Application of immunohistochemistry to the isolated mucosa of the mouse gastrointestinal tract, with special reference to somatostatin cells

In the present study, in order to easily grasp whole images of somatostatin (D) cells, the isolated mucosa of the mouse gastrointestinal tract was immunohistochemically treated. The present study revealed that: (1) in the stomach, small-intestinal villi and colon, about 20% of the D cells extrude basal cytoplasmic processes, showing terminal expansions in many cases; on the other hand, in the crypts of the small intestine, few D cells possess basal processes, and (2) in the stomach, there is no determined tendency in the direction of the basal processes of the D cells; on the other hand, in the small-intestinal villi and colon, most D cell basal processes run toward the villus base and colon crypt bottoms. The direction of the basal processes of the D cells in the gastrointestinal tract seems to be mostly in favor of the migration pattern of epithelial cells described previously. It is likely that, if the targets of the D cells are near the D cells, the basal process is not necessary for local secretion of somatostatin. During migration, however, D cells might extrude basal processes to keep relationships with their targets.     

Cell differentiation lineage in the prostate

Prostatic epithelium consists mainly of luminal and basal cells, which are presumed to differentiate from common progenitor/stem cells. We hypothesize that progenitor/stem cells are highly concentrated in the embryonic urogenital sinus epithelium from which prostatic epithelial buds develop. We further hypothesize that these epithelial progenitor/stem cells are also present within the basal compartment of adult prostatic epithelium and that the spectrum of differentiation markers of embryonic and adult progenitor/stem cells will be similar. The present study demonstrates that the majority of cells in embryonic urogenital sinus epithelium and developing prostatic epithelium (rat, mouse, and human) co-expressed luminal cytokeratins 8 and 18 (CK8, CK18), the basal cell cytokeratins (CK14, CK5), p63, and the so-called transitional or intermediate cell markers, cytokeratin 19 (CK19) and glutathione-S-transferase-pi (GSTpi). The majority of luminal cells in adult rodent and human prostates only expressed luminal markers (CK8, CK18), while the basal epithelial cell compartment contained several distinct subpopulations. In the adult prostate, the predominant basal epithelial subpopulation expressed the classical basal cell markers (CK5, CK14, p63) as well as CK19 and GSTpi. However, a small fraction of adult prostatic basal epithelial cells co-expressed the full spectrum of basal and luminal epithelial cell markers (CK5, CK14, CK8, CK18, CK19, p63, GSTpi). This adult prostatic basal epithelial cell subpopulation, thus, exhibited a cell differentiation marker profile similar to that expressed in embryonic urogenital sinus epithelium. These rare adult prostatic basal epithelial cells are proposed to be the progenitor/stem cell population. Thus, we propose that at all stages (embryonic to adult) prostatic epithelial progenitor/stem cells maintain a differentiation marker profile similar to that of the original embryonic progenitor of the prostate, namely urogenital sinus epithelium. Adult progenitor/stem cells co-express both luminal cell, basal cell, and intermediate cell markers. These progenitor/stem cells differentiate into mature luminal cells by maintaining CK8 and CK18, and losing all other makers. Progenitor/stem cells also give rise to mature basal cells by maintaining CK5, CK14, p63, CK19, and GSTpi and losing K8 and K18. Thus, adult prostate basal and luminal cells are proposed to be derived from a common pleuripotent progenitor/stem cell in the basal compartment that maintains its embryonic profile of differentiation markers from embryonic to adult stages.     

Dopamine beta-hydroxylase like immunoreactive cells in the frog taste disc

We immunohistochemically examined the existence of dopamine beta-hydroxylase (DBH), a noradrenalin (NA)-synthesizing enzyme from dopamine, in the taste disc of frog, Rana catesbeiana. DBH-like immunoreactive cells were located in the intermediate layer in the taste disc; the cells showed an apical process reaching the surface of the disc and one or several basal processes. Cells with a thick apical process and those with a thin apical process were both immunoreactive: these cells corresponded to type II and III receptor cells of the frog taste disc. Immunoreactive granules were observed in the cytoplasm of those cells. In the frog taste disc, only type III cells are reported to have afferent synapses with the nerve via basal processes but those basal processes have not been reported in type II cells. In the present study, we found that type II-like cells possessed a long basal process extending toward the basal lamina. Mucous (type Ia) cells, wing (type Ib) cells, and glia-like sustentacular (type Ic) cells were all immunohistochemically unreactive. The present observations support the argument that NA (or adrenalin) may work as a chemical transmitter in the frog taste organ.     

Biosynthesis of the basal lamina as a result of interaction between thyroid and mesenchymal cells in culture

Porcine thyroid cells were cultured alone or in mixed cultures with mesenchymal cells. The formation of a basal lamina in vitro was investigated ultrastructurally. Follicular reassociation of thyroid cells occurred in both types of culture; however, it was followed by formation of the basal lamina only when mesenchymal cells were present. The present findings suggest an epithelial origin of the basal lamina resulting from an interaction with mesenchymal cells.     

Fine structure of taste buds in the barbel of the catfish,Ictalurus punctatus

Summary Taste buds occur in the epithelium of the catfish barbel along its entire length. Two major cell types, light and dark cells, occupy the upper two-thirds of the taste bud. A third cell type, the basal cell, lies on the basal lamina and is essentially separated from the light and dark cells by a plexus of unmyelinated nerve fibers. The dark cells have branching processes, both apically and basally whereas the light cells have a single apical process and many basal processes. The apical processes of dark cells contain secretory granules, while the apical processes of light cells contain an abundant agranular endoplasmic reticulum. Light cell nuclei contain bundles of 10 nm filaments, often arranged in the shape of a cup or ring, but nucleoli are rarely seen. It is suggested that this morphology indicates a low degree of RNA synthesis by light cells. The basal cells contain large numbers of vesicles, about 60 nm in diameter, which are sometimes seen in clumps in relation to an adjacent nerve fiber in a configuration resembling a synapse. Curiously, although basal cells present a large surface to the basal lamina, there are no hemidesmosomes. This suggests that the basal cell does not originate from the epidermis.Supported by grant#NS-06181 from the National Institute of Neurological Diseases and Stroke, U.S. Public Health Service     

The fine structure of the area postrema of the sheep

The ultrastructural features of the area postrema (AP) were investigated in the suckling lamb, weaned lamb and adult sheep. No morphological differences were observed between lambs and sheep. Unciliated ependymal cells, linked by zonulae adherentes-type junctions and gap junctions, cover the AP ventricular surface. Clusters of pyriform neurons, glial cells, and axons are present in the parenchyma. The blood vessels are surrounded by wide perivascular spaces, which present an inner and outer basal lamina. The capillaries are of the fenestrated type. Perivascular glial cells rest on the outer basal lamina of the perivascular space and form a continuous ensheathment with their cell bodies or with flattened interdigitating processes. Along adjacent perivascular glial processes gap junctions are present. From our ultrastructural observations it appears that the overall cellular morphology of AP of the sheep does not differ substantially from that of monogastric mammals.     

Ultrastructure of the Olfactory Epithelium in the Australian Lungfish Neoceratodus forsteri

Four cell types are present in the olfactory epithelium of Neoceratodus forsteri, i.e., olfactory receptor cells, supporting cells, non-sensory ciliated cells, and basal cells. Only microvilli and no cilia were observed on the receptor cells. The neurotubules pass out into these microvilli. Conspicuous arrays of agranular endoplasmic reticulum are present in the nuclear region of the receptor cells. The supporting cells are provided with microvilli. These cells may be secretory. The non-sensory ciliated cells produce secretory granules containing acid mucopolysaccharides. A discontinuous zonula occludens appears to be present.     

The epithelial lining of the bovine ejaculatory duct

The bovine ejaculatory duct is lined by a pseudostratified columnar epithelium. Two cell types are present: small basal cells and columnar principal cells in different functional states. The basal cells are able to accumulate lipid material. The principal cells are observed in a less active state and in a state of either increased endocytosis and fluid uptake or active spermiophagy. Endocytotically active cells are characterized by an apical brush border and a system of microvesicles, multivesicular bodies and lysosomal dense bodies. Cells involved in phagocytosis of spermatozoa are mostly provided with a smooth apical border, an expanded Golgi apparatus, many phagocytic vacuoles and condensing phagolysosomes.     

The morphology of the denuded epidermal basal cell layer of the hairless mouse after different preparation methods. A scanning and transmission electron microscopical study

The denuded basal cell layer of the hairless mouse epidermis is described in the present scanning (SEM) and transmission electron microscopical (TEM) study. The suprabasal layers were removed mechanically after trypsinization or by extracellular calcium depletion. Trypsinization before removal of the suprabasal cells caused the basal cells to shrink. Characteristic surface plication and hemi-desmosomal attachment to the basement membrane were generally preserved. SEM revealed partly maintained intercellular bridging, whereas by TEM such contacts were absent because half desmosomes were internalized. Total calcium depletion induced more serious damage to the basal cell surface, which was smooth with apparent perforations. However, cell bridges, and occasional desmosomes were present. The cell interior demonstrated important cellular injury. If the calcium deprived explants were allowed to recover in calcium-containing medium, the cells acquired an activated "regenerative" morphology, without junctions, similar to that observed in wound healing. Epidermal non-keratinocytes were seen only after trypsinization. Control experiments revealed that they adapted poorly to organ culture conditions. By TEM, we observed several interesting aspects of the differences, between dark and clear basal keratinocytes. This was unexpected because fixation studies had shown, that with the present fixation method, typical dark and clear cells do not occur in untreated epidermis. We believe that membrane injury through mechanical stripping of partly adhering epidermal layers induced "clear cells", whereby the neighboring cells appeared darker. This provides additional evidence as to the origin of the two sub-populations, dark and clear basal cells. The clear cells may be injured cells, caused by cell damage, and not by processes of cellular differentiation. The results of the present investigation supports the view that basal keratinocytes have a polygonal shape with numerous free surface extensions and they are anchored to the basement membrane with "foot pads". Our study also shows that SEM of the epidermal basal layer might be feasible. Various artifacts, however, must be considered, depending on the denudation method used. We prefer trypsinization to calcium depletion because it is less time-consuming and results in a cell morphology which in TEM is comparable to that of basal cells in untreated whole epidermis. Extra-cellular calcium depletion, however, might be useful as a method to prepare single cell suspensions for flow cytometry. Restoration of a normal calcium concentration after stripping, provides an opportunity to mimic wound healing in situ, as an alternative t     

Ultrastructure of the main excretory duct of the cat submandibular gland

The main excretory ducts (MED's) from the submandibular gland of adult cats were examined by electron microscopy. The ducts consisted of a pseudostratified epithelial lining surrounded by abundant connective tissue and numerous, small, longitudinally-oriented blood vessels. The taller epithelial cells were closely coherent, without the luminal clefts between adjacent cells that are characteristic of rat MED's. In the cat, these cells lacked basal membrane specialization, but showed considerable lateral interdigitation. Some microvilli were present on the apical surface. In a'few rare cells, the luminal surface bore cilia of typical appearance. The smaller, pyramidal basal cells had irregular basal surfaces that gave rise to one or more long cytoplasmic processes. The basal surface of the pyramidal cells was studded with hemidesmosomes. The cytoplasm contained abundant tonofilaments, which sometimes aggregated in prominent perinuclear bundles. Occasional goblet cells were present in the duct wall. MED's perfused either in situ or in a perfusion chamber with Locke's solution also were studied. Even after perfusion of 160 minutes duration, the ultrastructure of the ductal epithelium showed remarkably few alterations. The MED model system thus remains stable long enough to carry out physiological experiments which may produce ultrastructural alterations.     

Polarization of thyroid cells in culture: evidence for the basolateral localization of the iodide "pump" and of the thyroid-stimulating hormone receptor-adenyl cyclase complex

When cultured in collagen gel-coated dishes, thyroid cells organized into polarized monolayers. The basal poles of the cells were in contact with the collagen gel, whereas the apical surfaces were facing the culture medium. Under these culture conditions, thyroid cells do not concentrate iodide nor respond to acute stimulation by thyroid-stimulating hormone (TSH). To allow the free access of medium components to the basal poles, the gel was detached from the plastic dish and allowed to float in the culture medium. After release of the gel, the iodide concentration and acute response to TSH stimulation were restored. Increased cAMP levels, iodide efflux, and formation of apical pseudopods were observed. When the thyroid cells are cultured on collagen-coated Millipore filters glued to glass rings, the cell layer separates the medium in contact with the apical domain of the plasma membrane (inside the ring) from that bathing the basolateral domain (outside the ring). Iodide present in the basal medium was concentrated in the cells, whereas no transport was observed when iodide was added to the luminal side. Similarly, an acute effect of TSH was observed only when the hormone was added to the basal medium. These results show that the iodide concentration mechanism and the TSH receptor-adenylate cyclase complex are present only on the basolateral domain of thyroid cell plasma membranes.     

Nonolfactory surface epithelium of the nasal cavity of the bonnet monkey: a morphologic and morphometric study of the transitional and respiratory epithelium

The purpose of the present study was to characterize ultrastructurally the nonolfactory nasal epithelium of a nonhuman primate, the bonnet monkey. Nasal cavities from eight subadult bonnet monkeys were processed for light microscopy, and scanning and transmission electron microscopy. Nonolfactory epithelium covered the majority of the nasal cavity and consisted of squamous (SE), transitional (TE), and respiratory epithelium (RE). Stratified SE covered septal and lateral walls of the nasal vestibule, while ciliated pseudostratified RE covered most of the remaining nasal cavity. Stratified, nonciliated TE was present between SE and RE in the anterior nasal cavity. This epithelium was distinct from the other epithelial populations in abundance and types of cells present. TE was composed of lumenal nonciliated cuboidal cells, goblet cells, small mucous granule (SMG) cells, and basal cells, while RE contained ciliated cells, goblet cells, SMG cells, basal cells, and cells with intracytoplasmic lumina lined by cilia and microvilli. TE and RE contained similar numbers of total epithelial cells and basal cells per millimeter of basal lamina. TE was composed of more SMG cells but fewer goblet cells compared to RE. We conclude that nonolfactory nasal epithelium in the bonnet monkey is complex with distinct regional epithelial populations which must be recognized before pathologic changes within this tissue can be assessed adequately.     

Differentiation of ciliated cells in the terminal bronchioles of neonatal calves

The bronchiolar ciliated cells are exquisitely sensitive to injury caused by infection or irritation of the airways. The mechanism by which bronchiolar ciliated cells are renewed following injury or during the normal course of differentiation is still debated. The present study aimed at recognizing the progenitor cell population for bronchiolar ciliated cells during early neonatal life of calves and to demonstrate the course of events occurs during its differentiation into ciliated cells. Scanning electron microscopy of the terminal bronchiolar epithelium revealed two distinct cell types namely ciliated and non-ciliated cells. Transmission electron microscopy revealed ciliated, non-ciliated (Clara), intermediate and basal cells. At least two categories of intermediate cells could be distinguished: intermediate cells with abundant glycogen and variable numbers of organelles; intermediate cells with little glycogen, large numbers of polyribosomes, and variable numbers of basal bodies. We conclude that: (1) both bronchiolar non-ciliated and basal cells serve as progenitors for the bronchiolar ciliated cells; (2) differentiation of ciliated cell from the non-ciliated one involves a transitional cell in which glycogen is lost, polyribosomes are synthesized before the synthesis of basal bodies and cilia.     

Fine structure of monoamine-containing basal cells in the taste buds on the barbels of three species of teleosts

Summary The taste buds on the barbels in three species of teleosts (Cyprinus carpio, Misgurnus anguillicaudatus, Parasilurus asotus) were studied by means of fluorescence and electron microscopy. Intensely yellow-fluorescent cells, which are disk-shaped and located exclusively in a basal position, are observed in the barbel-buds of all fishes examined. The basal cells contain a large number of small clear vesicles approximately 40–60 nm in diameter, which show a tendency to aggregate in the cytoplasm facing the junction of the nerve terminals; chemically transmitting synapses are seen in the latter region. It is suggested from the present observations that the basal cells in the barbel-bud may originate from Schwann cells and have a dual function both as mechanoreceptors and paracrine elements. Since the administration of 5,6-DHT results in an appearance of small dense vesicles among the small clear vesicles, the possibility exists that the basal cell may be capable of taking up monoamines and storing them in the small clear vesicles.     

The development of ciliated and mucus cells from basal cells in hamster tracheal epithelial cell cultures

Hamster tracheal epithelia consist of three cell types: ciliated, mucus and basal cells. Autoradiographic data from several studies suggest that either basal or non-ciliated columnar cells may serve as stem cells for regeneration of lost or damaged ciliated and mucus cells. The objective of the present study was to examine the role of basal cells in the formation of ciliated and mucus cells in hamster tracheal epithelial (HTE) cell cultures via tritiated thymidine ([3H]-TdR) autoradiography. When 3 day cultures were pulsed with [3H]-TdR for 6 hr and incubated for 2 additional days in non-radioactive media (5 day total) label was present in the nuclei of basal and columnar epithelial cells suggesting that the labeled columnar cells may be derived from basal cells. However, the morphological reorganization occurring during this 2 day interval may create difficulties in this interpretation. Since these morphological changes are minimal during the 6 day to 8 day in vitro period, 6 day HTE cultures were pulsed with [3H]-TdR for 6 hr and incubated for 2 additional days in non-radioactive media (8 day total), and examined to further study the fate of labeled basal cells during this period. Analysis of these 8 day cultures revealed that labeled nuclei were present in both basal cells and adjacent ciliated and mucus cells. These results do not exclude the possibility of non-basal cell origin of ciliated and mucus cells in other systems but suggest that, at least in HTE cultures, undifferentiated basal cells have the ability to develop into ciliated and mucus cells.     

Secretory and basal cells of the epithelium of the tubular glands in the male Mullerian gland of the caecilian Uraeotyphlus narayani (Amphibia: Gymnophiona)

Caecilians are exceptional among the vertebrates in that males retain the Mullerian duct as a functional glandular structure. The Mullerian gland on each side is formed from a large number of tubular glands connecting to a central duct, which either connects to the urogenital duct or opens directly into the cloaca. The Mullerian gland is believed to secrete a substance to be added to the sperm during ejaculation. Thus, the Mullerian gland could function as a male accessory reproductive gland. Recently, we described the male Mullerian gland of Uraeotyphlus narayani using light and transmission electron microscopy (TEM) and histochemistry. The present TEM study reports that the secretory cells of both the tubular and basal portions of the tubular glands of the male Mullerian gland of this caecilian produce secretion granules in the same manner as do other glandular epithelial cells. The secretion granules are released in the form of structured granules into the lumen of the tubular glands, and such granules are traceable to the lumen of the central duct of the Mullerian gland. This is comparable to the situation prevailing in the epididymal epithelium of several reptiles. In the secretory cells of the basal portion of the tubular glands, mitochondria are intimately associated with fabrication of the secretion granules. The structural and functional organization of the epithelium of the basal portion of the tubular glands is complicated by the presence of basal cells. This study suggests the origin of the basal cells from peritubular tissue leukocytes. The study also indicates a role for the basal cells in acquiring secretion granules from the neighboring secretory cells and processing them into lipofuscin material in the context of regression of the Mullerian gland during the period of reproductive quiescence. In these respects the basal cells match those in the epithelial lining of the epididymis of amniotes.     

Localisation of Epithelial Cells Capable of Holoclone Formation In Vitro and Direct Interaction with Stromal Cells in the Native Human Limbal Crypt

Limbal epithelial stem cells (LESCs) are essential to maintain the transparent ocular surface required for vision. Despite great advances in our understanding of ocular stem cell biology over the last decade, the exact location of the LESC niche remains unclear. In the present study we have used in vitro clonal analysis to confirm that limbal crypts provide a niche for the resident LESCs. We have used high-resolution imaging of the basal epithelial layer at the limbus to identify cells with a morphology consistent with stem cells that were only present within the basal layer of the limbal crypts. These cells are proximal to limbal stromal cells suggesting direct cell-to-cell interaction. Serial block-face scanning electron microscopy (SBFSEM) confirmed that the putative LESCs are indeed in direct contact with cells in the underlying stroma, a contact that is facilitated by focal basement membrane interruptions. Limbal mesenchymal cells previously identified in the human limbus collocate in the crypt-rich limbal stromal area in the vicinity of LESCs and may be involved in the cell-to-cell contact revealed by SBFSEM. We also observed a high population of melanocytes within the basal layer of the limbal crypts. From these observations we present a three dimensional reconstruction of the LESC niche in which the stem cell is closely associated and maintained by both dendritic pigmented limbal melanocytes and elongated limbal stromal cells.     

Molecular identification of the skin transformation center of anuran larval skin using genes of Rana adult keratin (RAK) and SPARC as probes

Anuran larval skin undergoes a process of metamorphosis into pre-adult and adult skin. Basal skein, larval basal and adult basal cells are basement membrane-attaching cells in the larval, pre-adult and adult epidermis, respectively, and are identified as cells expressing genes of RLK (Rana larval keratin), both RLK and RAK (Rana adult keratin), and RAK. Larval to pre-adult skin conversion takes place in the histological entity called the skin transformation center (STC). The present study performed a cDNA subtractive gene screening on cDNA of the larval and the pre-adult skin, and cloned the secreted protein acidic and rich in cysteine (SPARC) gene as an upregulated gene in the larva to pre-adult skin conversion. RAK gene-positive basal skein cells and fibroblasts in and around the STC were weakly and strongly sparc-positive, respectively. Using sparc and rak, we redefined the STC and visualized it on a histological section as an approximately 150 microm-long region that contained about 20 rak-negative and weakly sparc-positive basal cells. Intense sparc expression was observed in basal skein cells, but not in larval basal cells, suggesting that SPARC acts as a suppressor of rak during epidermal differentiation. This suggestion was tested by investigating the effect of SPARC on cultured larval basal cells. We observed that SPARC suppressed the expression of rak, but not rlk.     

Evidence for two points of restriction in the expression of adenovirus type 2 in cultured epidermal keratinocytes.

Cultures of epidermal keratinocytes contain two populations of cells, a basal undifferentiated population and a suprabasal terminally differentiated population. When exposed to wild-type adenovirus type 2 (wtAd2), the suprabasal cells are positive by immunofluorescence for capsid antigen and exhibit cytopathic effects (CPE) (R.F. LaPorta, and L.B. Taichman, Virology 110:137-146, 1981). The basal cells, although infected, are not positive for capsid antigen and do not display CPE. Despite CPE and capsid antigens in suprabasal cells, yields of virus from the entire culture are very low (10 PFU per cell). These observations suggest that Ad2 expression is restricted at different times in the viral life cycle in basal and suprabasal cells. To test this hypothesis, we isolated host range (hr) mutants of Ad2 on two lines of squamous cell carcinoma (SCC) keratinocytes which were shown to be restrictive for wtAd2 replication. The hrAd2 mutants produced high yields of progeny virus in epidermal cell cultures (500 to 600 PFU per cell). However, the pattern of CPE induction in these cultures was like that produced by wtAd2, i.e., basal cells were CPE negative and suprabasal cells were CPE positive. The high yield of hrAd2 progeny indicated that the restriction present in suprabasal cells was overcome. However, the failure of hrAd2 mutants to induce CPE in basal cells indicated that the hrAd2 mutants remain restricted in the basal population and supported our hypothesis that a second and distinct restriction exists in basal keratinocytes.