Coexistence of peptide YY and glicentin immunoreactivity in endocrine cells of the gut

Endocrine cells containing peptide YY (PYY) were numerous in the rectum, colon and ileum and few in the duodenum and jejunum of rat, pig and man. No immunoreactive cells could be detected in the pancreas and stomach. Coexistence of PYY and glicentin was revealed by sequential staining of the same section and by staining consecutive semi-thin sections. Since the PYY sequence is not contained in the glucagon/glicentin precursor molecule the results suggest that the PYY cell in the gut expresses two different genes coding for regulatory peptides of two different families.     

Localization of glucagon-like peptide (GLP) immunoreactants in human gut and pancreas using light and electron microscopic immunocytochemistry

The distribution of peptide immunoreactivities predicted from the sequence of the human preproglucagon gene in enteroglucagon (EG; glicentin-like immunoreactant-containing) cells of the human gut and A cells of the pancreas has been determined by light and electron microscopic immunocytochemistry. At light microscopy the application of peroxidase-antiperoxidase and immunogold-silver staining methods has revealed that glucagon-like peptide (GLP-1 and GLP-2) immunoreactivities coexist with a glicentin-related immunodeterminant in human colorectal EG cells and pancreatic A cells. Using single and double colloidal gold probe electron immunocytochemistry, we have been able to show the coexistence of glicentin, GLP-1, and GLP-2 immunoreactivities within single EG cell secretory granules. No morphologic segregation of the proglucagon immunoreactants was observed in EG cells of the colonic mucosa. In pancreatic A cells we have localized GLP-1, GLP-2, and glucagon-[16-29] immunoreactivities solely to the electron-dense core of the secretory granules, whereas glicentin-related immunoreactivity was restricted to the electron-lucent halo. The results obtained in the present study have shown that the peptide immunoreactivities predicted from cDNA sequencing of the human preproglucagon gene are indeed expressed in colorectal EG and pancreatic A cells. The topographical segregation of immunoreactivities in the A cell secretory granule shows that antigenic determinants derived from the C-terminal portion of proglucagon are stored with glucagon in the core of the secretory granule.     

Meal-induced peptide tyrosine tyrosine inhibition of pancreatic secretion in the rat

In the present studies we examined the distribution, release, and biological actions of peptide tyrosine tyrosine (PYY) in the rat. The concentration and distribution of PYY was highest in the ileum and colon as determined by both radioimmunoassay of rat tissue extracts and immunocytochemistry. An ultrastructural comparison of rat and dog colonic PYY cells revealed a bipolar distribution of peptide-containing secretory granules in both species. Serum PYY and pancreatic exocrine secretory responses were monitored after presentation of a meal to meal-trained rats (n = 12). A significant increase in PYY concentrations was not observed until 120 min after meal presentation, a delayed response similar to that previously observed in the dog. PYY responses were also observed in rats after perfusion of the intestine at the level of the duodenum and ileum with an 80 mOsm micellar solution of sodium oleate. Duodenal instillations of the fatty acids resulted in a maximum PYY response after 120 min, whereas rats subject to ileal perfusion of fat exhibited maximum PYY release within the first hour. In other experiments, infusion of exogenous PYY at 100 pmol.kg-1.h-1, which reproduced plasma PYY levels observed after a meal and perfusion of the gut with fat, significantly inhibited CCK-stimulated bile pancreatic volume (P less than 0.02), protein (P less than 0.01), and amylase (P less than 0.01) output. These studies demonstrate a bipolar distribution of PYY-containing secretory granules in cells of the jejunal, ileal, and colonic mucosa, and show that PYY is released in response to a meal in amounts sufficient to inhibit cholecystokinin-stimulated pancreatic secretion. Evidence is presented that PYY may mediate the delayed inhibition of pancreatic secretion that is observed in the rat after ingestion of a meal.     

Ultrastructural localization of serotonin and polypeptide YY (PYY) in endocrine cells of the human rectum

This study was performed with the aim of ultrastructurally localizing serotonin and polypeptide YY (PYY) in the endocrine cells of the human rectum. Existing basic methods for immunolocalization of antigenic sites in ultrathin sections were tested and modified to allow reproducible results with distinct localization of marker (colloidal gold probes coupled either to IgG or protein A). Probes signifying presence of serotonin were distinctly localized over all heteromorphous granules in argentaffin cells and, in addition, over some of the more monomorphous, rounded granules in a second cell type whose granules all were covered by probes showing localization of the PYY antigen. The results suggest that serotonin in endocrine cells of the gut is not confined to the enterochromaffin type but may also be present in trace amounts in non-enterochromaffin endocrine cells storing peptide hormones. Since probes marking sites of PYY were deposited over some heteromorphous granules in enterochromaffin cells, the evidence obtained also suggests that PYY may occur in low concentration in these cells. The distribution of probes in the sections indicated that antigenic sites were confined to granules in the cells.     

Two Dipolar α-Helices within Hormone-encoding Regions of Proglucagon Are Sorting Signals to the Regulated Secretory Pathway

Proglucagon is expressed in pancreatic α cells, intestinal L cells, and some hypothalamic and brainstem neurons. Tissue-specific processing of proglucagon yields three major peptide hormones as follows: glucagon in the α cells and glucagon-like peptides (GLP)-1 and -2 in the L cells and neurons. Efficient sorting and packaging into the secretory granules of the regulated secretory pathway in each cell type are required for nutrient-regulated secretion of these proglucagon-derived peptides. Our previous work suggested that proglucagon is directed into granules by intrinsic sorting signals after initial processing to glicentin and major proglucagon fragment (McGirr, R., Guizzetti, L., and Dhanvantari, S. (2013) J. Endocrinol. 217, 229–240), leading to the hypothesis that sorting signals may be present in multiple domains. In the present study, we show that the α-helices within glucagon and GLP-1, but not GLP-2, act as sorting signals by efficiently directing a heterologous secretory protein to the regulated secretory pathway. Biophysical characterization of these peptides revealed that glucagon and GLP-1 each encode a nonamphipathic, dipolar α-helix, whereas the helix in GLP-2 is not dipolar. Surprisingly, glicentin and major proglucagon fragment were sorted with different efficiencies, thus providing evidence that proglucagon is first sorted to granules prior to processing. In contrast to many other prohormones in which sorting is directed by ordered prodomains, the sorting determinants of proglucagon lie within the ordered hormone domains of glucagon and GLP-1, illustrating that each prohormone has its own sorting “signature.”     

Glucagon- and glicentin-immunoreactive cells in the human digestive tract

Summary The distribution and cellular location of substances reacting with anti-glucagon or anti-glicentin sera, i.e., glucagon-like and glicentin-like immunoreactivities, were studied in the human digestive tract using the immunofluorescence and immunoperoxidase methods. Both types of immunoreactivity were (1) absent in the antrum, (2) abundant in cells located at the periphery of pancreatic islets, (3) unevenly present in cells scattered in the epithelium of the small intestinal mucosa, the glicentin-immunoreactive cells being particularly abundant in the ileum. In the pancreas, and, when simultaneously present, in the intestine, both glucagon and glicentin immunoreactivities were located in the same cells.The precise ultrastructural location of each immunoreactivity was readily made using colloidal gold and ferritin tracers on ultrathin sections of glutaraldehyde-osmium fixed and epoxy resin-embedded tissues. In the pancreas, both glucagon and glicentin immunoreactivities were found in the granules of the A-type cells; the glucagon immunoreactivity was only present in the core of the granule, whereas the glicentin immunoreactivity was found either in the peripheral halo only, or throughout the entire granule. In the small intestine, both immunoreactivities were located inside the granules of the L-type cells.Quantitative specificity tests suggested that the glucagon- and the glicentin-like substances of the pancreas differ from those found in the intestine.Work supported by INSERM, A.T.P. number: 167539     

Electron-immunocytochemical localization of calcitonin and calcitonin-gene-related peptide in human c cells of the thyroid

A preembedding immunocytochemical technique enabled us to demonstrate normal human parafollicular (C) cells at the electron-microscopic level. The normal human C cells had numerous large secretory granules with a diameter of approximately 200 nm, well-developed rough endoplasmic reticulum and Golgi complex in their cytoplasm. Calcitonin immunoreactivity and calcitonin-gene-related peptide (CGRP) immunoreactivity were present only in the C cells whose secretory granules were heavily labeled. Both calcitonin and CGRP immunoreaction deposits were seen in the cytosol but not in the cisterna of endoplasmic reticulum, Golgi apparatus or mitochondrial matrix. The two peptides produced from a single calcitonin gene were stored in the secretory granules of the C cells.     

Plasma and tissue alterations of peptide YY and enteroglucagon in rats after colectomy.

Peptide YY (PYY) and enteroglucagon are produced by endocrine cells of the colonic mucosa. PYY inhibits upper gastrointestinal motility, and enteroglucagon is trophic for small bowel mucosa. Adaptive increase in the production and release of these peptides may improve functional results after colorectal resections. We hypothesized that if segments of the colon were resected, then production and release of PYY and enteroglucagon would increase in the remaining segments of bowel. Animals which underwent colonic transections and partial resections had transient elevations of PYY up to 250 +/- 80 pmol/L, which dropped to control group levels in the second week following surgery. Rats with an abdominal colectomy had significantly greater PYY levels than all other groups from the third (208 +/- 30 pmol/L) to the thirty-eighth (100 +/- 16 pmol/L) week of the study. Circulating levels of enteroglucagon were elevated to 156 +/- 35 pmol/L in rats with a right hemicolectomy during the first week following surgery. Enteroglucagon levels did not significantly vary in the other groups studied. Both tissue PYY (413 +/- 33 pmol/gram) and tissue enteroglucagon (171 +/- 17 pmol/gram) were significantly elevated in the rectums of the rats with an abdominal colectomy, as compared to all other groups. The elevated tissue levels may thus account for the ability to maintain elevated plasma PYY. Double immunogold labeling of endocrine cells in the colorectal tissue for PYY and enteroglucagon revealed both peptides within the same endocrine cells and secretory granules. These studies support the hypothesis that circulating levels of PYY are elevated after major colonic resections and suggest that L-type endocrine cells may participate in adaptive responses which improve intestinal function following colonic surgery.     

Electron-microscopic immunocytochemical study of the endocrine pancreas of sea bass (Dicentrarchus labrax)

Insulin (B)-, somatostatin 25 (SST-25) (D1)-, somatostatin 14 (SST-14) (D2)-, glucagon (A)-, and glucagon PP/PYY/NPY (PP-like)-immunoreactive cells in islets of sea bass (Dicentrarchus labrax) were characterized according to their ultrastructure and immunogold labeling. Cells labeled with antisera to bonito and salmon insulin had numerous secretory granules with a small halo and round core, and a few with wide halo and round or crystalloid core. Gold particles were found throughout the granule in tissue labeled with the former but only in the core in tissue labeled with the latter. D1 cells had large granules with a medium electron-dense content and some with a darker core. D2 had smaller medium or high electron-dense secretory granules than D1 cells, located mainly in cell periphery. Glucagon-immunoreactive cells contained some granules with a polygonal core that was heavily labeled and other granules with a round core with no or hardly any labeling. Glucagon and PP-like immunoreactivity were co-localized in secretory granules, in which the gold particles showed no different distribution with the various antisera used. PYY-immunoreactive granules were also found in nerve endings. All the pancreatic endocrine cell types showing involutive characteristics are found.     

Glicentin: A precursor of glucagon?

The relationships between glucagon and gut-glucagon like immunoreactants (gut-GLIs) have been investigated by immunofluorescence in canine gut mucosa. The R64 antiserum, raised against the purified gut-GLI-l glicentin, and which does not react with porcine glucagon, revealed immunofluorescent cells in the gastric and intestinal mucosa. Glicentin positive cells of the stomach oxyntic glands were also stained by N- and C- terminally directed antiglucagon sera, corresponding to the gastric A-cell. In the small and large intestine, glicentin immunoreactive cells reacted solely with the cross-reacting (N-terminal) glucagon antiserum, belonging to the L-cells. Based on chemical and immunochemical data, it has been suggested that glicentin could represent an intermediate in the glucagon biosynthesis. Therefore, the results of this immunofluorescence study, showing glicentin and glucagon immunodeterminants in the A-cell, strongly support such an hypothesis. In addition the presence of glicentin like material in the A- and L-cells suggests that these two cell types synthesize their secretory product via a common precursor.     

Ultrastructural immunocytochemical localization of prolactin and growth hormone in the porcine pituitary

Summary The immunocytochemical peroxidase-antiperoxidase technique was used to identify prolactin- and growth hormone-producing cells in the porcine pituitary at the ultrastructural level. The growth hormone-producing cells contain round secretory granules (300 nm to 500 nm in diameter). The prolactin-producing cells can be identified by their distinct round and ovoid secretory granules which vary in size. Most of these cells contain large granules (450 nm to 750 nm in diameter), but some prolactin-producing cells display smaller secretory granules (250 nm to 500 nm). The two hormones were localized exclusively in the secretory granules. Staining for prolactin was observed in round and ovoid granules, as well as in small and polymorphic granules within the Golgi complex. This study confirmed (i) that the two hormones are located in different cells, and (ii) that under normal physiological conditions no one cell can synthesize and store both hormones simultaneously.     

Glucagon, glicentin, proglucagon, PYY, PP and proPP-icosapeptide immunoreactivities of rectal carcinoid tumors and related non-tumor cells

Glucagon/PP-related peptides were detected immunohistochemically in 18 out of 22 cases of rectal tumors investigated. The reactive tumors showed prevalence of trabecular or mixed trabecular-acinar structure and moderate staining with Grimelius' silver and lead-hematoxylin. Three of the remaining 4 cases were characterized by reactivity for 5-hydroxytryptamine only, prevalence of a solid nest structural component and intense staining with Grimelius' silver technique and lead-hematoxylin. Fifteen of the 18 glucagon/PP-reactive cases were investigated immunohistochemically with a series of 6 sera directed against different sequences of glucagon, glicentin and proglucagon, and of 7 sera directed against PP, PYY and proPP-icosapeptide. A large spectrum of glucagon-related immunoreactivities, including C-terminus and mid-portion glucagon-immunoreactivity, N- and C-terminus glicentin-immunoreactivity, GLP1- and GLP2-immunoreactivity, were detected in human rectal L cells and most rectal carcinoids. With the exception of a few scattered cells in the rectal mucosa and in 3 tumors, C-terminus glucagon-immunoreactivity was obtained only after trypsin or subtilisin treatment of tissue sections. Both PYY and PP/proPP-like peptide(s) were detected in rectal L cells and carcinoids, with prevalence of PYY in normal cells and PP/proPP-like peptides in tumor cells. It is concluded that the same or closely related hormone/prohormone sequences are synthesized and stored in rectal endocrine cells and carcinoid tumors although differences of quantitative expression, post-translational cleavage or reactivity to antibodies may occur. The usefulness of protease treatments of tissue sections to unmask immunoreactivities of uncleaved propeptides or fixative-denatured peptides is outlined.     

Human pituitary corticotrophs: their amphophilic stainability and immunohistochemical characterization

Immunohistochemical characterization of the human pituitary beta(R) cells was investigated through the findings of the immunoreactivities with anti-porcine ACTH, -rat TSH, -rat FSH sera. Immunostained corticotrophs are oval or round in shape and localized in the anteromedial wedge. It is shown on the adjacent sections that they correspond to the beta(R) cells with amphophilic stainability with PAS-iron hematoxylin. In this wedge, amphophilic cells are preponderant, but PAS-positive thyrotrophs and gonadotrophs are not numerous. Amphophilic stainability varies in degree from cell to cell: One cell contains numerous medium-size of secretory granules weakly stained with iron hematoxylin and strongly with PAS in the PAS-positive cytoplasm, and the other cell is filled with big secretory granules intensively stained with iron hematoxylin and weakly with PAS. The immunostained TSH, LH and FSH cells are different from the beta(R) corticotrophs, because anti-ACTH serum never reacts to the TSH, LH and FSH cells in the two adjacent sections. LH and FSH reactivities are observed in the single cells. It is concluded that human corticotrophs are amphophilic beta(R) cells filled with secretory granules, and that they have quite a different appearance from the rat chromophobic stellate corticotrophs with a row arrangement of secretory granules along the plasma membrane.     

Intracellular localization of serotonin in mast cells of the colon in normal and colitis rats

Intracellular localization of serotonin (5-HT) in the mast cells of two phenotypes in normal rat colon and dextran sodium sulphate-induced colitis was studied by immunoelectron microscopy with a quantitative analysis of the distribution of immunogold labelling. Mucosal mast cells in normal rats contained round shape secretory granules with varying electron density. Immunogold labelling for 5-HT was concentrated over the secretory granules. In mucosal mast cells from colitis rats, vacuolated granules without 5-HT labelling were frequently observed and immunogold labelling over the secretory granules was significantly increased compared to controls. On the other hand, connective tissue mast cells in normal rats contained oval shape secretory granules with homogeneous electron density. Their immunogold labelling was diffusely scattered over the secretory granules as well as over the cytoplasm. In connective tissue mast cells from colitis rats, secretory granules with high electron density were increased and the immunogold labelling over the secretory granules was much higher than that in controls. The present results suggest that intracellular localization of 5-HT is different in two phenotypes of mast cells and they may release 5-HT in a different manner. Mucosal mast cells may release 5-HT by a degranulation or exocytosis, while connective tissue mast cells may release 5-HT by a diacrine manner of secretion.     

Immunocytochemical localization of cathepsins B and H in human pancreatic endocrine cells and insulinoma cells

Cathepsins B and H are representative cysteine proteinases localized to lysosomes of a variety of mammalian cells. Previous studies indicated the presence of these enzymes also in secretory granules of endocrine cells. Therefore, the human endocrine pancreas and human insulinomas were investigated by light microscopical immunohistochemistry on serial semithin plastic sections immunostained sequentially for cathepsins B or H and pancreatic hormones. Out of the four established endocrine cell types, insulin (B-) and glucagon (A-) cells showed immunoreactivities for these cathepsins. Cathepsin B immunoreactivities showed a dot-like appearance in A- and B-cells and in insulinoma cells. Immunoreactivities for cathepsin H additionally were found in cell parts containing secretory granules of B-cells and insulinoma cells. By single and double immunoelectron microscopy the dot-like immunoreactivities for cathepsin B were identified as immunoreactive lysosomes of A- and B-cells and insulinoma cells. In addition, some of the secretory granules of A- and B-cells showed cathepsin B immunoreactivities. Cathepsin H immunoreactivities showed an other pattern: they were found regularly in the secretory granules of A- and B-cells and insulinoma cells, and in lysosomes of A-cells. These findings suggest that cathepsins B and H in lysosomes of A- and/or B-cells are involved in the degradation of lysosomal constituents. In secretory granules of these cells, these cysteine proteinases may participate in the processing of the corresponding hormones from their precursor proteins.     

Ultrastructure of the human submandibular salivary glands]

By means of electron microscopy cells in the human submandibular glands were studied. It was demonstrated that in acini two types of glandular cells were present: mucosal and seromucosal. In the latter, secretory granules are descrete with electron opaque cores in most of them. Mucocytes are filled with an electron transparent secrete; secretory granules often confluent and their membranes rupture. The acini are surrounded with myoepithelial cells. Intercalated ducts consist of cells with moderately electron opaque granules. In some granules there are dense bodies excentrically situated. In these cells there occur lipid inclusions. Striated ducts are composed of basal (electron transparent) and high cylindric (light and dark) cells. The cylindrical cells have a large amount of mitochondria, deep folds in their basal plasmolemma protruding into cytoplasma. Most of the cells in these parts contain small apically accumulated secretory granules with a dense matrix and separate larger ones scattered in the cell. It is possible to suggest that some secretory granules of ductal or, perhaps, acinar origin contain hormonal products.     

Immunocytochemical identification of polypeptide YY (PYY) cells in the human gastrointestinal tract

Various parts of the human gastrointestinal tract were investigated immunocytochemically for the occurrence of polypeptide YY (PYY) and pancreatic polypeptide (PP). PYY-immunoreactive cells were observed in the lower part of the ileum, in the colon and in the rectum, and PP-immunoreactive cells were found in the colon and rectum. Both cell types were of the open type, i.e. they extended from the basal lamina to the gut lumen. PYY-immunoreactive cells were seen to emit cytoplasmic processes to the neighbouring goblet cells. This latter observation suggests that PYY cells may exert a paracrine action on the mucus-secreting goblet cells. Staining of consecutive thin plastic sections and staining of the same section simultaneously for two peptides showed that PYY-immunoreactivity did not occur in PP- or enteroglucagon-immunoreactive cells. On the ultrastructural level PYY-immunoreactivity was localized in basal granulated endocrine cells. These cells contained round or slightly oval electron dense granules with a mean diameter of 150 nm (range 100-300 nm).     

Immunocytochemical localization of cathepsins B and H in human pancreatic endocrine cells and insulinoma cells

Summary Cathepsins B and H are representative cysteine proteinases localized to lysosomes of a variety of mammalian cells. Previous studies indicated the presence of these enzymes also in secretory granules of endocrine cells. Therefore, the human endocrine pancreas and human insulinomas were investigated by light microscopical immunohistochemistry on serial semithin plastic sections immunostained sequentially for cathepsins B or H and pancreatic hormones. Out of the four established endocrine cell types, insulin (B-) and glucagon (A-) cells showed immunoreactivities for these cathepsins. Cathepsin B immunoreactivities showed a dot-like appearance in A- and B-cells and in insulinoma cells. Immunoreactivities for cathepsin H additionally were found in cell parts containing secretory granules of B-cells and insulinoma cells. By single and double immunoelectron microscopy the dot-like immunoreactivities for cathepsin B were identified as immunoreactive lysosomes of A- and B-cells and insulinoma cells. In addition, some of the secretory granules of A- and B-cells showed cathepsin B immunoreactivities. Cathepsin H immunoreactivities showed an other pattern: they were found regularly in the secretory granules of A- and B-cells and insulinoma cells, and in lysosomes of A-cells. These findings suggest that cathepsins B and H in lysosomes of A- and/or B-cells are involved in the degradation of lysosomal constituents. In secretory granules of these cells, these cystine proteinases may participate in the processing of the corresponding hormones from their precursor proteins.     

Delta sleep-inducing peptide (DSIP)-like immunoreactivity in gut: coexistence with known peptide hormones

Delta sleep-inducing peptide-like immunoreactivity (DSIP-LI) has previously been demonstrated in brain neurons and in endocrine cells of the pituitary and the adrenal medulla. By means of three different antisera against synthetic DSIP we now describe the occurrence and distribution of DSIP-LI in several gut endocrine cells. The human gut was the richest source, where DSIP-LI was located in gastrin/CCK, secretin and PYY/glicentin cells. The rat and pig gut harbour a moderate number of immunoreactive cells in the antral mucosa but in the intestines DSIP-LI-containing cells were very few. By radioimmunoassay, the concentration of DSIP-LI was determined in extracts of various gut regions from man, pig and rat. The highest concentrations were found in all human specimens compared with corresponding samples in the pig and rat. In all three species, high-performance liquid chromatography revealed a single peak of DSIP-like material with approximately the same retention time as DSIP 3-9. Taken together, the present results provide evidence for the presence of DSIP-LI in gut endocrine cells in man, pig and rat; the human gut seems to be the richest source of DSIP-like peptides.