Unstimulated amylase secretion is proteoglycan-dependent in rat parotid acinar cells

It is well-known that amylase is secreted in response to extracellular stimulation from the acinar cells. However, amylase is also secreted without stimulation. We distinguished vesicular amylase as a newly synthesized amylase from the accumulated amylase in secretory granules by short time pulse and chased with ³⁵S-amino acid. The newly synthesized amylase was secreted without stimulation from secretory vesicles in rat parotid acinar cells. The secretion process did not include microtubules, but was related to microfilaments. p-Nitrophenyl β-xyloside, an inhibitor of proteoglycan synthesis, inhibited the newly synthesized amylase secretion. This indicated that the newly synthesized amylase was secreted from secretory vesicles, not via the constitutive-like secretory route, which includes the immature secretory granules, and that proteoglycan synthesis was required for secretory vesicle formation.     

Changes in parotid acinar cells accompanying salivary secretion in rats on sympathetic or parasympathetic nerve stimulation

Morphological and secretory effects of stimulating autonomic nerves have been studied in parotid glands of rats. Sympathetic stimulation evoked a slow flow of saliva which had a high concentration of amylase. After long term sympathetic stimulation secretory granules were heavily depleted from the parotid acinar cells. Parasympathetic stimulation evoked a copious flow of saliva with a low concentration of amylase. However, at high frequency stimulation the total amount of amylase secreted on parasympathetic stimulation was as great or even greater than on symphatetic stimulation, nevertheless, any loss of secretory granules from the acinar cells was very small. It is concluded that secretion of parotid acinar granules in the rat is prinicipally a sympathetic function. Secretion of fluid is more effectively produced by parasympathetic stimulation and much of the amylase in such saliva appears to have arisen from sources other than the secretory granules.     

Nerve-induced secretion of parotid acinar granules in cats

Summary Electron microscopy of cat parotid glands revealed great heterogeneity in the secretory granules of normal unstimulated acinar cells. Electrical stimulation of the parasympathetic nerve to the gland evoked a copious flow of parotid saliva which was accompanied by an extensive depletion of the secretory granules from the acinar cells. Exocytosis was captured as it was occurring by means of perfusion-fixation, and showed that the events occur in a conventional manner. Stimulation of the sympathetic nerve caused only a very small flow of saliva, and no acinar degranulation was detected. It can be concluded that the parasympathetic secretomotor axons provide the main drive for parotid acinar degranulation in the cat. This contrasts with the rat in which sympathetic impulses provide the main stimulus for parotid acinar degranulation. These dissimilarities serve to emphasise how extensively species differences may influence autonomic responses in salivary glands.     

Salivary acinar cells from aquaporin 5-deficient mice have decreased membrane water permeability and altered cell volume regulation

Aquaporins (AQPs) are channel proteins that regulate the movement of water through the plasma membrane of secretory and absorptive cells in response to osmotic gradients. In the salivary gland, AQP5 is the major aquaporin expressed on the apical membrane of acinar cells. Previous studies have shown that the volume of saliva secreted by AQP5-deficient mice is decreased, indicating a role for AQP5 in saliva secretion; however, the mechanism by which AQP5 regulates water transport in salivary acinar cells remains to be determined. Here we show that the decreased salivary flow rate and increased tonicity of the saliva secreted by Aqp5(-)/- mice in response to pilocarpine stimulation are not caused by changes in whole body fluid homeostasis, indicated by similar blood gas and electrolyte concentrations in urine and blood in wild-type and AQP5-deficient mice. In contrast, the water permeability in parotid and sublingual acinar cells isolated from Aqp5(-)/- mice is decreased significantly. Water permeability decreased by 65% in parotid and 77% in sublingual acinar cells from Aqp5(-)/- mice in response to hypertonicity-induced cell shrinkage and hypotonicity-induced cell swelling. These data show that AQP5 is the major pathway for regulating the water permeability in acinar cells, a critical property of the plasma membrane which determines the flow rate and ionic composition of secreted saliva.     

Cytochemical localization of carbohydrates in intercalated duct and acinar cells of mouse parotid gland

Summary The glycoconjugate composition of mouse intercalated duct and acinar cells of parotid gland has been compared. Mucins containing 1,2-glycols were demonstrated by the tannic acid-uranyl acetate technique. Hexose residues of glycoconjugates were identified using ferritin conjugated withCanavalia ensiformis agglutinin (Con A),Triticum vulgare or wheat germ agglutinin (WGA),Ricinus communis I agglutinin (RCA-I),Phaseolus vulgaris agglutinin (PHA-E) andArachis hypogaea agglutinin (PNA). Whereas qualitative and quantitative differences were observed in sugar residues of secretory granules in intercalated duct and acinar cells, apical plasmalemmae were labelled sparsely and similarly. This indicates that the glycocalyx composition of apical plasma minae in the parotid acinar and intercalated duct cells is little influenced by secretory granule composition.     

Exocytosis in living salivary glands: direct visualization by video-enhanced microscopy and confocal laser microscopy

Although exocytosis is widely believed to involve granule movement, membrane fusion and the emptying of granule content, direct study of these processes has been difficult in living cells because of the limited resolution of conventional light microscopy. Using video-enhanced microscopy and confocal laser microscopy, we have now studied these processes in living rat parotid and submandibular gland acinar cells. Under a differential interference contrast (DIC) microscope equipped with a CCD camera and a high speed image processor, secretory granules were in general stationary even after secretory stimulation with isoproterenol (IPR). Following IPR stimulation, however, there were abrupt changes in light intensity of secretory granules, and many granules disappeared. Confocal microscopy was then performed to confirm whether the observed changes in granules were related to membrane fusion and content release. For this, cells were perfused with the fluid-phase tracer Lucifer Yellow; confocal images thus obtained clearly demonstrated the appearance of fluorescence in omega-shaped invaginations of the apical plasma membrane which corresponded to the sites at which changes were observed in DIC images. The time sequence analyses of confocal images showed that there was a repetitive appearance and disappearance of omega-shaped fluorescent foci at the apical plasma membrane until most of the granules were depleted. During this time, there did not appear to be any significant expansion of the apical plasma membrane and if endocytic uptake of the tracer occurred, it was below the limit of detection. These observations provide new insights into the exocytotic process in salivary glands and are at variance in some respects with previous interpretations made from electron microscopy.     

Aquaporin-5 (AQP5), a water channel protein, in the rat salivary and lacrimal glands: immunolocalization and effect of secretory stimulation

Aquaporin-5 (AQP5) is a water channel protein and is considered to play an important role in water movement across the plasma membrane. We raised anti-AQP5 antibody and examined the localization of AQP5 protein in rat salivary and lacrimal glands by immunofluorescence microscopy. AQP5 was found in secretory acinar cells of submandibular, parotid, and sublingual glands, where it was restricted to apical membranes including intercellular secretory canaliculi. In the submandibular gland, abundant AQP5 was also found additionally at the apical membrane of intercalated duct cells. Upon stimulation by isoproterenol, apical staining for AQP5 in parotid acinar cells tended to appear as clusters of dots. These results suggest that AQP5 is one of the candidate molecules responsible for the water movement in the salivary 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.     

Ultrastructure and complex carbohydrate ultracytochemistry of the cat parotid gland

The structure and glycoconjugate content of the cat parotid gland were analyzed at electron microscopic level by applying morphological techniques and three ultrastructural histochemical methods - HID-TCH-SP, LID-TCH-SP and PA-TCH-SP. This gland appeared as a typical salivary gland composed of acinar secretory cells, intercalated ducts, striated ducts and excretory ducts. The most common configuration of secretory granules consisted of a dense core surrounded by a variable electron-lucent halo. All ductal segments were characterized by the presence of different cell populations and small apical granules greatly different from those localized in the acinar cells. By using HID-TCH-SP we were able to demonstrate that in a few acinar cells there are sulphated sites, whereas PA-TCH-SP staining revealed the presence of vic-glycol radicals in all acinar cells preferentially located on the halo of secretory granules.     

Localization of cAMP-dependent protein kinase subunits along the secretory pathway in pancreatic and parotid acinar cells and accumulation of the catalytic subunit in parotid secretory granules following beta-adrenergic stimulation

Catalytic (C) and regulatory (RI and RII) subunits of cAMP-dependent protein kinases were localized by immunoelectron microscopy in cisternae of the rough endoplasmic reticulum (rER) and in the Golgi complex of rat pancreas or parotid cells. Zymogen granules of the exocrine pancreas showed C- and RI-immunoreactivity, secretory granules of parotid acinar cells only RII-immunoreactivity. Injection of rats with isoproterenol (IPR) increased in the parotid gland the number of acinar cells with RII-labeled granules. In addition, it led to the appearance of C-immunoreactivity in the condensing vacuoles and secretory granules with a maximum at 24 h after stimulation. This was confirmed by enzyme-linked immunosorbent assay (ELISA) determinations of C- and RII-subunits in secretory granules isolated from stimulated and control parotid glands. The amount of immunoreactive C-subunits in the secretory granules increased further following repeated injections of the beta-agonist. These findings suggest the existence of secretory forms of cAMP-dependent protein kinase R- and C-subunits and their separate regulation.     

Ultrastructural changes of rat parotid glands induced by a diet of liquid Metrecal

Summary The ultrastructure of parotid glands was studied in rats fed a diet of liquid Metrecal for two weeks and compared with that of parotid glands of control rats which received a diet of Purina lab chow. The liquid diet induced major alterations of acinar cells, but other parenchymal components were apparently unaffected.Most acinar cells of experimental rats were atrophic and some of these were undergoing necrosis. Lipid droplets and dense bodies (believed to be lysosomes) were numerous in atrophic cells. The Golgi apparatus, quantity of secretory granules, and intercellular canaliculi were smaller than in acinar cells of control rats.Such findings suggest that the secretory process was impaired and support the conclusion that parotid glands of rats maintained on a liquid diet are physiologically less active than those of chow fed rats. The decreased activity, as previously reported, may result from reduced masticatory activity.Supported by U.S.P.H.S. grant DE 02110.     

A primary culture of parotid acinar cells retaining capacity for agonists-induced amylase secretion and generation of new secretory granules

Exocrine acinar cells, like parotid cells, have difficulty in maintaining their functions in cell lines or in primary cultures. For this reason, molecular studies on exocrine cell functions are unsatisfactory. To examine the mechanisms whereby the functions of parotid acinar cells are maintained, we attempted to establish a system for primary culture and transfection of exogenous genes. Acinar cells were dispersed from rat parotid glands by digestion with enzymes and were cultured in a medium containing rat serum. Most of the cultured cells had secretory granules that contained amylase, suggesting that they were derived from acinar cells, although they spread on the dish surface and formed filopodia. The cultured cells retained both granules and the ability to release amylase in response to -adrenergic and cholinergic agonists, even 48 h after dispersion. However, the total amount of amylase in the cells decreased rapidly from 24 to 48 h after dispersion. These results suggested that amylase synthesis was more damaged than the machinery for exocytosis during culture in vitro. VAMP2 gene fused with enhanced green fluorescence protein was transfected into the dispersed acinar cells, and VAMP2 protein was expressed and localized to amylase-containing granules, as normally seen for endogenous VAMP2 protein. This indicated that new granules were generated, and that protein sorting was functional. The cells cultured by this method maintained their functions for at least 48 h. They can be used for examining the effects of exogenous genes on parotid acinar cell functions, such as regulated exocytosis and the maturation of secretory granules.This work was supported in part by Grants-in-aid for Scientific Research from the Ministry of Education, Culture, Sports, Science, and Technology of Japan (11771148, 13771104, 16390534, 16591868), by Nihon University Multidisciplinary Research Grant for 2001 and 2002, by a Suzuki Memorial Grant of Nihon University School of Dentistry at Matsudo (General Individual Research Grant for 2000 and 2002 and Joint Research Grant for 2003), and by a Grant-in-Aid for a 2001 Multidisciplinary Research Project from MEXT.     

Differential regulation of the apical plasma membrane Ca(2+) -ATPase by protein kinase A in parotid acinar cells

Cross-talk between intracellular calcium ([Ca(2+)](i)) signaling and cAMP defines the specificity of stimulus-response coupling in a variety of cells. Previous studies showed that protein kinase A (PKA) potentiates and phosphorylates the plasma membrane Ca(2+)-ATPase (PMCA) in a Ca(2+)-dependent manner in parotid acinar cells (Bruce, J. I. E., Yule, D. I., and Shuttleworth, T. J. (2002) J. Biol. Chem. 277, 48172-48181). The aim of this study was to further investigate the spatial regulation of [Ca(2+)](i) clearance in parotid acinar cells. Par-C10 cells were used to functionally isolate the apical and basolateral PMCA activity by applying La(3+) to the opposite side to inhibit the PMCA. Activation of PKA (using forskolin) differentially potentiated apical [Ca(2+)](i) clearance in mouse parotid acinar cells and apical PMCA activity in Par-C10 cells. Immunofluorescence of parotid tissue slices revealed that PMCA1 was distributed throughout the plasma membrane, PMCA2 was localized to the basolateral membrane, and PMCA4 was localized to the apical membrane of parotid acinar cells. However, in situ phosphorylation assays demonstrated that PMCA1 was the only isoform phosphorylated by PKA following stimulation. Similarly, immunofluorescence of acutely isolated parotid acinar cells showed that the regulatory subunit of PKA (RIIbeta) translocated to the apical region following stimulation. These data suggest that PKA-mediated phosphorylation of PMCA1 differentially regulates [Ca(2+)](i) clearance in the apical region of parotid acinar cells because of a dynamic translocation of PKA. Such tight spatial regulation of Ca(2+) efflux is likely important for the fine-tuning of Ca(2+)-dependent effectors close to the apical membrane important for the regulation of fluid secretion and exocytosis.     

Differences in claudin synthesis in primary cultures of acinar cells from rat salivary gland are correlated with the specific three-dimensional organization of the cells

Tight junctions are essential for the maintenance of epithelial cell polarity. We have previously established a system for the primary culture of salivary parotid acinar cells that retain their ability to generate new secretory granules and to secrete proteins in a signal-dependent manner. Because cell polarity and cell-cell adhesion are prerequisites for the formation of epithelial tissues, we have investigated the structure of the tight junctions in these cultures. We have found two types of cellular organization in the culture: monolayers and semi-spherical clusters. Electron microscopy has revealed tight junctions near the apical region of the lateral membranes between cells in the monolayers and cells at the surface of the clusters. The cells in the interior of the clusters also have tight junctions and are organized around a central lumen. These interior cells retain more secretory granules than the surface or monolayer cells, suggesting that they maintain their original character as acinar cells. The synthesis of claudin-4 increases during culture, although it is not detectable in the cells immediately after isolation from the glands. Immunofluorescence microscopy has shown that claudin-4 is synthesized in the monolayers and at the surface of the clusters, but not inside the clusters. Only claudin-3, which is present in the original acinar cells following isolation and in the intact gland, has been detected inside the clusters. These results suggest that differences in claudin expression are related to the three-dimensional structures of the cell cultures and reflect their ability to function as acinar cells. This work was supported by grants-in-aid for scientific research from the Ministry of Education, Science, Culture, Sports, and Technology of Japan (16591868, 16791135), by a Suzuki Memorial Grant of the Nihon University School of Dentistry at Matsudo (Joint Research Grant for 2003), by a Nihon University Multidisciplinary Research Grant for 2005 and 2006, and by a Grant-in-Aid for a 2003 Multidisciplinary Research Project from MEXT.     

Localization of VIP36 in the post-Golgi secretory pathway also of rat parotid acinar cells.

VIP36 (36-kD vesicular integral membrane protein), originally purified from Madin-Darby canine kidney (MDCK) epithelial cells, belongs to a family of animal lectins and may act as a cargo receptor. To understand its role in secretory processes, we performed morphological analysis of the rat parotid gland. Immunoelectron microscopy provided evidence that endogenous VIP36 is localized in the trans-Golgi network, on immature granules, and on mature secretory granules in acinar cells. Double-staining immunofluorescence experiments confirmed that VIP36 and amylase co-localized in the apical regions of the acinar cells. This is the first study to demonstrate that endogenous VIP36 is involved in the post-Golgi secretory pathway, suggesting that VIP36 plays a role in trafficking and sorting of secretory and/or membrane proteins during granule formation.     

Calcium transport in human salivary glands: a proposed model of calcium secretion into saliva

Salivary calcium plays a vital role in bio-mineralization of dental enamel and exposed dentin. In order to elucidate the yet unknown cellular and molecular mechanisms of calcium secretion in human salivary glands the presence of various relevant plasma membrane transport systems for calcium were investigated. Using an RT-PCR approach, expression of the epithelial calcium channel (CaT-Like), the calcium binding protein (calbindin-2), the endoplasmic reticulum pumps (SERCA-2 and -3), and the plasma membrane calcium ATPases (PMCA-1, -2, and -4), were found in parotid and submandibular glands. Immunohistochemistry revealed that CaT-Like is located in the basolateral plasma membrane of acinar cells; while calbindin-2, SERCA-2 and SERCA-3 were found inside the acinar cells; and PMCA-2 was found in the apical membrane and in the secretory canaliculi between the cells. Based on these findings, we propose the following model of calcium secretion in human salivary glands: (1) calcium enters the acinar cell at the basolateral side via calcium channel CaT-Like (calcium influx); (2) intracellular calcium is taken up into the endoplasmic reticulum by SERCA-2 and possibly SERCA3 or bound to calbindin-2 (intracellular calcium pool); and (3) calcium is secreted by PMCAs at the apical plasma membrane (calcium efflux).Evamaria Kinne-Saffran deceased on 6 December 2002     

Growth of exocrine acinar cells on a reconstituted basement membrane gel

Summary Methods have been developed for culturing a dividing population of morphologically differentiated rat parotid, lacrimal, and pancreatic acinar cells in vitro. Isolated acinar cells were plated onto tissue culture dishes coated with a three-dimensional, reconstituted basement membrane gel. After attachment in Ham’s nutrient mixture F12, the cells were cultured at 35°C in F12 supplemented with 10% heat inactivated rat serum, epidermal growth factor, dexamethasone, insulin, transferrin, selenium, putrescine, reduced glutathione, ascorbate, penicillin, streptomycin, and the appropriate secretagogue. Under these conditions, the cells attached rapidly and DNA synthesis was initiated within 2 to 3 d. Although the cells flattened on the substratum, they continued to maintain their differentiated morphology. The cells contained secretory granules, and the secretory enzymes peroxidase and amylase could be detected. The use of a reconstituted basement membrane gel proved critical for the attachment and growth of exocrine acinar cells.     

Aminopeptidase N- and human blood group A-antigenicity along the digestive tract and associated glands in the rabbit

Summary The cellular localization of an aminopeptidase N homologous to the brush-border intestinal enzyme and that of human blood group A-substances were investigated using the immunofluorescence technique on thin frozen sections (200 nm) of the digestive tract and associated glands of A⁺ and A^– rabbits. Aminopeptidase N was found to be a common specific marker of both the apical region of plasma membrane of acinar cells in submaxillary and parotid glands and pancreas and the brush border of jejunum and colon absorbing cells. In hepatocytes, the enzyme was localized in the sinusoidal domains. Soluble A-substances were present in mucus secretory granules of intestinal goblet cells and those of stomach and gall bladder mucous cells. In contrast, the mucous acini of sublingual and submaxillary glands were devoid of A-antigenicity. The columnar cells of striated ducts of these glands exhibited A-antigenicity. Soluble A-substances were also found in zymogen granules of parotid and pancreas acinar cells and those of stomach chief cells. Moreover, in all cells secreting A-substances, and in the non-secreting absorbing intestinal cells, the glycoproteins of the plasma membrane bore A-determinants. Aminopeptidase N was one of the membrane-bound glycoproteins that bore A-determinants in cells that expressed A-antigenicity.     

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.