Localization of basal cell antigen in the epithelial tissues of animals and humans detected by means of natural antibodies

By means of the immunofluorescent method using rabbit serum that contains natural antibodies against the basal cell antigen of epidermis, the distribution of the antigen has been demonstrated in cells of the basal layer of all types of the stratified epithelium. The reaction is also noted in cytoplasm of the epithelial cells in the thymus and the tracheal mucous membrane. This demonstrates their histogenic affinity to stratified epithelii. The antigen studied is not species-specific, since it is revealed in the stratified epithelium of all species examined (human being, mouse, rat, guinea pig, rabbit). It is possible to use the basal cell antigen as a marker for immunomorphological reveal of epithelial cells in the thymus in the process of its physiological and pathological involution.     

Immunological changes in the thymus epithelial tissue of mice during accidental involution

Using sera containing antibodies to antigens of epithelial reticular cells it is possible to detect by immunofluorescence early stages of organ accidental involution and to trace parenchyma demasking that results from lymphocyte migration upon injection of prednisolone, azathioprin or their combinations. Prior to the drug administration only certain short thin processes of epithelial cells masked by a great number of lymphoid elements are detectable in the cortical zone of the thymus. Injection of 10-40 mg/kg prednisolone, 100-200 mg/kg azathioprin or their combinations causes stable different-degree demasking of the epithelial reticulum seen during immunofluorescence as a network of fluorescent processes. Administration of drug combinations also causes marked attenuation of the reaction, probably resulting from dystrophic changes in thymic epithelial cells.     

Cell death by apoptosis during involution of the lactating breast in mice and rats

The role of cell death in involution of lactating breast was investigated in mice and rats by light and electron microscopy. Apoptosis, recognized by sharply demarcated compaction of chromatin against the nuclear envelope and by shrinkage and budding of the whole cell to form membrane-bounded apoptotic bodies, was responsible for major loss of cells in both species. In the mouse, rapid involution during the first 2 days was associated with shedding of large numbers of apoptotic bodies derived from alveolar epithelial cells into alveolar lumens. This was followed by more gradual regression, during which the bodies were mostly phagocytosed by macrophages within the epithelium. In the rat, glandular involution was a more gradual and uniform process, with shedding of apoptotic epithelial cells into alveolar lumens being much less conspicuous. Apoptosis of myoepithelial cells was observed in mice, the resulting apoptotic bodies being phagocytosed by intraepithelial macrophages, but was not detected in rats. Apoptosis of capillary endothelial cells caused rapid regression of the capillary beds in both mice and rats. Intraepithelial macrophages increased in number during involution, developed cytoplasmic lipofuscin pigment, and either remained within the epithelium or migrated to the interstitium and regional nodes. Cell loss by apoptosis has been demonstrated during involution and atrophy of a variety of other glands. It characteristically results in shrinkage of a tissue without disruption of its basic architecture.     

Histological changes of the mouse thymus during involution and regeneration following administration of hydrocortisone

Summary A histological study has been made of the thymus in mice during acute involution and regeneration following administration of hydrocortisone. The cortex undergoes remarkable changes in the microscopic structure during involution and regeneration. During involution the lymphocytes in the cortex rapidly decrease and are removed. Then a rapid replacement of lymphocytes occurs during regeneration. On the basis of formation and repopulation of lymphocytes the regenerative process of the cortex is divided into seven phases. The reconstitution of the cortex proceeds more rapidly in females than in males. Newly formed lymphocytes take origin from the mesenchymal cells in the cortex. Such mesenchymal cells become distinguishable from epithelial reticular cells during involution. They appear to engulf destroyed lymphocytes and debris during involution and then transform into immature lymphoid cells during early regeneration. The findings may support the recent reutilization concept that destroyed lymphocytes are phagocytized and reutilized by reticular cells in heteroplastic differentiation into immature lymphoid cells. In the cortex PAS-positive sudanophilic cells which are derived from the perivascular and subcapsular connective tissue appear with involutionary changes. They become gradually reduced again with progress of the regeneration of the cortex. During involution the medulla are temporarily filled with lymphocytes migrated from the cortex. The epithelial reticular cells in the medulla are found grouped in cords or clumps in the severely involuted thymus. In the medulla there are two types of PAS-positive epithelial reticular cells; one contains a large, colloid-like, PAS-positive inclusion within the cytoplasm and the other has cytoplasm diffusely filled with PAS-positive substance. During involution and early regeneration, the former type increases while the other shows almost no significant changes. Hassall's corpuscles somewhat increase in frequency during involution and early regeneration.     

Seasonal changes in the fine structure of the accessory sex gland in the mole (Talpa europaea)

The mole has a single pair of accessory sex organs with features of both the prostate and the seminal vesicle, for which the term prostate gland is not appropriate. Seasonal changes occuring in this gland were related to four periods: a) the quiescence period, b) the maturation period, c) the active period and d) the involution period. During the quiescence period the cuboidal epithelial cells display a quasi-embryonic fine structure and are sparse in cytoplasmic organelles, but rich in glycogen and lipopigment. With the onset of sexual activity glycogen and lipopigment disappear and the rough endoplasmic reticulum as well as the Golgi apparatus begin to proliferate. The fully active gland is lined by a low epithelium with parallel stacks of rough endoplasmic reticulum, a large Golgi apparatus and several lysosomes and secretory granules. In the involution period the gland collapses and the epithelial cells are eliminated by hetero- and autophagic processes. During this period a great number of presumably endocrine cells were observed. The results were compared with findings in experimental studies and those on postnatal development of accessory sex glands in laboratory animals.     

The thymus in fish: Development and possible function in the immune response

With the exception of Agnatha, fish possess the functional equivalent of the thymus gland found in higher vertebrates. As in other vertebrates, this gland originates from the pharyngeal pouches and ontogenically is the first lymphoid organ to be infiltrated with lymphoid cells. Histology of the structure may differ from one species to another but the cellular component is basically similar. The (paired) gland is surrounded by an epithelial capsule. Within the gland a framework of reticulo-epithelial cells supports the lymphocytes. The age-related involution process, which characterizes the thymus of higher vertebrates, does not necessarily occur in fish. Nevertheless, thymus growth and function may be modulated by those factors that induce its involution such as aging, season, sexual maturity, and stress. The major role played by the thymus in the immune response of higher vertebrates is presumed to occur in fish. Thymus-derived cell dependent immune reactions have been demonstrated in fish. The cells that mediate these functions are designated as T-like cells. So far, cell surface markers equivalent to those of mammalian T lymphocytes have not been characterized. The T lymphocyte specificities are supposed to be acquired within or via the thymic microenvironment. Unfortunately, there is limited data concerned with the cytological and physiological basis of the maturation of thymus-derived cells. Direct involvement of the fish thymus in defense mechanisms has not been investigated extensively. The gland appears to be weakly protected because of its superficial location and is easily exposed to pathogens. Neoplasia is the main pathologic condition reported in the thymus of fish, with little else having been published regarding thymic pathology.     

Acid phosphatase activity and cell death in mouse thymus

Summary The distribution of acid phosphatase activity in the thymus of young (8 week) and old (42 week) mice is presented. In 8 week old mice acid phosphatase positive cells represent 1.27±0.13% of the total population whereas in 42 week old mice, showing involution of the thymus, acid phosphatase positive cells represent 2.40±0.17% of the total population. Loci of free acid phosphatase activity have been interpreted as sites of cell lysis and death. This has been confirmed at electron microscope level where free acid phosphatase has been demonstrated in the cytoplasm of lysing thymic lymphocytes. Vacuolar sites of acid phosphatase activity have been demonstrated in macrophages which appear to dispose of the lymphocytes. Extensive autophagic activity occurs in the epithelial reticular cells. The role of acid phosphatase in thymic lymphocyte deletion and in the tissue dynamics of the thymus is discussed.     

An in vitro morphological study of the mouse visceral yolk sac and possible yolk sac immunocyte precursors

Summary Mouse visceral yolk sac has been organ cultured from 9 days of gestation, a time prior to the thymus being lymphoid, until 12 days of gestation, a time after which the thymus is lymphoid. During the culture period the endodermal epithelial cells survived well, erythropoiesis diminished, endothelial-lined cavities formed in the mesodermal mass, and cells developed which have been classified as large, medium and small immunocyte precursors. The cytoplasm of the immunocyte precursors contains polysomes, spherical mitochondria, a few profiles of rough endoplasmic reticulum, occasional granules and a large Golgi complex. This study offers morphological support for the yolk sac origin of immunocyte precursors in the mouse which may seed the thymus and liver.Supported by NIH Grant AI 13486-01     

Age-related hyperplasia of the thymus and T-cell system in the Buffalo rat

This report describes the development of hyperplasia of both the thymus and the peripheral T-cell system with advancing age in the Buffalo rat. Buffalo/Mna rats do not show age-related thymic involution, but rather develop thymic hyperplasia with advancing age. This thymic growth is expansile and there is no infiltration of the surrounding tissues. Because the enlarging thymus occupies the thoracic cavity, most of the rats die of respiratory failure by the age of 24 months. Thymic enlargement is due to primary hyperplasia of cortical epithelial cells and the large number of proliferating lymphocytes. The hyperplastic epithelial cells are bizarre in shape and strongly positive when stained with Th-3 monoclonal antibody (MoAb), anti-thymosin antibody and anti-EGF antibody, but negative with Th-4 MoAb. The patterns of distribution of CD-5+, CD-4+ and CD-8+ lymphocytes within the hyperplastic thymus are similar to those seen in young rats of other species. The high level of T-cell emigration from the thymus to the periphery appears to persist throughout life, since the percentage of normal splenic T-cells also increase with advancing age and exceed 70% of the total by 24 months of age. This thymic enlargement with abnormal hyperplasia of cortical epithelial cells can be prevented by hypophysectomy.     

Light and electron microscopic study of the normal and pathological thymus of the rat

Summary A combined light- and electron microscopic study of the normal thymus of young-adult, male Osborne-Mendel rats and, to a lesser extent, of young (8 days) and older (7–8 months) animals has been made. The data obtained provide a base line for submicroscopic investigations being in progress of the thymus in pathological conditions (acute involution followed by regeneration and virus-induced tumours). In addition, attention is given to the question whether the various thymic components show morphological signs which could represent secretory activity.Two main types of cells with epithelial characteristics (desmosomes, tonofilaments, basal membrane) are distinguished on the basis of their form, location and cytological features. The reticular type is most frequent in the cortex and contains round, clear structures partly filled with dense and/or membranous material. The cisternae of the endoplasmic reticulum frequently are dilated. The other cell type which only is present in the medulla, shows a more polygonal form. The clear cytoplasm is marked by an abundance of vesicles, golgi complexes and clusters of vacuoles provided with microvilli.The submicroscopic findings in the lymphocytes confirm in general previous reports. The nucleus of the large lymphocytes contains one or two faintly defined nucleoli. The nuclear pores show an inner clear zone with a central knob. The relatively large cytoplasm is studded with polyribosomes; a small band beneath the plasma membrane is devoid of organelles. The chromatin material in the nucleus of the small lymphocytes is condensed at the periphery and in the center; nucleoli are rare. Well developed golgi apparatuses with centrioles are present; multivesicular bodies and lysosomes are not invariably found. The intranuclear formation of mitochondria was never encountered. Interruptions of the cell membrane and cytoplasmic fragmentation are observed. Different phases of the mitotic cycle of the thymocytes are illustrated. Evidence of epithelial cell lymphocyte transformation cannot be given by the study of normal tissue.Mesenchymal reticular cells with or without evident phagocytic activity are described and can be regarded as representing different types.The number of plasma cells increases with age. The endoplasmic cisternae of some of them contain a material which is condensed in a crystalline form and probably represents proteins.The tubular structures which usually are located at the periphery of the thymic lobuli also have been examined. The epithelial cells lining these structures show irregular microvilli and the intracytoplasmic granules as well as the vacuoles and the well developed endoplasmic reticulum are supposed to be signs of a secretory activity. Moderately dense material condensed in a crystalline form is present in the tubular lumina; the significance is not clear, however.Many small cortical bloodvessels are only partly enclosed by epithelial cells and the lymphocytes lie nearly in direct contact with the endothelial basement membrane. These findings are discussed in relation to the existence of a thymus-blood barrier as proposed in other reports.     

The annual involution and regeneration of the thymus in hibernating animals and perspectives of its studies in gerontology and stem cell proliferation

Data on a unique phenomenon of annual involution and neogenesis of thymus gland in hibernating animals are reviewed. In accordance with morphological findings, the annual thymus involution in hibernating animals is close to the age-dependent thymus involution occurring in all mammals once in a lifetime. In opposite, thymus involution in hibernating animals is totally different from the accidental involution. During hibernation, the thymus tissue is substituted by the brown fat tissue. In the spring, thymus gland neogenesis stats with intensive growth of epithelial tissue followed by lymphocyte infiltration and exhaustion of brown tissue. Morphological changes in the thymus gland within the annual cycle were compared with seasonal dynamics of structural and functional changes in peripheral lymphoid organs (spleen, lymphoglandular, peritoneal fluid). A general regularity was observed involving a decreased functional activity of immune cells in autumn, its sharp depression during winter hibernation, and obvious increase in summer with the onset of a season of animal activity. It is supposed that a sharp increase in the tumor necrosis factor (TNF) production observed during short-term awakenings in winter may serve an important link in this unique immune adaptation mechanism. The season changes in cellular TNF secretion suggest a mobilization of protective resources in hibernating animals in autumn and winter, i.e. in seasons when the thymus gland activity is depressed. The annual involution of thymus gland cannot be related to droppings in the environmental or body temperatures, as it comes long before their fall. Additionally, it is not related to ageing, as it occurs already in young hibernating animals. The role of hormones, including melatonine and corticosteroids, in mechanisms regulating thymus gland involution in hibernating animals is discussed.     

Autophagy in the thymic epithelium is dispensable for the development of self-tolerance in a novel mouse model

The thymic epithelium plays critical roles in the positive and negative selection of T cells. Recently, it was proposed that autophagy in thymic epithelial cells is essential for the induction of T cell tolerance to self antigens and thus for the prevention of autoimmune diseases. Here we have tested this hypothesis using mouse models in which autophagy was blocked specifically in epithelial cells expressing keratin 14 (K14), including the precursor of thymic epithelial cells. While the thymic epithelial cells of mice carrying the floxed Atg7 gene (ATG7 f/f) showed a high level of autophagy, as determined by LC3 Western blot analysis and fluorescence detection of the recombinant green fluorescent protein (GFP)-LC3 reporter protein on autophagosomes, autophagy in the thymic epithelium was efficiently suppressed by deletion of the Atg7 gene using the Cre-loxP system (ATG7 f/f K14-Cre). Suppression of autophagy led to the massive accumulation of p62/sequestosome 1 (SQSTM1) in thymic epithelial cells. However, the structure of the thymic epithelium as well as the organization and the size of the thymus were not altered in mutant mice. The ratio of CD4 to CD8-positive T cells, as well as the frequency of activated (CD69+) CD4 T cells in lymphoid organs, did not differ between mice with autophagy-competent and autophagy-deficient thymic epithelium. Inflammatory infiltrating cells, potentially indicative of autoimmune reactions, were present in the liver, lung, and colon of a similar fraction of ATG7 f/f and ATG7 f/f K14-Cre mice. In contrast to previously reported mice, that had received an autophagy-deficient thymus transplant, ATG7 f/f K14-Cre mice did not suffer from autoimmunity-induced weight loss. In summary, the results of this study suggest that autophagy in the thymic epithelium is dispensable for negative selection of autoreactive T cells.     

Autoantibodies to the thymus and skin epithelium in NZB/N mice and (NZBxNZW)F1 hybrids

Antibodies reacting with thymus and skin epithelial cells were revealed by indirect immunofluorescence in sera of NZB/N mice and (NZB X NZW)F1 hybrids (B/W) 1-2 and 4-5 months of age. Similar antibodies were not found in sera of BALB/c mice. The inhibition experiments with DNA have shown that antibodies reacting with the thymus and skin epithelium differ from those reacting with the cellular nucleus. Positive reactions with the epithelium were obtained in all thymus and skin tissue samples of humans, guinea-pigs and NZB/N, B/W and BALB/c mice, including autologous tissues of NZB/N and B/W mice. Thus, antibodies reacting with thymus and skin epithelial tissues belong to autoantibodies. These autoantibodies are revealed during the first month of life before the onset of autoimmune processes. The role of these autoantibodies in the damage of thymus epithelium and the development of immunoregulatory disturbances, typical of autoimmune processes, needs further study.     

Thymic dysfunction in the mutant diabetic (db/db) mouse

Thymic function has been explored in genetically diabetic homozygous C57BL/KsJ (db/db) mice by evaluating their serum thymic factor (FTS) levels with a rosette assay. As previously reported for other autoimmune mice (NZB or MRL/I mice), the age-dependent decline of FTS levels was significantly accelerated in diabetic mice when compared to heterozygous littermates. Furthermore, FTS inhibitory molecules were detected in db/db mouse sera (as early as 10 wk of age) as evaluated by their ability to absorb in vitro the activity of synthetic FTS in the rosette assay, and in vivo for their capacity to induce the disappearance of endogenous FTS when injected into normal mice. These inhibitors were shown to be immunoglobulins. Histologically, the thymus presented an accelerated involution starting with a cortical lymphocytic depletion and an increased number of Hassall's corpuscles. Ultrastructural studies showed alterations in thymic epithelial cells, mainly represented by an increasing number of cytoplasmic vacuoles. By means of indirect immunofluorescence with anti-FTS monoclonal antibodies, it was shown that the number of FTS+ cells was reduced in db/db mouse thymuses: at the age of 22 wk, diabetic mice had 10 times fewer FTS+ cells than heterozygotes of the same age. Taken together, these results indicate important abnormalities in the thymus of diabetic mice. It is possible that the associated lymphocyte dysfunction plays a role in the pathogenesis of the autoimmune disease presented by db/db mice.     

Multinucleate cells in thymus of C3H mice

Summary Multinucleate epithelial cells occur in the thymus of C3H mice. They are poorly differentiated and scarce, but are more numerous in the medulla than in the cortex. Their increase in number with age is particularly significant between the first and the third months especially for cells with a large number of nuclei, and may be related to thymic involution.Viral particles of type C, similar to those described in murine leukemias, are found in mono- and multinucleate medullary epithelial cells.Research supported by grant 10.013 of the Fonds de la Recherche Fondamentale Collective (Brussels)     

The initial age-associated decline in early T-cell progenitors reflects fewer pre-thymic progenitors and altered signals in the bone marrow and thymus microenvironments

Age-related thymus involution results in decreased T-cell production, contributing to increased susceptibility to pathogens and reduced vaccine responsiveness. Elucidating mechanisms underlying thymus involution will inform strategies to restore thymopoiesis with age. The thymus is colonized by circulating bone marrow (BM)-derived thymus seeding progenitors (TSPs) that differentiate into early T-cell progenitors (ETPs). We find that ETP cellularity declines as early as 3 months (3MO) of age in mice. This initial ETP reduction could reflect changes in thymic stromal niches and/or pre-thymic progenitors. Using a multicongenic progenitor transfer approach, we demonstrate that the number of functional TSP/ETP niches does not diminish with age. Instead, the number of pre-thymic lymphoid progenitors in the BM and blood is substantially reduced by 3MO, although their intrinsic ability to seed and differentiate in the thymus is maintained. Additionally, Notch signaling in BM lymphoid progenitors and in ETPs diminishes by 3MO, suggesting reduced niche quality in the BM and thymus contribute to the early decline in ETPs. Together, these findings indicate that diminished BM lymphopoiesis and thymic stromal support contribute to an initial reduction in ETPs in young adulthood, setting the stage for progressive age-associated thymus involution.     

Inhibition of mammary epithelial apoptosis and sustained phosphorylation of Akt/PKB in MMTV-IGF-II transgenic mice

IGF-II is a growth factor implicated in human cancers and animal tumor models. While the mitogenic properties of IGF-II are well documented, its ability to suppress apoptosis in vivo has never been proven. We generated independent MMTV-IGF-II transgenic mice to examine the control of epithelial apoptosis at the morphological, cellular and molecular levels during the physiological event of postlactation mammary involution. Transgenic IGF-II expression was achieved in mammary epithelium and increased IGF-II bioactivity was confirmed by phosphorylation of the insulin receptor substrate-1, a signaling molecule downstream of the type I IGF receptor. IGF-II overexpression induced a delay in mammary involution, as evident by increased mammary gland to body weight ratios and persistence of both functionally intact lobulo-alveoli and mammary epithelial cellularity. The delayed mammary involution resulted from a significant reduction in mammary epithelial apoptosis, and not from increased epithelial proliferation. Recombinant IGF-II pellets implanted into involuting mammary glands of wild-type mice provided further evidence that IGF-II protein inhibited local epithelial apoptosis. At the molecular level, phosphorylated Akt/PKB, but not Erk1 or Erk2, persisted in IGF-II overexpressors and temporally correlated with reduced epithelial apoptosis. Levels of the phosphatase PTEN were unaltered in the transgenic tissue suggesting that the maintenance of Akt/PKB phosphorylation resulted from sustained phosphorylation rather than altered dephosphorylation of PIP-3. Together, this data reveal that IGF-II inhibits apoptosis in vivo and this effect correlates with prolonged phosphorylation of Akt/PKB