Immunophenotype of porcine oviduct epithelial cells during the oestrous cycle: a double-labelling immunohistochemical study

The luminal epithelium of the porcine oviduct is composed of ciliated cells and secretory cells, but it is assumed for several species that under the control of steroid hormones secretory cells are able to be transformed into ciliated cells. In order to better understand such physiological changes during the different stages of the oestrous cycle, we evaluated epithelial cell proliferation together with oestrogen receptor (ER) expression of porcine ampullary oviducts. To identify the immunophenotype of proliferating cells, double immunohistochemistry was performed using anti-chromogranin A antibody (anti-CgA) as the second primary antibody. Anti-CgA, recently shown to be an immunocytochemical marker of ciliated cells of the cow, also labelled specifically the luminal surface of ciliated cells of the pig. Double labelling of sections with the monoclonal antibody MIB-1 against the proliferation-associated nuclear epitope Ki-67 and anti-CgA clearly demonstrates that MIB-1 was selectively localised in the nuclei of secretory cells. Proliferative activity was not observed in CgA-positive ciliated cells in all examined stages of the oestrous cycle. The percentage of Ki-67-positive epithelial cells was higher at pro-oestrus, compared with the other stages of the oestrous cycle. Furthermore, ER immunoreactivity was exclusively detected in the nuclei of the epithelial cells, which were negative for CgA. We conclude, therefore, that oestrogen may induce the initial proliferation of secretory cells and promote the differentiation into ciliated cells.     

Organization of the nematocyst battery in the tentacle of hydra: Arrangement of the complex anchoring junctions between nematocytes,epithelial cells,and basement membrane

Summary Nematocytes (stinging cells) of hydra tentacles are anchored to the basement membrane by peculiar complex junctions in which a flattened tongue of an epithelial cell is interposed between the nematocyte and the basement membrane. In this paper we describe the arrangement of these junctions with emphasis on how they are related to the architecture of the epithelial cell. Each epithelial cell, called a battery cell, harbors 10–20 nematocytes and bears muscle processes that extend along the basement membrane. The epithelial cell component of the complex junction is usually a lateral extension of a muscle process. All nematocytes within a battery cell make junctions with muscle processes of the same (resident) epithelial battery cell despite the presence of numerous muscle processes from adjacent (foreign) cells. Some nematocytes make junctions with several resident processes, spanning the foreign processes to do so. Most junctions reside near the proximal ends of the muscle processes. New findings are reported on the substructure of the junctions. They are composed of aggregates of smaller elements, and the cytoskeleton within the complexes has a pronounced longitudinal organization. These observations are consistent with a suggestion that the complex junctions develop by aggregation of smaller junctional units originating elsewhere on the cells.     

Endoplasmatisches Retikulum und „Sekretkörper“ im Glomerulum-Epithel der Säugerniere

Zusammenfassung Im visceralen Glomerulum-Epithel der Niere von Mensch und Ratte wurden innerhalb erweiterter Cisternen des rauhen ER (Ergastoplasma) bandförmige Kondensate und rundliche oder ovale Sekretkörper beobachtet. Die Sekretkörper sind PAS-positiv und bestehen aus einer dichten, in der Regel durch bestimmte Muster (Linienmuster, Filigranmuster) ausgezeichneten und aus einer weniger dichten, stets homogenen Komponente. Das Linienmuster, möglicherweise auf Lipiden beruhend, dokumentiert einen parakristallinen Ordnungszustand des verdichteten Sekretmateriales. Im Entstehungsmechanismus sind die Sekretkörper der Glomerulumepithelien den Russelschen Körperchen und Eiweißkristallen der Plasmazellen vergleichbar. Die morphologischen Befunde dürfen als Beweis für eine sekretorische Tätigkeit des Glomerulumepithels gewertet werden.In Übereinstimmung mit Farquhar et al. wird angenommen, daß die beschriebenen Cisternen-Kondensate des Glomerulumepithels Vorläufer-Substanzen der Basalmembran darstellen. Unter Einbeziehung von Befunden, welche an intravitalfixierten Glomerula erhoben wurden, wird abschließend das Problem der Basalmembranbildung unter speziellen (Glomerulum, Nephron) und allgemeinen Gesichtspunkten erörtert. Mehrere Argumente sprechen dafür, daß sowohl im Glomerulum als auch an anderen Epithelverbänden das Epithel selbst bei der Produktion der Basalmembran zumindest eine wesentliche Rolle spielt.

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Summary Within large distended cisternae of ergastoplasm in visceral glomerular epithelium from mammalian kidneys dense sheets and round or oval secretory bodies were observed. These secretory bodies are perjodat-reactive and consist of a more dense component, regularly showing a certain pattern (parallel line array or filigran pattern), and a less dense one which is constantly homogeneous. The line pattern, possibly due to lipids, reflects a paracristalline state of the condensed secretory material. Concerning to the development the secretory bodies of the glomerular epithelium can be compared with Russel bodies and protein crystals of plasma cells. The observations must be considered as a proof for an secretory activity of the glomerular epithelium.We agree with Farquhar et al. and suppose that the condensed secretory material within the dilated ergastoplasmic sacs of glomerular epithelium represent precursor substances of the basement membrane. Finally, including some observations of glomerula fixed in vivo, the problems of building of basement membrane is discussed under special (glomerulum, nephron) and general aspects. Several observations suggest that the epithelial cells themselves at least play an important role in the production of the basement membrane as well in the glomerulum as in other epithelial formations.

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Teilweise mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Characterization of mussel gill cells in vivo and in vitro

Mussel gill cells are attractive models in ecotoxicological studies because gills are the first uptake site for many toxicants in the aquatic environment; gill cells are thus often affected by exposure to pollutants. Our aim was to characterize mussel gill cells in vivo and in vitro by using morphological, histochemical and functional end-points. In paraffin sections stained with haematoxylin–eosin, three zones were distinguished in the long central gill filaments: frontal, intermediate and abfrontal. Various types of ciliated cells were present in the frontal zone, and both ciliated and non-ciliated cells were found in the abfrontal zone. The intermediate zone was comprised of flattened endothelial cells. Lipofuscin granules occurred in the three zones in variable amounts, depending on the specimen. Haemocytes were found in the haemolymph sinus of gill filaments. Mucocytes were identified in both frontal and abfrontal zones by means of periodic acid Schiff-alcian blue (PAS-AB) staining. In cryostat sections, succinate dehydrogenase (SDH) activity was mainly found in ciliated cells, whereas neutral lipids and acid-phosphatase-reactive lysosomes were present in all portions of the gill filament, mostly being related to lipofuscin granules. In mussels exposed to 5-bromo-2-deoxyuridine in vivo, proliferating cells were scattered throughout the gill filament. Gill cells (typically 2×10⁷ cells/ml per mussel; 95% viability) were isolated by dissociation with dispase. Gill cell suspensions were heterogeneous: 58% were ciliated epithelial cells (positive for SDH), 42% were non-ciliated cells (including epithelial cells and haemocytes), 2.3% were mucocytes (positive for PAS-AB) and 4.25% were haemocytes (able to phagocytose neutral red-stained zymosan). Gill cell cultures were maintained up to 18 days without changing the culture medium, viability decreasing below 50% at day 18. Primary cultures of mussel gill cells might therefore be useful models for the in vitro assessment of xenobiotic impacts on coastal and estuarine ecosystems.This work was funded by the Spanish Ministry of Science and Technology (project AMB99-0324), by the Basque Government through the Cooperation Fund Aquitaine/Euskadi 2001, by the University of the Basque Country through a grant to Consolidated Research Groups and by the European Commission (BEEP project, contract no. EVK3-CT2000-00025). Amagoia Gómez-Mendikute is the recipient of a predoctoral fellowship from the Spanish Ministry of Education and Culture.     

Innervation of skin glands in the frog

Summary A comparative study was undertaken on the innervation of mucous and granular glands in frog skin. Results obtained by the Falck-Hillarp fluorescence technique and cholinesterase staining indicated that both types of glands receive exclusively adrenergic innervation. Electron microscopy was used to investigate the innervation pattern at the ultrastructural level. The distribution of nerve terminals was found to differ in the two types of glands. In the mucous gland, terminals were found at a distance of about 0.5 m from the basement membrane but never within the gland parenchyma. In the granular gland, the terminals were located between smooth muscle cells and also in direct contact with the secretory epithelium but never outside the basement membrane.This work was carried out in part at King Gustaf V:s Forskningsinstitut, Stockholm, and was supported by a grant from Karolinska Institutet     

The nerve fibres in the basement membrane and related structures in Saccoglossus horsti (Enteropneusta)

Summary The structure of the basement membrane of Saccoglossus horsti has been examined with the electron microscope. The membrane consists of two lamellae each of two layers. An outer amorphous layer 150 nm across and an inner fibrillar layer 1–3 m across. The fibrils of the fibrillar layer are two sizes, the majority are 5–9 nm in diameter and at least 2 m long. The thicker 30 nm fibrils occur in small patches and have striations with a 30 nm period.Within the lamellae of the basement membrane are blood spaces. The only regularly found structures in these spaces are blood particles some 12–16 nm in diameter.Nerve fibres of varying diameters traverse all the layers of basement membrane. These fibres run longitudinally and obliquely through the basement membrane, and emerge amongst the muscle cells inserted into the coelomic side of the membrane. No motor end plates have been seen. Preliminary observations suggest that many of the nerve fibres have no sheath other than the cell membrane of the fibre itself.The muscle cells are attached to the basement membrane by structures that resemble hemidesmosomes. The blood vessels of Saccoglossus have a basement membrane on the lumenal side of the endothelial cell cytoplasm.I wish to thank Professor J. Z. Young, F. R. S. for continuous encouragement and advice. To Dr. R. Newell I am indebted for the collection and identification of the specimens. I am pleased to acknowledge my debt to Dr. R. Bellairs for the use of electron microscope facilities, and to Mrs. J. Hamilton and Mr. R. Moss for skillful technical assistance.     

Histology and ultrastructure of male mullerian gland of Uraeotyphlus narayani (Amphibia: Gymnophiona)

This study reports the anatomy, histology, and ultrastructure of the male Mullerian gland of the caecilian Uraeotyphlus narayani, based on dissections, light microscopic histological and histochemical preparations, and transmission electron microscopic observations. The posterior end of the Mullerian duct and the urinogenital duct of this caecilian join to form a common duct before opening into the cloaca. The boundary of the entire gland has a pleuroperitoneum, followed by smooth muscle fibers and connective tissue. The Mullerian gland is composed of numerous individual tubular glands separated from each other by connective tissue. Each gland has a duct, which joins the central Mullerian duct. The ducts of the tubular glands are also surrounded by abundant connective tissue. The tubular glands differ between the column and the base in regard to the outer boundary and the epithelial organization. The basement membrane of the column is so thick that amoeboid cells may not penetrate it, whereas that around the base of the gland is thin and appears to allow migration of amoeboid cells into and out of the basal aspect of the gland. The epithelium of the column has nonciliated secretory cells with basal nuclei and ciliated nonsecretory cells with apical nuclei. In the epithelium of the base there are secretory cells, ciliated cells, and amoeboid cells. The epithelium of ducts of the tubular glands is formed of ciliated dark cells and microvillated light cells. The epithelium of the central duct is formed of ciliated dark cells also possessing microvilli, ciliated light cells also possessing microvilli, and microvillated light cells that lack cilia. It is regressed during March to June when the testis lobes are in a state of quiescence. The Mullerian gland is active in secretion during July to February when the testis is active in spermatogenesis.     

Regeneration of the respiratory epithelium]

It is very important to clarify the mechanism of the regeneration of the respiratory epithelium in not only Oto-Naso-Laryngology but also in the field of chest medicine and surgery. Because of the experimental study carried out on dogs, involving the curing process of the tracheal anastomosis site, a scanning electron microscopic study showed that after two weeks, ciliated cells could be seen making a thin layer. It took nine weeks or more till the whole tracheal anastomosis site was completely covered by the ciliated epithelial cells. Having reviewed the experimental papers concerning the regeneration of the respiratory epithelium which have been published since 1953, a conclusion has been reached that after the injury of the respiratory mucosa, the existence of the basement membranes remains were covered by the migration of the traditional epithelium from the margin of the wound and four weeks later, the wound was covered by the normal epithelium. It has been stated up until now that the differentiation of the epithelium was covered from basement cells, but in fact, it seems to occur from the secretory cells. This has been demonstrated by the culture process of the respiratory epithelium. From these facts, the cultured respiratory epithelium cells are very important in elucidating carcinogenesis.     

Repair and regeneration of the airway epithelium

Despite an efficient defence system, the airway surface epithelium, in permanent contact with the external milieu, is frequently injured by inhaled pollutants, microorganisms and viruses. The response of the airway surface epithelium to an acute injury includes a succession of cellular events varying from the loss of the surface epithelium integrity to partial shedding of the epithelium or even to complete denudation of the basement membrane. The epithelium has then to repair and regenerate to restore its functions, through several mechanisms including basal cell spreading and migration, followed by proliferation and differentiation of epithelial cells. The cellular and molecular factors involved in wound repair and epithelial regeneration are closely interacting and imply extracellular matrix proteins, matrix metalloproteinases (MMPs) and their inhibitors as well as cytokines and growth factors secreted by airway epithelial and mesenchymal cells. The development of in vitro and in vivo models of airway epithelium wound repair allowed the study of the spatio-temporal modulation of these factors during the different steps of epithelial repair and regeneration. In this context, several studies have demonstrated that the matrix and secretory environment are markedly involved in these mechanisms and that their dysregulation may induce remodelling of the airway mucosa. A better knowledge of the mechanisms involved in airway epithelium regeneration may pave the way to regenerative therapeutics allowing the reconstitution of a functional airway epithelium in numerous respiratory diseases such as asthma, chronic obstructive pulmonary diseases, cystic fibrosis and bronchiolitis.     

Ultrastructural analysis of the pathogenesis of Neisseria gonorrhoeae endometrial infection

We have studied gonococcal infection in human endometrium organ culture and in human primary endometrial epithelial cells using various microscopic techniques including scanning electron microscopy, transmission electron microscopy, bright field light microscopy and laser scanning confocal microscopy. Here we describe the interactions between Neisseria gonorrhoeae and human endometrial luminal epithelial cells at the ultrastructural levels. N. gonorrhoeae attached to cilia but were not observed associated with the plasma membrane of ciliated epithelial cells or internalized into ciliated epithelial cells. N. gonorrhoeae could be found in intracellular vacuoles in secretory epithelial cells. N. gonorrhoeae have diverse interactions with endometrial epithelium. These include intimate association and colocalization with asialoglycoprotein receptor (ASGP-R) and CEACAM, lamellipodia and ruffle formation and colocalization with CR3, and microvillus engagement. These studies indicate that N. gonorrhoeae utilize multiple mechanisms to associate with endometrial epithelial cells and can associate with both ciliated and secretory cells. This diversity is consistent with a role of the endometrium as a transition zone between frequently asymptomatic cervical gonorrhoea and symptomatic pelvic inflammatory disease.     

Quantitative analysis of the distribution of organelles in tobacco pollen tubes: implications for exocytosis and endocytosis

Summary The present study provides the first quantitative analysis on the distribution of organelles in pollen tubes ofNicotiana tabacum L. Organelles were studied on living pollen tubes by means of fluorescence confocal laser scanning microscopy and on cryo-fixed, freeze-substituted and serially sectioned material by electron microscopy. In the tip a 300 nm to 400 nm thick wall was secreted that proximately gradually separated into a wall with an opaque inner side and a more translucent, layered outer side. Tubular endoplasmic reticulum was particularly abundant in the tip of the tube, surrounding the region where secretory vesicles (SV) accumulated. Mitochondria were randomly distributed throughout the cytoplasm, no accumulations were present. Dictyosomes, however, showed an increased abundance at 25–30 m behind the tip. The accumulation of coated pits (CP) in a zone 6–15 m behind the tip identifies this zone as the major site of endocytosis: 50% of all CP occur in this zone. Quantification of exo- and endocytosis showed that only part of the membrane material of the SV can be retrieved after exocytosis. The typical zonation in endocytotic activity may serve to maintain a difference in membrane protein composition between the tip and the tube.     

The structure of the nerve fibre layer and neurocord in the enteropneusts

Summary The nerve fibre layer and the neurocord of the Enteropneusts Saccoglossus horsti, Harrimania kupfferi and Ptychodera flava have been examined with the electron microscope. The nerve fibres vary in diameter between 0.15 to 10 m. The majority of the fibres are of the smaller diameters. The nerve fibre layer is intraepidermal, and is divided by processes running radially from the epithelial cells to the basement membrane that separates the nerve fibre layer from the muscle cells.The cells of origin of these nerve fibres are situated mainly in the innermost layers of the epidermal cells. The nerve fibre profiles contain numerous vesicles of very varied diameter and contents, together with larger granular inclusions that are also found in the nerve cell bodies.Morphologically recognisable synapses are rare, but the majority of fibres are in intimate contact with one another. Sometimes the mass of fibres is divided into bundles by the epithelial cell processes. The majority of giant fibres are situated near to the basement membrane of the neurocord. The giant fibres also have a varied content of vesicles as well as neurofilaments and neurotubules.The central canal in Ptychodera flava and the remnants of the central canal in Saccoglossus horsti are both lined by columnar cells that bear microvilli as well as cilia with the typical 9 + 2 pattern of tubules. Scattered amongst these cells are mucus secreting cells which open into the cavity of the canal.I (P.N.D.) should like to thank Professor J. Z. Young, F. B. S. for much advice and encouragement. Dr. R. Bellairs generously provided the electron microscope facilities, and Dr. R. Newell kindly collected and identified the Saccoglossus specimens. Mr. R. Moss, Mrs. J. Hamilton and Mr. A. Aldrich gave excellent technical and photographic assistance.     

Formation of the basement membrane during regeneration of the corneal epithelium

Summary The epithelium regenerating after a surface lesion of the cornea forms a new basement membrane. This process begins 6–8 days after the lesion when the wound is completely covered, and epithelial cells have ceased to migrate. Only that part of the epithelial cells facing the stroma is involved. First, tufts of fine filamentous structures (about 30 Å thick) appear on the internal side of the plasma membrane, and apparently penetrate it reaching the extracellular space where they form a loose network. This then differentiates into two discrete layers, a very thin discontinuous one, restricted to areas with tufts, very close to the plasma membrane (juxtamembranous layer), and a thick continuous layer, the basement membrane proper, parallel to and much further away from the plasma membrane. The basement membrane appears to be the product of cytoplasmic secretion by epithelial cells, and there is no evidence for connective tissue cells taking part in this process.Supported by the Deutsche Forschungsgemeinschaft.     

Differentiated and functional human airway epithelium regeneration in tracheal xenografts

To investigate the regeneration process of a well-differentiated and functional human airway epithelium, we adapted an in vivo xenograft model in which adult human nasal epithelial cells adhere and progressively repopulate denuded rat tracheae grafted in nude mice. The proliferating activity, the degree of differentiation, and the barrier integrity of the repopulated epithelium were studied during the regeneration process at optical and ultrastructural levels with immunocytochemistry and a permeability tracer. Three days after implantation in nude mice, tracheal xenografts were partially repopulated with a flattened nonciliated and poorly differentiated leaky epithelium. By the end of the first week after the graft, cell proliferation produced on the entire surface of the rat trachea an epithelium that was stratified into multiple layers and tightly sealed. During successive weeks, cell proliferation dramatically decreased. Moreover, the epithelium became progressively columnar, secretory, ciliated, and transiently leaky. At 4-5 wk, a fully differentiated pseudostratified functional epithelial barrier impermeable to a low-molecular-weight tracer was reconstituted. The regeneration of a well-differentiated and functional human airway epithelium in rat tracheae grafted in nude mice includes several steps that mimic the regeneration dynamics of airway epithelium after injury.     

E-cadherin is critical for collective sheet migration and is regulated by the chemokine CXCL12 protein during restitution

Chemokines and other immune mediators enhance epithelial barrier repair. The intestinal barrier is established by highly regulated cell-cell contacts between epithelial cells. The goal of these studies was to define the role for the chemokine CXCL12 in regulating E-cadherin during collective sheet migration during epithelial restitution. Mechanisms regulating E-cadherin were investigated using Caco2(BBE) and IEC-6 model epithelia. Genetic knockdown confirmed a critical role for E-cadherin in in vitro restitution and in vivo wound repair. During restitution, both CXCL12 and TGF-β1 tightened the monolayer by decreasing the paracellular space between migrating epithelial cells. However, CXCL12 differed from TGF-β1 by stimulating the significant increase in E-cadherin membrane localization during restitution. Chemokine-stimulated relocalization of E-cadherin was paralleled by an increase in barrier integrity of polarized epithelium during restitution. CXCL12 activation of its cognate receptor CXCR4 stimulated E-cadherin localization and monolayer tightening through Rho-associated protein kinase activation and F-actin reorganization. These data demonstrate a key role for E-cadherin in intestinal epithelial restitution.     

Electron microscopy of the tracheal ciliated mucosa in rat

Summary The structure of the tracheal epithelial cells from rat has been studied by electron microscopy on approximately 200 Å thick sections with a resolution of better than 30 Å.The epithelium is found to be of a simple columnar type composed of ciliated cells, mucus producing (goblet) cells, basal cells and a fourth kind of cell, here called brush cell. A great number of non-ciliated cells has also been encountered. It has been proved that these represent goblet cells in different stages of intracellular synthesis of mucous granules. The ciliated cells have approximately 8–9 cilia per square micron and there are about 270 cilia on each cell, the calculated surface area being 33 square microns. They are covered by a 70 Å thick membrane. The ciliary filaments are arranged in a pattern of 2 separate ones in the center and a ring of 9 peripheral ones, each divided into 2 subfilaments by a wall with same thickness as the filamentous wall itself, this being 60 Å. The peripheral filaments are continuous with the basal corpuscles. The structure of the corpuscles as compared with earlier findings is discussed. A number of 0.05 micron thick and 1 micron long filiform projections emerge from the cell surface. No cuticle is present.The cell membrane facing adjacent cells is 90 Å and separated from their cell membrane by a 105 Å wide space, this space, being expanded towards a level corresponding to the proximal parts of the cell. A structure that represents terminal bar has been encountered. The cytoplasm is loose and composed of 160 Å thick granules. Spaces enclosed by 50 Å thick membranes with attached 160 Å thick granules (-cytomembranes) are rare. The Golgi zone is analyzed and its regular composition of -cytomembranes, granules and vacuoles is confirmed. The mitochondria with a mean width of 0.23 micron differ to their inner structure from the common type in that the triple layered membranes are highly interconnected. Large opaque granules are encountered in the cytoplasm. Ring-shaped, 850 Å wide, structures are present in the nuclear membrane. The goblet cells are not as abundant as the ciliated cells, the ratio being 14. Small filiform projections covered by a 95 Å thick membrane protrude from the cell surface. This membrane is continuous with the cell membrane, the latter with the same dimensions as in the ciliated cells. Terminal bars are present. The cytoplasm is very opaque due to a dense packing of the 165 Å opaque granules, many in clusters of 4–6. The -cytomembranes have the same dimensions as mentioned above for those present in the ciliated cells. The Golgi zone is of regular composition. There is a suggestion that the Golgi vacuoles and the -cytomembranes are involved in the formation of mucus. In the stage of cellular activity with but few mucous granules, there is a great number of large opaque granules, the size varying from 0.4–1 micron. The mitochondria with a mean width of 0.23 micron have an outer triple layered membrane with a total thickness of 180 Å. The central less opaque layer is 70 Å and the opaque layer on either side is 55 Å. The inner membranes are arranged parallel to each other and have a triple layered composition where the central less opaque layer is 65 Å and the opaque layers each 60 Å. The brush cells belong to the non-ciliated cells. They are encountered singly, surrounded by goblet cells. The surface structures are shaped like brushes or clumsy protrusions which emerge from the distal end of the cell, and are covered by a 95 Å thick membrane. There have been no suggestions of the brushes being cilia in a stage of growth, nor is it probable that they represent stereocilia. They most nearly resemble the intestinal brush border extensions and thus might serve as a resorbing structure.The cytoplasm of the brush cells appears of medium opacity between the ciliated cells and goblet cells and is composed of 155 Å opaque granules. The -cytomembranes are very rare. The Golgi zone is diminutive though of regular composition. The mitochondria are abundant and small with a mean width of 0.14 micron. The outer and inner membranes are triple layered with approximately the same dimensions as reported for the mitochondria of the ciliated and goblet cells. The inner membranes are very few, often only one or two are present. Some of the large opaque granules have inside a very regular arrangement of small 60 Å thick opaque granules arranged in a crystallinic pattern. In the cytoplasm 0.5–1 micron long bundles of 30–40 Å wide fibrils are encountered. The nucleolus shows a characteristic structure of concentrically arranged thin membranes. The basal cells are believed to represent lymphocytes or white blood cells. They sometimes rest on the basement membrane, sometimes are encountered in the distal part of the intercellular spaces. They are bordered by a 110 Å thick cell membrane and have a rather opaque cytoplasm characterized by 160 Å thick opaque granules. A very small Golgi zone is present. The mitochondria, the mean width being 0.14 micron, have triple layered outer and inner membranes, where the less opaque central layer is 65–70 Å and the opaque layers 45–50 Å each. The basement membrane has a thickness of 600 Å. No inner structure has been resolved. The basement membrane is separated from adjacent parts of the ciliated, goblet, brush, and basal cells by a 250 Å wide less opaque space. Below the basement membrane is the lamina propria of the trachea, which is composed of collagen and elastin fibers together with fibroblasts, white blood cells and lymphocytes. The relationship between different types of tracheal epithelial cells in rat has been analyzed. There has been found no indication of a transformation of any type of cells observed into a different type of cell. The development of basal cells via supporting cells or intermediate cells to goblet cells or ciliated cells has not been noticed. On the contrary, all cells that in light microscopy could have been considered to be supporting or intermediate cells, we have been able to recognize as brush cells or as goblet cells to a varying degree filled with mucous granules. If the cells did not seem to reach the cell surface it has been found to be due to a diagonal direction of the sectioning. In this connection it should be emphasized that this relationship is valid only in rat where it is known that the epithelium is of a simple columnar type as distinct from the conditions in man, that epithelium being of a pseudostratified columnar type.This paper is based on a report given at the meeting of Deutsche Gesellschaft für Elektronenmikroskopie in Münster, March 28–31, 1955 and at the Scandinavian Electron Microscope Society Meeting in Stockholm, May 13, 1955.     

Regeneration of nasopharyngeal epithelium in Macaca fascicularis.

Regeneration of the nasopharyngeal epithelium in Macaca fascicularis occurs as a result of migration of epithelial cells from the margins of the lesions as well as from the neighbouring glandular ducts and epithelial crypts. The study further reveals that the basal cells are the progenitors of both goblet and ciliated cells. The regenerating epithelium at first consists of mucus-containing cells which are finally converted into normal globlet and ciliated cells. The formation of centrioles and concurrent reduction in the amount of 'mucus' droplets, and rearrangement of centrioles towards the luminal surface of the cells along with simultaneous development of cilia in some of these mucus-containing cells are stages in the differentiation of ciliated cells. However, some cells which do not possess secretory droplets may also develop into ciliated cells directly.     

Histogenesis and morphogenesis of epidermoid metaplasia in hamster tracheal organ explant culture

The formation of epidermoid metaplasia was studied in hamster tracheal epithelium in long-term serum-free organ explant culture. Explants were cultured up to 5 weeks in CMRL 1066 with antibiotics and amphotericin B. At 3 weeks there were rare small foci of epidermoid metaplasia and they became larger and more numerous at 4 and 5 weeks. Three dimensional reconstructions from serial sections demonstrated that the small deep-seated foci were discrete and did not reach the epithelial surface, whereas the larger foci were expansive and involved the full thickness of the explant epithelium. Each small focus consisted of a few swollen electron-lucent basal cells attached to the basal lamina, covered by a layer of flattened electron-dense secretory cells which formed a tight-fitting cap over the basal cells. The altered secretory cells displayed moderately well-developed rough endoplasmic reticulum and tonofilament bundles. During the early stages of formation the deep-seated metaplastic foci were completely covered by a layer of normal appearing cuboidal to low-columnar secretory and ciliated cells. Expansion of the metaplastic foci occurred by addition of flattened, electron-dense secretory cells to the cap so that multiple layers of altered secretory cells covered a core of basal cells, analogous to the structure of an onion. The secretory cells became cornified and with time the foci broke through the columnar mucociliary surface layer. In well-advanced foci, the uppermost cornified squames (metaplastic secretory cells) exfoliated into the tracheal lumen. The study emphasizes similarities and differences between the morphogenesis and histogenesis of epidermoid metaplasia in vivo and in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)