Heterogeneity of rat thymic epithelium defined by monoclonal anti-keratin antibodies

Immunohistochemical characterization of rat TEC has been studied using a panel of monoclonal anti-keratin antibodies. These mAbs identified three distinct patterns of keratin subunit expression within thymic epithelium assessed by streptavidin-biotin immunoperoxidase staining and double immunofluorescence staining. K8 and KII mAbs labelled almost all epithelium, while K18 stained cortical epithelium and a subpopulation of medullary TEC. KI, K7 and K19 mAbs bound to the subcapsular/subtrabecular flat epithelial cell layer, TEC lining some perivascular spaces in the cortex, a subpopulation of medullary TEC and interstitial epithelial cystic structures. Double immunostaining revealed further heterogeneity of subunit keratin compositions in epithelial cells of particular thymic microenvironments suggesting their different origin or development stage.     

Cytoskeletal proteins in thymic epithelial cells of the Australian lungfish Neoceratodus forsteri

The vertebrate thymus consists of distinctive subpopulations of epithelial cells that contain a diverse repertoire of cytoskeletal proteins. In this study of the thymus in the Australian lungfish, Neoceratodus forsteri , immunohistochemistry was used to distinguish the cytoskeletal proteins present in each class of thymic epithelial cell. A panel of antibodies (Abs), each specific for a different cytoskeletal polypeptide (keratins, vimentin, desmin, actin and tubulins), was used on paraffin and ultrathin resin sections of thymus. Ab AE I (reactive against human type I cytokeratins (CK) 14, 16 and 19) selectively stained the cytoplasm of capsular, trabecular and the outermost epithelial cells of Hassall's corpuscles. Anti-CK 10 Abs strongly labelled the capsular epithelial cells and less than 20% of cortical and medullary epithelial cells. The anti-50-kDa desmin Ab did not react with any thymic cells, whereas the anti-53-kDa desmin Ab labelled some capsular, cortical and medullary thymic epithelial cells. The anti-vimentin Ab stained most of the capsular and ~60% of the cortical epithelium. Thymic nurse cells and Hassall's corpuscles were found to be devoid of actin, which was strongly detected in medullary and perivascular epithelium. Both α and β tubulins were detected in all thymic cells. This study extends the concept of thymic epithelial heterogeneity. The complexity of thymic epithelium in N. forsteri may indicate a relationship between thymic epithelial subpopulations and the thymic microenvironment. These data identify anti-keratin Abs as a valuable tool for studying differentiation and ontogeny of the thymic epithelium in N. forsteri .     

In vitro growth and phenotypic characterization of mesodermal-derived and epithelial components of normal and abnormal human thymus

Long-term in vitro cultures of human thymic tissue were established and phenotypically characterized using monoclonal reagents that define distinct components of the human thymic microenvironment. The epithelial component of the thymus, defined by monoclonal antibodies TE-3, TE-4, BBTECS, and AE1 (anti-keratin) was isolated from the mesodermal component, defined by antibody TE-7, and maintained separately in long-term culture. The epithelial cells were subcultured repeatedly and recovered from storage in liquid nitrogen. The in vitro phenotype of the cultured cells was compared to that of cultured human epidermal cells. A subpopulation of cultured thymic epithelial cells along with a subpopulation of cultured epidermal cells expressed antigens (TE-8, TE-15) characteristic of late stages of keratinized epithelial cell differentiation. Thus, we have established a system whereby components of the human thymic microenvironment can be cultivated in vitro while maintaining the capacity to differentiate. This approach can be used to evaluate the role of components of the thymic microenvironment at various stages of differentiation on developing T lymphocytes. In addition, keratin-containing thymic epithelial cells were successfully cultured from thymuses obtained from patients with myasthenia gravis and thymoma. Cultivation of abnormal thymic epithelium will provide insight into aberrant T lymphocyte-thymic epithelial interaction.     

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.     

Immunohistochemical staining patterns of keratins in normal oesophageal epithelium and carcinoma of the oesophagus

To clarify the keratin staining patterns of invasive carcinoma of the oesophagus, 22 cases of formalin-fixed paraffin-embedded surgical specimens were examined immunohistochemically with the labelled streptavidin biotin method using a panel of six different monoclonal anti-keratin antibodies. The antibody reacted adequately when antigen was retrieved in a microwave oven, and the relationship between morphological characteristics and keratin reaction patterns was analyzed in carcinomas and compared with adjacent histologically normal epithelium. In the normal oesophageal epithelium, AE3 and CK8.12 labelled all layer of cells, KS-1A3, E3 and KL1 labelled suprabasal cells, and LL002 selectively labelled the basal cells. In squamous cell carcinomas, AE3, CK8.12, KL1 and LL002 labelled almost all the tumour cells regardless of their differentiation, E3 only labelled keratinized cells, while marked decrease or loss of KS-1A3 staining was seen in all cases examined. Therefore, the characteristic profile of squamous cell carcinoma was a strong and diffuse expression of keratin 14 and 16, strong but localized expression of keratin 17, and loss of keratin 13 expression. Undifferentiated carcinoma totally lacked all keratin reactivity. The findings suggested that the neoplastic epithelial cells showed different keratin reactivity and distribution compared to normal oesophageal epithelium. In addition, histologically normal epithelium, dysplasia and carcinoma-in-situ adjacent to or overlying carcinoma expressed keratin 14.     

A Common Stem Cell for Murine Cortical and Medullary Thymic Epithelial Cells?

We have addressed the question whether the epithelial stroma in the thymus is derived from a common stem cell or whether cortical and medullary epithelial cells are derived from different embryonic stem cells emerging, for example, from endoderm and ectoderm. By the use of rapidly expanding cultures of thymic epithelial cells (TEC) from 14 to 16 day-old murine fetuses and by specific antibodies against cortical and medullary epithelium, respectively, we were able to demonstrate a small subpopulation of double-labeled TEC in the cultures. These cells were not present in TEC cultures initiated from thymuses of neonatal mice. Double-labeled TEC were also found in tissue sections from fetal thymuses. These findings may indicate that TEC populations of the cortex and the medulla are derived from a common stem cell, with potential for differentiation toward both cortical and medullary TEC.     

The effect of cyclosporine on murine thymic epithelial cells--an immunohistochemical study

The authors recently demonstrated that cyclosporine (CsA) treatment of mice caused a remarkable reduction of L3T4+Lyt-2- subset in the thymocytes as well as the striking decrease in the size and cellularity of the thymic medulla. To elucidate the underlying mechanism of such thymic alterations, an immunohistochemical study on the thymic epithelial cells was made in mice receiving CsA. In the medulla, a marked reduction of Ia-positive, keratin positive and Ulex europeus agglutinin 1 (UEA 1) binding epithelial cells was observed. CsA also induced a reduction of anti-keratin stainability of cortical epithelial cells and of Ia antigen expression by them. The results of this study indicate that CsA is not only directly impair thymocyte function but also may act on epithelial cells in the thymus. It is suggestive that CsA may affect T cell differentiation and maturation via alteration of Ia-positive thymic epithelial cells.     

Epithelial proliferation in thymic hyperplasia. An immunohistochemical study and correlation with the developing fetal thymus

Thymic hyperplasia is a B-cell lymphoid proliferation in which an epithelial component has not, to our knowledge, been previously described. We present a case of thymic hyperplasia in which numerous lymphoid follicles with germinal centers were partially surrounded by small sheets of spindle and epithelioid cells. Electron microscopy confirmed the epithelial nature of these cells. Immunostaining was performed using antibodies to keratins, S100 protein, and two B-cell markers, LN1 and MB2. The proliferated epithelium stained only for high-molecular-weight keratin, whereas the lymphoid tissue stained positively for both B-cell markers. To determine the origin of the proliferated epithelium, the staining was compared with that of the developing fetal and normal adult thymus. We have shown that during fetal development, the keratin composition of thymic epithelium changes from staining predominantly with low- to high-molecular-weight keratin. The immunostaining characteristics of the epithelium in this case of thymic hyperplasia suggest an origin from adult-type epithelium. Furthermore, the association of S100-positive interdigitating reticulum cells with the proliferated epithelium suggests that it is of medullary origin. Our results indicate that epithelial proliferation can be an important component of thymic hyperplasia.     

Expression of cell cycle and apoptosis regulators in thymus and thymic epithelial tumors

The human thymus supports the production of self-tolerant T cells with competent and regulatory functions. Various cellular components of the thymic microenvironment such as thymic epithelial cells (TEC) and dendritic cells play essential roles in thymic T cell differentiation. The multiple cellular events occurring during thymic T cell and TEC differentiation involve proteins regulating cell cycle and apoptosis. Dysregulation of the cell cycle and apoptosis networks is involved in the pathogenesis of thymic epithelial tumors (TET) which are divided into two broad categories, thymomas and thymic carcinomas. The present review focuses on the usefulness of the analysis of the expression patterns of major cell cycle and apoptosis regulators in order to gain insight in the histophysiology of thymus and the histopathology, the clinical behavior and the biology of TET.     

Anergy induced by thymic medullary epithelium.

Thymocytes can be rendered tolerant by non-deletional mechanisms upon interaction with major histocompatibility complex (MHC) antigens on thymic epithelium. Whether the epithelial cells in the cortex or medulla could mediate this effect was not clear so far. To address this question, a transgenic mouse was generated in which the bovine keratin IV promoter was used to control expression of the alloantigen Kb. In the periphery the Kb transgene was expressed on a subset of keratinocytes. In the thymus expression was restricted to a subpopulation of medullary epithelial cells. No expression was found in the cortex. Such a tissue distribution has been reported for the keratin IV molecule demonstrating the faithfulness of the promoter used here. To follow the fate of the Kb-reactive thymocytes, this mouse was mated with another transgenic mouse expressing an anti-Kb T cell receptor (TcR). In the double-transgenic mice the CD8+CD4- thymocytes were not deleted but they were found to be anergic as assayed by their failure to be activated in vitro by either Kb-positive spleen cells or by cross-linked anti-TcR antibodies. These observations establish that expression of an MHC class I antigen in the thymic medullary epithelium is sufficient to induce anergy in the mature CD8+CD4- thymocyte population.     

Interspecies differences in expression of cytokeratin polypeptides within thymic epithelium: a comparative immunohistochemical study.

Cytokeratin (CK) polypeptide expression within the thymic epithelium of several mammalian species (mouse, rat, calf, pig, rabbit, and human) has been analyzed by the streptavidin-biotin immunoperoxidase method. Comparative analysis by a large panel of 17 monoclonal antibodies (mAbs) specific for individual CK polypeptides, pairs, or groups showed considerable heterogeneity of thymic epithelial cells (TEC) in each species. In addition, extreme interspecies difference in CK contents was observed. Four main phenotypic zones: the subcapsule/perivascular area, cortex, medulla, and Hassall's corpuscles (HC) were clearly identified, each characterized by different CK expression. Medullary TEC were more heterogenous and shared common CK polypeptides either with subcapsular/perivascular TEC, cortical TEC, or HC, in most species.     

Rat thymic epithelial cells in culture constitutively secrete IL-1 and IL-6.

To study the in vitro interactions between rat thymic non-lymphoid cells and thymocytes, we established a system for long-term cultivation of thymic epithelial cells (TEC). TEC were cultivated and successfully propagated for over 8 months in RPMI 1640 medium containing 15% FCS, dexamethasone, insulin, epidermal growth factor, and poly-L-lysin as an adhesive matrix. Their epithelial nature has been confirmed using monoclonal anti-cytokeratin (CK) antibodies. More than 95% of these cells were reactive with K 8.13 and CK 8 mAbs, which are pan-epithelial markers for rat TEC in situ. An epithelial cell clone (TE-R 2.5) established from a long-term TEC culture was 100% reactive with these anti-CK antibodies. Phenotypic analysis of TEC cultures was performed by a large panel of mAbs reactive with a subset of rat TEC or CK polypeptides as well as UIex europaeus agglutinin I using a streptavidin-biotin immunofluorescence assay. Although the results obtained demonstrated phenotypic heterogeneity among these cells, most cultures, including the TE-R 2.5 clone, were of subcapsular/medullary phenotype. Medium conditioned by TEC cultures exhibited IL-1 and IL-6 activities when tested on D10S and B9 sensitive cell lines, respectively. Cytokine activities were neutralized (IL-1) or significantly inhibited (IL-6) by specific polyclonal antibodies. In addition, both anti-IL-1 and anti-IL-6 antibodies reacted with TEC in culture and epithelial (CK-positive) cells on thymic cryostat sections, indicating that thymic epithelium provides an important intrathymic source for molecules contributing to T cell activation.     

Epithelial cell markers and proliferating cells in odontogenic jaw cysts

The expression of keratins, CEA, EMA, and rat liver antigen (RLA) and the presence of Ki67+ proliferating cells were studied in the epithelial linings of 50 odontogenic cysts using an indirect immunoperoxidase method on acetone-fixed frozen sections. All cysts were positive with monoclonal antibodies of broad keratin specificity (CK1, AE1-3), and between 40 and 100 per cent of epithelial cells expressed keratins 13 and 19. Keratins 7, 8, and 18 were rarely expressed although surface cells in areas of mucous metaplasia often expressed keratins 7 and 18. Expression of keratin 10/11 was related to the presence of a well-ordered epithelial lining and was detected in isolated cells in 4/32 non-keratinizing cysts and in the upper suprabasal cell layers of 17/18 keratocysts. Although CEA, EMA, and RLA were detected in the epithelium of all specimens, the pattern of expression of CEA and EMA differed between cyst types. Ki67+ proliferating cells were most prevalent in keratocyst epithelia, where they were usually found within lower suprabasal layers which were negative or weakly positive for keratins 10/11 and 13. These results indicate differences in keratin, CEA, and EMA expression between cyst types which appear to be dependent on epithelial differentiation/structure rather than cyst type or histogenesis. Although these differences may not be of diagnostic significance, the consistent expression of both keratins 13 and 19 may provide a useful marker of odontogenic epithelium in general.     

Immunohistochemical investigation of different cytokeratins and vimentin in the prostate from the fetal period up to adulthood and in prostate carcinoma

From the fetal period up to puberty the immature epithelium of the prostate glands, the prostatic ducts, the ejaculatory ducts and the seminal vesicles as well as the urothelium of the prostatic urethra are extensively positive for different keratin antibodies (antibody against keratins from human stratum corneum, broadly reacting antibody "AE1 and AE" and antibodies against the keratins 7, 8, 18 and 19) immunohistochemically. The epithelium of the ejaculatory ducts and seminal vesicles in addition regularly exprimates vimentin which is found in the epithelium of the prostate glands focally. During puberty, the immature epithelium of the prostate glands differentiates into the two cell types basal cell and secretory epithelium which differ immunohistochemically: Keratins from human stratum corneum are exclusively demonstrable in the basal cells, the keratins 8 and 18 only in the secretory epithelium. For keratin 7, 19 and the antibody "AE1 and AE3" both cell types are positive. Keratin 7 is demonstrable only focally. The secretory epithelium partly co-exprimates keratins and vimentin. Prostatic carcinomas of different grades virtually contain no keratins from stratum corneum. All other keratins are found in variable extension in the vast majority of the tumors independent of the differentiation. Vimentin is positive mostly focally in about 50% of the tumors. Prostatic carcinoma and the secretory epithelium of the prostate glands share identical immunohistochemical features and differ from the basal cell by several markers. This indicates that prostatic carcinoma rather derives directly from the secretory epithelium than from the basal cell.     

The human thymus microenvironment: heterogeneity detected by monoclonal anti-epithelial cell antibodies.

Monoclonal antibodies were raised against human thymus stromal cells and their specificity for the epithelial component of thymus stroma assessed by double immunofluorescence using anti-keratin antibodies to identify epithelium. Our monoclonal antibodies identify six distinct patterns of epithelial cell antigen expression within the thymus: pan epithelial (antibody IP1); cortex (MR3 and MR6); cortical/medullary junction (IP2); subcapsule and subpopulation of medulla (MR10/MR14); Hassall's corpuscles and adjacent subpopulation of medulla (IP3); Hassall's corpuscles only (MR13/IP4). This heterogeneity of antigen expression suggests that many different epithelial microenvironments exist within the human thymus.     

The epithelial framework of the thymus in normal and pathological conditions

Summary Autopsy specimens of normal human thymus, from cases of accidental involution, follicular hyperplasia, thymomas and a teratoma were investigated by immunocytochemistry using specific immune sera to small and large keratins. Keratin antisera represent a marker of both Hassall's corpuscles (HC) and so-called epithelial reticular cells. There were no apparent differences in keratin polypeptides distribution between cortical and medullary thymic epithelial cells. In accidental involution, the epithelial framework became prominent: epithelial cortical borders and epithelial perivascular sheaths appeared often to be discontinous structures. The central and occasionally cystic spaces of HC did not react with keratin antisera. In follicular hyperplasia, almost solid epithelial aggregates were seen which were located around germinal centers. In thymic tumours, neoplastic epithelial cells displayed a marked immunorectivity with keratin antisera. Immune sera against keratin filaments represent an interesting tool in thymus research and in the diagnostic pathology of thymic tumours.Dedicated to Professor Dr. G. Seifert on the occasion of his 60th birthdayThis study was supported by a grant from the Deutsche Forschungsgemeinschaft (Lo 285/2-1; Ot 53/4-7)     

Ontogeny of rat thymic epithelium defined by monoclonal anticytokeratin antibodies.

Ontogenetic study on the expression of cytokeratin (CK) polypeptides within particular subsets of rat thymic epithelial cells (TEC) has been performed by a large panel of anti-CK monoclonal antibodies (mAbs) using the streptavidin-biotin immunoperoxidase method. Simultaneous presence of two or more CK subunits in the same TEC has been demonstrated by double immunofluorescence labeling. The obtained results showed that the expression of CK polypeptides in fetal and neonatal thymus differed from the adult patterns. The main difference was observed in expression of CK10, 18, and 19 polypeptides. During fetal ontogeny, CK10 and 18 are markers for most medullary TEC or a subset of medullary TEC, respectively, whereas CK19 is mainly a pan-TEC marker. In the adult animals, they are localized in the cortical and a subset of medullary TEC (CK18), subcapsular/perivascular and some medullary TEC (CK19), or in a subset of medullary TEC and Hasall's corpuscles (HC) (CK10). The switch in their expression in the cortex was observed during the first two weeks of postnatal life.     

Ontogeny of Rat Thymic Epithelium Defined by Monoclonal Anticytokeratin Antibodies

Ontogenetic study on the expression of cytokeratin (CK) polypeptides within particular subsets of rat thymic epithelial cells (TEC) has been performed by a large panel of anti-CK monoclonal antibodies (mAbs) using the streptavidin-biotin immunoperoxidase method. Simultaneous presence of two or more CK subunits in the same TEC has been demonstrated by double immunoflouorescence labeling. The obtained results showed that the expression of CK polypeptides in fetal and neonatal thymus differed from the adult patterns. The main difference was observed in expression of CK10, 18, and 19 polypeptides. During fetal ontogeny, CK10 and 18 are markers for most medullary TEC or a subset of medullary TEC, respectively, whereas CK19 is mainly a pan-TEC marker. In the adult animals, they are localized in the cortical and a subset of medullary TEC (CK18), subcapsular/perivascular and some medullary TEC (CK19), or in a subset of medullary TEC and Hasall’s corpuscles (HC) (CK10). The switch in their expression in the cortex was observed during the first two weeks of postnatal life.     

Calcifying odontogenic cyst immunohistochemical detection of keratin and involucrin in cyst wall

Summary Calcifying odontogenic cysts (COC) were immunohistochemically described using different keratin proteins and involucrin as well as histopathology. The cystic lining epithelium was composed of calcifying, keratinizing, squamous, and columnar epithelial cells, and included calcified masses of irregular shape and various size as well as ghost cells. Calcifying epithelium gave negative or only trace staining for keratins detected with low molecular keratin (PKK1), but were regularly positive with high molecular keratin (KL1) and polyclonal antibody for keratin (TK). They were occasionally positive for involucrin. The cells located in the periphery of the calcified masses had a particular abundance of high molecular weight and total keratins (KL1 and TK). Calcified bodies and ghost cells were devoid of any immunoreactivity. Squamous epithelium was relatively similar to that of normal squamous cell epithelium in the oral mucosa. It were most commonly found in columnar cystic epithelial cells which displayed intense staining with all immunoreagents. It is postulated that such epithelial cells may have a strong potentiality to transform into ghost cells or to undergo metaplasia. They may develop altered synthesis of homogenous acellular materials and finally become transformed into calcifying epithelium containing dystrophic calcified masses.     

Phenotypic and ultrastructural characterization of an epithelial cell line established from rat thymic cultures.

An epithelial cell line (TE-R 2.5) was established from a long-term culture of rat thymic epithelium. Its epithelial nature was confirmed using anti-cytokeratin (CK) monoclonal antibodies (mAb) and electron-microscopy. TE-R 2.5 cells were reactive with K 8.13, K 8.12, CK 8, R-MC 18, R-MC 19 and Mar 3 mAb and bind Ulex europaeus agglutinin I. Based on the results of this study it was concluded that they possess the phenotype of subcapsular/perivascular or medullary epithelium. This was in accordance with Western blot analysis of water-insoluble cell extracts showing the presence of 56,000, 52,000, 50,000 and 48,000 MW CK polypeptides. In addition, TE-R 2.5 cell line coexpressed CK and vimentin (a 57,000 MW polypeptide) which was demonstrated using dual immunohistochemistry and Western blot analysis. Electron microscopy demonstrated that TE-R 2.5 cells have all the characteristics of hypertrophic thymic epithelial cells (TEC) localized in situ exclusively in the medulla and thus further characterized this line as a type of medullary TEC. Finally, TE-4F10 mAb raised against an antigen of TE-R 2.5 cells selectively stained a subset of medullary TEC in situ including Hassall's corpuscles indicating again the medullary origin of this TEC line.