Localization of kallikrein in porcine pancreas and submandibular gland as revealed by the indirect immunofluorescence technique.

The glandular kininogenase kallikrein is known to occur in many mammalian organs and glands but direct histochemical localization has been achieved in only a few cases. We have now been able to localize porcine kallikrein in the acinar cells of the pancreas and in the striated and collecting duct cells of the submandibular gland. Incubation of frozen and fixed sections with one of the crossreacting antibodies, anti-pancreatic, anti-submandibular or anti-urinary kallikrein IgG resulted in the same immunofluorescence pattern. There was evidence of a specific fluorescence neither in the acinar cells, nor in the interstitial tissue or blood cells of the submandibular gland nor in the islets of Langerhans, the interlobular ducts or blood vessels of the pancreas. From all data now available about glandular kallikreins, it seems that the kallikreins in these organs are very similar.     

Ultrastructural aspects of cat submandibular glands

Submandibular glands of five adult female cats were examined by conventional electron microscopic techniques. All gland acini are mucous secreting and each acinus is capped with mucous secreting demilunar cells. Secretory product of demilunar cells is more electron lucent than that of acinar cells. The demilunes show intercellular tissue spaces and intercellular canaliculi whereas similar specializations are absent between acinar cells. Mitochondria and arrays of granular endoplasmic reticulum are more numerous in demilunar cells than in acinar cells. In acinar and demilunar cells secretory droplets first appear as enlarged Golgi saccules which subsequently become closely related to cisternae of the granular endoplasmic reticulum. Filamentous structures, interpreted as mucin molecules, are present in secretory droplets of acinar cells. Intercalated ducts are short, consisting of several junctional cells between acini and striated ducts. Striated ducts are long and tortuous and contain light cells, dark cells and basal cells. Light cells contain numerous membrane bound granules in their distal ends whereas dark cells show electron lucent vesicles in the same position. Basal cells contain a paucity of organelles and membrane plications but exhibit hemidesmosomes along their basal plasma membranes. Myoepithelial cells are abundant in relation to acinar and demilunar cells. Nerve terminals are present in some instances between acinar cells or between acinar and myoepithelial cells.     

Effects of nerve stimulation and denervation on secretory material in submandibular striated duct cells of cats,and the possible role of these cells in the secretion of salivary kallikrein

Striated ducts in cats after 24 hours starvation normally contained glycogen, especially in the basal regions. They also contained neutral mucin and tryptophan in apical parts of "light" cells and small irregular "secretory" granules were found in a similar distribution by electron microscopy.--Parasympathetic nerve stimulation caused a loss of glycogen but no apparent change in the apical secretory material, despite a copious secretion.--Sympathetic stimulation caused a loss of glycogen and an extensive depletion of apical secretory material, although the salivary flow was small.--Parasympathetic denervation caused progressive atrophy of striated ducts and oedematous degeneration of some cells occurred. Persisting "light" cells tended to contain few basal infoldings, few mitochondria and little apical secretory material.--Sympathetic denervation caused a loss of apical secretory material between 2-4 days, which may have been due to "degeneration activation". Thereafter little change was evident but some ductal atrophy had occurred by 32 days.--These changes in ductal secretory material correspond more closely than acinar changes to the alterations in glandular and salivary kallikrein resulting from similar experiments by other workers. It therefore seems likely that submandibular salivary kallikrein in the cat is present in the secretory material of striated ducts.     

Localization of kallikrein in the coagulating and submandibular glands of the guinea pig.

Antibody to pure kallikrein from the coagulating gland of the guinea pig was used to localize kallikrein in the gland by immunofluorescence techniques. This antibody also reacted with the guinea pig's submandibular gland kallikrein. The specific fluorescence in the coagulating gland was present diffusely in all secretory cells lining the crypts. In contrast to its diffuse location in the coagulating gland, kallikrein in the submandibular gland was specifically located in the luminal border of striated and some larger duct cells, whereas the acinar cells and interstitial tissue showed no significant fluorescence.     

Enzyme-and immuno-histochemical localization of kallikrein

Summary Localization of kallikrein in the human parotid gland was investigated simultaneously by two markers: kallikrein-like (enzyme) activity and kallikrein antigenicity. Kallikrein-like activity was histochemically demonstrated by using a synthetic substrate, pro-phe-arg-naphthylester. Kallikrein antigenicity was demonstrated by an unlabelled antibody peroxidase-antiperoxidase method, where monospecific antiserum against highly purified urinary kallikrein was used as the primary antiserum. The results showed that kallikrein-like activity and kallikrein antigenicity were identical in their locations in the ductal cells, being localized in the luminal part of the striated ducts and to a lesser degree in the excretory ducts. This indicates the presence of active kallikrein in these regions. No enzyme activity nor antigenicity was observed either in acini or in intercalated ducts. Moreover, the peroxidase-antiperoxidase method reveated kallikrein antigenicity for the first time extracellularly in the basement-membrane region of acini and of ducts as well as in the interstitium surrounding ducts and major vessels.     

Enzyme- and immuno-histochemical localization of kallikrein. I. The human parotid gland

Localization of kallikrein in the human parotid gland was investigated simultaneously by two markers: kallikrein-like (enzyme) activity and kallikrein antigenicity. Kallikrein-like activity was histochemically demonstrated by using a synthetic substrate, pro-phe-arg- naphthylester . Kallikrein antigenicity was demonstrated by an unlabelled antibody peroxidase-antiperoxidase method, where monospecific antiserum against highly purified urinary kallikrein was used as the primary antiserum. The results showed that kallikrein-like activity and kallikrein antigenicity were identical in their locations in the ductal cells, being localized in the luminal part of the striated ducts and to a lesser degree in the excretory ducts. This indicates the presence of active kallikrein in these regions. No enzyme activity nor antigenicity was observed either in acini or in intercalated ducts. Moreover, the peroxidase-antiperoxidase method revealed kallikrein antigenicity for the first time extracellularly in the basement-membrane region of acini and of ducts as well as in the interstitium surrounding ducts and major vessels.     

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.     

II. Ultrastructure of duct cell granules in mammalian submaxillary glands

Summary Discrete, PAS-positive granules of relatively uniform electron-density and size characterise the intercalated duct cells of mammalian submaxillary glands. Smaller, electron-dense organelles are seen in the cells at the junction of the intercalary-striated duct region in the guinea-pig. The large granules of variable electron-density which are observed in the proximal, modified intercalary cells in the rabbit closely resemble the granules in the acinar cells of the guinea-pig. Several populations of granules differing in size are found in the striated granular tubules of the rat and hamster; the organelles in the rat show two grades of electron-density whereas those in the hamster are uniformly dense. Numerous small granules with compactly arranged intragranular material occupy the apical part of the striated ducts of the cat, dog and rabbit. The chemical composition of each population of duct cell granules is unknown. The question whether granules containing kallikrein, trypsin-like enzymes and amylase are stored in the duct cells is discussed.We wish to thank The Wellcome Trust for a travel grant to attend the International Symposium on Vasopeptides (Florence, July 1971) where this work was briefly reported.     

Ultrastructure of bovine parotid glands

Bovine parotid glands exhibit outstanding structural differences when compared with those of non-ruminant mammals. The acini are tortuous, branched and lined with cells of different heights, imparting a scalloped appearance to acinar lumina. Numerous microvilli, ca. 1.5 μ in length, extend into the lumina and intercellular canaliculi. Intercellular canaliculi measure ca. 3 μ in diameter and interweave in close association with intercellular tissue spaces. Intercellular tissue spaces are separated from the extraacinar spaces across a basal lamina only, whereas junctional complexes guard canaliculi from direct continuity with tissue spaces and/or extraacinar spaces. Flattened cytoplasmic lamellae extend from adjacent acinar cells and loosely interdigitate with one another across the tissue spaces. Acinar cells contain more mitochondria and less granular endoplasmic reticulum than parotid glands of non-ruminant mammals. Two types of secretory material, in the form of inclusions which vary in size and electron density, are present in the acinar cells. Intercalated ducts connect acini with striated ducts which in turn, empty into collecting ducts located between gland lobules. In terms of frequency of “basal infoldings” and numbers of mitochondria, striated ducts of calf parotid glands are not as well developed as those of certain other salivary glands. Myoepithelial cells are most often present at junctions of acini and intercalated ducts where they may attach to both acinar and ductal epithelium. Nerve “terminals” were not observed on the epithelial side of basement membranes in relation to the secretory cells.     

Localisation of immunoreactive kininogen and tissue kallikrein in the human nephron

The cellular localisation of kininogen and its relationships with tissue kallikrein containing cells was studied in the human kidney by the peroxidase-antiperoxidase method using antisera to human LMW kininogen and to human tissue kallikrein. Immunoreactive kininogen was localised in the principal cells of collecting ducts. Immunoreactive tissue kallikrein was detected in the connecting tubule cells, segment of the nephron preceding the cortical collecting ducts. The co-existence of tissue kallikrein and kininogen in the same transitional tubule, but in different cells, was established by the use of serial sections and double immunostaining. This anatomical relationship is in accordance with known studies that describe intermingling of principal cells and connecting tubule cells where connecting tubules merge into cortical collecting ducts in the human nephron. The close relationship between cells that contain tissue kallikrein and its substrate, kininogen, suggests that kinins could be generated in the lumen of distal cortical segments of the human nephron.     

Localisation of immunoreactive kininogen and tissue kallikrein in the human nephron

Summary The cellular localisation of kininogen and its relationships with tissue kallikrein containing cells was studied in the human kidney by the peroxidase-antiperoxidase method using antisera to human LMW kininogen and to human tissue kallikrein. Immunoreactive kininogen was localised in the principal cells of collecting ducts. Immunoreactive tissue kallikrein was detected in the connecting tubule cells segment of the nephron preceeding the cortical collecting ducts. The co-existence of tissue kallikrein and kininogen in the same transitional tubule, but in different cells, was established by the use of serial sections and double immunostaining. This anatomical relationship is in accordance with known studies that describe intermingling of principal cells and connecting tubule cells where connecting tubules merge into cortical collecting ducts in the human nephron. the close relationship between cells that contain tissue kallikrein and its substrate, kininogen, suggests that kinins could be generated in the lumen of distal cortical segments of the human nephron.     

Nerve-induced secretion of glycoconjugates from cat submandibular glands: a correlative study with lectin probes on tissues and saliva.

Horseradish peroxidase-conjugated lectins were used on tissue sections to localize the main secretory glycoproteins in cat submandibular glands and on Western blots to evaluate their movement into saliva with selective nerve stimulation. Central acinar cells bound lectins from Arachis hypogaea (PNA) specific for the terminal disaccharide Gal beta 1, 3GalNac, Griffonia simplifolia (GSA I-B4) specific for terminal alpha Gal, and Lotus tetragonolobus (LTA) specific for fucose. Lectins from Limax flavus (LFA) specific for sialic acid and Dolichos biflorus (DBA) specific for terminal alpha GalNac reacted preferentially with demilunar cells, whereas apical granules in striated ducts were recognized principally by LTA. Parasympathetic stimulation promoted the release of lectin-reactive glycoconjugates from both central and demilunar cells. In contrast, sympathetic stimulation caused almost complete release of LTA-reactive granules in striated ducts and only moderate secretion from demilunar cells. Lectin blots of stimulated saliva discriminated many of the constituent bands, providing information about their glycosylation. Several bands were common to both parasympathetic and sympathetic saliva, and many bands gave wider ranges of lectin binding than anticipated from the histochemistry. The major component in parasympathetic saliva was a glycoconjugate of less than 12 KD which reacted with every lectin tested. Lectin blots of sympathetic saliva showed a prominent diffuse LTA-reactive band around 33 KD, which was attributed to tissue kallikrein. The identity and cellular origin of most bands in stimulated submandibular saliva are still unclear but the technique shows considerable promise for improving the recognition and characterization of individual glycoconjugates.     

Distribution of gamma-glutamyl transpeptidase in human pancreas: immunohistochemical study with a monoclonal antibody.

We studied in detail the distribution pattern of gamma-glutamyl transpeptidase (gamma-GT) in human pancreas, using the immunoperoxidase technique and a monoclonal antibody to human kidney gamma-GT. Positive reaction was confined exclusively to the luminal surface of the centroacinar cells and the epithelia of the intercalated, intralobular, and interlobular ducts. The immunoreaction was stronger in the intercalated and intralobular ducts than in the interlobular ducts. The acinar cells did not show any reaction. The islets of Langerhans were heavily surrounded by the ducts, and normal islet cells showed no reaction. The course of the ducts, from the acinar lumina to the interlobular ducts, was delineated by using reaction sites positive for gamma-GT as markers. The courses of the ducts, which comprise the pathway for pancreatic juice, were found to vary widely in their connections with each other, especially between the intralobular and interlobular ducts. At least three separate routes could be identified.     

Characterization of ducts isolated from the pancreas of the rat

Rat pancreases were minced and treated with collagenase or collagenase supplemented with chymotrypsin to yield a mixture of ducts, islets, acinar cell clusters, blood vessels, and nerves. Histologically and ultrastructurally, the isolated tissues resembled their in situ counterparts in most respects, the major difference being the destruction of the basement membranes (basal laminae). Ducts ranging in size from the common bile/main pancreatic duct to the intercalated ducts were identified in the digest, although interlobular ducts were most frequently observed. Acinar tissue fragments were separated from nonacinar structures either by flotation through discontinuous gradients of Ficoll or by sieving, the latter technique being the more efficient. Common bile/main ducts, interlobular ducts, and blood vessels were selected manually from the nonacinar fractions. Biochemical analyses showed that the entire nonacinar fraction, as well as isolated ducts and blood vessels, contained larger alkaline phosphatase, carbonic anhydrase, and Mg-ATPase specific activities than acinar tissue, whereas acinar tissue contained larger gamma-glutamyltranspeptidase and amylase activities. However, greater than 63% of the total recovered activity of each enzyme was associated with the acinar tissue. Both the association of the majority of each of these enzyme activities with the acinar tissue and the similarity in specific activities associated with ducts and blood vessels indicate that none of the enzymes tested is a unique marker for interlobular and larger ducts of the pancreas of the rat.     

Fine structure of the parotid gland in the pika and the volcano rabbit

The parotid glands of the pika and the volcano rabbit were examined by light and transmission electron microscopy. The acinar cells of the pika consisted of light cells containing basophilic granules of low density, while in the volcano rabbit the acinar cells consisted of light and dark cells containing acidophilic granules of moderate density. Intercalated duct cells were composed of light cells containing a few granules of moderate density. These segments of the two animals were similar in morphology. The striated duct cells in both species were composed of light and dark cells. Most of those in the pika contained a few moderately dense granules. In both animals, no myoepithelial cells were detected around the acini, intercalated ducts or striated ducts, while nerve terminals were observed among the adjacent acinar cells.     

Growth factor regulation of the amylase promoter in a differentiating salivary acinar cell line

Salivary glands contain two major epithelial cell types: acinar cells which produce the primary salivary secretion, including amylase, and ductal cells which reabsorb electrolytes but also secrete kallikrein. Here we investigated salivary acinar cell differentiation in vitro using the activity of the salivary amylase and tissue kallikrein promoters as markers of acinar cell and ductal cell differentiation, respectively. Each of the promoter sequences was cloned into a replication-deficient adenoviral vector containing the luciferase reporter gene. Previous studies showed that a human submandibular gland cell line (HSG) differentiated into acinar cells when cultured on a reconstituted basement membrane matrix (Matrigel). The luciferase activity of the amylase promoter vector (AdAMY-luc) was low in HSG cells cultured on plastic, where they grow as an epithelial monolayer. The promoter activity increased approximately tenfold when HSG cells were cultured on Matrigel and developed an acinar phenotype. Under the same conditions, the luciferase activity of the kallikrein promoter (AdKALL-luc) was not induced. Because HSG cells demonstrate acinar cell morphology, but not amylase gene expression, when cultured on laminin-1, certain soluble components of Matrigel were tested for their ability to induce the amylase promoter during in vitro differentiation of acinar cells. We find that epidermal growth factor (EGF) and transforming growth factor-alpha (TGF-alpha), which are present in the basement membrane, and hepatocyte growth factor (HGF) increase activity of the amylase promoter. Other basement membrane-derived growth factors such as TGF-beta, basic fibroblast growth factor (bFGF), and platelet-derived growth factor (PGDF), as well as tumor necrosis factor (TNF-alpha), keratinocyte growth factor (KGH), nerve growth factor (NGF) and interferon gamma (IFN-gamma) were inactive. This system will be further exploited to study the mechanisms by which extracellular matrix molecules and growth factors regulate salivary acinar cell differentiation.     

Occurrence and Nuclear Localization of cAMP Response Element- Binding Protein in the Post-natal Development of the Rat Submandibular Gland

Cyclic AMP response element-binding protein (CREB) is a 43-kDa polypeptide that binds a cAMP response element located at the 5 promoter region of cAMP regulatory genes. The spatial and temporal distribution of CREB in the post-natal development of the rat submandibular gland was investigated using immunohistochemistry with a specific antibody. At birth, cells of the terminal tubules and ducts in the submandibular gland showed a nuclear CREB immunoreactivity of moderate intensity. At 1–2 weeks after birth, an intense CREB immunoreactivity was localized primarily to acinar cells. When the r352;-adrenergic agonist isoproterenol was administered to 2-week-old rats, a twofold transient increase in the number of immunoreactive acinar cells was induced. Beginning 3 weeks after birth, CREB immunoreactivity shifted from acini to the duct system and showed a clear localization in the cells of the intercalated ducts and distal portions of striated ducts, where the granular convoluted tubule develops after 4 weeks. Immunopositive materials were localized exclusively in the nuclei of both acinar and ductal immunoreactive cells. After the development of the granular convoluted tubules, CREB immunoreactivity was absent in the tubule cells and was gradually reduced in intensity over the entire gland. In order to examine a hypothesis that CREB is involved in the initial differentiation of the granular convoluted tubular cells, testosterone was administered to hypophysectomized adult rats. Whereas the tubular cells of hypophysectomized rats showed a complete regression, and no CREB immunoreactivity was found in any acinar or duct cells, administration of testosterone for a few days induced an intense CREB immunoreactivity in the nuclei of duct cells, followed by their differentiation into the granular convoluted tubular cells. These results suggested that CREB is involved not only in the growth and differentiation of acinar ce lls that are regulated by r352;-adrenergic nerves but also in those of the duct system, and especially in the androgen-regulated differentiation of the granular convoluted tubular cells, during the post-natal development of the rat submandibular gland.     

The presence of carbonic anhydrase in orbital glands. An enzyme-histochemical study in cynomolgus monkeys and rabbits

The distribution of carbonic anhydrase (CA) was studied in the lacrimal gland of the cynomolgus monkey as well as in the lacrimal, infra-orbital and harderian glands of the rabbit. In the lacrimal gland of the cynomolgus monkey, a number of acini with positive staining were found; however, another group of acini did not stain. In the positively stained acinar cells, large amounts of reaction product were located in the cytoplasm, but only weak staining was observed in the membranes. In the endothelial cells of capillaries a strong staining reaction was only seen in those vessels which were adjacent to the acinar cells containing CA. In the lacrimal and infra-orbital glands of the rabbit, there was intense staining of the cell membranes in all acinar cells and weak staining of the cytoplasm in a few acinar cells. Stained capillaries were also found here, but these were not as numerous as in the lacrimal gland of the cynomolgus monkey. In the harderian gland of the rabbit, there was no staining in the white lobe. In the red lobe the acinar cells displayed distinct staining exclusively in the basolateral membranes. There was no staining of capillaries in the harderian gland. In none of the glands studied was there staining of the epithelial cells of the excretory ducts. The functional significance of these findings is discussed.     

Salivary glands of the cat: A histochemical study

Synopsis The submandibular, sublingual and parotid glands of the cat have been studied. Mucosubstance histochemistry demonstrated acidic mucosubstances with varying properties in the acini. Thiamine pyrophosphatase and nucleoside diphosphatase reaction products were seen with a Golgi-like appearance in acinar cells. Granules of acid phosphatase, -glucuronidase and E600-resistant esterase reaction products, presumably representing lysosomal enzyme activities, were seen in acinar and ductal cells. Diffuse acid phosphatase and -glucuronidase reaction products were seen in central cells of the submandibular acini, and diffuse non-specific esterase reaction product was seen in acinar and ductal cells. Arylamidase reaction product was associated with some acinar cells. Reaction product from a peroxidase technique was seen in demilunar cells of the submandibular acini, in parts of the sublingual acini, in parotid acini, and in ductal cells. Cytochrome oxidase and succinate dehydrogenase reaction products were seen most strongly in striated ducts, whereas NADH- and NADPH-diaphorase reaction products were seen at a high level throughout the ducts.