Electron immunocytochemical co-localization of prochymosin and pepsinogen in chief cells, mucous neck cells and transitional mucous neck/chief cells of the calf fundic glands

The electron immunocytochemical co-localization of prochymosin and pepsinogen in chief cells, mucous neck cells and transitional mucous neck/chief cells of calf fundic glands was studied using specific antisera for prochymosin and pepsinogen with a protein A-gold method. Prochymosin and pepsinogen immunoreactivities were detected in the same secretory granules of the chief, mucous neck and transitional cells, simultaneously using small and large colloidal gold particles. In chief cells, both immunoreactivities were distributed uniformly over the same zymogen granules showing a round, large, homogeneous and electron-dense appearance. In mucous neck cells, both immunoreactivities were found exclusively on the same electron-dense core located eccentrically in the mucous granule showing light or moderate electron density. In transitional mucous neck/chief cells, electron-dense cores became larger in size and some granules were occupied by the electron-dense core without a halo between the core and the limiting membrane. Both immunoreactivities were found uniformly over the electron-dense core. The granules having no halo in the transitional cells could not be distinguished from the typical zymogen granules in the chief cells.     

Immunocytochemistry and in situ hybridization studies of pepsinogen C-producing cells in developing rat fundic glands

The ontogeny of pepsinogen C-producing cells in rat fundic glands was studied by means of light and electron microscopy using an antiserum raised against a synthetic peptide based on rat pepsinogen C. To confirm the immunocytochemistry results, the expression of rat pepsinogen C messenger RNA (mRNA) in the fundic gland was also examined by in situ hybridization using a digoxigenin-labeled RNA probe. In adult rats, pepsinogen C was produced by chief cells, mucous neck cells, and intermediate mucopeptic cells. Pepsinogen C-producing cells appeared in embryos as early as 18.5 days’ gestation. The development of these cells could be classified into four stages: (1) 18.5 days’ gestation to 0.5 days after birth; (2) 0.5 days to 2 weeks after birth; (3) 3–4 weeks after birth; (4) 4–8 weeks after birth. In embryos and young animals, pepsinogen C-producing cells were mucopeptic cells. By 4 weeks after birth, mucous neck cells could be distinguished morphologically. The maturation stages of the chief cells could be traced by electron microscopy along the longitudinal axis of the rat fundic gland by double-staining with anti-pepsinogen C antibody and periodic acid-thiocarbohydrazide-silver proteinate. Positive reactions for pepsinogen C and pepsinogen C mRNA expression were detected in mucous neck cells. Therefore, we conclude that mucous neck cells are precursor cells of chief cells. Mucous neck cells, intermediate cells, and chief cells are in the same differentiating cell lineage.     

Immunocytochemical study of pepsinogen 1-producing cells in the fundic mucosa of the stomach in developing mice

Summary Development and maturation of pepsinogen 1-producing cells were studied in the gastric fundic mucosa of the mouse by means of light- and electron-microscopic immunocytochemistry using rabbit anti-rat pepsinogen 1-serum. In the adult mouse, secretory granules in mucous neck cells, transitional mucous neck/chief cells and chief cells are immunolabeled. The numerical density of gold particles on zymogen granules is not significantly altered among different stages of maturation of chief cells. In addition, rough endoplasmic reticulum and Golgi complex of these cell types show a weak labeling. In mice from day 16 of gestation to postnatal day 14 mucous neck cells and chief cells cannot be distinguished, but only one type of pepsinogen 1-producing cell, called primitive chief cell, is identified in the fundic gland. The intensity of immunoreactivity of secretory granules in primitive chief cells is uniform within an individual cell but varies greatly among different cells. The majority of primitive chief cells contains weakly labeled granules regardless of the maturation stage of cells or of animals. On postnatal day 21, mucous neck, transitional and chief cells are distinguishable, and secretory granules in these cells are intensely immunolabeled as in the adult. These results suggest that pepsinogen 1-production rapidly increases with differentiation of mucouse neck and chief cells.     

Mating-induced luteinizing hormone surge and ovulation in the female camel (Camelus dromedarius)

Blood samples were collected after mating from four female one-humped camels every 10 min for 9-12 h. Luteinizing hormone (LH) was quantified in plasma by radioimmunoassay using antibovine LH. Of the seven observed matings, five were followed by a release of LH, and three by an ovulation (indicated by a subsequent secretion of progesterone). LH levels at the time of mating ranged from 0.7 to 3 ng/ml. When an LH response occurred, the levels increased 1 h after mating and reached a maximum in 2-3 h (ranging from 2.9 to 19.1 ng/ml). A decrease in LH was observed starting 6 h after mating and lasting for 6 h. These results are in agreement with a coitus-induced mechanism of ovulation in the one-humped camel (Camelus dromedarius). They confirm and extend the observations reported in the bactrian camel (Camelus bactrianus).     

The oesophagus and stomach of dolphins (Tursiops, Delphinus, Stenella)

The morphology of the oesophagus and stomach has been studied in several species of Tursiops, Delphinus and Stenella and correlated with the histological and ultrastructural characteristics of each region. The oesophagus opens into a saccular forestomach, lined by stratified squamous epithelium. A narrow opening leads into a globular main stomach with a plicated glandular mucous membrane possessing mucous, parietal and chief cells. The main stomach communicates with pyloric stomach by a narrow connecting channel possessing sphincteric constrictions. Variations in the connecting channel have been found in the species examined. The mucosae of the channel and the pyloric stomach are similar and contain typical pyloric glands. Argentaffin cells are present. The cytological and other characteristics of the component chambers have been interpreted in relation to feeding habits and digestion in dolphins.     

Pepsinogen Induction in Chick Stomach Epithelia by Reaggregated Proventricular Mesenchymal Cells In Vitro

In vitro organ culture system which permits embryonic chick proventriculus (glandular stomach) to synthesize pepsinogen de novo was developed. Explants of the proventricular rudiment were cultured on Millipore filters in Medium 199 with Earle's salts supplemented with 50% 12-day embryo extract at 38°C in 95% air and 5% CO₂.
In these culture conditions, pepsinogen, a functional marker protein of proventriculus, was first detected after 3 days of cultivation of 6-day chick proventricular rudiment. When recombined and cultured with 6-day proventricular mesenchyme, 6-day oesophageal, proventricular or gizzard (muscular stomach) epithelium expressed pepsinogen while small intestinal epithelium did not. These results were consistent with the previous results obtained by chorioallantoic membrane (CAM) grafting, and showed that the culture conditions are permissive for pepsinogen expression.
When recombined and cultured with reaggregated mesenchymal cells isolated from 6-day proventricular mesenchymal fragments, both 6-day proventricular and gizzard epithelia formed glandular structure and expressed pepsinogen. This indicates that the proventricular mesenchymal cells retain the ability to induce morphogenesis and cytodifferentiation of the proventricular epithelium even if the normal organization of proventricular mesenchyme is once destroyed.     

Heterogeneity of glycoconjugates in the secretory cells of the chinchilla middle ear and eustachian tubal epithelia: a lectin-gold cytochemical study

The present study was conducted to characterize and localize the glycoconjugates in the tubotympanum (auditory or eustachian tube and middle ear cavity) of chinchilla on an ultrastructural level, using lectin-gold complexes with six different lectins: BPA, ConA, RCA-1, WGA, LFA, and SNA. A comparison of the affinity of these lectins demonstrated the heterogeneity of secretory cells. The glandular serous cells and epithelial dark granulated cells produced "serum"-type glycoprotein. The glandular mucous cells and goblet cells produced dominantly "mucin"-type glycoprotein in the light granules, but "serum"-type glycoprotein in the dark cores. The labeling of LFA and SNA showed that sialic acids existed mainly in the mucinous granules of secretory cells and ciliated epithelium glycocalyx, and in the mucous blanket. The results also suggested that the dominant linkage of sialic acids of mucin is a Neu5Ac(alpha 2-6)Gal/GalNAc sequence. Furthermore, the data obtained from ConA and BPA suggested that initial O-glycosylation of mucin took place in the cis side of the Golgi apparatus and that initial N-glycosylation of the serum occurred in the rough endoplasmic reticulum.     

Growth of fetal rat gastro-intestinal epithelial cells is region-specifically controlled by growth factors and substrata in primary culture

The mammalian gastro-intestinal tract can be divided into three parts: esophagus and forestomach, glandular stomach, and intestine. We have previously reported primary culture systems for duodenal and glandular stomach epithelial cells in which the cells express tissue-specific marker proteins. However, the effects of growth factors and substrata on cell growth have not been fully investigated. In this study a primary culture system was established for forestomach epithelial cells and the mechanism by which the growth of gastro-intestinal epithelial cells is controlled in primary culture was examined. Forestomach, glandular stomach and duodenal epithelial cells proliferated rapidly in culture, increasing their numbers about 30-, 20-and 10-fold, respectively, in the first 5 days. Scanning electron microscopy showed that these three types of epithelial cells exhibited region-specific morphologies in culture. Results on the effects of growth factors and substrata on the proliferation of the epithelial cells revealed that the culture conditions required to induce maximal epithelial growth differed. Forestomach and glandular stomach epithelial cells required similar combinations of growth factors to proliferate, and these were quite different from those required for duodenal epithelial cells. Glandular stomach and duodenal epithelial cells could proliferate in a serum-free condition while forestomach epithelial cells could not. Thus, glandular stomach epithelial cells exhibited intermediate characteristics between forestomach and duodenal epithelial cells regarding their growth factor requirement. Glandular stomach and duodenal epithelial cells could not proliferate on plastic without collagen substrata while forestomach epithelial cells could. Duodenal epithelial cells proliferated faster on collagen gels than on collagen films, and forestomach epithelial cells faster on collagen films than on collagen gels. Glandular stomach epithelial cells proliferated similarly on both substrata. Thus again, glandular stomach epithelial cells exhibited intermediate characteristics between forestomach and duodenal epithelial cells regarding their substratum dependency. We conclude that the growth of gastro-intestinal epithelial cells is affected by both growth factors and substrata, and that glandular stomach epithelial cells exhibit intermediate characteristics between forestomach and duodenal epithelial cells in responding to these factors. These results suggest that a head-to-tail gradient exists in the gastro-intestinal tract which controls the epithelial response to growth factors and substrata.     

Light and electron microscope observations on the gastric mucosa of the frog (Rana esculenta)

Summary The structure of the frog gastric and esophageal mucosa was studied in the course of a complete hibernation period and compared with that in summer frogs (see preceding article).It appeared that especially chief cells and parietal cells are liable to cytoplasmic remodelling. Thus, in chief cells the rough endoplasmic reticulum (RER) undergoes disorganization, the number of free ribosomes increases and the Golgi system becomes transformed into a compact vesicular structure. The number of pepsinogen granules in chief cells of late winter frogs is only 20% of that in frogs studied at the onset of hibernation. The loss of pepsinogen granules is at least partly due to autophagy. In addition, lysosomes are involved in focal degradation of the cytoplasm, which may ultimately result in complete degeneration of some chief cells. The presence of zymogen granules containing fibrocyte-like cells in the tunica propria proved heterophagocytosis by these cells.In parietal cells, the area occupied by smooth endoplasmic reticulum becomes reduced. The basal cytoplasm of both chief cells and parietal cells contains numerous lipid droplets, which, in contrast to those in summer frogs, are continuous with RER cisternae. The juxtaposition of lipid droplets and mitochondria seen in summer frogs is eventually lost in hibernating animals.Apart from the appearance of supra-nuclear lipid droplets, the mucous cells of the surface epithelium show no striking alterations. However, in the glandular pits both surface mucous cells and mucous neck cells contain less mucous granules than in summer frogs.The results are discussed in connection with parallel biochemical work and available literature, and in the light of our previous studies on the exocrine pancreas in hibernating frogs.     

Immunocytochemical localization of pepsinogen in rat stomach

The localization of pepsinogen in rat stomachs was investigated by a postembedding immunoferritin method. When the preparations embedded in Epon were used, the secretory granules of chief cells were stained heavily and the granules of mucous neck cells were stained moderately. The secretory granules of cells intermediate between mucous neck cells and chief cells showed a bizonal staining; the electron dense parts were stained heavily and the electron lucent parts were stained moderately. The secretory granules of pyloric gland cells, on the other hand, were labeled faintly. However, the secretory granules of surface mucous cells, foveolar mucous cells, endocrine cells, cardiac mucous cells and cardiac serous cells were not stained by the method. The protein A-gold method showed a similar staining pattern of pepsinogen to that of the immunoferritin method. When the samples embedded in Lowicryl K4M were used to enhance the stainability of pepsinogen, essentially the same staining pattern as that of the samples embedded in Epon was obtained. In addition, the Golgi apparatus and the rough surfaced endoplasmic reticulum were more easily stained.     

Cellular and subcellular localization of progastricsin in calf fundic mucosa: colocalization with pepsinogen and prochymosin

The presence of gastricsin in bovine abomasal juice has been reported previously, but its exact site of origin has not yet been established. Specific polyclonal antibodies were used in the peroxidase-antiperoxidase method or the protein A/gold technique to label cells producing progastricsin. This immunocytolocalization was correlated with that of pepsinogen and prochymosin using specific polyclonal antibodies against those zymogens. The present study clearly established that progastricsin was located exclusively in chief, mucous neck, transitional mucous neck/chief, foveolar epithelial and surface epithelial cells of the calf fundic mucosa. Furthermore, progastricsin was found to be colocalized with pepsinogen and prochymosin in the same secretory granules of these cells. Progastricsin was not observed in parietal, gastric endocrine and undifferentiated neck cells.     

The cells of the rat gastric groove and cardia

The distal wall of the groove between the rat forestomach and glandular stomach is lined with a special type of columnar cells (CCGG) and with fibrillovesicular cells (FVC). The cardiac glands contain cardiac mucosa (CMC) and serous cells (CSC). The CCGG contain small mucous granules and special vesicles and tubules. The CMC are filled with large mucous granules and resemble mucous neck cells. The CSC are filled with large proteinaceous granules. The FVC are characterized by long microvilli, apical bundles of microfilaments and a complex "tubulovesicular system". The pattern of 3H-thymidine incorporation and the presence of immature and transitional forms indicate a possible origin of all the cell types concerned from a common undifferentiated precursor. The membranes of the tubulovesicular system of FVC as well as the apical cell membrane were reactive to Thiéry's carbohydrate stain. However, lanthanum tracing of the extracellular space and ultrastructural stereoscopy did not reveal a permanent continuity between both membrane systems. The absence of 3H-thymidine label showed that FVC were not proliferative. The structural characteristics of FVC do not account for a secretory, resorptive or receptive function. The special arrangement of microfilaments and the tubulovesicular system suggests an ability to fast changes in surface area.     

Cultivation of chicken proventricular epithelial cells and their potential for differentiation

Epithelial cells of chicken proventriculus (glandular stomach) differentiate into two types; luminal and glandular epithelial cells. The molecules regulating the differentiation of proventricular epithelial cells are not well understood. As the first step in screening the molecular determinants involved in the cell differentiation process, we tried to establish an in vitro culture system for isolated proventricular epithelial cells. Various basal media, growth factors and sera were tested. The medium that supports well the proliferation of epithelial cells was composed of Ham's F12 as the basal medium with epidermal growth factor (10 μg/mL), insulin (10 μg/mL), cholera toxin (1 μg/mL) and bovine pituitary extract (100 μg/mL). Fetal calf serum stimulated cell proliferation 1.7-fold, while horse serum was rather toxic. Proventricular epithelial cells proliferated for 3 days, but began to die out within 1 week of culture. Cultured epithelial cells never expressed embryonic chicken pepsinogen (ECPg), a marker gene of glandular epithelial cells, or maintained ECPg expression. The capacity for ECPg expression in cultured epithelial cells was analyzed by recombination with the proventricular mesenchyme and ECPg was detected in epithelial cells cultured up to 3 days. We concluded therefore, that epithelial cells keep the capacity for ECPg expression for 3 days of cultivation and proventricular mesenchymal cells are required for the actual expression of the ECPg gene.     

Differential development of aldehyde dehydrogenase in fore- and glandular stomach in postnatal rats

Many foods contain the unsaturated aldehyde, hexadienal (HX). Human exposure is thus unavoidable. HX feeding to rodents caused cancers only in the forestomach. Aldehyde dehydrogenases (ALDH) are key enzymes in the metabolism of aldehydes. We examined the distribution of ALDH using HX as the substrate (HXDH) along the GI tract of adolescent rats and found that their stomachs have high levels of HXDH activity and the enzyme preferred HX > 9-cis-retinal > acetyl aldehyde > formyl aldehyde. We also followed the postnatal development of the stomach. At birth, the forestomach represented 40-50% of the total stomach weight. Both fore- and glandular stomach gained weight, with the glandular portion gaining at a faster rate. By 21 days, the forestomach was 24-28% of the total weight and decreased slightly to an adult level of 22-24%. Gastric HXDH is low from birth to 14 days of age. HXDH activity increased thereafter, reaching higher levels at 21 days and peaking around 30-36 days of age. The activity then decreased to the adult level. The fore- and glandular stomach had the same level of HXDH activity in the newborn and at 7 and 14 days of age. At weaning, HXDH activity was higher (3x) in the forestomach than in the glandular stomach. In adults, the forestomach still had 2x the HXDH activity compared to the glandular stomach. Zymograms showed similar isozyme patterns of HXDH but with different ratios of the three major forms between the forestomach and the glandular stomach. Results indicate a differential development of HXDH between the fore- and glandular stomach that might be related to the higher sensitivity of the forestomach to HX feeding.     

Fluid dynamics of the excretory flow of zymogenic and mucin contents in rat gastric gland processed by high-pressure freezing/freeze substitution.

The high-pressure freezing/freeze substitution technique followed by Lowicryl K4M embedding provided an excellent ultrastructure and retention of antigenicity of rat gastric glands as well as the intraluminal fluid contents. By taking this advantage, we histochemically investigated the excretory flow of the zymogenic and mucin contents in rat gastric glandular lumen at the ultrastructural level. The combination of KMnO(4)-UA/Pb staining for zymogenic contents and Griffonia simplicifolia agglutinin-II (GSA-II) labeling for mucous neck cell (MNC) mucin distinguished the exocytosed zymogenic contents from the MNC mucin in the glandular lumen. Interestingly, at the base and neck regions, the zymogenic contents showed a droplet-like appearance, forming a distinct interface with the MNC mucin. At the pit region, the GSA-II labeling demonstrated restricted paths, designated as MNC mucous channels, which flowed into the surface mucous gel layer. It should be noted that the interface between exocytosed zymogenic contents and MNC mucin disappeared, and that the zymogenic contents merged into the MNC mucous channels. At the top pit region, the surface mucous gel layer showed laminated arrays of three types of gastric mucins. On the basis of these ultrastructural findings, we propose a model of the excretory flow in rat gastric gland.     

Disorganization of stroma alters epithelial differentiation of the glandular stomach in adult mice

Summary The response of adult epithelium in contact with heterologous mesenchymes/stromas was studied in three digestive organs (forestomach, glandular stomach, and duodenum). After various tissues were implanted beneath the epithelial layer of adult mice, the epithelial differentiation was examined after sacrifice of animals at intervals up to 24 weeks. In the forestomach and duodenum, the epithelial differentiation was not affected at all by the tissue implantation. In the glandular stomach, in contrast, epithelial cells exhibited altered differentiation in which chief and parietal cells disappeared and were replaced by columnar epithelial cells with PAS-positive granules. These epithelial cells often formed immature villi. Such differentiation-altered columnar epithelium (DACE) was induced by implanting any type of tissue and even by sham operation, indicating that it was induced by disorganization of the tissue-implanted stroma. The size of DACE was significantly influenced by the stage of implanted tissue; 14.5-day fetal mesenchyme induced the largest DACE, and was followed by 16.5-day fetal mesenchyme, adult stroma, and sham operation. These results suggest the importance of stromal organization in maintaining epithelial differentiation in the glandular stomach.     

Localization of DNA-synthesizing cells and cell proliferation pattern in developing proventricular (glandular stomach) epithelium of embryonic and hatched chickens

Localization of DNA-synthesizing cells in the developing proventricular (glandular stomach) epithelium of embryonic and hatched chickens was investigated. DNA-synthesizing cells were scattered throughout the proventricular epithelium during all developmental stages studied. The results indicate that there is no clear proliferative zone in the proventricular epithelium of the chicken. The labeling indices (LI) of proventricular epithelial cells were measured. On the 6.5th day of incubation, the LI of glandular epithelium reached 29.5 ± 1.5%. the highest value of all the stages studied. This extremely rapid cell proliferation can be considered to be a driving force for the elongation of the proventricular glands during the following stages. Just after hatching, the LI of both the glandular and luminal (non-glandular) epithelia significantly increased from those on the 18th day of incubation. It is suggested that the rise in LI possibly reflected proventricular growth to fit in the change in the method of nourishment after hatching. In 2 week old chickens, the LI of both the glandular and luminal epithelia were reduced to approximately 1%. The active production of embryonic chicken pepsinogen in all glandular epithelial cells of the embryonic chicken revealed that proliferation and differentiation are not necessarily exclusive during the embryonic stages of proventricular development.