An improved fluorescent substrate for assaying soluble and membrane-associated ADAM family member activities

A fluorescent resonance energy transfer substrate with improved sensitivity for ADAM17, −10, and −9 (where ADAM represents a disintegrin and metalloproteinase) has been designed. The new substrate, Dabcyl-Pro-Arg-Ala-Ala-Ala-Homophe-Thr-Ser-Pro-Lys(FAM)-NH₂, has specificity constants of 6.3 (±0.3) × 10⁴ M⁻¹ s⁻¹ and 2.4 (±0.3) × 10³ M⁻¹ s⁻¹ for ADAM17 and ADAM10, respectively. The substrate is more sensitive than widely used peptides based on the precursor tumor necrosis factor-alpha (TNF-alpha) cleavage site, PEPDAB010 or Dabcyl-Ser-Pro-Leu-Ala-Gln-Ala-Val-Arg-Ser-Ser-Lys(FAM)-NH₂ and Mca-Pro-Leu-Ala-Gln-Ala-Val-Dpa-Arg-Ser-Ser-Arg-NH₂. ADAM9 also processes the new peptide more than 18-fold better than the TNF-alpha-based substrates. The new substrate has a unique selectivity profile because it is processed less efficiently by ADAM8 and MMP1, −2, −3, −8, −9, −12, and −14. This substrate provides a unique tool in which to assess ADAM17, −10, and −9 activities.     

Probing gene function in thymic epithelial cells

Thymic epithelial cells (TECs) provide a highly specialized microenvironment for the generation of a functional and self-tolerant T cell repertoire. Much of our current view of TEC biology is derived from gain- or loss-of-function approaches, which have significantly contributed to our understanding of gene function in TEC development and T cell repertoire selection. Here, we will review transgenic and viral strategies that have been used to manipulate gene expression in TECs, highlight some of the shortcomings of particular currently available tools and provide a brief outline of our own attempts to more rapidly and/or more specifically assess gene function in TECs.     

Age-related changes in rat thymic epithelial cells

We investigated age-related changes in immunocytochemical localisation of cytokeratin 16 (CK16) in thymuses of female Wistar rats at various stages of adult life (months 1, 3, 6, 12). Within the 1 st month of life, distribution of CK typical for individual subsets of thymic epithelial cells (TEC) was observed. The most numerous CK16+ TEC were observed in the outer region of medulla, in the outer cells of Hassall's corpuscles and in the superficial epithelial layer neighbouring the connective tissue of the capsule, septa and vessels of the thymus. In the 3rd month of life, increased intensity of CK16 reaction in superficial TEC was accompanied by increased numbers of CK 16+ TEC in the outer region of the medulla. Age-related alterations in the distribution of the studied markers were evident beginning from the 6th month of life and involved increased expression of CK16 in the superficial layer of TEC, which at the interface with the septa formed stratified epithelium. In parallel, decreased numbers of CK16+ TEC were observed in the outer region of the medulla. Changes in CK16+ TEC distribution of a similar type developed in 12-month old rats and they probably reflected altered functions of some TEC populations and decreased or increased biological activity of other TEC populations.     

Reduced expression of Ia antigens by thymic epithelial cells of aged mice

Thymic Ia antigen expression was examined with biochemical and immunohistochemical techniques. We found that expression of Ia antigens was reduced in thymic tissue of aged mice and that much of this loss was associated with cortical thymic epithelial cells. The ontologic pattern of Ia antigen expression in the thymus closely followed that observed for thymic weight, reaching maximal values at 4 wk of age and declining thereafter.     

Thymosin-beta 4 gene. Preliminary characterization and expression in tissues, thymic cells, and lymphocytes

A cDNA for rat thymosin-beta 4 was used to investigate the expression of this gene in different tissues, thymic cells, and lymphocytes. Hybridization analysis of total RNA from 13 rat tissues demonstrated the presence of an 800 nucleotides-long mRNA in all the tissues surveyed, with the highest levels in spleen, thymus, and lung. Examination of thymic cells showed that the thymosin-beta 4 gene is predominantly expressed in thymocytes. The thymosin-beta 4 mRNA was also studied in Ig+ and Ig- lymphocytes, being fourfold more abundant in Ig- than Ig+ splenic lymphocytes, whereas similar levels were found in both types of blood cells. The analysis of RNA from T cells at different maturation stages evidenced slight differences in their thymosin-beta 4 mRNA content, indicating that thymosin-beta 4 gene expression is not clearly related to the differentiation process of T cells. All these results do not support the roles for thymosin-beta 4 in cellular immunity and differentiation of lymphoid cells, suggesting a more general function for this peptide. Preliminary characterization of the human beta 4 gene by restriction analysis disclosed a complicated pattern consistent with multiple genes and/or introns. The analysis of genomic DNA from different species ranging from humans to Escherichia coli showed that this gene is only highly conserved in mammals.     

Interferon-gamma modulates HLA class II antigen expression on cultured human thymic epithelial cells

Cultures of human thymic epithelial cells (TEC) were tested for the expression of HLA class I (A, B, C) and class II (DR and DC) antigens by indirect immunofluorescence. The epithelial nature of the cells was proven by using an antikeratin antiserum. A high level of expression (close to 100% positive cells) of HLA class I antigens was observed on TEC at the beginning of the culture and remained unchanged for up to 12 days. In contrast, HLA class II antigen expression (85% DR+ and 75% DC+ cells on day 2) decreased gradually and reached very low levels (less than 5% DR+ or DC+) by day 7 of culture. This loss of class II antigen expression was not seen when cultures were performed in the presence of supernatants from activated T cells containing interferon-gamma (IFN-gamma). Furthermore, the presence of recombinant IFN-gamma (rIFN-gamma) in the medium from the onset of culture maintained HLA-DR and DC antigen expression on a high number of cells (comparable to that observed on day 2 of culture). A large percentage of rIFN-gamma-treated cells also showed intracytoplasmic HLA-DR antigen expression. Addition of rIFN-gamma at various times after the onset of the culture led to a reinduction of DR and DC antigen expression. This effect of rIFN-gamma was observed in 48 hr with concentrations as low as 10 IU/ml and was apparently specific for this IFN species, in that rIFN-alpha was unable to modify HLA class II antigen expression at concentrations up to 1000 IU/ml. The increased expression of HLA class II antigen was truly due to induction in individual TEC, rather than selection of class II-positive cells, because induction under the influence of IFN-gamma was reversible and occurred in the absence of proliferation in mitomycin-treated or gamma-irradiated cultures. Our results indicate that synthesis and membrane expression of class II HLA antigens are enhanced by IFN-gamma in TEC cultures. This finding raises the possibility that IFN-gamma participates in the mechanisms that assure the permanent expression of DR and DC antigens observed in TEC in vivo, with potentially important functional consequences in terms of education for self recognition.     

Human thymic epithelial cells produce interleukin 1

Although the thymus plays a critical role in generation of immunocompetent T lymphocytes, the precise role of the epithelial component of the thymus in the induction of T cell proliferation and maturation remains unknown. Since interleukin 1 (IL 1) is required for mature T cell activation, we have determined whether human thymic epithelial (TE) cells produce IL 1. By using a system for longterm culture of human TE cells, we found that human TE cells produced an IL 1-like factor (TE-IL 1) that augmented the proliferation of C3H/HeJ mouse thymocytes to phytohemagglutinin. IL 1 activity (20 to 200 U/ml) was detected in supernatants of TE cultures from all individuals (2 to 13 yr old) tested. IL 1 activity was also detected in supernatants of TE cultures from a 17-wk fetus but not from a 10-wk fetus. Production of TE-IL 1 was dependent on TE cell density and time in culture with optimal TE-IL 1 activity observed at 10(6) TE cells/ml after 48 to 72 hr of culture. With the use of high performance liquid chromatography, TE-IL 1 chromatographed as a molecule of 18,000 to 20,000 relative molecular mass, and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, TE-IL 1 migrated at 15,000 to 17,000 Mr. With the use of isoelectrofocusing gels, charge heterogeneity of TE-IL 1 was demonstrated with two major isoelectric points of 5.7 to 5.8 and 6.9 to 7.0. Polyclonal antibody to human monocyte IL 1 markedly inhibited the TE-IL 1 activity. In indirect immunofluorescence assay of frozen human thymic sections, rabbit anti-IL 1 antibody reacted with epithelial cells in human thymic cortex and medulla. Furthermore, high performance liquid chromatography-purified TE-IL 1 augmented human thymocyte proliferation to suboptimal concentrations of phytohemagglutinin. Thus, thymic epithelial cells are capable of providing an intrathymic source of IL 1-like cytokine (TE-IL 1), which affects thymocyte proliferation. We propose that TE-IL 1 may play an important role in intrathymic proliferation and differentiation of human thymocytes.     

Antigen presenting ability of thymic macrophages and epithelial cells: evidence for defects in the antigen processing function of thymic epithelial cells

We compared the antigen presenting ability of cloned thymic macrophage and epithelial cell lines using T cell hybridomas with well-characterized activation requirements. A cloned thymic epithelial cell line (3D.1), preinduced with interferon-gamma (IFN-gamma) activated the T cell hybridoma 3DO-18.3 but not the T cell hybridoma DO-11.10. Analyses using preprocessed antigen suggest that the failure of 3D.1 to activate DO-11.10 is due to its inability to process chicken ovalbumin to produce a peptide recognized by the Ag:MHC T cell receptor of DO-11.10. The epithelial cell line 3D.1 was able to activate DO-11.10 if the superantigen staphylococcal enterotoxin B was used for activation instead of ovalbumin. These observations indicate that IFN-gamma-induced 3D.1 expresses sufficient I-Ad molecules to activate DO-11.10 but is unable to produce the peptide of ovalbumin recognized by DO-11.10. Furthermore, 3D.1 appears to be representative of nonmacrophage thymic stromal cells cultured in vitro, since heterogeneous cultures containing epithelial cells exhibited the same selective T cell activation characteristics. In contrast, thymic macrophage cell lines activated all T cells studied. These results suggest that there is a functional difference between the capacity of thymic epithelial cells and macrophages to process and present antigen to T cells.     

Epidermal growth factor promotes a neural phenotype in thymic epithelial cells and enhances neuropoietic cytokine expression

Neural crest-derived cells populate the thymus, and their coexistence with epithelial cells is required for proper organ development and T cell education function. We show here that epidermal growth factor (EGF), a major epithelial cell growth-enhancing agent, has a morphogenetic action to promote the expression of a neuronal phenotype (e.g., neurofilament expression) in cultured thymic epithelial cells that are characterized by a cytokeratin-positive epithelial cell background. The proliferation of such neurodifferentiated cells is also enhanced by EGF. Furthermore, the growth factor enhances cells that express the genes encoding the preprotachykinin A-generated neuropeptides and bipotential neuropoietic and lymphopoietic cytokines ciliary neurotrophic factor and interleukin-6. These cytokines also enhance the neuronal phenotype of thymic epithelial cells. Therefore, EGF appears to be a composite autocrine/paracrine neuromodulator in thymic stroma. This suggests that EGF may regulate thymus-dependent immune functions by promoting neuronal gene expression in neural crest- derived cells.     

Presence of glucocorticoid receptors in cultured thymic epithelial cells

We investigated the presence of glucocorticoid receptors (GC) in human thymic epithelial cells grown in primary cultures and in a pure epithelial rat cell line. These GR levels were compared to those determined concomitantly in fresh human thymocytes. The average number of sites were 54,457/cell for males (n = 8) and 58,224/cell for females (n = 8) with mean Kd values of 1.5 and 1.7 X 10(-8) M, respectively, in cultured human epithelial cells. These results are comparable to those obtained for rat thymic epithelial cells. Competition experiments showed that the relative affinities of the steroids tested were in decreasing order: dexamethasone greater than progesterone greater than testosterone and estradiol. This observation is compatible with binding to physiological GR. Moreover, the mean GR value appeared to be approximately 10 times higher for human thymic epithelial cells than for thymocytes. Thus, human epithelial cells as well as thymocytes should be considered as a specific target for glucocorticoid hormones.     

Long-term proliferation of mouse thymic epithelial cells in culture

Summary Epithelial cells from the normal mouse thymus were successfully cultivated on tissue culture plastic when plated with lethally irradiated support cells of the LA7 rat mammary tumor line. As the irradiated LA7 cells slowly decreased in number the thymus cells proliferated concomitantly to form a confluent monolayer. The cells now in culture have been subcultured 8 times, have doubled in number at least 30 times, and are still proliferating vigorously. The culture technique also supported clonal growth from a single cell, and nine clones have been isolated. The colony-forming efficiency of thymic cells plated at low concentrations was about 8%. These cultures were never overgrown by fibroblasts. The thymus cells were characterized as epithelial by the presence of cytoplasmic keratin and numerous desmosomes and tonofilaments. They were shown to be mouse cells by immunocytochemistry with species specific antibodies, by isoenzyme analysis, and by karyology. The cells stained when reacted with antibodies to tubulin, vimentin, and actin, but not with antibodies to Thy-1.2, Lyt-1, Lyt-2, Ia, or H-2 proteins. More than 85% of the cells had a normal mouse diploid chromosome number of 40. This culture technique opens the way for future studies of T-cell education with homogeneous thymic epithelial cell populations both in vitro and after reimplantation into genetically defined strains of mice. This work was supported by the Veterans Administration, Washington, D.C.     

Monoclonal antibodies reactive with subsets of mouse and human thymic epithelial cells

We describe monoclonal antibodies (MAB) reactive with subsets of mouse and human thymic epithelial cells. Rat MAb CDR1 reacts with mouse but not human cortical epithelial cells. Immunologic staining of thymic nurse cells in suspension indicates the CDR1 antigen is located on the cell surface. Mouse MAb CDR2 reacts with human but not mouse cortical thymic epithelial cells. Rat MAb MD1 and MD2 detect different determinants expressed by most medullary epithelial cells in mouse thymus but fewer such cells in human thymus. In addition, MD1 detects flattened subcapsular cells rarely in mouse thymus but frequently in human thymus. Two-color stains using an anti-keratin antiserum demonstrate the epithelial nature of the cells reactive with these antibodies. The antigens detected by CDR1 and MD1 first appear during the neonatal period, achieving adult distribution by postnatal days 14 and 4, respectively. The extra-thymic staining of these MAb is described. On the basis of their intra- and extra-thymic reactivities, these MAb differ from those previously reported and may permit dissection of the thymic microenvironment.     

Normal thymic cortical epithelial cells developmentally regulate the expression of a B-lineage transformation-associated antigen

Nonlymphoid, stromal cells in the mouse thymus are believed to be important in T cell maturation and have been proposed to play a central role in the acquisition of major histocompatibility complex (MHC) restriction and self-tolerance by maturing thymocytes. Both cortical and medullary epithelial cells in the thymus express high levels of class II (A) major histocompatibility antigens (MHC Ags). We show here that a specific subset of these A^– epithelial cells express a transformation-associated antigen (6C3Ag) found previously on the surfaces of Abelson murine leukemia virus-transformed pre-B cells and on those bone marrow-derived stromal cell clones which support normal and preneoplastic pre-B cell proliferation. Among solid lymphoid organs, only the thymus contains 6C3Ag¹ cells and within the thymus, this antigen is found exclusively on A^– epithelial cells in cortical regions. It is striking that the expression of the 6C3Ag on thymic epithelium is developmentally regulated, suggesting a role for this lymphostromal antigen in the maturation of the thymic microenvironment.     

Nerve growth factor stimulates proliferation, adhesion and thymopoietic cytokine expression in mouse thymic epithelial cells in vitro

Thymic epithelial cells, which constitute a major component of the thymic microenvironment, provide a crucial signal for intrathymic T cell development and selection. Neuroimmune networks in the thymic microenvironment are thought to be involved in the regulation of T cell development. NGF is increasingly recognized as a potent immunomodulator, promoting “cross-talk” between various types of immune system cells. The present study clearly shows that NGF stimulates mouse thymic epithelial cell activities in vitro including cell proliferation, thymocyte adhesion to thymic epithelial cells, and the expression of cell adhesion molecules such as ICAM-1 and VCAM-1, and thymopoietic factors including IL-7, GM-CSF, SDF-1, TARC and TECK. Thus, our data are of considerable clinical importance showing that trophic NGF activity could be used to enhance the thymus regeneration and develop methods to improve host immunity when the immune function is depressed due to thymic involution.     

Synergistic induction of interleukin-6 production and gene expression in human thymic epithelial cells by LPS and cytokines

We examined the ability of LPS and several cytokines (TNF-alpha, IL-1-beta, IFN-gamma, IL-4) to modulate IL-6 production by cultured human thymic epithelial cells (TEC). IL-6 activity was measured by the hybridoma growth factor biological activity. Moderate but detectable IL-6 activity was spontaneously produced in the presence of serum proteins. LPS as well as the cytokines TNF-alpha and IL-1-beta was a potent inducer of IL-6, increasing, respectively, IL-6 levels by 9-, 28-, and 75-fold (mean values) while IL-4 and IFN-gamma provoked no significant effect. Interestingly, clearly different kinetics were observed for IL-6 induction by the various activation agents, the maximal effect being reached at 24, 48, and 72 hr, respectively for LPS, TNF-alpha, and IL-1-beta. Moreover, a synergistic effect of TNF-alpha and either LPS or IL-1-beta was observed. Indeed, TEC incubated with the cytokines in combination at optimal doses produced 5- to 170-fold more IL-6 than TEC stimulated with the cytokines individually. Neutralizing anti-IL-6 polyclonal and monoclonal antibodies completely blocked hybridoma proliferation stimulating activity of TEC supernatants; thus, implying that this activity is essentially due to IL-6. In situ hybridization analysis of cytocentrifuged TEC with an mRNA antisense probe specific for human IL-6 and labeled with 35S demonstrated that up to 90% of TEC could be induced to express the IL-6 gene. Computer-aided quantification of IL-6 mRNA levels indicated that upon stimulation with TNF-alpha combined to LPS, both the numbers of cells expressing IL-6 mRNA and the amounts of cytoplasmic IL-6 mRNA per cell were increased. Taken altogether these results demonstrate that LPS and/or cytokines can modulate and synergistically stimulate IL-6 production. In addition to a possible role in regulating normal thymic T cell activation, the IL-6 produced by TEC could be of pathophysiological relevance in disregulated situations such as in hyperplastic thymuses from patients with myasthenia gravis.     

Effects of PAMK on lncRNA,miRNA, and mRNA expression profiles of thymic epithelial cells

Functional & Integrative Genomics - Polysaccharides from Atractylodes macrocephala Koidz (PAMK) can promote the proliferation of thymocytes and improve the body’s immunity. However, the...     

Effects of cytokines on human thymic epithelial cells in culture: IL1 induces thymic epithelial cell proliferation and change in morphology

The role of thymic epithelium in T cell development has given rise to a number of studies, but less information is available concerning the factors regulating thymic epithelial cells (TEC) themselves. Several cytokines, natural or recombinant, were investigated for their effects on human TEC proliferation. This study presents evidence for the first time that human recombinant interleukin 1 (IL1) and IL1-containing mixed cytokine preparations induced DNA synthesis of TEC as measured in a 48-hr stimulation assay. The effects of IL1 were dose dependent and sustained in time. The following recombinant cytokines, IL2, IL3, IL4, interferon-gamma (IFN-gamma), IFN-alpha, tumor necrosis factor-alpha (TNF alpha), and TNF beta, as well as thymosin fraction 5 and Escherichia coli lipopolysaccharide (LPS), were not found to modify TEC proliferation but IFN-gamma and TNF alpha enhanced the effects of IL1. We also report that IL1 induced a profound change in the morphology of TEC. Our observations suggest that TEC are targets for the action of cytokines and emphasize the important role played by IL1 within the thymus.     

Consequences of interactions between thymic lymphoid and epithelial cells in vitro

A 24-hour co-cultivation of thymocytes and epithelial cells taken from human thymus results in mutual activation of epitheliocytes and thymocytes, as well as in apoptosis of thymocytes. The apoptosis can also be induced by a cultural supernatant of the thymic-epithelial cells, its level being lower, however, than in the co-culture. Thymocyte death and elimination develop faster in a co-culture with allogeneic thymic epithelial cells.