Immunocytochemical localization of nerve growth factor in mouse salivary glands

Summary The submandibular glands of female mice and the sublingual and parotid glands of adult male and female mice have been examined by light microscopical immunocytochemistry for nerve growth factor (NGF). In female submandibular glands, staining for NGF was observed in granular convoluted tubule and striated duct cells. Sublingual glands of the mouse contained relatively few granular cells staining for NGF compared with submandibular glands. However, such granular cells appeared to be more numerous in male sublingual glands than in female glands. The remainder of the intralobular duct cells in both male and female sublingual glands exhibited apical subluminal staining for NGF as well as light basal plasmalemmal staining. Parotid glands in both male and female mice exhibited a similar pattern of staining for NGF in striated duct cells. However, the glands did not contain granular cells nor did they exhibit any pattern of staining which reflected a sexual dimorphism. Immunodot staining of salivary gland extracts confirmed the presence of immunoreactivity for NGF in all three of the major salivary glands.     

Endocrine cells of the esophageal glands]

Distribution of endocrine cells in the human oesophagus was studied histochemically. Large amount of endocrine cells was discovered in terminal parts and excretory ducts of the cardial glands. Endocrine cells of the oesophageal cardial glands are represented, at least, by three types: argentaffine, argyrophil in the reactions of Grimelius and Sevier, Munger and argyrophil in the reaction of Grimelius only. The amount of argentaffine cells in the oesophageal cardial glands was observed to be 5 times as large as that of in the gastric cardial glands. The reason is evidently in functional difference of the oesophageal and gastric cardial glands. The endocrine cells were absent in the mucous glands of the oesophagus.     

A high resolution sem study of human minor salivary glands

By SEM we have investigated the human minor salivary glands using the NaOH method for the visualization of endpieces and myoepithelial cells, and the osmium maceration technique that reveals membranous intracellular structures. With the former method all minor glands, including the posterior deep (Ebner's) lingual glands, consist of tubules sometimes dilated into alveoli, while true acini of the kind observed in human major salivary glands, are absent. Tubules of the posterior deep lingual gland exhibit stellate myoepitelial cells that leave a substantial part of the secretory cells uncovered. The latter cells, at variance with serous cells of major glands, do not show basal folds. In contrast, tubules of the other minor glands, like the mucous ones of major glands, are covered almost completely by band-like myoepithelial cells. The osmium maceration method clearly demonstrates that posterior deep lingual glands are serous in character and that all the other minor glands, together with the predominant mucous cells, possess a variable number of seromucous cells that, despite variations among individuals, increase in order from palatine and posterior superficial lingual (Weber's), to minor sublingual, labial, anterior lingual (Blandin and Nuhn's), and buccal glands.     

Expression and localization of immunoreactive-sialomucin complex (Muc4) in salivary glands

Sialomucin Complex (SMC; Muc4) is a heterodimeric glycoprotein consisting of two subunits, the mucin component ASGP-1 and the transmembrane subunit ASGP-2. Northern blot and immunoblot analyses demonstrated the presence of SMC/Muc4 in submaxillary, sublingual and parotid salivary glands of the rat. Immunocytochemical staining of SMC using monoclonal antisera raised against ASGP-2 and glycosylated ASGP-1 on paraffin-embedded sections of parotid, submaxillary and sublingual tissues was performed to examine the localization of the mucin in the major rat salivary glands. Histological and immunocytochemical staining of cell markers showed that the salivary glands consisted of varying numbers of serous and mucous acini which are drained by ducts. Parotid glands were composed almost entirely of serous acini, sublingual glands were mainly mucous in composition and a mixture of serous and mucous acini were present in submaxillary glands. Since immunoreactive (ir)-SMC was specifically localized to the serous cells, staining was most abundant in parotid glands, intermediate levels in submaxillary glands and least in sublingual glands. Ir-SMC in sublingual glands was localized to caps of cells around mucous acini, known as serous demilunes, which are also present in submaxillary glands. Immunocytochemical staining of SMC in human parotid glands was localized to epithelial cells of serous acini and ducts. However, the staining pattern of epithelial cells was heterogeneous, with ir-SMC present in some acinar and ductal epithelial cells but not in others. This report provides a map of normal ir-SMC/Muc4 distribution in parotid, submaxillary and sublingual glands which can be used for the study of SMC/Muc4 expression in salivary gland tumors.     

Immunohistochemical evidence for the presence of progesterone receptor in rat submandibular glands.

Immunohistochemical analysis of progesterone receptor was carried out in rat submandibular glands. Immunoreactivity to progesterone receptors was found in cell nuclei of the intralobular duct system within male and female rat submandibular glands. The female glands contained more immunoreactive cells than the male glands. In ovariectomized rats progesterone receptor-containing cells decreased in number while testectomized glands revealed an increase. When estradiol was administered to gonadectomized rats of both sexes, the immunoreactivity in cells of the intralobular duct system markedly increased. These results suggest the possibility that progesterone may modulate various metabolic functions in the rat submandibular glands.     

Biological behavior of myoepithelial cells in the regeneration of rat atrophied sublingual glands following release from duct ligation

Summary The present study aimed to clarify how myoepithelial cells behave during regeneration of an atrophied sublingual gland by investigating cell proliferation and ultrastructure. Atrophy of rat sublingual glands was induced by unilateral ligation of the excretory duct near the hilum with metal clips, which were then removed after one week of ligation for regeneration. The sublingual glands 0–14 days after unligation were examined with single immunohistochemistry for actin as a marker of myoepithelial cells, double immunohistochemistry for actin and proliferating cell nuclear antigen (PCNA) as a marker of proliferating cells, and transmission electron microscopy (TEM). The single immunohistochemistry and TEM showed that myoepithelial cells surrounded residual ducts in the atrophied glands and immature and mature acini in the regenerating glands. Although PCNA-positive myoepithelial cells were identified during regeneration, PCNA labeling indices of myoepithelial cells were low at all time points except at day 7. Ultrastructurally, myoepithelial cells showing bizarre shaped structures in the atrophy changed with maturation of differentiating acinar cells and appeared normal in the regenerated glands. There was no differentiation of the remaining duct cells to myoepithelial cells. These observations suggest that proliferation of myoepithelial cells and differentiation to myoepithelial cells do not commonly participate in the regeneration of atrophied sublingual glands and that the bizarre shaped myoepithelial cells in the atrophied sublingual glands recover the original shapes with acinar cell regeneration.     

Different localizations of 21 and 27 kDa gap-junction proteins in rat salivary glands

Antibodies against 21 and 27 kDa gap-junction proteins from rat liver were used to examine the identification and localization of gap-junction proteins in rat salivary glands. Acinar cells of the submandibular glands and parotid glands stained well for the 27 kDa gap junction protein and less intensely for the 21 kDa protein. Acinar cells of the sublingual glands were stained heavily for the 27 kDa gap junction protein and stained well for 21 kDa gap junction protein. No 27 kDa protein was observed in the ducts of the salivary glands. The 21 kDa gap-junction protein was distributed in some of the intercalated ducts in the parotid and submandibular glands. Immunoblotting of an extract of parotid glands with antibodies against 21 and 27 kDa gap-junction proteins revealed the presence of 21 and 27 kDa proteins in the parotid glands. It is concluded that the 27 kDa gap-junction protein in tistributed as a major component of the gap junctions in the acinar cells of all the salivary glands; the 21 kDa protein is localized as a minor component in the acinar cells and some portions of the intercalated ducts in the salivary glands. It is possible that these gap-junction proteins might contribute to the regulation of function of the salivary glands.     

Glycoprotein hormone alpha-subunit in human stomach

To demonstrate the immunoreactive alpha-subunit of human chorionic gonadotropin (hCG) or glycoprotein hormones in non-neoplastic gastric mucosa, and to clarify the nature and significance of alpha-subunit-immunoreactive cells, immunohistochemical studies were performed on gastric mucosa using polyclonal antibodies for hCG alpha and beta, hLH beta, hFSH beta, hTSH beta, and gastrin, and a monoclonal antibody for hCG alpha. Surgically resected stomachs were classified as follows: nearly normal (Group A); antral gastritis (Group B); fundic gastritis with pseudopyloric glands (Group C); and intestinal metaplasia (Group D). Cells immunoreactive for the alpha-subunit were present in the pyloric glands and to a lesser extent in the fundic glands (Groups A and B). Almost all alpha-subunit-immunoreactive cells were nonreactive for the beta-subunits of the four glycoprotein hormones. alpha-subunit-immunoreactive cells corresponded to gastrin-containing cells in the pyloric glands, but were unrelated to gastrin in the fundic glands. In fundic gastritis, alpha-subunit-immunoreactive cells appeared to increase (Group C), and many hyperplastic foci were observed in atrophic glands with hyperplasia of the argyrophilic cells (Groups C and D). Isolated hCG alpha or the alpha-subunit of glycoprotein hormones may be present in the endocrine cells of gastric mucosa, and alpha-subunit-immunoreactive cells in the fundic glands seem to proliferate in fundic gastritis.     

Ultrastructure of the cardiac and pyloric glands of the gastric mucosa of the South African hedgehog,Atelerix frontalis

The cardiac and pyloric glands in the gastric mucosa of the South African hedgehog, Atelerix frontalis, are described. The cardiac area of the stomach contains proper cardiac glands and lacks undifferentiated fundic glands. The cardiac glands are simple tubular, coiled, and lined with columnar cells ultrastructurally similar to those of the gastric surface epithelium. Secretory granules with varying electron densities fill the apical cytoplasm of these cells. In contrast to other mammals, these glands lack mucous neck cells. The neck of the pyloric glands contains only a single cell type, whereas the basal regions of these glands contain “light” and “dark” cells. The secretory granules in the “dark” cells and the pyloric neck cells have a moderate electron density and often contain an electron dense core. An electron-lucent cytoplasm with numerous polysomes is characteristic of the “light” cells. Some “light” cells contain electron-dense granules in the apical cytoplasm. The presence of only neutral mucins in the cardiac gland cells denotes the absence of mucous neck cells. The acidic mucins within the pyloric neck cells seem to indicate that these cells are mucous neck cells, whereas the neutral mucins within the basally located pyloric gland cells show at least a partial functional difference from the pyloric neck cells. © 1993 Wiley-Liss, Inc.     

Turkey breeder hen infertility associated with plasma cells in the uterovaginal sperm storage glands

Uterovaginal sperm storage glands taken from fertile and infertile turkey breeder hens were analyzed morphologically using transmission electron microscopy. Sperm storage glands from the infertile hens were generally devoid of spermatozoa, while glands from the fertile hens contained many such cells. Extensive lymphocytic infiltration into the basolateral clefts between contiguous cells of the sperm glands was found in both fertile and infertile hens. Plasma cell infiltration into these intracellular clefts was also found in infertile turkeys. Plasma cells were not found, however, in the glandular clefts of fertile hens.Lymphocytes present in the sperm storage glands of fertile hens are theorized to be regulatory suppressor T-cells, which could explain the hen's immunological tolerance to continual exposure to antigenic spermatozoa. Conversely, the presence of antibody-producing plasma cells in the sperm storage glands of infertile hens could explain the absence of stored spermatozoa and the reduced fecundity of these hens.     

Gastric lipase and pepsinogen during the ontogenesis of rabbit gastric glands

In rabbit stomach, gastric lipase activity level was found to increase from birth to 30 days old (weaning), and then decreased. In contrast, pepsin activity only appeared between 30 to 45 days old, and increased till to the adult level. It was observed that maturation of gastric glands in cardial mucosa was a downward elongation process from the mitotic cell pool. These mitotic cells were always found in the neck of the gastric glands, corresponding to the bottom of the gland at 6 days old and to the mid-zone of the gland in adult. Location of rabbit gastric lipase (RGL) cells in cardial glands varied with age and was found along the pit of the gastric glands at 6 days old. The extent of this cellular location decreased with age, whereas a second RGL cell zone appeared below the mitotic cell area at 18 and 30 days old. At 45 days old, the pepsinogen cells appeared in the bottom of the gland, and consequently the RGL cells were located in the mid-zone of the gastric glands, between mitotic cells (neck of the gland) and pepsinogen cells (lower part of the gland). Ultrastructural study of cardial gastric glands revealed different morphologies of the secretion granules in the cells along the gastric glands. In 6-day-old rabbits, secretory granules were found uniformly electron dense in the bottom of the glands and were RGL-labeled by the immunogold technique. In the medium part of the glands, granules appeared biphasic, with a clear and a dense part, and RGL labeling was confined to the electron-dense part.(ABSTRACT TRUNCATED AT 250 WORDS)     

Distribution of S-100 protein and its subunits in bovine exocrine glands

 The distribution of S-100 protein and its α- and β-subunits in bovine exocrine glands was studied by indirect immunohistochemistry. The entire spectrum of salivary glands, glands of the respiratory tract, intestinal glands, male and female genital glands, and skin glands was examined. S-100 and its β-subunit were identified in most serous secretory cells of mixed salivary glands, although secretory acini in some serous glands remained unreactive for these antigens. Mucous cells were constantly negative; mucoid cells were positive in the lacrimal and Harderian gland. The α-subunit of S-100 protein was identified in serous cells but the staining reaction was faint. Subunits of S-100 showed a characteristic distribution along the excretory duct systems of compound glands: S-100 and the β-subunit were present in intercalated duct epithelium, while striated duct epithelium stained for S100-α. Therefore, it is suggested that S100-α is related to resorption and secretion in striated ducts, while S100-β may govern acinar exocytosis and probably regulates proliferation and differentiation of glandular cells. Differing staining intensities for S-100 and its subunits in secretory cells of exocrine glands most probably indicate functional differences with regard to secretory activity and the cell cycle. Accepted: 11 February 1997     

Absent secretion to vasoactive intestinal peptide in cystic fibrosis airway glands

We are testing the hypothesis that the malfunctioning of airway gland serous cells is a component of cystic fibrosis (CF) airway disease. CF is caused by mutations that disrupt CF transmembrane conductance regulator, an anion channel essential for proper fluid secretion in some epithelia. Submucosal glands supply most of the mucus in upper airways, and gland serous cells are the primary site of CF transmembrane conductance regulator expression in airways. We have discovered a major defect in CF glands by in situ optical monitoring of secretions from single human airway glands. CF glands did not secrete to agents that elevated [cAMP](i) (0 responses/450 glands, 8 subjects), whereas glands were responsive in all donor tracheas (605/827 glands, 15 subjects) and in bronchi from subjects who were transplanted because of other lung diseases (148/166 glands, n = 10). CF glands secreted to cholinergic stimulation, and serous cells were abundant in glands from all CF subjects. The complete absence of secretion to agents that elevate [cAMP](i) suggests that altered secretion of gland mucus could contribute to CF lung disease.     

Postnatal growth of the rat palatine gland

To elucidate how the palatine glands grow postnatally, the palatine glands of rats from 0 to 8 weeks of age were investigated histologically and immunohistochemically. Under light microscope, three dimensions of the right part of the palatine glands were measured and the total number of excretory ducts of the glands was counted from the parasagittal serial sections. Immunohistochemistry with anti-5-bromo-2'-deoxyuridine (BrdU) monoclonal antibody was also employed to detect the cellular proliferative activity. At birth (0 weeks), the palatine glands consisted of ducts and immature acini. The ducts in the glands were connected with excretory ducts. After 2 weeks, there was no duct in the glands. Most acinar cells became mature as mucous cells and took the form of tubulo-acini connected directly with excretory ducts. In the posterior region of the glands, serous acinar cells forming demilunes were occasionally seen. All three dimensions of the palatine glands became longer, and the number of excretory ducts tended to increase. Immunohistochemistry showed acinar and duct cells were highly proliferative in early stage of postnatal life and their proliferative activity decreased thereafter. This study demonstrated that immature rat palatine glands of newborn rats grow three-dimensionally during maturation, and that the parenchymal cell proliferation contributes to the growth of the rat palatine glands. In addition, it is suggested that the glandular tissue arises from the excretory ducts formed postnatally.     

Immunohistochemical and ultrastructural investigation of acinar cells in submandibular and sublingual glands of rats fed a liquid diet

In atrophic parotid glands induced by liquid diet, acinar cell apoptosis is increased while proliferative activity is reduced. This study aimed to clarify how liquid diet affects submandibular and sublingual glands, including acinar cell apoptosis and proliferation. Seven-week-old male Wistar rats were fed either a liquid (experimental group) or pellet diet (control group) from 3 to 21 days, respectively. Submandibular and sublingual glands were weighed and examined histologically, ultrastructurally, and immunohistochemically using antibodies to cleaved caspase-3 (Casp-3) and 5-bromo-2′-deoxyuridine (BrdU). Weights of submandibular and sublingual gland from the experimental group were not significantly different from controls at any time point. Histological and ultrastructural characteristics of experimental acinar cells in both glands were normal. Acinar cells in control and experimental submandibular glands were positively stained with periodic acid Schiff (PAS) and weakly stained by alcian blue (AB). In control and experimental sublingual glands, mucous acinar cells were PAS-positive and strongly AB-positive. Although Casp-3- and BrdU-positive acinar cells were identified in both glands in the experimental group, their labeling indices were not significantly different from controls. In conclusion, liquid diet in rats does not induce atrophic alterations to acinar cells, including apoptosis and proliferative activity in submandibular and sublingual glands.     

Morphological and Histochemical Study of Cephalic Glands of Bothrops jararaca (Ophidia,Viperidae)

Morphological and histochemical studies of the cell types in the cephalic glands of Bothrops jararaca have been performed. It is concluded: 1) mucous cells are found in the salivary labial, accessory glands; mucous-serous cells are found in the salivary labial, accessory and Harderian glands; serous-mucous cells are found only in the venom gland; 2) neutral mucosubstances and protein were found in the salivary labial, venom, accessory and Harderian glands; 3) hyaluronic acid was detected in the Harderian gland; 4) of the to sulfated acid mucosubstances, only chondroitin sulfate B was detected in the salivary labial and accessory glands; 5) sialic acid was detected in the salivary labial, accessory and Harderian glands.     

Ultrastructure of the glands producing sex pheromones of the male Nauphoeta cinerea (Insecta,Dictyoptera)

Summary The abdominal glands described here play a decisive role in the typical sexual behavior of Nauphoeta cinerea. Unlike other cockroaches, the males of this species produce two successive chemical signals: the sex pheromone itself, produced by the sternal glands, attracts the female from a distance, and the aphrodisiacs, secreted by the tergal glands, are licked by the female who is thus in a favorable position for mating. The well developed glandular apparatus is composed of 5 sternal glands (St3 to St7) and 7 tergal glands (T2 to T8). These glands appear as a thickening of the epithelium without significant modification of the external cuticle. The glandular epithelium is made up of several kinds of cells: ordinary epidermal cells (which only exist in the sternal glands), cells with microtubules, type 2 cells (oenocytes), and especially type 3 glandular units (composed of a secretory cell and a canal cell). The products secreted by the sternal glands are chiefly volatile products and fatty acids and those secreted by the tergal glands are primarily fatty acids and proteins. In this work, the relationship between the cytology of the glandular cells and the nature of the secreted products is discussed.     

Foot glands in Perna indica and Perna viridis (Pelecypoda: mytilidae) histology and histochemistry

The foot of Perna viridis is found to contain three main types of glands, the white gland, phenol gland and the enzyme gland. But in Perna indica there are only two glands, the phenol gland and the enzyme gland. Besides these, mucous glands are found in both of the species. The shape and size of the cells of these glands vary from species to species. Glycogen and 1 : 2 glycol groups are found in these gland cells. Proteins rich in disulfides and sulfhydryls are present in the phenol glands of both the species and in the white gland of p. viridis but they vary in the intensity of staining. The presence of phenols is confirmed in the phenol gland cells. Phospholipids and lipoproteins are intense in the white and phenol gland cells. They are absent in the enzyme gland. Alkaline and acid phosphatases activity in the enzyme gland cells could be demonstrated. The secretions of these glands help in the formation of the byssus threads. The mucous gland cells are subepithelial localised they secrete acid and neutral mucopolysaccharides together with glycoproteins. Which participate in the attachment of the byssus disc.     

Morphofunctional studies on human labial salivary glands

In this study, the first experimental investigation carried out at the ultrastructural level on mucous cells of human salivary glands, we have examined by light microscopy (LM), transmission electron microscopy (TEM), high resolution scanning electron microscopy (HRSEM), the secretory response of labial glands stimulated in vitro by the beta-adrenergic agent, D,L isoproterenol, and by the muscarinic agent carbachol. For comparison we have used identical methods to study samples of mixed portions of human submandibular glands. Morphological findings obtained here on both submandibular and labial glands mucous cells demonstrate that mucous droplets are released solely by muscarinic stimulation, and that cytological events occurring during secretory discharge are similar to those described by others, using TEM, on stimulated mucous cells of rat sublingual glands. Despite the fact that human labial glands are said to have a prominent cholinergic innervation with scanty adrenergic nerves, the response of seromucous cells in these organs to stimulation with carbachol and with isoproterenol was similar to that observed by us, (using LM, TEM and HRSEM), in serous cells of human major salivary glands.     

Quantitative characteristics of the endocrine cells of the duodenal glands of Carnivora

In the duodenal glands of the Carnivora investigated endocrine elements have been revealed, a part of them is presented as serotonin-producing EC-cells. Endocrine cells are situated in terminal parts and in glandular ducts, among them elements of open and close types are distinguished. Distribution of these cells in the glandular lobules is subjected to the distal gradient regularity, specific for the gastrointestinal tract mucosal membrane. Amount of endocrinocytes in the glands is much less than in the gut crypts. There is no correlation between distribution of the endocrine cells in the glands and in the crypts. The results of unifactor analysis of variance demonstrate a slight effect of the taxonomic position of the species on the number of endocrine cells in the duodenal glands. The proper endocrine apparatus of the duodenal glands is supposed to produce a local regulatory influence on the secretory activity of exogenic glandulocytes, as well as ensure humoral connections of the duodenal glands with other parts of the gastrointestinal tract.