Glycoconjugate histochemistry of the rat fundic gland using Griffonia simplicifolia agglutinin-II during the development

The development and maturation of fundic glands of Wistar rats were studied using Griffonia simplicifolia agglutinin-II (GSA-II) histochemistry at the light microscopic and electron microscopic levels. In adult rats, mucous neck cells and cells intermediate between mucous neck cells and chief cells were specifically labeled with GSA-II, whereas other fundic gland cells were virtually negative. Ontogenetic studies revealed that GSA-II positive cells appeared at the bottom of the gland by 21 days of gestation. With differentiation and aging, the elongation of the fundic gland continued, and the labeling intensity of the mucous neck cells increased by 3 weeks after birth. Cells intermediate between mucous neck cells and chief cells were discernible from 3 days after birth. Typical mucous neck cells appeared at 3 weeks after birth, when their labeling intensity with colloidal gold (CG) particles approximated that of adults. On the other hand, the reactive cell population gradually moved from the bottom toward the middle portion of the gland. Finally, the reactive cells were localized at the neck portion of the fundic gland. These results suggest that GSA-II is a valuable marker for studying mucous neck cells and both their precursor cells and their derivatives.     

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.     

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.     

Localization of pepsinogen and cellular differentiation in the human gastric mucosa using lowicryl K4M

The localization of pepsinogens (PG A and PG C) was studied intracellularly in human gastric biopsies embedded in Lowicryl K4M, using affinity purified antibodies and protein A-gold. The homogeneous secretory granules of the chief cells contained both PG A and PG C, as was proved in serial sections. Identical reaction was seen in the core of the biphasic mocous neck cell granules, whereas the mantle did not label. Even the rough endoplasmic reticulum (RER) and Golgi complex of the chief- and mucous neck cells contained label. Transitional cells identified by the presence of granules of both chief- and mucous neck cells were seen. This type of mucous neck cell is thought to transform into a chief cell. However an increase of RER that could explain an increase of the pepsinogen production was not observed. A mixture of these granules were also found in morphologically characterized young parietal cells, suggesting a common precursor for these three cell-types. These observations makes the transformation from mucous neck- into chief cells questionable. In conclusion Lowicryl K4M appeared to be a significant improvement compared to the Epon 812. Its shows a better preservation of both cytoplasmic antigens and cellular fine structure. This improvement adds information on the transformation hypothesis. Lowicryl K4M enables us, firstly to distinguish PG A and C synthesizing RER in different types of cell and secondly to recognize immature cells with the characteristics of chief-, mucous neck-, and parietal cells in the fundic gland. Very likely these three cell-types all arise from a common precursor. It is questionable that in normal human gastric mucosa the mucous neck cells transform into chief cells.     

Glycoconjugate cytochemistry of the rat fundic gland using lectin/colloidal-gold conjugates and Lowicryl K4M. Helix pomatia lectin is a specific marker for mucous neck cells in fundic glands of the rat gastric mucosa

The fundic gland of the rat stomach was studied using the low-temperature embedding resin Lowicryl K4M and postembedding staining with lectin/colloidal-gold (CG) conjugates. Intense labeling with Ricinus communis agglutinin I was observed not only in mucous-producing cells but also in parietal cells. In contrast, Helix pomatia agglutinin (HPA) only labeled mucous neck cells and intermediate cells between mucous neck cells and chief cells. The other epithelial cells present in the rat fundic gland showed virtually no reaction with this lectin. Our results indicate that HPA might be a marker lectin of mucous neck cells and their derivatives. The combination of embedding in the hydrophilic resin Lowicryl K4M and postembedding staining with lectin-CG conjugates provided satisfactory staining results, and made it possible to visualize the precise distribution of terminal glycoconjugates in intracellular components as well as on the plasma membrane.     

Localization of pepsinogen (A and C) and cellular differentiation of pepsinogen-synthesizing cells in the human gastric mucosa

The localization of pepsinogens (PG A and PG C) was studied intracellularly in human gastric biopsies embedded in Lowicryl K4M, using affinity-purified antibodies and protein A-gold. The homogeneous secretory granules of the chief cells contained both PG A and PG C, as was proved by serial sections. Identical reaction was also seen in the core of the biphasic mucous neck cell granules, whereas the mantle did not label. The rough endoplasmic reticulum (RER) and Golgi complex of the chief cells and mucous neck cells contained ample label. Transitional cells identified by the presence of granules of both chief cells and mucous neck cells were recognized. This type of mucous neck cell is thought to transform into a chief cell. However, an increase of RER that could explain an increase of the pepsinogen production was not observed. A mixture of these granules was also found in cells morphologically characterized as young parietal cells, suggesting a common precursor for these three cell types. These observations make the transformation from mucous neck to chief cells questionable. Antral gland cells contained only PG C, as was shown in serial section, too.     

Glycoconjugate cytochemistry of the rat fundic gland using lectin/colloidal-gold conjugates and Lowicryl K4M

Summary The fundic gland of the rat stomach was studied using the low-temperature embedding resin Lowicryl K4M and postembedding staining with lectin/colloidal-gold (CG) conjugates. Intense labeling with Ricinus communis agglutinin I was observed not only in mucous-producing cells but also in parietal cells. In contrast, Helix pomatia agglutinin (HPA) only labeled mucous neck cells and intermediate cells between mucous neck cells and chief cells. The other epithelial cells present in the rat fundic gland showed virtually no reaction with this lectin. Our results indicate that HPA might be a marker lectin of mucous neck cells and their derivatives. The combination of embedding in the hydrophilic resin Lowicryl K4M and postembedding staining with lectin-CG conjugates provided satisfactory staining results, and made it possible to visualize the precise distribution of terminal glycoconjugates in intracellular components as well as on the plasma membrane.     

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.     

Expression of N-acetylglucosamine residues in developing rat fundic gland cells

The development of rat fundic gland was studied by immunohistochemistry using a recently developed monoclonal antibody, HIK 1083, at both light and electron microscope levels. Antibody HIK 1083 recognized oligosaccharides with a non-reducing terminal -linked N-acetylglucosamine (GlcNAc) residue. In the developing rat fundic gland, cells expressing -GlcNAc residues were discernible from day 19.5 of gestation and continued to exist till adult. The distribution of the -GlcNAc expressing cells was consistent with that described previously for cells reacting to Griffonia simplicifolia lectin (GSA-II) in all developmental stages. These cells were located at the bottom of the fundic gland when they first appeared. With the elongation and maturation of the gland, these cells moved upwards and were finally restricted in the neck region of the gland. Combining previous reports and the present electron microscopical observations, HIK 1083-positive cells in the adult rat fundic gland are mucous neck cells. The interaction between antibody HIK 1083 and GSA-II lectin was investigated. GSA-II prevented the subsequent binding of HIK 1083, while HIK 1083 did not prevent GSA-II binding to mucous neck cells. Our results suggested that -GlcNAc residues exist in rat fundic gland from day 19.5 of gestation and continue to exist till adult. Cells expressing -GlcNAc residues appeared as typical mucous neck cells from postnatal four weeks.     

Ontogeny of sulphated glycoconjugate-producing cells in the rat fundic gland

Summary The ontogeny of sulphated glycoconjugate-producing cells in the rat fundic gland has been studied using high iron diamine (HID), Alcian Blue (AB) at pH 1.0, high iron diamine in combination with Alcian Blue at pH 2.5 (HID-AB), cationic colloidal gold (CCG) at pH 1.0 under light microscopy and CCG (1.0), HID-thiocarbohydrazide (TCH)-silver proteinate (SP)-physical development (PD) under electron microscopy. From day 19.5 of gestation, sulphated glycoconjugate-producing cells were discernible under both light and electron microscopy. The development of such cells can be classified into four stages: (1) a prenatal period from day 19.5 of gestation extending to 0.5 days after birth; (2) 1 day to 2 weeks after birth; (3) 2 to 4 weeks after birth; and (4) the final period from 4 to 8 weeks after birth. Glycoconjugate-producing cells reached maturity by 4 weeks after birth. Our results indicated that glycoconjugate-producing cells were cells along the wall of foveolar lumen, but not those covering the gastric mucosa surface. Our results also suggested that thetrans totransmost Golgi apparatus lamellae were the sites of sulphation in the developing rat stomach.     

Bromodeoxyuridine-immunohistochemistry on cellular differentiation and migration in the fundic gland of Xenopus laevis during development

Summary Cellular differentiation and migration in the fundic glands of adult and larval Xenopus laevis have been examined using bromodeoxyuridine-immunohistochemistry. In the adult fundic gland, cumulative labeling with bromodeoxyuridine revealed a proliferative cell zone between the surface mucous cells and mucous neck cells, in what is referred to as the neck portion of the gland. The labeling-index of mucous neck cells had rapidly increased by week-5. The labeling-index of oxynticopeptic cells showed a more delayed increase until week-7, coincident with the decrease in the labeling of mucous neck cells. In the immature fundic glands of larvae, the labeled proliferating cells were randomly distributed throughout the developing gastric mucosa. During metamorphosis, the labeling-index of immature epithelial cells was highest at stage 63. Following administration of bromodeoxyurdine at this, stage, there was no significant loss of labeled epithelial cells during the metamorphosing period. Furthermore, there was no significant difference in the labeling-indices among the epithelial cells, such as surface mucous cells/generative cells, mucous neck cells, and oxynticopeptic cells, 7 days after administration. Cellular differentiation and migration pathways of epithelial cells in the fundic gland of adult X. laevis and its larvae are discussed.     

Angiotensin I converting enzyme in gastric mucosa of the rabbit: localization by autoradiography, immunofluorescence, and immunoelectron microscopy.

To localize angiotensin converting enzyme (ACE) in the fundic mucosa of the rabbit, we used autoradiography with the ACE inhibitor [3H]-trandolaprilate and post-embedding immunocytochemical techniques with a goat anti-rabbit ACE, using fluorescence and electron microscopy. Autoradiographic localization of [3H]-trandolaprilate in rabbit fundus sections shows that ACE is present in the fundic mucosa and mainly in the gland area. Fundic mucosa was fixed with 4% formaldehyde and embedded in Lowicryl K4M. Semi-thin (1 micron) or thin sections (800-900 A) were stained with anti-rabbit ACE followed by fluorescein isothyocyanate-labeled rabbit anti-goat IgG or protein A-gold reagent, respectively. Label was present on endothelium of all blood vessels running through the mucosa. Label was prominently localized in the granules of mucous surface and neck cells and on the granules of chief cells. The intracellular localization of ACE, and particularly its intragranular presence within chief and mucous cells, suggests that the enzyme, at the fundic level, is involved in the intragranular processing of a peptide, the nature of which remains to be determined.     

Development of gastric proteases in fetal pigs and pigs from birth to thirty six days of age. The effect of adrenocorticotropin (ACTH).

Development of the synthesis and secretion of gastric proteases was studied in 55 Large White x Landrace pigs from 22 days before birth (93 days gestation) to 36 days of age. The pigs came from eight litters and were 0.4 - 13.5 kg body weight. Littermate pairs were treated with either saline or adrenocorticotropin (ACTH) from three days of age. Secretion of protease activity (milk-clotting and general proteolytic activity) was investigated in anaesthetized pigs by a gastric perfusion technique using intravenous infusion of pentagastrin at dose rates of 4 and 8 micrograms/h per kg body weight. In addition, concentrations of protease zymogens (prochymosin, pepsinogen A, progastricsin) were measured in fundic tissue extracts by rocket immunoelectrophoresis. Prochymosin was present in fundic tissue at 22 days before birth, reached peak concentrations at birth and decreased in concentration during the subsequent 36 days. Pepsinogen A and progastricsin were absent or present in trace amounts in the first week after birth, but thereafter concentrations of both zymogens increased rapidly. Development of the pentagastrin-stimulated secretion of protease activity reflected the changes of zymogen concentrations in fundic tissue. Chronic treatment of pigs with ACTH from three days of age significantly increased the concentration of prochymosin in fundic tissue at 9-11 days and the concentrations of pepsinogen A and progastricsin at 34-36 days of age. Hormones such as ACTH and glucocorticoids may therefore play a regulatory role in the ontogeny of porcine gastric proteases.     

Glycoconjugate distribution in the human fundic mucosa revealed by lectin- and glycoprotein-gold cytochemistry

The glycoconjugates of the human fundic mucosa were characterized at the ultrastructural level by means of direct (Helix pomatia agglutinin-gold complex) and indirect lectin techniques (Concanavalin A and horseradish peroxidase-gold complex; wheat germ agglutinin and ovomucoid-gold complex). Surface mucous cells and mucous neck cells secreted O-glycoproteins with N-acetylgalactosamine and N-acetylglucosamine residues at the non reducing terminus of the saccharidic chain. The secretory granules of the mucous neck cells showed condensed areas slightly reactive to ConA. The results obtained in the chief cells suggest that these cells secrete N-glycoproteins rich in mannose and/or glucose residues. "Transitional cells", presenting both morphological characteristics and lectin binding pattern intermediate to the mucous neck and chief cells have been observed. The surface of the intracellular canaliculi of the parietal cell was labelled by HPA, WGA and ConA. In the neck region of the gastric glands, immature parietal cells containing abundant mucous granules reactive to HPA, WGA and ConA were observed. The present results further corroborate the existence of a common cell precursor for surface mucous, mucous neck and parietal cells. In a further step, mucous neck cells gradually differentiate into chief cells the transitional cells being an intermediate stage.     

Self-renewal of the human gastric epithelium: new insights from expression profiling using laser microdissection

The gastric mucosa is subject to continual bidirectional renewal by differentiation from stem and transit amplifying cells. It was the aim of this study to characterize the self-renewal of the human gastric mucosa and its two major types of glands in the fundus and antrum, respectively. Three characteristic regions (pit, proliferative, and lower neck regions) were isolated from fundic and antral units by the use of laser microdissection, and expression profiles concerning 15 marker genes were generated by RT-PCR analysis. The surface mucous cells (SMCs) of fundic and antral units differed in their expression of at least four secretory genes, i.e., gastric lipase, TFF3, FCGBP, and lysozyme. The maturation of mucous neck cells was shown to occur stepwise, first towards a mucous phenotype followed by a serous differentiation step. Also, a stepwise maturation of both the antral SMCs and antral gland cells was observed. Additionally, the presence of gastric lipase was also demonstrated for the first time in antral gland cells. In conclusion, the different expression profiles of SMCs of the fundic and antral units could be the basis for the different self-renewal rates of fundic and antral SMCs and could influence the spatial organization of the bacterial microbiota within the various parts of the gastric mucosa.     

Immunocytochemical localization of cyclooxygenase-1 and cyclooxygenase-2 in the rat stomach

Summary Prostaglandins are considered to play important roles in gastric mucosal protection. The rate-limiting enzyme involved in the biosynthesis of prostaglandins is cyclooxygenase (COX), also known as prostaglandin H synthase. Two forms of COX are known: a constitutively expressed form (COX-1) and a newly-characterized, inducible form (COX-2). In the present study, the immunocytochemical localization of COX-1 and COX-2 was examined in the rat gastrointestinal tract. A strong immunoreactivity for COX-1 was localized in the mucous neck cells of gastric gland. A weak reactivity for COX-1 was also found in the mucous cell types in the cardiac gland and pyloric gland of the stomach as well as in the Brunner's gland of duodenum. Ultrastructurally, the immunoreactivity was localized to the apical cytoplasm of these cells. On the other hand, immunoreactivity for COX-2 was distributed in the surface mucous cells in both the fundic and pyloric regions of stomach. These results suggest that a subset of mucous cells is the primary site for production of prostaglandins in the rat gastrointestinal tract, and that two forms of COX are expressed in distinct types of mucous cell.     

Distribution of the glio-interstitial system in molluscs

Summary Ten hamsters received repeated injections of ³H-thymidine for 4 days and were allowed to survive for 7, 28, 42 and 100 days. Changes in spatial distribution of the labelled cells and in labelling indices of each cell line in the gastric glands were studied at various days after ³H-thymidine injections, and the fate of the mucous neck cell, the replacement of the chief cell and the mode of cell migration were discussed.After 4 days of repeated injections of ³H-thymidine, the labelled parietal cells and the mucous neck cells were concentrated at the neck area. Starting from the neck area, they migrated an average of 3 micra downwards per day. By 42 days, they reached the middle level of the glands, where the labelled mucous neck cells decreased but the labelled chief cells increased in number. The differentiation of the chief cell then appears to take place at the middle level of the glands through transformation of the migratory mucous neck cells. After 4 days of the labelling, about 1.8% of the chief cells located in the lower part of the glands was found to undergo in situ replication. This indicates that the renewal of this cell type is partly assured by its own mitotic activity.The foveolar cell — the future surface epithelium — seems to migrate upwards along the long axis of the glandular tubule in the pipe line system, which means first produced, first migrates. After migrating out from the neck area, the parietal cell and the mucous neck cell (the future chief cell) take an average of 200 days to reach the lower end of the glands. In the process of migration, however, the cells produced contemporaneously at the neck area became scatteringly spread from the neck towards the bottom of the gland. The time required for the newly-formed cells to reach the lower end of the gland varied between 100 and 300 days. In the gastric glands the cells first produced at the neck area do not first reach the lower end of the glands. This mode of random migration is referred to as the stochastic flow system. As one of the probable factors which disturb the pipe line flow of downward cell migration, cellular movements perpendicular to the long axis of the glandular tubule were suggested to occur at random at an any level of the gastric glands.Supported by a Grant-in-Aid for Cancer Research from the Ministry of Education, Science and Culture, Japan     

The origin of pre-neoplastic metaplasia in the stomach: chief cells emerge from the Mist

The digestive-enzyme secreting, gastric epithelial chief (zymogenic) cell is remarkable and underappreciated. Here, we discuss how all available evidence suggests that mature chief cells in the adult, mammalian stomach are postmitotic, slowly turning over cells that arise via a relatively long-lived progenitor, the mucous neck cell, The differentiation of chief cells from neck cells does not involve cell division, and the neck cell has its own distinct pattern of gene expression and putative physiological function. Thus, the ontogeny of the normal chief cell lineage exemplifies transdifferentiation. Furthermore, under pathophysiogical loss of acid-secreting parietal cell, the chief cell lineage can itself trasndifferentiate into a mucous cell metaplasia designated Spasmolytic Polypeptide Expressing Metaplasia (SPEM). Especially in the presence of inflammation, this metaplastic lineage can regain proliferative capacity and, in humans may also further differentiate into intestinal metaplasia. The results indicate that gastric fundic lineages display remarkable plasticity in both physiological ontogeny and pathophysiological pre-neoplastic metaplasia.