cells intermixed with lymphocytes, and late cultures showed a typical pattern of stratified keratinizing epithelium. However, squamous metaplasia was avoided by the use of low Ca2+ medium, which also proved essential for cell transfer. MHC class II antigen was detected on the majority of the cultured cells, and culture supernatants contained co-mitogenic activity for thymocytes and GM-colony stimulating activity.

Patterns of keratin expression in the murine thymus

Polyclonal and monoclonal antibodies recognizing different species of keratin molecules were used to characterize the expression of keratins by epithelial cells in the murine thymus. Some of the reagent antibodies used in this study were raised against human keratins and cross-react with murine keratins. Both cortical and medullary thymic epithelial cells were found to contain keratin with apparent molecular weight of 52 KD, which is considered to be associated with simple or stratified epithelium. In addition, medullary epithelial cells were found to contain other species of keratin molecules, ranging in apparent molecular weight from 40 to 67 KD. This latter population of keratins is thought to be associated with stratified and/or keratinizing epithelia.

Medullary epithelial cell lines from murine thymus constitutively secrete IL-1 and hematopoietic growth factors and express class II antigens in response to recombinant interferon-gamma

In this report, we describe the generation of two cloned epithelial cell lines, TE-71 and TE-75, from murine thymus. These cell lines resemble medullary thymic epithelium by a number of criteria, including reactivity with the monoclonal antibodies A2B5 and ER-TR5, the fucose-specific lectin derived from Ulex europeus, and the expression of keratins normally expressed by medullary thymic epithelial cells in situ. Constitutive Class II antigen expression by these cells is not detectable at the light or electron microscopic level or with flow cytometry. Following exposure to recombinant interferon-gamma or supernatants from mitogen-stimulated spleen cells, expression of Class II antigens by these thymic epithelial cell lines is increased, although less than the levels expressed by spleen cells. Medium conditioned by TE-71 and TE-75 cells exhibited colony-stimulating activity for bone marrow cells. In addition, TE-71-conditioned medium exhibited IL-1-like activity which could be neutralized with anti-IL-1 antibodies.