Immunohistochemical localization of chromogranin A and B in endocrine cells of the alimentary tract of the adult lizard Podarcis sicula

The distribution, argyrophilia, and the possible amine/peptide co-localizations in endocrine cells immunoreactive (IR) to antisera against chromogranin A (CgA) and chromogranin B (CgB) in the alimentary tract of the lizard Podarcis sicula have been investigated using novel monoclonal antibodies. Many CgA-IR and CgB-IR cells were found in the tract, except in the distal small intestine. Almost all chromogranin-IR cells (Cgs-IR) were also argyrophilic with parallel intensity. Some CgA-IR and CgB-IR cells did not display co-localized amines or peptides. CgA or CgB or both were found co-localized, with some local differences, in almost all serotonin-IR, histamine-IR, substance P-IR and gastric peptide tyrosine tyrosine (PYY)-IR cells. Moreover, both Cgs were co-localized only in some somatostatin-IR cells, whereas neurotensin-IR, gastrin/cholecystokinin-IR, pancreatic polypeptide-IR and intestinal PYY-IR cells did not show any co-localization with Cgs. The presence of Cgs in the endocrine cells was heterogeneous with regard to the complex interrelationship with their amine/peptide content. Consequently, Cgs cannot be considered as universal markers of all endocrine cell types.     

Expression of the Bitter Taste Receptor,T2R38, in Enteroendocrine Cells of the Colonic Mucosa of Overweight/Obese vs. Lean Subjects

Bitter taste receptors (T2Rs) are expressed in the mammalian gastrointestinal mucosa. In the mouse colon, T2R138 is localized to enteroendocrine cells and is upregulated by long-term high fat diet that induces obesity. The aims of this study were to test whether T2R38 expression is altered in overweight/obese (OW/OB) compared to normal weight (NW) subjects and characterize the cell types expressing T2R38, the human counterpart of mouse T2R138, in human colon. Colonic mucosal biopsies were obtained during colonoscopy from 35 healthy subjects (20 OW/OB and 15 NW) and processed for quantitative RT-PCR and immunohistochemistry using antibodies to T2R38, chromogranin A (CgA), glucagon like peptide-1 (GLP-1), cholecystokinin (CCK), or peptide YY (PYY). T2R38 mRNA levels in the colonic mucosa of OW/OB were increased (> 2 fold) compared to NW subjects but did not reach statistical significance (P = 0.06). However, the number of T2R38 immunoreactive (IR) cells was significantly increased in OW/OB vs. NW subjects (P = 0.01) and was significantly correlated with BMI values (r = 0.7557; P = 0.001). In both OW/OB and NW individuals, all T2R38-IR cells contained CgA-IR supporting they are enteroendocrine. In both groups, T2R38-IR colocalized with CCK-, GLP1- or PYY-IR. The overall CgA-IR cell population was comparable in OW/OB and NW individuals. This study shows that T2R38 is expressed in distinct populations of enteroendocrine cells in the human colonic mucosa and supports T2R38 upregulation in OW/OB subjects. T2R38 might mediate host functional responses to increased energy balance and intraluminal changes occurring in obesity, which could involve peptide release from enteroendocrine cells.     

Localization and development of chromogranin A and luteinizing hormone immunoreactivities in the secretory-specific cells of the hypophyseal pars tuberalis of the chicken

 The pars tuberalis mainly consists of the secretory cells specific to this portion of the pituitary. We examined the localization and development of luteinizing hormone (LH) and chromogranin A in the chicken pars tuberalis by immunohistochemistry. The vast majority of the chicken pars tuberalis was occupied by cells immunoreactive for both LH and chromogranin A. Furthermore, immunoblot analysis of chicken pars tuberalis extracts with LH antiserum demonstrated that two bands, the large α-subunit and small β-subunit of the LH molecule, were expressed in this tissue as well as in the pars distalis. A band for chromogranin A was also detected in pars tuberalis extracts with chromogranin A antiserum. In contrast to the cells of mammalian species that contain only a few small secretory granules, the specific cells of the chicken pars tuberalis were characterized by the presence of many secretory granules ranging from 90 to 400 nm in diameter. Postembedding immunogold labeling showed that gold particles representing immunoreactivity for LH were densely located on all secretory granules of the secretory-specific cells. Many secretory granules, especially the large ones, of the cells were also loaded with immunogold particles for chromogranin A. Double immunogold labeling confirmed that LH and chromogranin A were colocalized on the same secretory granules. During embryonic development, the primordium of the pars tuberalis was first detected at 8 days of incubation as a small group of cells containing LH- and chromogranin-immunoreactive cells. In the pars distalis, the onset of LH and chromogranin expression occurred earlier, at 6 days of incubation. At 10 days of incubation, the pars tuberalis primordium became large cell masses consisting of LH- and chromogranin-immunoreactive cells, which were located close to the median eminence. Subsequently, the primordium extended along the median eminence progressively with age. At 14 days of incubation, it reached to the rostral end and surrounded the median eminence as slender cell cords. These results indicate that specific cells of the chicken pars tuberalis synthesize a glycoprotein hormone related to the LH molecule, which is stored in the secretory granules together with chromogranin A. The pars tuberalis may be involved in the regulation of gonadal function in a different way from that of the pars distalis. Accepted: 26 August 1997     

Expression of the noradrenaline transporter and phenylethanolamine N-methyltransferase in normal human adrenal gland and phaeochromocytoma

Expression of the noradrenaline transporter (NAT) was examined in normal human adrenal medulla and phaeochromocytoma by using immunohistochemistry and confocal microscopy. The enzymes tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) were used as catecholamine biosynthetic markers and chromogranin A (CGA) as a marker for secretory granules. Catecholamine content was measured by using high performance liquid chromatography (HPLC). In normal human adrenal medulla (n=5), all chromaffin cells demonstrated strong TH, PNMT and NAT immunoreactivity. NAT was co-localized with PNMT and was located within the cytoplasm with a punctate appearance. Human phaeochromocytomas demonstrated strong TH expression (n=20 samples tested) but variable NAT and PNMT expression (n=24). NAT immunoreactivity ranged from absent (n=3) to weak (n=10) and strong (n=11) and, in some cases, occupied an apparent nuclear location. Unlike the expression seen in normal human adrenal medullary tissue, NAT expression was not consistently co-localized with PNMT. PNMT also showed highly variable expression that was poorly correlated with tumour adrenaline content. Immunoreactivity for CGA was colocalized with NAT within the cytoplasm of normal human chromaffin cells (n=4). This co-localization was not consistent in phaeochromocytoma tumour cells (n=7). The altered pattern of expression for both NAT and PNMT in phaeochromocytoma indicates a significant disruption in the regulation and possibly in the function of these proteins in adrenal medullary tumours.     

Distribution and ontogeny of chromogranin A and tyrosine hydroxylase in the carotid body and glomus cells located in the wall of the common carotid artery and its branches in the chicken

Development and distribution of chromogranin A and tyrosine hydroxylase in the carotid body and glomus cells located in and around arteries were examined in chickens at various developmental stages by an immunohistochemical staining. In 9-day-old embryos, numerous cells immunoreactive for tyrosine hydroxylase were already detected in the connective tissue surrounding the carotid body. Some of these cells also showed immunoreactivity for chromogranin A. At 10 days of incubation, a few cells immunoreactive for tyrosine hydroxylase and chromogranin A were detected within the carotid body parenchyma. At 12 days of incubation, almost all glomus cells of the carotid body were intensely immunoreactive for these substances. Furthermore, numerous tyrosine hydroxylase- and chromogranin A-immunoreactive cells were observed in the wall of the common carotid artery, along the whole length of the carotid body artery, and around the roots of the inferior thyroid artery, the ascending esophageal artery and the esophagotracheobronchial artery; the cells already exhibited adult pattern of distribution at this stage of development. Thereafter, glomus cells immunoreactive for both substances gradually increased in number and in intensity of immunoreactivity with age, although the cells located in the wall of the common carotid artery lost immunoreactivity for tyrosine hydroxylase after hatching.     

Distribution and ontogeny of chromogranin A and tyrosine hydroxylase in the carotid body and glomus cells located in the wall of the common carotid artery and its branches in the chicken

Summary Development and distribution of chromogranin A and tyrosine hydroxylase in the carotid body and glomus cells located in and around arteries were examined in chickens at various developmental stages by an immunohistochemical staining. In 9-day-old embryos, numerous cells immunoreactive for tyrosine hydroxylase were already detected in the connective tissue surrounding the carotid body. Some of these cells also showed immunoreactivity for chromogranin A. At 10 days of incubation, a few cells immunoreactive for tyrosine hydroxylase and chromogranin A were detected within the carotid body parenchyma. At 12 days of incubation, almost all glomus cells of the carotid body were intensely immunoreactive for these substances. Furthermore, numerous tyrosine hydroxylase- and chromogranin A-immunoreactive cells were observed in the wall of the common carotid artery, along the whole length of the carotid body artery, and around the roots of the inferior thyroid artery, the ascending esophageal artery and the esophagotracheobronchial artery; the cells already exhibited adult pattern of distribution at this stage of development. Thereafter, glomus cells immunoreactive for both substances gradually increased in number and in intensity of immunoreactivity with age, although the cells located in the wall of the common carotid artery lost immunoreactivity for tyrosine hydroxylase after hatching.     

Immunoelectron microscopic study of the luminal release of chromogranin A from rat enterochromaffin cells

 Recently we found that raising the intraluminal pressure caused an increase in the luminal release of serotonin from enterochromaffin (EC) cells and serotonin immunoreactivity normally restricted within the secretory granules was diffusely scattered over the extragranular matrix. In the present study we investigated the intracellular localization of chromogranin A, a protein co-stored with serotonin in the EC cells, after stimulating the luminal release of serotonin. In situ vascularly and luminally perfused rat duodenum was exposed to intraluminal pressure and fixed for immunoelectron microscopic study. For immunoelectron microscopy, the pre-embedding DAB reaction for serotonin combined with the postembedding immunogold reaction for chromogranin A was used. Results showed that a number of secretory granules labeled with immunogold chromogranin A immunoreactivity located close to the apical plasma membrane. Some EC cells showed that one part of the apical cytoplasm was protruded into the lumen and a number of secretory granules with immunogold labeling were included in the protruded cytoplasm. These results suggest that EC cells may release chromogranin A into the intestinal lumen together with serotonin, by means of a different manner of secretion from that in serotonin. Received / Accepted: 9 December 1998     

Immunocytochemical demonstration of octopamine-immunoreactive cells in the nervous system of Locusta migratoria and Schistocerca gregaria

Summary The distribution of octopamine in the metathoracic ganglion, brain and corpus cardiacum of Locusta migratoria and Schistocerca gregaria was investigated by means of immunocytochemistry with an antiserum against octopamine. The dorsal unpaired median (DUM) cells of the metathoracic ganglion were found to be strongly octopamine-immunoreactive. In the rostroventral part of the protocerebrum a group of seven immunopositive cells was demonstrated. Stained nerve fibres of these cells run into three directions: circumoesophageal connectives, midbrain, and optic lobes. As far as the protocerebrum is concerned, immunoreactive fibres were found in the central body, the protocerebral bridge, and in other neuropile areas. In the optic lobe a dense plexus of immunopositive fibres was found in the lobula and in the medulla. In the brain one other immunopositive cell was demonstrated, situated at the lateral border of the tritocerebrum. Octopamine could not be shown to occur either in the globuli cells of the mushroom bodies or in the dorsolateral part of the protocerebrum, where the perikarya of the secretomotor neurones are located that innervate the glandular cells of the corpus cardiacum. In the nervi corporis cardiaci II, which contain the axons of the neurones that extend into the glandular part of the corpus cardiacum, and in the corpus cardiacum proper no specific octopamine immunoreactivity could be found.     

Cellular distribution and amount of chromogranin A in bovine endocrine pancreas

We determined the cellular distribution and the amount of chromogranin A in endocrine cells of bovine pancreas using a polyclonal antibody against bovine adrenomedullary chromogranin A. The relative amounts of chromogranin A in the different cells of the endocrine pancreas were determined by computer-assisted analyses of the optical densities of the immunoreactivities in the stained sections. More than 80% of the immunoreactive chromogranin A was located in the pancreatic B-cells. In immunoblots of acid tissue extracts, only one chromogranin A band (MW 74 KD) was observed. Quantification of the immunoblots revealed that 3 micrograms of chromogranin A and 918 micrograms of insulin were present per gram pancreas (wet weight), equivalent to a molar ratio of 460 mumol chromogranin A per mol insulin.     

An immunological study on chromogranin A and B in human endocrine and nervous tissues

Summary Antisera were raised against synthetic peptides derived from the primary amino acid sequence of human chromogranin B. These antisera recognized in one- and two-dimensional immunoblotting a component previously designated as chromogranin B. In human chromaffin granules, the major endogenous processing product of chromogranin B is formed by proteolytic cleavage of the protein near theC-terminus. Immunohistochemical localizations were obtained with antisera against human chromogranins A and B and against a synthetic peptide corresponding to the B sequence. In human tissues, chromogranin B is co-stored with chromogranin A in the adrenal medulla, the anterior pituitary, parafollicular cells of the thyroid, in some cells of the endocrine pancreas and in some enterochromaffin cells, whereas only chromogranin A is found in the parathyroid gland and enterochromaffin cells of the gastric corpus mucosa. In the nervous system, no immunostaining was observed for chromogranin A and only a weak one for chromogranin B in some cells of the spinal cord. However, the Purkinje cells of the cerebellum were strongly positive for chromogranin B.     

Immunocytochemical localization of carbamyl phosphate synthetase in the filamentous heterocystous cyanobacteriumNostoc PCC 73102

Summary Free-living nitrogen-fixingNostoc PCC 73102 cells, a filamentous heterocystous cyanobacterium originally isolated from the cycadMacrozamia, were grown without or with the addition of either citrulline or ornithine and examined for the presence of carbamyl phosphate synthetase (CPS) by SDS-PAGE and Western immunoblots. Transmission electron microscopy and immunocytochemical labelling were used to study the cellular and subcellular distribution of CPS in theNostoc cells.Western immunoblots revealed that a polypeptide with a molecular weight of approximately 130 kDa was immunologically related to CPS purified fromE. coli. Nitrogen-fixingNostoc 73102 cultures grown without or with the addition of either citrulline or ornithine showed no differences in their CPS-polypeptide levels, indicating no regulatory effect on the CPS-protein level by these two amino acids. Immunolocalization demonstrated that the CPS protein was located both in vegetative cells and heterocysts, subcellularly evenly distributed over the two cell-types. Using the particle analysis of an image processor and cells grown both without or with addition of either citrulline or ornithine, about 2.5 times more CPS-gold labelling per cell area were observed in the photosynthetic vegetative cells compared to the nitrogen-fixing heterocysts.Abbreviations CPS carbamyl phosphate synthetase - IgG immunoglobulin G - OCT omithine carbamyl transferase     

Endocrine Cells in the Oesophagus of the Ascidian Styela clava,a cytochemical and immunofluorescence study

Summary Immunocytochemical studies have demonstrated the occurrence of an insulin-immunoreactive cell type in the oesophageal epithelium of the Ascidian Styela clava. Staining with aldehyde fuchsin has demonstrated a number of similar small, triangular, cells located on the basement membrane, which may have an endocrine function. Argyrophilic cells have also been found, suggesting the presence of a second endocrine cell type. The absence of argentaffin cells has led us to believe that the cells so far observed do not produce biogenic amines such as 5-HT (5-Hydroxytryptamine). The nature of these cells is discussed with reference to endocrine-like cells found in the digestive tracts of other protochordates.Animals were collected by courtesy of the Admiralty Marine Trials Station, Portsmouth. This research was carried out during the tenure of an S.R.C. grant no. B/RG 82919 to one of us (M.C.T.). —The localisation of polypeptide hormones in the pharynx and gut of protochordates     

Protoplast responses in the epidermis of Allium cepa induced by penetration by Botrytis allii

Penetration of Allium cepa epidermal cells (white, yellow, and red varieties) by Botrytis allii induced a response by host protoplasts in normal tissue which was not observed when penetrations were made in protoplast-free host cell walls. Callose and auto-fluorescing substances (possibly phenolic compounds) were located at the penetration sites only in normal host cells containing protoplasts. Lignin tests were negative. Halos were clearly visible in both types of tissue. Autofluorescence was observed at penetration sites in normal cells of all cultivars but general wall background autofluorescence was not observed in white onions. Autofluorescence was generally yellow green and when treated with ammonium hydroxide became green. Treatment with sodium hydroxide abolished autofluorescence. No attempt was made to isolate the autofluorescing material.     

5-Hydroxytryptamine immunoreactivity in the epidermal sacciform gland cells of the clingfish Lepadogaster candollei Risso

Summary Serotonin has been demonstrated in the epidermal sacciform glandular cells of the clingfish Lepadogaster candollei by use of immunocytochemistry.Serotonin immunoreactivity is found both in the peripheral cytoplasm of the glandular cells and their luminal secretion. The presence of serotonin in the sacciform glandular cells parallels that located by both biochemical and immunocytochemical procedures in the cutaneous glands of many amphibian species.     

ATPase activity of the polar organelle demonstrated by cytochemical reaction in whole unstained cells of Rhodopseudomonas palustris

The polar organelle, a structure associated with the flaggelar apparatus of bacteria, has been demonstrated in whole unstained cells of the photosynthetic bacterium Rhodopseudomonas palustris. It is subpolarly located close to the surface of the bacterial cell and has a round or ellipsoidal shap. It shows a strong ATPase activity which enables its cytochemical electron microscopical visualization.     

Chromogranin in bronchopulmonary neuroendocrine cells. Immunocytochemical detection in human, monkey, and pig respiratory mucosa

Immunoreactive chromogranin A was demonstrated by immunocytochemistry in the cytoplasm of neuroendocrine cells (NEC) and neuroepithelial bodies (NEB) in human, monkey, and pig respiratory mucosa. Three different antisera (one monoclonal and one polyclonal to human chromogranin A, and one polyclonal to bovine chromogranin A) were applied in this study. Chromogranin immunopositivity varied in extent and intensity according to the antiserum applied and the tissue investigated. The monoclonal antibody revealed the strongest immunoreaction. Good correlation between chromogranin immunoreactivity and Grimelius silver staining was observed by comparing adjacent sections, although more cells seemed to reveal chromogranin immunoreactivity than argyrophylia. Chromogranin appears to be a useful histological marker for APUD cells in the respiratory mucosa of several species.     

Gene expression and intracellular localization of somatolactin in the pituitary of rainbow trout

The gene expression and intracellular localization of somatolactin (SL), a putative pituitary hormone structurally related to both growth hormone and prolactin, were investigated in the pituitary of rainbow trout, Oncorhynchus mykiss. Using an in situ hybridization technique, we demonstrated the gene expression of the SL molecule in cells bordering the neurohypophysial tissue in the pars intermedia. These cells were identified immunocytochemically as SL-cells on the adjacent section. Electron-microscopic immunocytochemistry by means of the protein A-gold technique, also revealed that the SL-immunoreactivity was located mostly on the secretory granules in SL-cells. Our findings clearly indicate that SL is biosynthesized and stored in the granules in these cells.     

Secretin-cells of the mammalian intestine contain serotonin

Summary Various endocrine cells contain biogenic amines in addition to their peptide hormones. In the digestive tract, one of these amines is serotonin that is regularly present in enterochromaffin (EC-) cells. Previously, it has been assumed that other entero-endocrine cell types also contain this amine. Moreover, it was presumed that chromogranin A, an acidic glycoprotein, is involved in storage mechanisms for biogenic amines in endocrine cells. Using immunohistochemical techniques, we now exemplarily investigated cholecystokinin (CCK-) and secretin (S-) cells of five adult mammalian species for their content of serotonin and of chromogranin A. In all mammalian species, CCK-cells were devoid of serotonin but contained chromogranin A immunoreactivity of varying densities. In contrast, S-cells of all mammals were immunoreactive for serotonin; however, immunoreactivities for this biogenic monoamine were heterogeneous and varied from dense to faint or lacking immunostainings. Likewise, immunoreactivities for chromogranin A in S-cells showed inter-species and inter-cellular heterogeneities. S-cells containing serotonin were simultaneously immunoreactive for chromogranin A and the density of immunoreactivities for both were correlated in given S-cells. Based on mutual relationships of chromogranin A and serotonin immunoreactivities, we assume that chromogranin A is virtually a prerequisite for the S-cells' content of serotonin and that this protein participates in storage mechanisms for biogenic amines in endocrine cells.S-cells have now to be added to the family of amine-storing endocrine cells. Basically, serotonin-storing endocrine cells in the digestive tract cannot be simply regarded as enterochromaffin (EC-) cells any longer; the current nomenclature and classification of entero-endocrine cells should be reviewed in this respect.This work was supported by grants of the Deutsche Forschungs-gemeinschaft (EN 65/15-2)     

Chromogranin A biosynthetic cell populations in bovine endocrine and neuronal tissues: detection by in situ hybridization histochemistry

Chromogranin A is a highly acidic protein that is found in the secretory granules of many endocrine and neuronal cells. To localize bovine cell populations involved in chromogranin A biosynthesis, the distribution of the mRNA encoding this protein was determined with in situ hybridization histochemistry. In the adrenal gland, the mRNA was found in the chromaffin cells of the medulla but was absent from the cortex. The distribution of the mRNA in the medulla was uneven; cells located at the periphery were more heavily labeled than those in the center of the gland. Because the adrenal medulla is composed of several cell types, the chromogranin A-containing cells were further characterized for the presence of neuropeptide and adrenergic markers. Adjacent sections were examined for the mRNAs encoding enkephalin and phenylethanolamine N-methyltransferase (PNMT), the enzyme that catalyzes the formation of epinephrine from norepinephrine. Both mRNAs were present in a narrow band of cells at the periphery of the medulla. However, in contrast to the distribution of chromogranin A mRNA, the enkephalin and PNMT mRNAs were detected in only a small number of cells in the inner medullary region. The difference in the distribution of the enkephalin and PNMT mRNAs from that of chromogranin A suggests that the expression of these genes is differentially regulated. In addition to the adrenal gland, chromogranin A mRNA is expressed by many other tissues. In the parathyroid gland, which is rich in the mRNA but exhibits little chromogranin A-like immunoreactivity, the message was present in most cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Secretin-cells of the mammalian intestine contain serotonin

Various endocrine cells contain biogenic amines in addition to their peptide hormones. In the digestive tract, one of these amines is serotonin that is regularly present in enterochromaffin (EC-) cells. Previously, it has been assumed that other entero-endocrine cell types also contain this amine. Moreover, it was presumed that chromogranin A, an acidic glycoprotein, is involved in storage mechanisms for biogenic amines in endocrine cells. Using immunohistochemical techniques, we now exemplarily investigated cholecystokinin (CCK-) and secretin (S-) cells of five adult mammalian species for their content of serotonin and of chromogranin A. In all mammalian species, CCK-cells were devoid of serotonin but contained chromogranin A immunoreactivity of varying densities. In contrast, S-cells of all mammals were immunoreactive for serotonin; however, immunoreactivities for this biogenic monoamine were heterogeneous and varied from dense to faint or lacking immunostainings. Likewise, immunoreactivities for chromogranin A in S-cells showed inter-species and inter-cellular heterogeneities. S-cells containing serotonin were simultaneously immunoreactive for chromogranin A and the density of immunoreactivities for both were correlated in given S-cells. Based on mutual relationships of chromogranin A and serotonin immunoreactivities, we assume that chromograinin A is virtually a prerequisite for the S-cells' content of serotonin and that this protein participates in storage mechanisms for biogenic amines in endocrine cells. S-cells have now to be added to the family of amine-storing endocrine cells. Basically, serotonin-storing endocrine cells in the digestive tract cannot be simply regarded as enterochromaffin (EC-) cells any longer; the current nomenclature and classification of entero-endocrine cells should be reviewed in this respect.