The antrat gastrin-producing G-cell: Biochemical and ultrastructural responses to feeding

Summary The effect of feeding on serum and antral immunoreactive gastrin (IRG) concentrations and on the ultrastructural appearance of antral G-cell granules has been examined. Serum and tissue IRG concentrations were dependent upon the length of time (12 or 48 h) the rats had been fasted before receiving food; IRG release was biphasic; the first peak was more pronounced in rats fasted 12h. Antral tissue IRG content increased significantly postprandially. An initial depletion of antral IRG was seen in rats fasted 48 h. Examination of the subcellular distribution of antral IRG revealed more of the 5–15 min postprandal total IRG in the cytoplasm and less in the secretory granules.Ultrastructurally, G-cells from fasting rats contained mainly electron-dense granules. Five minutes postprandially numerous electron-lucent granules were observed. More electron dense granules were apparent 60 and 120 min postprandially. Fasting rats had the highest G-cell granule density index; a significantly lower index was observed 5 min postprandially. Indices at 60 and 120 min postprandially increased but were still lower than the fasting index. These studies indicate that gastrin biosynthesis is necessary for food stimulated gastrin release and that the electron density of the G-cells' granules is not an accurate reflection of the G-cell gastrin content.The authors thank Elisabeth Bothe, Heidi Dörler and Heide Karl for technical assistance and the Deutsche Forschungsgemeinschaft (Bonn-Bad Godesberg, Grant Cr 20/7), the Atkinson Charitable Foundation and the Canadian MRC for financial support     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1-13 and gastrin 2-17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

Summary The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1–13 and gastrin 2–17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Quantitative electron microscopic studies on the kinetics of secretory granules in G-cells

Summary Ultrastructural studies of secretory granules of rat antral G-cells and measurement of serum gastrin level were performed under the condition of fasting and administration of alkaline solution into the stomach. On electron micrographs, no qualitative difference was observed among those experimental groups. However, morphometrical analysis revealed significant quantitative differences. The population density of secretory granules of the rats treated once with alkali first increased and then decreased reaching that of the fasted group, while that of the repeatedly treated group remained nearly equal to the maximum value. The average sectioned surface area of secretory granules tended to decrease for 1.5h after the stimulation but the difference was not significant among those groups.From the results obtained at present, responding to chemical stimulation such as pH changes in the antrum, it seems probable that not only exocytosis but also migration of secretory granules from supra- and/or para-nuclear portion to the basal portion of the cell occurs rapidly in G-cells and that both these processes are inhibited immediately by antral acidification. Moreover, the present results apparently indicate that under the condition of no antral acidification G-cells have a capacity of secreting gastrin for a fairly long time, such as 4–8 h, responding to adequate stimulus. These findings are strongly suggestive of the existence of a capacious pool of granules in the supra- and/or para-nuclear cytoplasm or of fairly speedy production of secretory granules in the Golgi area.The author wishes to express thanks to Prof. R. Furihata, Department of Surgery, and Prof. T. Nagata, Department of Anatomy, Shinshu University School of Medicine, for their constant interest and guidance, and to Dr. F. Iida, Department of Surgery, who has followed the course of this work throughout     

The G-cells in the dog: a light and electron microscope immunocytochemical study

Summary An immunohistochemical study has been performed to analyse the distribution of gastrin cells in the gastrointestinal tract of the dog. This study revealed that G-cells immunoreactive for gastrin were almost exclusively present in the pyloric antral mucosa, mainly in the middle third of the pyloric mucosa. The calculated number of G-cells per surface unit area was 8.5×10³–1.2×10⁴ cells cm^–2. Some gastrin-immunopositive cells were found in the first 10 mm of the proximal duodenum, mainly in the villous region. The fundic area of the dog stomach, the oesophagus, small intestine, caecum, colon, rectum, salivary glands, liver and pancreas were all immunonegative for gastrin. At the ultrastructural level, three different types of granules (150–400 nm) were evident in G-cells: electron-dense, electron-lucent and intermediate forms. Most of them were located in the subnuclear region of the cell. The effect of fixation of the antral mucosa at different pH levels was studied. In samples fixed with acid solutions, most of the G-cell granules were of the electron-dense type and were stronly immunopositive for gastrin. Fixation of samples at a basic pH resulted in most of the gastrin granules losing their contents into the cytoplasm, and the positive reaction to gastrin was then located in the cytoplasm and at the periphery of the electron-lucent granules.     

Total counts of antral gastrin cells: a simple direct method

A simple technique has been developed to quantitate the gastrin cells (G-cells) from the pyloric antrum of the rat. The antrum was digested in pronase to suspend the epithelial cells. This cell suspension was counted and pelleted. The pellet was embedded in paraffin, sectioned, then labeled using the indirect immunofluorescence technique specific for gastrin. The percentage of G-cells was determined from photographs of fluorescing sections and total G-cell numbers were determined by relating these data to total epithelial cell counts. In 14 rats the average G-cell population totaled 1.03 +/- 0.21 X 10(5) G-cells/antrum. The technique is simple, time-saving and avoids the uncertainties inherent in previous procedures for the estimation of G-cell numbers.     

Co-localization of xenopsin and gastrin immunoreactivity in gastric antral G-cells

Studies indicating evidence for the presence of the amphibian octapeptide xenopsin in gastric mucosa of mammals prompted us to investigate the cellular localization of this peptide. Using the peroxidase-antiperoxidase method and a specific antiserum to xenopsin (Xen-7) on paraffin and adjacent semithin sections of gastric antral mucosa from man, dog, and Tupaia belangeri, we found numerous epithelial cells showing a specific positive immunoreaction. These cells were of typical pyramidal shape and could be classified as of the "open" type. Cell quantification in serial sections processed for xenopsin and gastrin immunoreactivity, respectively, revealed an identical number of cells per section and an identical distribution of these cells in the middle zone of the antral mucosa. Furthermore, adjacent semithin sections demonstrated the colocalization of xenopsin and gastrin immunoreactivity within the same G-cell. The xenopsin antiserum could be completely absorbed with synthetic xenopsin but not with gastrin. Preabsorption tests with neurotensin, a xenopsin related peptide, or with somatostatin, glucagon, and enkephalins gave no evidence for crossreactivity of the xenopsin antiserum with these peptides. It is concluded that gastric antral G-cells in addition to gastrin also contain the amphibian peptide xenopsin.     

Total Counts of Antral Gastrin Cells: A Simple Direct Method

A simple technique has been developed to quantitate the gastrin cells (G-cells) from the pyloric antrum of the rat. The antrum was digested in pronase to suspend the epithelial cells. This cell suspension was counted and pelleted. The pellet was embedded in paraffin, sectioned, then labeled using the indirect immunofluorescence technique specific for gastrin. The percentage of G-cells was determined from photographs of fluorescing sections and total G-cell numbers were determined by relating these data to total epithelial cell counts. In 14 rats the average G-cell population totaled 1.03 ± 0.21 ± 10⁵ G-cells/antrum. The technique is simple, time-saving and avoids the uncertainties inherent in previous procedures for the estimation of G-cell numbers.     

Gastrin release in obese Zucker rats

In this study, gastrin release in the obese Zucker rat was investigated by in vivo and in vitro experiments. Obese rats exhibited normal plasma gastrin levels at 3 weeks (preobese), were moderately hypergastrinemic at 3 months and severely hypergastrinemic at 5 months, compared to lean littermates. Following oral peptone, plasma gastrin levels doubled in both lean and obese rats. Basal and vagally stimulated gastrin release from perfused stomachs was greater in obese compared to lean rats and atropine had no effect on basal gastrin release in either group. Basal somatostatin release from the perfused stomach was found not to differ in both groups of animals. Morphological studies revealed an increase in the number of gastrin-containing G-cells in adult obese rats compared to lean littermates, but not in 3-week-old pups compared to lean littermates, indicating a strong correlation between cell number and plasma gastrin levels. These data indicate that the obese Zucker rat exhibits fasting hypergastrinemia in vivo, a condition which appears after weaning and increases in severity with age. Gastrin hypersecretion persists from the vascularly perfused stomach preparation. The basal hypergastrinemia of the obese Zucker rat is independent of a hyperactive postganglionic cholinergic drive but is associated with and probably causally related to an increase in antral G-cell numbers.     

The effect of total parenteral nutrition (TPN) on gastrin release in the rat

The effect of short-term (7 days) total parenteral nutrition (TPN) on gastrin release was studied in vivo and in the isolated vascularly perfused rat stomach. The daily plasma gastrin concentration of parenterally fed rats was significantly lower than in ad lib fed control animals (53 +/- 17 pg/ml vs 159 +/- 32 pg/ml, P less than 0.05) as early as day 2 and a similar pattern was observed on days 4 and 6. The fasting plasma gastrin concentration of control animals was 2-fold greater than of the parenterally fed group (P less than 0.05). Following oral peptone, the gastrin response of TPN and control animals doubled although peak gastrin levels were greatly reduced in TPN rats. Basal gastrin release from the perfused stomachs of control rats was 2-fold greater than from TPN rats (P less than 0.05). Electrical stimulation of the vagal trunks resulted in a significantly greater elevation in gastrin secretion from control stomachs compared to TPN animals (4-fold vs. 2.4-fold increase, P less than 0.05). Quantification of the antral G-cell population revealed a significant reduction in the number of G-cell of TPN rats compared to controls (97 +/- 8 cells/mm vs 76 +/- 6 cells/mm, P less than 0.05). These results indicate that luminal nutrient stimulation is necessary for the maintenance of normal G-cell secretory activity in vivo and from the in vitro stomach. G-cell hypoplasia appears to be partially responsible for reduced gastrin output to basal and stimulated conditions after TPN.     

Co-localization of xenopsin and gastrin immunoreactivity in gastric antral G-cells

Summary Studies indicating evidence for the presence of the amphibian octapeptide xenopsin in gastric mucosa of mammals prompted us to investigate the cellular localization of this peptide. Using the peroxidase-antiperoxidase method and a specific antiserum to xenopsin (Xen-7) on paraffin and adjacent semithin sections of gastric antral mucosa from man, dog, and Tupaia belangeri, we found numerous epithelial cells showing a specific positive immunoreaction. These cells were of a typical pyramidal shape and could be classified as of the open type. Cell quantification in serial sections processed for xenopsin and gastrin immunoreactivity, respectively, revealed an identical number of cells per section and an identical distribution of these cells in the middle zone of the antral mucosa. Furthermore, adjacent semithin sections demonstrated the colocalization of xenopsin and gastrin immunoreactivity within the same G-cell. The xenopsin antiserum could be completely absorbed with synthetic xenopsin but not with gastrin. Preabsorption tests with neurotensin, a xenopsin related peptide, or with somatostatin, glucagon, and enkephalins gave no evidence for crossreactivity of the xenopsin antiserum with these peptides.It is concluded that gastric antral G-cells in addition to gastrin also contain the amphibian peptide xenopsin.     

Intracellular topography of glycine-extended pro-gastrin-processing intermediates in human antral mucosa: an electron-microscopic immunocytochemical study

To identify and characterize the subcellular topography of glycine-extended pro-gastrin-processing intermediates (G-Gly) in human antral mucosa, we performed an electron microscopic immunocytochemical study using region-specific antisera generated against the synthetic peptide, Tyr-Gly-Trp-Met-Asp-Phe-Gly (GL7), and C-terminal-specific anti-gastrin antisera. As has been previously reported, G-cells contained both electron-dense and electron-lucent granules, with a range of intermediate forms. Gastrin immunoreactivity was demonstrated in almost all granules of each type, whereas anti-GL7 antisera immunostained chiefly electron-dense granules. The relative ratio of GL7/gastrin granules varied among different cells but was approximately 1:10 on average. Other cytoplasmic organelles were devoid of specific labeling for GL7 or gastrin. As we have assumed that G-Gly serves as the immediate precursor for each molecular form of gastrin, electron-dense granules with high labeling for GL7 are regarded as the principal site for conversion of G-Gly to gastrin. This speculation supports many previous reports that electron-dense granules are immature and that the granules become less electron-dense with maturation.     

Gastrin and the ultrastructure of G cells after stimulation with acetylcholine

The effect of intragastric administration of acetylcholine on serum and antral gastrin concentrations of rats has been examined using a radioimmunoassay and quantitative electron microscopy. Exposure of the stomach of rats, previously fasted for 24h, to 2% acetylcholine for either 0.5 or 2h resulted in a significant 4--5 fold increase in serum gastrin concentrations to levels similar to those found in fed animals. Such treatment produced no detectable change in antral gastrin concentration or in the number or electron density of secretory granules in the G cells. This lack of detectable change in the G cells was not unexpected since our calculations suggest that less than 10% of the total gastrin stored in the antrum is released over 2h as a result of the stimulation with acetylcholine. The proportion of electron-lucent secretory granules was, however, markedly increased by prolonged fixation in aldehydes. The increase was similar in both ACh stimulated and control animals. These results indicate that the ultrastructural appearance of G cell secretory granules in influenced far more by the conditions of fixation than by the release of gastrin. They therefore cast considerable doubt on the hypothesis that gastrin is released by molecular dispersion from the granules.     

Studies of isolated and enriched rat antral mucosa gastrin cells

A technique has been developed to obtain viable, isolated and enriched populations of gastrin cells (G-cells) from the rat stomach. Restricted tissue samples from a small area of the pyloric antrum known to be particularly rich in G-cells, were sequentially digested with pronase followed by mechanical agitation, to remove the epithelial cells. This technique resulted in a significant enrichment of G-cells (3-4 fold) since the surface epithelial cells and upper portions of the glands were discarded before the initial G-cell fraction was collected. These cells in suspension were then isolated from each other by gentle pipetting in a DNase containing solution and designated the crude preparation (CP). The G-cells were then purified further by separating the cells according to size by velocity sedimentation. The greatest concentration of G-cells (15-25%) was found in the fraction containing cells with diameters of 10 to 12 micrometer. The effectiveness of the technique was evaluated by counting G-cells as identified by electron microscopy and immunofluorescence and assessing gastrin activity by radioimmunoassay. All three methods indicated that cell separation by gravity velocity sedimentation enriched the G-cell population 15-20 fold over their concentration in the CP. The combined techniques of selective pronase digestion followed by gravity velocity sedimentation resulted in an isolated cell preparation containing a 50-100 fold increase of G-cells over their normal distribution in the intact gastric mucosa. Since these isolated G-cells retain features indicating viability, their usefulness for in vitro studies is suggested.     

Effect of starvation on endocrine cells in the rat stomach

The influence of food deprivation on gastric G- and D-cells and on parietal cells was studied in the rat. In fed controls and groups of rats fasted for 12 and 96 h G-, D- and parietal cell densities, somatostatin and gastrin concentration in antral and fundic specimens and serum gastrin were compared. Gastrin in antral mucosa, serum gastrin, G-cell density as well as antral D-cell density decreased in long-term fasted rats by 52%, 90%, 58% and 42%, respectively. Fundic D-cell density remained unchanged. After 96 h starvation somatostatin concentration slightly increased in antral mucosa (+35%; P less than 0.05), but decreased in fundic mucosa (-40%; P less than 0.05). Parietal cell density was not influenced by prolonged fasting. These findings demonstrate that changes in D-cell morphology and mucosal somatostatin content are not parallel and that the rat gastric D-cell is less dependent on food in the gastric lumen than the G-cell. The unaltered fundic D-cell density reflects the functional activity of gastric D-cell which has also been shown to be independent of the presence or absence of food.     

Gastrin producing G-cells after chronic ethanol and low protein nutrition

Male Wistar rats, (2 months old), randomly divided according to the diet offered to four groups (C-control; A- alcoholized, PD-protein-deprived, A-PD- alcoholized protein-deprived). In group A and A-PD rats, the number of gastrin producing G-cells was significantly lower. The volume density of G-cells was significantly decreased in alcoholic rats. Fasting serum gastrin level (FSGL) significantly raised due to combined effect of alcohol consumption and protein malnutrition. In group A rats, the profile area of G-cells and their nuclei increased. In PD rats, the profile area of G cells also increased. There were no differences in nucleus/cell ratio due to alcohol ingestion alone, but it decreased significantly in PD and A-PD rats. Pale and lucent types of granules were predominantly seen in G-cells of animals of group A and A-PD. Mean diameter of granules increased in A, PD and A-PD rats. Other endocrine cells (ECL, D, EC) also decreased in number in A rats. Somatostatin producing D-cells decreased significantly in A-PD rats, both in fundic and pyloric mucosa.     

Expression and post-translational processing of gastrin in heterologous endocrine cells

The biosynthesis of gastrin involves a complex series of post-translational processing reactions that result in the formation of a biologically active secretory product. To study the mechanisms for two specific reactions in gastrin processing, namely dibasic cleavage and amidation, we infected AtT-20, GH3, and Rin5-f cells with the retroviral expression vector, pZip-NeoSV(X), containing human gastrin cDNA. We detected gastrin and its glycine extended post-translational processing intermediates (G-gly) in the media and cell extracts of successfully infected cells. Characterization of the molecular forms of gastrin in these cell lines revealed that GH3 and Rin5-f processed gastrin in a manner similar to antral G-cells but the cleavage of the Lys74-Lys75 bond that converts G34 to G17 appeared to be suppressed in AtT-20 cells. Even after conversion of this site to Arg74-Arg75 via site-directed mutagenesis, the At-20 cells synthesized G34 predominantly. All of the infected cells amidated gastrin but the gastrin/G-gly ratio, a reflection of amidation within the cells, was enhanced in GH3 and Rin5-f cells but diminished in AtT-20 cells upon treatment with dexamethasone (10(-4) M) for 3 days. The dibasic cleavage of gastrin was uneffected by dexamethasone. Our data suggest that the activities of post-translational processing reactions responsible for the synthesis of biologically active gastrin exhibit considerable tissue and substrate specificity.     

The life cycle of the gastrin granule

Summary The ultrastructure of gastrin cells in the rat antrum was analyzed with standardized and quantitative planimetric methods. Resting and active cells were compared. The gastrin cells were activated by removal of the acidproducing part of the stomach (fundectomy). As a result the serum gastrin concentrations were greatly elevated. Compared with gastrin cells in fasted control rats the gastrin cells in fundectomized rats were increased in number, contained fewer cytoplasmic granules, increased amount of endoplasmic reticulum, and an enlarged Golgi area.Generally, the secretory granules of the gastrin cell displayed a wide range of electron density from highly electron-dense to electron-lucent. They exhibited certain characteristic features: 1) Electron-dense granules made up a greater proportion of the total granule population in active gastrin cells than in resting cells. 2) Electron-dense granules were more frequent near the Golgi stacks than in the periphery of the cell. 3) Electron-dense granules were smaller in size than the electron-lucent granules; hence, small electron-dense granules probably represent young granules (progranules), while large, electron-lucent granules represent mature (old) granules. 4) Electron-dense granules invariably displayed a more intense immunoreactivity than electron-lucent granules.The gastrins are generated from a large precursor molecule. The posttranslational processing of this precursor is reflected in the gastrin-component pattern. The gastrin-component pattern in antral extracts of fundectomized and normal fasting rats differed in that the proportion of the gastrin-4-like component was reduced, whereas the gastrin-34-like component was increased in the fundectomized rats. The results suggest a greater proportion of small gastrin components in the mature granules than in the newly formed ones, presumably due to more extensive conversion of larger forms into smaller forms with a longer granule half-life. As a result gastrin-17-and gastrin-34-like components make up a larger proportion of total gastrin in active gastrin cells than in resting gastrin cells.The findings were presented at the Meeting of the European Gastro-Club, Erlangen, October 1980 (R. Håkanson, J.F. Rehfeld, M. Ekelund, and F. Sundler 1981)     

Gastrin secretion by ovine antral mucosa in vitro

The effect on gastrin and somatostatin release in sheep of stimulatory and inhibitory peptides and pharmacological agents was investigated using an in vitro preparation of ovine antral mucosa. Carbachol stimulated gastrin release in a dose-dependent manner but had no effect on somatostatin release. As atropine blocked the effect of carbachol, cholinergic agonists appear to stimulate gastrin secretion directly through muscarinic receptors on the G-cell and not by inhibition of somatostatin secretion. Both vasoactive-intestinal peptide (VIP) and gastric-inhibitory peptide (GIP) increased somatostatin release but did not inhibit basal gastrin secretion, although VIP was effective in reducing the gastrin response to Gastrin-releasing peptide (GRP). Porcine and human GRP were stimulatory to gastrin secretion in high doses but bombesin was without effect. The relative insensitivity to GRP (not of ovine origin) previously reported from intact sheep may be caused either by a high basal release of somatostatin or by the ovine GRP receptor or peptide differing from those of other mammalian species.     

Effects of porcine gastrin releasing peptide (GRP) on canine antral motility and gastrin release in vivo

The effect of GRP on the vivo canine antrum was investigated. GRP caused a dose-dependent increase in antral gastrin output which was not significantly altered by administration of tetrodotoxin. The higher doses of GRP administered also caused excitation of antral motility which was abolished by tetrodotoxin, a finding in contrast to previous in vitro results demonstrating bombesin-induced antral smooth muscle contraction to be tetrodotoxin-resistant. These data suggest that in the vivo canine model GRP causes antral gastrin release via non-reurally mediated mechanisms (probably by acting directly on the G-cell) and excites antral motility via neurally-mediated mechanisms.