Localization of amylase and mucins in the major salivary glands of the mouse

Summary Antibodies against murine submandibular and sublingual mucins have been raised in rabbits. Both antisera appeared to be specific. Using these antibodies, the mucins were localized in the acinar cells of the submandibular and sublingual glands respectively.The dyed amylopectin method was used to estimate the activity of amylase in the salivary glands. The enzyme was localized either by a starch-substrate film method or with antibodies against purified parotid amylase. The activity of amylase in parotid homogenates is about 1000-fold higher than that in homogenates of either submandibular or sublingual glands, in which the activity was comparable. Amylase was localized in the acinar cells of the parotid gland with both localization techniques. In the sublingual gland, amylase was found predominantly in the stroma around the acini, and there was some evidence that amylase was present in the demilune cells as well. In the submandibular gland, contradictory results were obtained with both techniques. With the starch-substrate film method, amylase activity was found in the granular convoluted tubular cells, whereas immuno-reactive amylase could only be demonstrated in the acinar cells of this gland. It is concluded that in the submandibular gland amylase and mucin are present in the same cell type.     

Trafficking and postsecretory events responsible for the formation of secreted human salivary peptides: a proteomics approach

To elucidate the localization of post-translational modifications of different classes of human salivary proteins and peptides (acidic and basic proline-rich proteins (PRPs), Histatins, Statherin, P-B peptide, and "S type" Cystatins) a comparative reversed phase HPLC-ESI-MS analysis on intact proteins of enriched granule preparations from parotid and submandibular glands as well as parotid, submandibular/sublingual (Sm/Sl), and whole saliva was performed. The main results of this study indicate the following. (i) Phosphorylation of all salivary peptides, sulfation of Histatin 1, proteolytic cleavages of acidic and precursor basic PRPs occur before granule storage. (ii) In agreement with previous studies, basic PRPs are secreted by the parotid gland only, whereas all isoforms of acidic PRPs (aPRPs) are secreted by both parotid and Sm/Sl glands. (iii) Phosphorylation levels of aPRPs, Histatin 1, and Statherin are higher in the parotid gland, whereas the extent of cleavage of aPRP is higher in Sm/Sl glands. (iv) O-Sulfation of tyrosines of Histatin 1 is a post-translational modification specific for the submandibular gland. (v) The concentration of Histatin 3, Histatin 5, and Histatin 6, but not Histatin 1, is higher in parotid saliva. (vi) Histatin 3 is submitted to the first proteolytic cleavage (generating Histatins 6 and 5) during granule maturation, and it occurs to the same relative extent in both glands. (vii) The proteolytic cleavages of Histatin 5 and 6, generating a cascade of Histatin 3 fragments, take place after granule secretion and are more extensive in parotid secretion. (viii) Basic PRPs are cleaved in the oral cavity by unknown peptidases, generating various small proline-rich peptides. (ix) C-terminal removal from Statherin is more extensive in parotid saliva. (x) P-B peptide is secreted by both glands, and its relative quantity is higher in submandibular/sublingual secretion. (xi) In agreement with previous studies, S type Cystatins are mainly the product of Sm/Sl glands.     

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.     

Expression and distribution of osteopontin and matrix metalloproteinase (MMP)-3 and -7 in mouse salivary glands

We investigated the expression and distribution of osteopontin in mouse salivary glands. Western blot analysis showed intense positive bands at the predicted molecular mass (about 60 kDa) in mouse parotid and sublingual glands. However, a cross-reacted band around 30 kDa was strongly detected in submandibular glands. Indirect immunofluorescent analysis showed that osteopontin was localized at the luminal (apical) membranes of the acinar cells in parotid and sublingual glands. However, it was not detected in acinar cells of submandibular glands. No expression was found in ductal cells of any glands. We also examined the expression of matrix metalloproteinase (MMP)-3 and -7. In parotid gland, MMP-3 was observed at 57 kDa, indicating a latent form, but MMP-7 was not detected. In contrast, MMP-7 definitely was observed at 28 kDa area in submandibular gland, whereas MMP-3 was not detected. These results suggest that osteopontin localizes at luminal sites of acinar cells and may be associated with saliva secretion in mouse salivary gland. It is also suggested that osteopontin may be cleaved by MMP-7 in mouse submandibular gland.     

Immunofluorescence-microscopic demonstration of myosin and actin in salivary glands and exocrine pancreas of the rat

Summary Actin and myosin were localized in various salivary glands (parotid, submandibular, sublingual, lingual and Harderian gland) and the exocrine pancreas of rats by indirect immunofluorescence microscopy using specific rabbit antibodies against chicken gizzard myosin and actin. A bright immunofluorescent staining with both antibodies was observed at three main sites: (1) In myoepithelial cells of all salivary glands, (2) in secretory gland cells underneath the cell membrane bordering the acinar lumen (except Harderian and mucous lingual gland), and (3) in epithelial cells of the various secretory ducts (of all glands) in similar distribution as in acinar cells. The present immunohistochemical findings in acinar cells could lend further support to a concept suggesting that myosin and actin are involved in the process of transport and exocytosis of secretory granules.Supported by grants form Deutsche Forschungsgemeinschaft (Dr. 91/1, Ste. 105/19 and U. 34/4). We thank Mrs. Ursula König, Mrs. Christine Mahlmeister and Miss Renate Steffens for excellent technical assistance.     

Cellular compartmentation of lysozyme and alpha-amylase in the mouse salivary glands. Immunogold approaches at light and electron microscopy level

The research was planned to study the subcellular distribution of enzymatic secretory products within the secretory structures of the mouse major salivary glands at light and electron microscopy level by immunogold silver stain (IGSS) technique and double-sided post-embedding immunogold binding and silver amplification in order to speculate about their compartmentation. In particular, we experimented the above immunogold labeling approaches to localize the lysozyme and to verify its distribution patterns in relation to another secretion enzyme, alpha-amylase. Co-presence of lysozyme and alpha-amylase was observed in the convoluted granular tubule cells of the submandibular gland and in the demilunar cells of the sublingual gland as well as in the electron-dense regions of the mottled secretory granules in the parotid gland. Exclusive binding patterns of lysozyme were observed in the acinar cells of the submandibular and sublingual glands where alpha-amylase did not occur.     

Electron microscopic immunocytochemical localization of proline-rich proteins in normal mouse parotid salivary glands

Summary Rabbit polyclonal antibodies against isoproterenol-induced mouse proline-rich proteins (PRPs) were used to localize PRPs in the parotid salivary glands of normal adult BALB/c mice. The antibodies recognized both acidic-type and basic-type PRPs. Immunoblotting experiments revealed that the glands contained an acidic-type and a basic-type PRP. Parotid gland tissue was fixed with Karnosky's fixative and embedded in Lowicryl resin at low temperature. PRPs were localized at the electron microscope level using an indirect post-embedding staining technique with protein A-gold. The secretion granules of the acinar cells were strongly labelled. Pre-absorption of the antibody with purified acidic-type and basic-type PRPs indicated that the basic-type PRP is mainly located at the periphery of the granules but that the acidic-type PRP is more evenly distributed within the granules. Pre-absorption of the antibody with -amylase did not affect the staining pattern, suggesting minimal cross-reactivity. PRPs were also detected within the rough endoplasmic reticulum and the Golgi apparatus of acinar cells, within the granules of the proacinar cells and in the lumena of the ducts, but not within the intercalated or striated duct cell granules.     

Immunohistochemical localization of carbonic anhydrase isoenzymes VI, II, and I in human parotid and submandibular glands

Human salivary carbonic anhydrase (HCA VI) was purified by inhibitor affinity chromatography and its location in the human parotid and submandibular glands identified, using a polyclonal antiserum raised against the purified enzyme in rabbits in conjunction with the peroxidase-antiperoxidase complex method. The antibodies raised against the purified enzyme in rabbits did not crossreact with the HCA II or I. However, they slightly recognized human IgA; the antiserum was therefore absorbed with human IgA before immunohistochemical use. HCA VI-specific staining was detected in the cytoplasm and particularly in the secretory granules of the serous acinar cells of both parotid and submandibular glands, the staining of the secretory granules being most distinct in paraformaldehyde-fixed tissues. Some epithelial cells and the luminal content of the striated ducts also gave a specific HCA VI staining. Staining specific for HCA II was also found in the granules of the serous acinar cells, particularly in the submandibular gland when Carnoy fluid fixation was used. Slight HCA II-specific staining was also detected in the striated ductal cells in the Carnoy fluid-fixed specimens. No staining specific for HCA I was detected. The results indicate that the serous acinar cells in human parotid and submandibular glands contain abundant HCA II and HCA VI. Interestingly, only HCA VI is secreted into the saliva, although both enzymes appear to be located in structures resembling the secretory granules in the acinar cells. The enzymes probably form a mutually complementary system regulating the salivary buffer capacity.     

Immunochemical study and acinar localization of AM1, a murine submandibular glycoprotein with esterolytic activity

Glycoprotein AM1, a glycoprotein from the submandibular glands of the mouse was isolated from the 100 000 X g tissue extract by polyacrylamide gel electrophoresis. An antiserum to purified glycoprotein AM1 was prepared, and its specificity was tested by immunodiffusion and immunoelectrophoresis. Glycoprotein AM1 could be detected in large quantity only in the submandibular glands of the mouse and in very small amounts in the parotid and sublingual glands and in serum. No glycoprotein AM1 was found in the murine brain, heart, lung, liver, spleen, kidney, pancreas, spinal cord and testis. In addition, glycoprotein AM1 was not detectable in the submandibular glands of the rat and rabbit, and in whole human saliva. No cross-reactivity was found with murine submandibular proteinase A and porcine pancreatic kallikrein. The cellular localization of glycoprotein AM1 was determined by the indirect immunofluorescence technique. In the submandibular glands bright fluorescence was only present in the acinar cells, throughout the whole gland. In the sublingual glands faint fluorescence was detectable as a diffuse network around the acini and possibly in the serous acinar demilune cells. On a subcellular level, glycoprotein AM1 could be demonstrated in the extract of the SMC secretory granular fraction, which originates largely from the acinar cells. On the other hand, glycoprotein AM1 was hardly detectable in the SMB secretory granular fraction, which originates predominantly from the granular convoluted tubular cells. Concomitantly, glycoprotein AM1 was secreted in vivo and could be detected in whole saliva, particularly after stimulation with isoproterenol and carbamylcholine, and also with phenylephrine, but to a much lesser extent.     

Light microscopic detection of sugar residues in glycoconjugates of salivary glands and the pancreas with lectin-horseradish peroxidase conjugates. I. Mouse

Summary Mouse salivary glands and pancreases were stained with a battery of ten horseradish peroxidase-conjugated lectins. Lectin staining revealed striking differences in the structure of oligosaccharides of stored intracellular secretory glycoproteins and glycoconjugates associated with the surface of epithelial cells lining excretory ducts. The percentage of acinar cells containing terminal -N-acetylgalactosamine residues varied greatly in submandibular glands of 30 male mice, but all submandibular acinar cells contained oligosaccharides with terminal sialic acid and penultimate -galactose residues. The last named dimer was abundant in secretory glycoprotein of all mucous acinar cells in murine sublingual glands and an additional 20–50% of these cells in all glands contained terminalN-acetylglucosamine residues. In contrast, terminal -N-acetylgalactosamine was abundant in sublingual serous demilune secretions. Serous acinar cells in the exorbital lacrimal gland, posterior lingual gland, parotid gland and pancreas exhibited a staining pattern unique to each organ. In contrast, the apical cytoplasm and surface of striated duct epithelial cells in the submandibular, sublingual, parotid and exorbital lacrimal gland stained similarly. A comparison of staining with conjugated lectins reported biochemically to have very similar carbohydrate binding specificity has revealed some remarkable differences in their reactivity, suggesting different binding specificity for the same terminal sugars having different glycosidic linkages or with different penultimate sugar residues.     

The coupling of RP-HPLC and ESI-MS in the study of small peptides and proteins secreted in vitro by human salivary glands that are soluble in acidic solution

The aim of this study was the development of a method based on the coupling of RP-HPLC and ESI-MS for identifying and quantifying proteins and peptides secreted by human salivary glands in vitro. Salivary gland specimens, obtained from informed patients undergoing surgical resection, were incubated in an optimized medium. Incubation media of glandular specimens, selected on the basis of cytomorphological and ultrastructural analysis, were investigated by HPLC-MS. Several salivary peptides/proteins, previously recognized in human whole saliva, were searched for along the chromatogram by the selected ion monitoring (SIM) strategy. Analysis of the incubation media of parotid glands revealed the presence of basic PRPs PC, PD, PH, IB-1, II-2, and acidic PRP-1 and PRP-3 in all of the investigated samples. Basic PRPs PB and PA, acidic PRPs, and cystatins SN and S1 were detected in all of the incubation media of submandibular glands, whereas histatin 1 was detected in only one sample. Moreover, the method allowed detection of some post-translational derivatives of known salivary proteins, as well as of several previously unidentified small peptides. The present method represents a sensitive and powerful instrument to detect peptides and proteins secreted by human salivary glands in vitro.     

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.     

Rate of protein synthesis in rat salivary gland cells after pilocarpine or feeding

In untreated, fasting animals the cells of the serous demilunes of the sublingual gland incorporate [3H]-leucine at a higher rate than any other of the 5 main cell types of the 3 major salivary glands. The acinar cells of the submandibular and the mucous cells of the sublingual gland show intermediate values, while the cells of the granular ducts of the submandibular and the acini of the parotid gland have a low rate of incorporation. In fasting animals extrusion of newly synthesized protein starts early in the cells of the serous demilunes. It starts between 4 and 7 hrs after [3H]-leucine injection in the acinar cells of the submandibular gland, while the other cell types did not lose substantial amounts of labelled (glyco)protein within 7 hrs. The secretion of protein is stimulated by the cholinergic drug pilocarpine in all but one of the 5 types of salivary gland cells studied. The acinar cells of the submandibular gland react strongly, the granular duct cells less strongly. Still less are the reactions of the acinar cells of the parotid and of the nucous cells of the sublingual gland. The cells of the serous demilunes of the latter appear to be insensible to pilocarpine. The effect of food uptake on secretion does not differ from pilocarpine stimulation, with one exception: the acinar cells of the parotid gland react more strongly on food uptake than on cholenergic stimulation.     

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.     

Isoproterenol increases sorting of parotid gland cargo proteins to the basolateral pathway

Exocrine cells have an essential function of sorting secreted proteins into the correct secretory pathway. A clear understanding of sorting in salivary glands would contribute to the correct targeting of therapeutic transgenes. The present work investigated whether there is a change in the relative proportions of basic proline-rich protein (PRP) and acidic PRPs in secretory granules in response to chronic isoproterenol treatment, and whether this alters the sorting of endogenous cargo proteins. Immunoblot analysis of secretory granules from rat parotids found a large increase of basic PRP over acidic PRPs in response to chronic isoproterenol treatment. Pulse chase experiments demonstrated that isoproterenol also decreased regulated secretion of newly synthesized secretory proteins, including PRPs, amylase and parotid secretory protein. This decreased efficiency of the apical regulated pathway may be mediated by alkalization of the secretory granules since it was reversed by treatment with mild acid. We also investigated changes in secretion through the basolateral (endocrine) pathways. A significant increase in parotid secretory protein and salivary amylase was detected in sera of isoproterenol-treated animals, suggesting increased routing of the regulated secretory proteins to the basolateral pathway. These studies demonstrate that shifts of endogenous proteins can modulate regulated secretion and sorting of cargo proteins. amylase; parotid secretory protein; polarized secretion     

Secretory proteins as markers for cellular phenotypes in rat salivary glands

The neonatal submandibular glands (SMG) of the rat contain two types of cells: Type III cells secrete a group of proteins in response to beta-adrenergic stimulation, and Type I cells secrete a different protein, called Protein C (89 kDa), in response to cholinergic stimuli (Ball and Redman, 1984). Polyclonal antibodies raised to Protein B1 (26 kDa) showed that the several proteins in the B1-Immunoreactive Protein (B1-IP) group are localized exclusively to Type III cells. Although we expected that antibodies to Protein B1 would label only the submandibular gland, we found instead that the serous demilunes of the sublingual gland (SLG) and the acinar cells and intercalated ducts of the parotid gland (PRG) were strongly reactive in both the neonate and the adult. Immunoelectrophoretic analysis of gland extracts showed the major reactive species in the sublingual gland to have different mobilities than the B1-IP. On the other hand, reactive species in the parotid gland had mobilities identical to those of two SMG proteins. In the adult SMG, the neonatal Type I and Type III cells are not present, and the acinar cells are devoid of B1-IP reactivity; however, the cells of the intercalated ducts have components reactive with anti-B1 antibodies, and these do not appear to be identical to any neonatal bands. In contrast to the submandibular gland, the adult parotid and sublingual glands retain the localization of B1-IP reactivity in PRG acinar and intercalated duct cells and in SLG demilunes, and they show the neonatal immunoelectrophoretic pattern. This raises the possibility that the major B1-IP species in the adult PRG may be identical to transient proteins of the neonatal SMG.     

The influence of fixation on the carbohydrate cytochemistry of rat salivary gland secretory granules

Synopsis A series of studies was performed to assess the optimum fixation conditions for staining of carbohydrate-containing constituents of rat salivary gland secretory granules. In the parotid and submandibular salivary glands of the rat, the reactivity of secretory granules, at both the light and electron microscopic level, with routine stains and with cytochemical reagents was highly dependent upon the nature of the fixative employed. At the light microscopic level, secretory granules in rat parotid gland were periodic acid-Schiff (PAS) positive if fixed with buffered formalin fixatives. However, if the gland was fixed with lipid-solvent-containing fixatives, or with formalin at a very acid pH (as in Bouin's fixative), the PAS reactivity of the granules was lost. In the submandibular gland of rats, the acinar cells and granular tubules behaved similarly after such fixation in terms of their PAS reactivity, particularly in males; acinar cells of the female submandibular gland stained only lightly with PAS. At the fine structural level, the morphology of secretory granule constituents depended on the buffer used (cacodylate, phosphate or collidine) and on whether or not tissue was post-osmicated. Post-osmication considerably reduced the reaction of secretory granule components with stains for carbohydrates.The experimental evidence indicated that the carbohydrate-containing components of both parotid and submandibular gland secretory granules were not typical long-chain neutral or acidic mucins, but were rather glycolipids or lipophilic glycoproteins that were solubilized by lipid solvents or at acidic pH and were lost or destroyed in the presence of strong oxidants.     

Nitric oxide synthase immunoreactive nerves in rat and ferret salivary glands, and effects of denervation

Nitric oxide has been implicated in mechanisms mediating nerve-evoked vasodilatory and secretory responses in salivary glands. In the present study, the occurrence and distribution of nitric oxide synthase (NOS)-immunoreactive nerves in ferret and rat salivary glands were investigated using immunocytochemistry with rabbit and sheep NOS antisera, and using NADPH-diaphorase enzyme histochemistry. In the parotid, submandibular and sublingual glands of the rat and the ferret, NOS-immunoreactive varicose terminals encircled acini and arteries of various sizes. In the ferret, collecting ducts were also supplied with NOS-immunoreactive fibres. In the rat, only the granular ducts of the submandibular gland were supplied with such fibres. The NOS-immunoreactive innervation of acinar cells was more abundant in the rat than in the ferret, whereas the opposite was true for the innervation of blood vessels. No NOS immunoreactivity was observed in the vascular endothelium. In both species, NOS-positive ganglionic cell bodies were found in the hilar regions of the submandibular and sublingual glands, whereas none could be detected in the parotid glands. NADPH-diaphorase reactivity had the same neuronal distribution as NOS immunoreactivity and, in addition, NADPH-diaphorase reactivity was expressed in ductal epithelium. Neither sympathetic denervation (by removal of the superior cervical ganglion) nor treatment with the sensory neurotoxin capsaicin reduced the NOS-immunoreactive innervation of the parotid gland. However, parasympathetic denervation (by cutting the auriculo-temporal nerve) caused an almost total disappearance of the NOS-immunoreactive innervation. The present findings provide a morphological background to the suggested role of nitric oxide in parasympathetic secretory and vascular responses of salivary glands. This revised version was published online in November 2006 with corrections to the Cover Date.     

Kallikrein localization in rodent salivary glands and kidney with the immunoglobulin-enzyme bridge technique.

Kallikrein has been localized in rodent kidney and salivary glands by means of an immunoglobulin-enzyme bridge technique. In sections of kidney, anti-kallikrein antibodies bound to the apical region of certain distal tubule segments in the cortex, to reabsorption droplets of proximal convoluted tubules, and to certain duct segments in the papilla. In salivary glands of both male and female rats and mice, and apical rim of most striated duct cells of submandibular, parotid and sublingual glands and granular tubules of submandibular glands exhibited immunoreactivity. Granular intercalated duct cells in female submandibular glands also displayed immunostaining for kallikrein. Phenylephrine administration resulted in loss of immunoreactive granules from the granular convoluted tubule cells of male mouse submandibular gland. This response was paralleled by a biochemically demonstrable decrease in kallikrein-like tosylarginine methyl ester (TAME) esterase activity.