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.     

A Combined Stain for Identifying Epithelial Cells of the Gastric Mucosa

New techniques are proposed for differentiating each type of gastric epithelial cell in the same tissue section. The techniques combine the following stains: A) paradoxical concanavalin A staining (PCS) to identify mucous neck cells, B) periodic acid Schiff-concana-valin A staining to distinguish mucous neck cells from surface mucous cells, and C) a modified Bowie's stain to demonstrate zymogen granules of chief cells. Feulgen hydrolysis preceding the Bowie stain was found to remove most of the nonspecific coloration encountered with the original Bowie method. The results obtained by the new sequences were as follows: 1) Feulgen hydroIysis-PCS-Bowie staining: mucous neck cells stained brown and chief cell zymogen granules deep blue. The other mucin-secreting cells remained unstained; 2) Feulgen hydrolysis-PAS-concanavalin A-Bowic staining: mucous neck cells stained brown, zymogen granules stained deep blue to purplish blue and surface mucous cells stained purplish red.     

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.     

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.     

A combined stain for identifying epithelial cells of the gastric mucosa

New techniques are proposed for differentiating each type of gastric epithelial cell in the same tissue section. The techniques combine the following stains: paradoxical concanavalin A staining (PCS) to identify mucous neck cells, periodic acid Schiff-concanavalin A staining to distinguish mucous neck cells from surface mucous cells, and a modified Bowie's stain to demonstrate zymogen granules of chief cells. Feulgen hydrolysis preceding the Bowie stain was found to remove most of the nonspecific coloration encountered with the original Bowie method. The results obtained by the new sequences were as follows: Feulgen hydrolysis-PCS-Bowie staining: mucous neck cells stained brown and chief cell zymogen granules deep blue. The other mucin-secreting cells remained unstained; Feulgen hydrolysis-PAS-concanavalin A-Bowie staining: mucous neck cells stained brown, zymogen granules stained deep blue to purplish blue and surface mucous cells stained purplish red.     

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.     

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.     

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.     

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

Summary 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.     

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 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.     

Synthesis and migration of proteins and glycoproteins in juxtaglomerular cells of sodium-deficient rats

Summary Sections of juxtaglomerular cells from sodium-deficient rats were subjected to radioautography after a single intravenous injection of L-tyrosine3,5 ³H or of L-fucose ³H to identify the sites of synthesis and to follow the migration of newly-formed proteins and glycoproteins. As early as 2 min after injection of L-tyrosine ³H, the label was highest in the rough endoplasmic reticulum (RER), suggesting that cisternal ribosomes are sites of protein synthesis. By 60 min, much of the label had migrated from the RER to the Golgi complex. Some radioactivity was already present over specific granules by 2 min but a peak was reached at 4h. The label over myofilaments was evident at all time intervals, indicating a certain incorporation of tyrosine into their contractile and/or structural proteins. The label over the cell surface peaked at 4h. After injection of L-fucose ³H, there was an early and important relative specific radioactivity in the Golgi complex at 5 min with a peak at 20 min and a decrease thereafter. The label increased slightly but steadily in secretory granules and cell surface to reach maxima at 4 h. A low level of radioactivity was recorded in mitochondria at all time intervals. After injection of both fucose ³H and tyrosine ³H, the label was detected at relatively low levels in the cytosol. These results suggest that renin, as the major secretory glycoprotein of juxtaglomerular cells, is synthetized in the RER, packaged in the Golgi complex and found relatively rapidly in newly-formed secretory granules. Part of the fucose and tyrosine labels is also associated with the thick cell coat of these cells.Recipient of a summer fellowship from the Kidney Foundation of Canada     

Light and electron microscopic cytochemistry of glycoconjugates in the rectosigmoid colonic epithelium of the mouse and rat

The several cell types in mouse and rat rectosigmoid colon have been examined with light and electron microscopic methods for localizing and characterizing complex carbohydrates. Mucous cells, also termed vacuolated cells, and goblet cells comprised most of the deep crypt epithelium in both species, and absorptive columnar cells and goblet cells mainly populated the more superficial epithelium of the upper crypts and main lumen. Occasional tuft cells and enteroendocrine cells were also encountered. Transitional cells structurally intermediate between mucous cells and absorptive cells contained granules characteristic of mucous cells and vesicles like those of columnar absorptive cells. These intermediate cells supported the concept of replacement of mucous by absorptive cells through transformation of mucous into absorptive cells. The intermediate cells also contained numerous lysosomes often in apparent fusion with mucous granules, indicating crinophagic disposal of mucous granules as a mechanism in the cell transformation. Glycoconjugate in absorptive cell vesicles resembled that coating the apical plasmalemma and appeared to represent the source of the glycocalyx of the brush border. Complex carbohydrate in these vesicles differed cytochemically from that of the mucous cell granules, which release their content into the crypt lumen. The absorptive cell vesicles, therefore, constitute an organelle distinct from the mucous cell granules rather than an atrophic form of the latter in a more mature cell. Goblet cells differed in failing to transform morphologically with age but changed in the cytochemical characteristic of their secretion during migration up the crypts. Terminal N-acetylglucosamine residues diminished, while terminal sialic acid-galactose dimers increased during the upward migration, indicating activation of glycosyl transferase synthesis in relation to goblet cell maturation. Glycoconjugate in secretion of mucous cell granules differed markedly from that in goblet cell granules, and content of both organelles differed from that of absorptive cell vesicles. However, secretion in mucous cell granules appeared generally similar for mice and rats with minor exceptions, and secretion in goblets of mice generally resembled that in goblets of rats. Cells interpreted tentatively as Kulchitsky cells stained for high content of fucose with the Ulex europeus I lectin. Globoid leukocytes infiltrating the epithelium of the rat but not the mouse rectosigmoid colon resembled globoid leukocytes in rat tracheal epithelium and, like the latter, appeared to derive from mast cells.     

Ultrastructural radioautography of the incorporation of tritiated leucine by the rat adrenal medulla in vivo

Summary Sections of tissues from the adrenal medullae of young rats were subjected to radioautography after a single intravenous injection of L-leucine 4,5 ³H to identify the sites of synthesis and follow the migration of newly-formed proteins in both adrenaline-storing (A) and noradrenaline-storing (N) cells. As early as 2 min after injection of leucine ³H, the label was highest in the rough endoplasmic reticulum (RER) of A and N cells, suggesting that cisternal ribosomes are sites of protein synthesis. By 5 and 10 min, much of the label had migrated from the RER into the Golgi complex of both cell types. Some label was already present over the secretory granule matrix (chromogranins) by 2 min but the peak was reached at 1 h in both A and N cells. By 4 h, the label over the secretory granules had diminished, indicating a release of newly-synthetized chromogranins outside the cells. The label over the hyaloplasm was relatively high at 2 min but it decreased rapidly to low levels. In contrast, the label over the cell surface continually increased to reach the highest levels among all organelles at 4 h in both cell types. The pattern of increment of the label over the cell surface suggests that the newly-formed proteins of these sites are also synthetized in the RER, pass through the Golgi complex and are transported in the hyaloplasm, before reaching the surface of A and N cells.Supported in part by the Quebec Heart Foundation, the Medical Research Council of Canada (Grant MT-1973), the J.-L. Levesque Foundation, the Ministry of Education of Quebec (Formation de Chercheurs et Action Concertée) and the Fond de l'Université de Montréal (Cafir)     

Association of glycoproteins and pepsinogen in the secretory granules of fundic epithelial cells isolated from guinea pig stomach

Epithelial cells were isolated from the fundic portion of the guinea pig stomach. Cells were separated by velocity sedimentation at unit gravity in a Ficoll 70 gradient and pooled in three fractions. By morphological and biochemical criteria, each fraction was characterized as a population highly enriched in one of the three main functional types: oxyntic cell; chief cell and mucus-secreting cell. Measure of the pepsinogen content and specific stainings of the secretory granules for light and electron microscopy led to the definition of two types of mucus-secreting cells in nearly equal quantity; mucous cells with smaller secretory granules entirely glycoproteic in nature and muco-peptic cells containing larger heterogeneous secretory granules. These granules were made of a proteic core containing pepsinogen surrounded by a thin membrane and a voluminous cap, both containing carbohydrates. The cap appeared as if built of orderly packed layers of glycoproteins. Secretory granules of chief cells were also surrounded by a membrane containing glycoproteins and occasionally a small glycoproteic cap. Pepsinogen content was estimated to be three times higher in a single chief cell than in a muco-peptic cell.     

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.     

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.     

Application of rapid freezing followed by freeze-substitution acrolein fixation for cytochemical studies of the rat stomach

Summary A method involving rapid freezing followed by substitution fixation was developed, using acrolein as a fixative. This was then applied to several cytochemical stainings, and showed well preserved and clear cell structures. Membranes were apparently negatively stained and the ultrastructure of mitochondria, rough endoplasmic reticulum and Golgi apparatus was clearly discernible. The mitochondrial and cytoplasmic matrices were stained rather densely compared with routine chemically fixed preparations, implying a good preservation of matrix substrances. Periodic acid-thiocarbohydrazide-silver proteinate staining was applied to the present method. The mucous granules of surface covering epithelial cells indicated fine staining of bipartite structure and the Golgi apparatus of mucous cells showed clear staining differences based on polarity. Postembedding lectin-ferritin and immunocytochemical stainings were applicable to the present preparations and stable stainings of secretory granules were obtained. A low temperature embedding material, Lowicryl K4M, was also examined. The cell preservation of these samples was not as good as those embedded in Epon, but the rough endoplasmic reticulum and Golgi apparatus of chief cells were stained with anti-pepsinogen antibody as were the secretory granules. The present method was also applicable to light microscopy.     

Subcellular distribution of secretogranins I and II in GH3 rat tumoral prolactin (PRL) cells as revealed by electron microscopic immunocytochemistry

The GH3 rat pituitary cell line which secretes prolactin (PRL) is characterized by the paucity and small size of secretory granules. We looked for the presence, in these cells and in normal PRL cells, of two acidic tyrosine-sulfated proteins which are widely distributed in dense-core secretory granules of endocrine and neuronal cells, secretogranins I and II, using immunofluorescence and electron microscope immunoperoxidase techniques. Both secretogranins were detected in secretory granules of GH3 cells and of normal cells. Moreover, with our pre-embedding approach, secretogranins were localized within some RER cisternae and within all sacules of the Golgi stacks in both PRL cell models. A few small vesicles, large dilated vacuolar or multivesicular structures, and some lysosome-like structures were also immunoreactive. Double localization of secretogranins and PRL performed on GH3 cells by immunofluorescence indicated that all cells contained secretogranins I and II, whereas only 50-70% of the cells contained PRL. Moreover, in the case of hormone treatment known to increase the number of secretory granules, most if not all mature secretory granules were immunoreactive for secretogranins, whereas in certain cells some of the granules were apparently not immunoreactive for PRL. These immunocytochemical observations show that GH3 cells, which under normal conditions form only a small number of secretory granules, produce secretogranins and package them into these granules.