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.     

Histochemical and biochemical determination of calcium in salivary glands of cat

Although feline salivary glands have been used in investigations on secretion and microlithiasis and both processes involve calcium, nothing is known about its distribution in these glands. Therefore we have demonstrated the presence of calcium by a histochemical technique using glyoxal bis(2-hydroxyanil) and a biochemical technique using dry ashing. The histochemical technique stained serous acinar cells weakly and rarely found mucous acinar cells strongly in the parotid gland, mucous acinar cells moderately to strongly and serous acinar cells weakly in the sublingual gland, and central and demilunar acinar cells moderately to strongly in the submandibular gland. The biochemical technique revealed less calcium in the parotid than in the submandibular and sublingual glands. Both techniques revealed a decrease of calcium in submandibular and sublingual glands following parasympathetic stimulation. The histochemical distribution of calcium, which corresponds to that of acinar secretory glycoprotein, and the loss of calcium following parasympathetic stimulation, which causes release of secretory granules, indicate the presence of calcium in secretory granules. The concentration of calcium in the different types of acinar cell corresponds to the acidity of the secretory glycoprotein and suggests that calcium is present as a cationic shield to allow the condensation of polyionic glycoprotein in secretory granules.     

Electron microscopic immunogold localization of salivary mucins MG1 and MG2 in human submandibular and sublingual glands.

The human salivary mucins MG1 and MG2 are well characterized biochemically and functionally. However, there is disagreement regarding their cellular and glandular sources. The aim of this study was to define the localization and distribution of these two mucins in human salivary glands using a postembedding immunogold labeling method. Normal salivary glands obtained at surgery were fixed in 3% paraformaldehyde-0.1% glutaraldehyde and embedded in Lowicryl K4M or LR Gold resin. Thin sections were labeled with rabbit antibodies to MG1 or to an N-terminal synthetic peptide of MG2, followed by gold-labeled goat anti-rabbit IgG. The granules of all mucous cells of the submandibular and sublingual glands were intensely reactive with anti-MG1. No reaction was detected in serous cells. With anti-MG2, the granules of both mucous and serous cells showed reactivity. The labeling was variable in both cell types, with mucous cells exhibiting a stronger reaction in some glands and serous cells in others. In serous granules, the electron-lucent regions were more reactive than the dense cores. Intercalated duct cells near the acini displayed both MG1 and MG2 reactivity in their apical granules. In addition, the basal and lateral membranes of intercalated duct cells were labeled with anti-MG2. These results confirm those of earlier studies on MG1 localization in mucous cells and suggest that MG2 is produced by both mucous and serous cells. They also indicate differences in protein expression patterns among salivary serous cells.     

Ultrastructural immunocytochemical localization of cyclic AMP-dependent protein kinase regulatory subunits in rat parotid acinar cells

Polyclonal antibodies to types I and II regulatory (R) subunits of cyclic AMP-dependent protein kinase (cA-PK) were utilized in a post-embedding immunogold-labeling procedure to localize these proteins in rat parotid acinar cells. Both RI and RII were present in the nuclei, cytoplasm, rough endoplasmic reticulum (RER), Golgi apparatus, and secretory granules. In the nuclei, gold particles were mainly associated with the heterochromatin. In the cytoplasm, the label was principally found in areas of RER. Most gold particles were located between adjacent RER cisternae or over their membranes and attached ribosomes; occasional particles were also present over the cisternal spaces. Labeling of the Golgi apparatus was significantly greater than background, although it was slightly lower than that over the RER cisternae. In secretory granules, gold particles were present over the granule content; no preferential localization to the granule membrane was observed. Morphometric analysis revealed equivalent labeling intensities for RI and RII in the cytoplasm-RER compartment. Labeling intensities for RII in the nuclei and secretory granules were about 50% greater than in the cytoplasm-RER, and 3 to 4-fold greater than values for RI in these two compartments. Electrophoresis and autoradiography of the postnuclear parotid-tissue fraction, the contents of purified secretory granules and saliva collected from the main excretory duct, after photoaffinity labeling with [32P]-8-azido-cyclic AMP, revealed the presence of R subunits. Predominantly RII was present in the granule contents and saliva, while both RII and RI were present in the cell extracts. Additionally, R subunits were purified from saliva by affinity chromatography on agarose-hexane-cyclic AMP. These findings confirm the localization of cA-PK in parotid cell nuclei and establish the acinar secretory granules as the source of the cyclic AMP-binding proteins in saliva.     

Morphology,histochemistry and physiology of the major salivary glands in the echidna Tachyglossus aculeatus (Monotremata)

The three major salivary glands of the monotreme echidna are described. The parotid is a typical serous gland with tubulo-acinar secretory endpieces and a well-developed system of striated ducts. The mandibular gland, although light microscopically resembling a mucous gland, secretes very little glycoprotein. Its cells are packed instead with serous granules, resembling in fine structure the “bull's eye” granules in the mandibular gland of the European hedgehog Erinaceus europaeus. The sublingual glands secrete an extremely viscous mucous saliva. Expulsion of this saliva through the narrow ducts is probably aided by contraction of the extensive myoepithelial sheaths surrounding the secretory tubules. Application of the glyoxylic acid induced fluorescence method failed to demonstrate adrenergic innervation in any of the glands.     

Immunogold localization of the type II regulatory subunit of cyclic AMP-dependent protein kinase. Monoclonal antibody characterization and RII distribution in rat parotid cells

A mouse monoclonal antibody of the IgM class, MAb BB1, specific for the type II regulatory subunit (RII) of cyclic AMP-dependent protein kinase (cAPK), was produced using a purified subcellular protein fraction from rat parotid gland as the original antigen. The antibody immunoprecipitated radioactivity labeled RII from bovine heart cAPK, and from rat and human parotid saliva. Western blot analysis revealed specific binding of the antibody to proteins of 52 and 54 KD in extracts of rat parotid tissue, parotid saliva, and bovine heart cAPK. Immunogold labeling of thin sections of rat parotid gland revealed specific labeling of acinar cell nuclei (especially the heterochromatin), cytoplasm (particularly in areas containing granular endoplasmic reticulum), and the content of secretory granules. Labeling was greatly reduced (approximately 84%) when the antibody was pre-absorbed with an excess of bovine heart cAPK. In duct cells the cytoplasm and nuclei were also labeled, but few gold particles were present over secretory granules. These results provide additional evidence for the presence of nuclear cAPK in rat parotid cells, and confirm previous observations on the presence of cAPK regulatory subunits in acinar secretory granules and saliva. The hybridoma reagent will be used for studies of stimulus responses in the parotid and for immunocytochemical analyses of RII distribution in other secretory tissues.     

Immunocytochemical localization of amylase in gerbil salivary gland acinar cells processed by rapid freezing and freeze-substitution fixation

We examined the immunocytochemical localization of amylase in cryofixed serous acinar cells of gerbil major salivary glands by indirect immunostaining, using anti-gerbil parotid amylase antibody and protein A-gold complex. Fresh tissue blocks were quickly frozen by the metal-contact method, using liquid helium, and were freeze-substituted with either osmium-acetone solution or glutaraldehyde-containing acetone. They were then embedded in an epoxy resin mixture which was polymerized at 60 degrees C. Some tissue blocks substituted with aldehyde-acetone solution were embedded in Lowicryl K4M, polymerized at -30 degrees C. Thin sections of epoxy resin-embedded materials were treated with an oxidizing agent before immunostaining. The labeling density on the materials processed by various protocols for preparatory procedures was quantitatively compared to examine the usefulness of application of cryofixation to immunocytochemistry. The central dense core of heterogeneous secretory granules in the serous acinar cells of the parotid and sublingual glands was heavily labeled with immunogold, regardless of substitution media and embedding resins employed. The immunolabeling pattern clearly distinguished between the dense core and the surrounding matrix. Labeling density in the cryofixed materials was about 1.5 times greater than in those processed by conventional chemical fixation. Seromucous secretory granules in the submandibular gland acinar cells were only faintly labeled. The results obtained indicate that application of immunostaining to quick-frozen, substitution-fixed tissues is useful for high-resolution immunocytochemistry.     

Localization of cellular regulatory proteins using postembedding immunogold labeling

Cyclic AMP-dependent protein kinase (cAPK) mediates the effects of catecholamines and hormones that cause elevation of intracellular cyclic AMP levels. The holoenzyme is a tetramer consisting of catalytic (C) and cyclic AMP-binding regulatory (R) subunits. The type I and type II cAPK isoenzymes are defined by R subunits (RI and RII) of differing molecular weight, primary structure, and cyclic AMP-binding properties. Postembedding immunogold labeling procedures and specific polyclonal and monoclonal antibodies to RI, RII, and C were used to study the subcellular distribution of cAPK subunits in several tissues. In the rat parotid gland, both RI and RII were present in the cytoplasm, nuclei, and secretory granules of the acinar cells, whereas secretory granules of intercalated and striated duct cells were poorly labeled. These results confirmed that the acinar secretory granules are the source of R subunits previously identified in saliva by specific photoaffinity labeling techniques. Zymogen granules of pancreatic acinar cells and secretory granules of seminal vesicle cells were labeled with antibody to RII. Pancreatic and seminal fluids were shown to contain cyclic AMP-binding proteins. The granules of several endocrine cells (pituitary, pancreatic islet, intestinal) also labeled with RII antibody. Double labeling of ovarian granulosa cells showed that both RI and C were present in the nuclei and cytoplasm. The localization of cAPK subunits revealed by postembedding immunogold labeling is consistent with the postulated regulatory functions of these proteins in gene expression, cell proliferation, exocytosis, and various metabolic events The widespread occurrence of cAPK subunits in secretory granules and their release to the extracellular environment suggests that they play an important role in secretory cell function.     

Morphologic diversity of the minor salivary glands of the rat: fertile ground for studies in gene function and proteomics

In this article the locations and histologic and ultrastructural features of all of the minor salivary glands of the rat are presented; similarities and differences among them are highlighted. These glands are almost as diverse morphologically as the major salivary glands of the rat. The acini of von Ebner's glands are serous; those of the anterior and posterior buccal glands and minor sublingual glands are mucous; and those of the glossopalatal, palatal, and Weber's glands are mucous with serous demilunes. The anterior buccal, minor sublingual and von Ebner's glands have striated and stratified columnar ducts, while only the minor sublingual and von Ebner's glands have intercalated ducts. The glossopalatal, palatal, posterior buccal and Weber's glands have none of these ducts; the tubulo-acini drain abruptly into short terminal ducts composed of stratified squamous epithelium. All of the mucous acini react with an antibody to a mucin (Muc19) of the rat major sublingual gland, but in some of the glands the reaction varies in intensity among the acinar cells. Ultrastructurally, the mucous secretory granules of the anterior buccal, glossopalatal, palatal and Weber's glands are biphasic, while those of the minor sublingual and posterior buccal glands are monophasic. Although there is a considerable body of literature concerning the development, innervation, physiology and proteomics of von Ebner's glands, investigation of the other minor salivary glands of the rat ranges from modest to nearly nonexistent.     

SD大鼠和Beagle犬大唾液腺的形态学观察

目的-研究及观察SD大鼠和Beagle犬大唾液腺正常比较组织学.方法-SD大鼠和Beagle犬三对大唾液腺剖取后进行石蜡切片、HE染色和PAS染色,光学显微镜观察.结果-SD大鼠腮腺是纯浆液腺,Beagle犬腮腺属混合腺,以浆液性腺泡为主,偶见小的粘液细胞群.SD大鼠的下颌下腺属于以浆液腺泡为主的混合腺,Beagle犬的下颌下腺属于以粘液腺泡为主的混合腺.SD大鼠与Beagle犬的舌下腺均为粘液性腺泡为主的混合腺.Beagle犬的眶腺亦是以纯粘液性腺泡为主的混合腺结构.     

Cl(-)/HCO(3)(-) exchange is acetazolamide sensitive and activated by a muscarinic receptor-induced [Ca(2+)](i) increase in salivary acinar cells

Large volumes of saliva are generated by transepithelial Cl(-) movement during parasympathetic muscarinic receptor stimulation. To gain further insight into a major Cl(-) uptake mechanism involved in this process, we have characterized the anion exchanger (AE) activity in mouse serous parotid and mucous sublingual salivary gland acinar cells. The AE activity in acinar cells was Na(+) independent, electroneutral, and sensitive to the anion exchange inhibitor DIDS, properties consistent with the AE members of the SLC4A gene family. Localization studies using a specific antibody to the ubiquitously expressed AE2 isoform labeled acini in both parotid and sublingual glands. Western blot analysis detected an approximately 170-kDa protein that was more highly expressed in the plasma membranes of sublingual than in parotid glands. Correspondingly, the DIDS-sensitive Cl(-)/HCO(3)(-) exchanger activity was significantly greater in sublingual acinar cells. The carbonic anhydrase antagonist acetazolamide markedly inhibited, whereas muscarinic receptor stimulation enhanced, the Cl(-)/HCO(3)(-) exchanger activity in acinar cells from both glands. Intracellular Ca(2+) chelation prevented muscarinic receptor-induced upregulation of the AE, whereas raising the intracellular Ca(2+) concentration with the Ca(2+)-ATPase inhibitor thapsigargin mimicked the effects of muscarinic receptor stimulation. In summary, carbonic anhydrase activity was essential for regulating Cl(-)/HCO(3)(-) exchange in salivary gland acinar cells. Moreover, muscarinic receptor stimulation enhanced AE activity through a Ca(2+)-dependent mechanism. Such forms of regulation may play important roles in modulating fluid and electrolyte secretion by salivary gland acinar cells.     

Differential expression of proline-rich proteins in rabbit salivary glands.

Salivary glands synthesize and secrete an unusual family of proline-rich proteins (PRPs) that can be broadly divided into acidic and basic PRPs. We studied the tissue-specific expression of these proteins in rabbits, using antibodies to rabbit acidic and basic PRPs as well as antibodies and cDNA probes to human PRPs. By immunoblotting, in vitro translation, and Northern blotting, basic PRPs could be readily detected in the parotid gland but were absent in other salivary glands. In contrast, synthesis in vitro of acidic PRPs was detected in parotid, sublingual, and submandibular glands. Ultrastructural localization with immunogold showed heavy labeling with antibodies to acidic PRPs of secretory granules of parotid acinar cells and sublingual serous demilune cells. Less intense labeling occurred in the seromucous acinar cells of the submandibular gland. With antibodies to basic PRPs, the labeling of the parotid gland was similar to that observed with antibodies to acidic PRPs, but there was only weak labeling of granules of a few sublingual demilune cells, and no labeling of the submandibular gland. These results demonstrate a variable pattern of distribution of acidic and basic PRPs in rabbit salivary glands. These animals are therefore well suited for study of differential tissue expression of PRPs.     

Morphologic diversity of the minor salivary glands of the rat: fertile ground for studies in gene function and proteomics

In this article the locations and histologic and ultrastructural features of all of the minor salivary glands of the rat are presented; similarities and differences among them are highlighted. These glands are almost as diverse morphologically as the major salivary glands of the rat. The acini of von Ebner's glands are serous; those of the anterior and posterior buccal glands and minor sublingual glands are mucous; and those of the glossopalatal, palatal, and Weber's glands are mucous with serous demilunes. The anterior buccal, minor sublingual and von Ebner's glands have striated and stratified columnar ducts, while only the minor sublingual and von Ebner's glands have intercalated ducts. The glossopalatal, palatal, posterior buccal and Weber's glands have none of these ducts; the tubulo-acini drain abruptly into short terminal ducts composed of stratified squamous epithelium. All of the mucous acini react with an antibody to a mucin (Muc19) of the rat major sublingual gland, but in some of the glands the reaction varies in intensity among the acinar cells. Ultrastructurally, the mucous secretory granules of the anterior buccal, glossopalatal, palatal and Weber's glands are biphasic, while those of the minor sublingual and posterior buccal glands are monophasic. Although there is a considerable body of literature concerning the development, innervation, physiology and proteomics of von Ebner's glands, investigation of the other minor salivary glands of the rat ranges from modest to nearly nonexistent.     

The fine structure of sublingual gland acinar cells of the Mongolian gerbil,Meriones unguiculatus,processed by rapid freezing followed by freeze-substitution fixation

Summary We compare the ultrastructure of the gerbil sublingual gland as seen after cryofixation followed by substitution with osmium tetroxide, with the more familiar appearance of material processed by glutaraldehyde-osmium chemical fixation. After primary cryofixation of fresh salivary glands, the nuclei of the mucous cells are found to be spherical in shape and, rather than being displaced toward the cell base, occupy a nearly central position in the cytoplasm, even in the storage phase of the secretory cycle. The mucous secretory granules are seen as membrane-limited inclusions, only rarely partially fused to each other. In both mucous and serous cells the Golgi cisterns have numerous large fenestrae which are aligned to form cytoplasmic channels which extend across the stack.     

Comparison of the secretory processes in the parotid and sublingual glands of the mouse. 1. Regulation of the secretory processes.

1. Secretion from the mucous sublingual gland of the mouse has been investigated and compared with the serous parotid gland. The influence of acetylcholine, noradrenalin and adrenalin on the secretion of glycoproteins (e.g. mucins) and proteins (e.g. amylase) from these glands in vitro, and the involvement of cyclic AMP and Ca2+ has been studied. 2. Secretion from the parotid gland could be stimulated by both acetylcholine and the catecholamines. It appears that cyclic AMP plays an important role in the adrenergic secretory process, but not in the cholinergic-induced secretion. In the latter case, exogenous Ca2+ strongly increased the secretion. 3. Mucin secretion from the sublingual gland could be affected by acetylcholine in the presence of exogenous Ca2+. Noradrenalin and adrenalin induced only a slow mucin secretion and, for this secretory process, exogenous Ca2+ is also required. Though cyclic AMP is present in the sublingual gland, no influence on its level could be detected in this gland after stimulation of the adrenergic beta-receptor, whereas, in contrast to the parotid gland, dibutyryl cyclic AMP induced only a slow secretion. Because it was observed that the sublingual gland of the mouse is not innervated sympathetically, it seems reasonable to suppose that the catecholamines stimulate the mucin secretion from this gland via hormonal receptors and not via the adrenergic beta-receptor. 4. The protein secretion from the sublingual gland could be stimulated by both acetylcholine and the catecholamines. An involvement of cyclic AMP in this process was not observed. Addition of exogenous Ca2+ is less important, as was found for the mucin secretion. So it has been concluded that protein and mucin secretion from the sublingual gland are regulated via different pathways.     

Cell biology of human salivary secretion

We treated surgical specimens of human parotid and submandibular glands in vitro to manipulate the receptor-signaling cascade pharmacologically and analyzed cellular responses by light microscopy on epoxy embedded sections. Treatment of specimens with the b-agonist, isoproterenol, and with the second messenger analog, dibutyryl cyclic AMP, stimulated serous acinar cells to engage in exocytosis and degranulation. The muscarinic agonist, carbachol, and the calcium ionophore, A23187, on the other hand, elicited formation of "vacuoles" in the cytoplasm of serous acinar cells. Taking previous in vivo human and animal studies into account, these changes are suggested as the morphological expression of enzyme release and fluid secretion, respectively. Specimens obtained from patients over 70 years old exhibited poor response even though their morphological appearance remained intact. Aged salivary glands are thus suggested to experience a decline in their secretory activity at the cellular level, probably by impairment of the signaling processes downstream to the receptor activation and second messenger production.     

Immunolocalization patterns of cytokeratins during salivary acinar cell development in mice

Embryonic development of the mouse salivary glands begins with epithelial thickening and continues with sequential changes from the pre-bud to terminal bud stages. After birth, morphogenesis proceeds, and the glands develop into a highly branched epithelial structure that terminates with saliva-producing acinar cells at the adult stage. Acinar cells derived from the epithelium are differentiated into serous, mucous, and seromucous types. During differentiation, cytokeratins, intermediate filaments found in most epithelial cells, play vital roles. Although the localization patterns and developmental roles of cytokeratins in different epithelial organs, including the mammary glands, circumvallate papilla, and sweat glands, have been well studied, their stage-specific localization and morphogenetic roles during salivary gland development have yet to be elucidated. Therefore, the aim of this study was to determine the stage and acinar cell type-specific localization pattern of cytokeratins 4, 5, 7, 8, 13, 14, 18, and 19 in the major salivary glands (submandibular, sublingual, and parotid glands) of the mouse at the E15.5, PN0, PN10, and adult stages. In addition, cell physiology, including cell proliferation, was examined during development via immunostaining for Ki67 to understand the cellular mechanisms that govern acinar cell differentiation during salivary gland morphogenesis. The distinct localization patterns of cytokeratins in conjunction with cell physiology will reveal the roles of epithelial cells in salivary gland formation during the differentiation of serous, mucous or seromucous salivary glands.     

The cytochemical localization of adenylate cyclase activity in mucous and serous cells of the salivary gland

The present study was undertaken to localize adenylate cyclase activity in salivary glands by cytochemical means. For the study, serous parotid glands and mixed sublingual glands of the rat were used. Pieces of the fixed glands were incubated with adenosine triphosphate (ATP) or adenylyl-imidodi-phosphate (AMP-PNP) as substrate: inorganic pyrophosphate or PNP liberated upon the action of adenylate cyclase on the substrates is precipitated by lead ions at their sites of production. In both glands, the reaction product was detected along the myoepithelial cell membranes in contact with secretory cells, indicating that a high level of adenylate cyclase activity occurs in association with these cell membranes. The association with a high level of the enzyme activity might be related to the contractile nature of myoepithelial cells which are supposed to aid secretory cells in discharging secretion products. A high level of adenylate cyclase activity was also detected associated with serous secretory cells (acinar cells of the parotid gland and demilune cells of the sublingual gland), but not with mucous secretory cells. In serous cells, deposits of reaction product were localized along the extracellular space of the apical cell membrane bordering the lumen. This is the portion of the cell membrane which fuses with the granule membranes during secretion. Since the granule membranes are not associated with a detectable level of adenylate cyclase activity, it appears that the enzyme activity becomes activated or associated with the granule membranes as they become part of the cell membrane by fusion. The association with a high level of adenylate cyclase activity appears to be related to the ability of the membrane to fuse with other membranes. It is likely, since the luminal membrane of mucous cells which does not fuse with mucous granule membranes during secretion is not associated with a detectable enzyme activity.     

Histology and mucosubstance histochemistry of ferret lingual glands.

The histology and mucosubstance histochemistry of the ferret lingual glands were studied. Both serous and mucous minor salivary glands were present in the posterior part of the tongue. In serous glands, acinar cells and a very few cells of the excretory ducts contained granules which gave reactions for neutral mucopolysaccharides only. The mucous glands, including the duct system, contained mainly weakly sulphated acidic mucin, some neutral mucin but no carboxylated mucin. Occasional goblet cells were present in the excretory ducts of both serous and mucous glands. They contained weakly sulphated mucin.