Occurrence and neonatal development of gastrin immunoreactivity in the digestive tract of the rat

Summary The distribution of gastrin immunoreactivity in the rat gut was examined by immunochemical and immunohistochemical techniques. Gastrin occurs predominantly in the antrum proper, but gastrin is found also in the adjacent part of the oxyntic mucosa and in the duodenum. In the remainder of the gut the gastrin concentration is very low. No gastrin cells and very low gastrin concentrations are observed in the antrum at birth. The gastrin concentration as well as the number of gastrin cells increases progressively with age. The antral gastrin concentration reaches adult or near-adult values 30–40 days after birth.This study was supported by the Swedish Medical Research Council (04 X-1007), by Riksföreningen mot Cancer (660-0 IX), Landsforeningen till Kraeftens Bekampelse, Danish Medical Research Council (512-6) and Fonden for Storkobenhavn, Faeroerne og Gronland.     

Distribution,ontogeny and ultrastructure of somatostatin immunoreactive cells in the pancreas and gut

Summary Somatostatin cells are numerous in the pancreas and digestive tract of mammals as well as birds. In the pancreas of chicken, cat and dog they occur in both the exocrine parenchyma and in the islets. In the rat and rabbit, somatostatin cells have a peripheral location in the islets, whereas in the cat, dog and man the cells are usually more randomly distributed. In the stomach of rabbits and pigs, somatostatin cells are more numerous in the oxyntic gland area than in the pyloric gland area, whereas the reverse is true for the cat, dog and man. In the cat, pig and man, somatostatin cells are fairly numerous in the duodenum, whereas in the rat, rabbit and dog they are few in this location. In the remainder of the intestines somatostatin cells are few but regularly observed. Somatostatin cells are numerous in the human fetal pancreas and gut. In the fetal rat, somatostatin cells first appear in the pancreas and duodenum (at about the 16–17th day of gestation) and subsequently in the remainder of the intestine. Somatostatin cells do not appear in the gastric mucosa until after birth. Three weeks after birth, somatostatin cells show the adult frequency of occurrence and pattern of distribution. In the chicken, somatostatin cells are numerous in the proventriculus, absent from the gizzard, abundant in the gizzard-duodenal junction (antrum), infrequent in the duodenum and virtually absent from the remainder of the intestines. No immunoreactive cells can be observed in the thyroid of any species nor in the ultimobranchial gland of the chicken. In the chick embryo, somatostatin cells are first detected in the pancreas and proventriculus (at about the 12th day of incubation). They appear in the remainder of the gut much later, in the duodenum at the 16th day, in the antrum at about the 19th day and still later in the lower small intestine. The ultrastructure of the somatostatin cells was studied in the chicken, rat, cat and man; the cells were identified by the consecutive semithin/ultrathin section technique. The somatostatin cells display the properties of the D cell. There was no difference in granule ultrastructure between somatostatin cells in the gut and the pancreas. The granules, which are the storage site of the peptide, are round, supplied with a tightly fitting membrane and have a moderately electron-dense, fine-granulated core. The mean diameter of the somatostatin granules is smallest in rat (155–170 nm) and largest in the chicken (270–290 nm).     

Growth pattern of the polypeptide-YY cell population in the upper digestive tract of the rat during the perinatal period and after weaning

Summary The distribution of polypeptide-YY cells within the gastric and duodenal mucosa of the rat and the development of their populations were examined daily from 3 days before birth until day 8 postpartum and after weaning, on day 25 postpartum, using a precise technique of quantification. Polypeptide-YY cells appeared in the stomach around the 19th day of gestation. They were always more numerous in the antral mucosa and particularly in the pyloric sphincter area than in the fundic mucosa. Immunogold staining at the electron-microscopic level revealed that, in the antrum, polypeptide-YY was colocalised with gastrin in endocrine cells mainly of type G and, more rarely, in cells of intestinal type IG. Comparison of the gastrin and polypeptide-YY cell populations in the same rats indicated that, except at day 6 postpartum, there were fewer gastric polypeptide-YY cells than immunoreactive gastrin cells and that polypeptide-YY cells were 8 times less numerous than gastrin cells at day 25 postpartum. Polypeptide-YY cells were clearly present in the duodenum of the 19-day-old embryo. This population increases with age until day 8 postpartum, then significantly decreases (by 87%) between days 8 and 25 postpartum. Because polypeptide-YY may inhibit secretion of gastric acid, it is possible that the presence of significant population of polypeptide-YY cells in the upper digestive tract during the first postnatal week of life may play a role (endocrine or paracrine) in the decreased acid secretion occurring in the newborn rat.     

The ontogeny of regulatory peptide-containing cells in the human fetal stomach: an immunocytochemical study

The antral and fundic regions of the stomachs from 24 human fetuses were examined by immunocytochemistry for the presence of three regulatory peptides (gastrin, somatostatin, and glucagon) and one amine (serotonin (5-HT)) in the epithelial endocrine cells. Gastrin- and somatostatin-containing cells were present at the earliest stage examined (8 weeks). Gastrin cells were restricted to the antrum, while somatostatin cells were found in both the antrum and the fundus. Glucagon-immunoreactive cells were detected from 10 weeks and were confined to the fundus. Serotonin-containing cells were found in both the antrum and the fundus from 11 weeks. Changes in the number of immunoreactive gastrin and somatostatin cells during gestation were quantified. The increase in the number of cells/mm length of vertically sectioned mucosal epithelium best reflects the change in cell population. The peptides and amine studied were found to be contained in separate cell types. Electron microscopic examination of the peptide-containing cells showed that the fetal cells contain granules of similar morphology to their adult counterparts.     

Co-localization of synaptophysin with different neuroendocrine hormones in the human gastrointestinal tract

 Colocalisation of synaptophysin has been studied in different neuroendocrine cell types in histologically normal mucosa from human gastrointestinal tract (corpus, antrum, duodenum, ileum and colon) using double-immunofluorescence stainings. Numerous synaptophysin immunoreactive cells were seen in the antrum, while a smaller number were found in the intestinal tract. Synaptophysin immunoreactivity was strong in the antrum but weak in the intestine. In the intestinal colocalisation studies the synaptophysin immunoreactivity was enhanced by using the tyramide amplification method. Synaptophysin and chromogranin A were colocalised but the latter occurred mainly basally, whereas synaptophysin was found to occur diffusely throughout the cytoplasm. Synaptophysin immunoreactivity occurred in the serotonin cells throughout the gastrointestinal tract, and in the antral gastrin and somatostatin cells. In the intestinal tract only a small fraction of somatostatin, gastrin, cholecystokinin, enteroglucagon, enteroglucagon/ peptide tyrosine tyrosine displayed synaptophysin immunoreactivity. In the gastrointestinal tract (except the antrum), chromogranin A is a better general neuroendocrine marker than synaptophysin. The functional role of synaptophysin is unclear but it may be involved in the intracellular transport and release of hormones. Based on the distribution background of synaptophysin, it seems to be of greater importance in the antrum than in the intestinal tract as a whole. Accepted: 3 September 1998     

Self-replication of somatostatin cells in the antral mucosa of rodents

The possibility that antral somatostatin cells have a self-replicating activity has been studied in three species of rodents: mice, rats and guinea-pigs, after a flash tritiated thymidine injection. The immunocytochemical staining of somatostatin cells, using specific antiserum, was combined with radioautographic procedures. The labelling index for somatostatin cells--and for gastrin cells identified on serial sections--was established after counting a large number of cells at the optical microscope level, on parallel tissue strips removed throughout the entire antrum. A significant percentage of the somatostatin cell population synthesized DNA. Values were similar for the three species of rodents ranging from 0.8 to 1.1%, that is slightly higher than the percentage of labelled gastrin cells, which was 0.67-0.7%. After a 36-hr continuous infusion of radioactive precursor in one rat, the labelling index observed remained low; 2.33% for somatostatin cells and 1.68% for gastrin cells. Colchicine injection in mice allowed the observation of mitotic figures in well differentiated somatostatin cells. Four hours after that injection, the mitotic index was estimated roughly at 0.3%. Thus, evidence has been presented that in rodents a fraction of the antral somatostatin cell population is capable of dividing, similar to the situation in gastrin cells.     

Self-replication of somatostatin cells in the antral mucosa of rodents

Abstract. The possibility that antral somatostatin cells have a self-replicating activity has been studied in three species of rodents: mice, rats and guinea-pigs, after a flash tritiated thymidine injection. The immunocytochemical staining of somatostatin cells, using specific antiserum, was combined with radioautographic procedures. The labelling index for somatostatin cells–and for gastrin cells indentified on serial sections–was established after counting a large number of cells at the optical microscope level, on parallel tissue strips removed throughout the entire antrum.
A significant percentage of the somatostatin cell population synthesized DNA. Values were similar for the three species of rodents ranging from 0.8 to 1.1%, that is slightly higher than the percentage of labelled gastrin cells, which was 0.6–0.7%. After a 36-hr continuous infusion of radioactive precursor in one rat, the labelling index observed remained low; 2.33% for somatostatin cells and 1.68% for gastrin cells. Colchicine injection in mice allowed the observation of mitotic figures in well differentiated somatostatin cells. Four hours after that injection, the mitotic index was estimated roughly at 0.3%.
Thus, evidence has been presented that in rodents a fraction of the antral somatostatin cell population is capable of dividing, similar to the situation in gastrin cells.     

Ultrastructure of the gut neurotensin cell

Summary In mammals, neurotensin cells occur scattered in the epithelium of the jejunum-ileum. In chicken, neurotensin cells are abundant in the region of the gizzard-duodenal junction (antrum) where they occur intermingled with numerous somatostatin and gastrin cells. The neurotensin cells in chicken, dog and man were identified at the electron microscopic level by immunocytochemistry, using the consecutive semithin/ultrathin section technique. They contain numerous electron dense cytoplasmic granules, predominantly in the basal portion of the cell. It was shown that these granules are the storage site for neurotensin. The neurotensin granules are round, highly electron dense and of about the same size in the different species examined (mean diameter 260–290 nm). in dog and man the granules have a tightly applied surrounding membrane while in the chicken a relatively electron lucent zone separates the electron dense core from the granule membrane. The ultrastructure of the neurotensin granules in chicken is some-what reminiscent of that of the gastrin granules. The mean diameter of the gastrin granules in chicken antrum is 230 nm; for the somatostatin granules the mean diameter is 305 nm.     

Identification of gastrin-secreting cells and cholecystokinin-secreting cells in the gastrointestinal tract of the human fetus and adult man

Summary Gastrin-and cholecystokinin (C.C.K.)-containing cells were detected by using anti-gastrin and anti-C.C.K. sera in the gastrointestinal tract of human fetuses and premature infants and in the stomach and duodenum of adult man obtained by biopsy from eight patients with normal gastro-duodenal endoscopy. The specificity of immunocytological reactions was ascertained by studying the inhibition of the reaction by gastrin, C.C.K., secretin, somatostatin, glucagon, insulin, serotonin, histamin, caerulein and octapeptide of C.C.K. In adult man, the gastrin cells are located only in the antrum and juxtapyloric region; C.C.K. was detected in the duodenum. In the human fetus, the first gastrin cells are seen in the antrum at 14 weeks of age and in the duodenum as early as 10 weeks; the C.C.K. cells are seen in the small intestine at 10 weeks of age. Acknowledgements. The authors should like to thank Professors Magnin and Liaras, Hôpital Edouard Herriot, M. Dumont, Hôpital de la Croix-Rousse, Notter et Garmier, Hôtel-Dieu, Bethenod, Hôpital Debrousse, Lyon, for their cooperation. We also thank Professor R. Guillemin, the Salk Institute, La Jolla, California, Doctor M.P. Dubois, I.N.R.A., Station de Physiologie de la Reproduction, Nouzilly, Mme Vagne, U. 45, I.N.S.E.R.M. and Professor Y. Minaire, Hôpital Edouard Herriot, Lyon, for their donations. This work was supported by a grant from the Institut National de la Santé et de la Recherche Médicale     

Coexpression of the gastrin and somatostatin genes in differentiating and neoplastic human cells

Double immunofluorescence and in situ hybridizations performed on adjacent thin sections show that a population of normal antropyloric cells of the human stomach expresses both gastrin and somatostatin mRNA's and the corresponding peptides. Such cells were present in both adult and fetal antropyloric mucosa and were situated in the regenerative (isthmus) region of the antropyloric tubes. It is, hence, likely that these cells represent immature endocrine cells that yet have to be committed to either the gastrin or somatostatin lineage. Cells coexpressing gastrin and somatostatin were also detected in pancreatic endocrine tumours. The presence of gastrin-somatostatin cells during development and in tumours suggests that gastrin and somatostatin cells may differentiate from such multipotent precursor cells.Presented in part at the 76th Annual Meeting of the Endocrine Society, 15–18 June 1994, Anaheim, Calif., USA, Abstract no. 691