Fetal Rat Pancreas in Organ Culture: Effects of Serum on the Development of the Endocrine Cells

Eighteen-day-old rat fetal pancreas was grown in organ culture for four days on medium consisting of tissue culture Medium 199 and varying concentrations of chicken serum. The glucagon and somatostatin concentration of the explants was decreased when the serum concentration of the medium was reduced from 50 to 10%. There was a further reduction in these hormones when the explants were cultured on Medium 199 alone. Explant insulin content was reduced only when serum was omitted from the medium. A "serum factor" tripeptide was not able to substitute for this serum requirement. Heat-inactivation of the serum resulted in a significant increase in medium insulin content and an increase in both the insulin and glucagon contents of the explants. This increase in hormone content was directly correlated with increases in the beta and alpha cell volumes of the explants. There was no change in the somatostatin content or delta cell volume of the explants grown on heat-inactivated medium. It is suggested that the serum is an important component of the culture media and is apparently required in high concentration for the development of the islet cells in vitro. The islet cell types differ in their requirement for serum. The alpha and delta require a higher concentration than do the beta cells.     

Fetal rat pancreas in organ culture: effects of serum on the development of the endocrine cells

Eighteen-day-old rat fetal pancreas was grown in organ culture for four days on medium consisting of tissue culture Medium 199 and varying concentrations of chicken serum. The glucagon and somatostatin concentration of the explants was decreased when the serum concentration of the medium was reduced from 50 to 10%. There was a further reduction in these hormones when the explants were cultured on Medium 199 alone. Explant insulin content was reduced only when serum was omitted from the medium. A "serum factor" tripeptide was not able to substitute for this serum requirement. Heat-inactivation of the serum resulted in a significant increase in medium insulin content and an increase in both the insulin and glucagon contents of the explants. This increase in hormone content was directly correlated with increases in the beta and alpha cell volumes of the explants. There was no change in the somatostatin content or delta cell volume of the explants grown on heat-inactivated medium. It is suggested that the serum is an important component of the culture media and is apparently required in high concentration for the development of the islet cells in vitro. The islet cell types differ in their requirement for serum. The alpha and delta a higher concentration than do the beta cells.     

Effects of dissociation and culture on the maintenance of insulin, glucagon and somatostatin release by neonatal rat islets of Langerhans

The ability of the principal islet cell types to maintain their differentiated function in vitro was assessed in a tissue culture system using neonatal rat pancreata. The effects of tissue dissociation and culture on the yield of islet tissue was measured at various times during the preparation and maintenance of cultures for 8 days. As estimated by the radioimmunoassay of insulin, glucagon and somatostatin in tissue extracts, the amount of islet tissue available for culture was reduced 50-70% following dissociation; an additional loss occurred after the first day in vitro. Only the insulin content of the tissue increased during culture. The hormone content of the media indicated that B-, A- and D-cell function was maintained throughout the culture period. The concentrations of insulin and glucagon in the medium approximately doubled and somatostatin increased 3-fold. This system has been shown to be a useful tool for the simultaneous study of the three major islet cell types and their secretory products.     

Cellular distribution of insulin, glucagon, pancreatic polypeptide hormone and somatostatin in the fetal and adult pancreas of the guinea pig: a comparative immunohistochemical study

Antibodies to insulin, glucagon, pancreatic polypeptide hormone and somatostatin were utilized to demonstrate the cellular localization of the hormones in pancreatic tissue of fetal guinea pig of advanced gestation by immunofluorescence histochemistry. The topographical distribution of the 4 endocrine cell types was compared with those of the adult pancreas and was found to be significantly different particularly for cells immunostaining for insulin, glucagon and somatostatin. These observations suggest changes in histogenesis of pancreatic endocrine cells during transition from fetal to postnatal and adult life. The presence of the 4 islet hormones in the fetal pancreas of this species implies that they may be important in fetal metabolism and growth.     

Ontogeny of cells containing insulin, glucagon, pancreatic polypeptide hormone and somatostatin in the bovine pancreas

Antibodies to insulin, glucagon, pancreatic polypeptide hormone (PP) and somatostatin were used in the immunofluorescence histochemical procedure to study the ontogeny of pancreatic endocrine cells containing the four hormones in the bovine fetus of approximately 100 days gestation to term. Pancreatic sections from the bovine neonate and adult were also examined for the cellular distribution of the four hormones. Immunoreactive cells staining for insulin, glucagon, PP and somatostatin were present in the pancreas of all fetuses studied. Each endocrine cell type displayed a characteristic distribution within the developing pancreas and in the neonate and adult. The presence of the four islet hormones relatively early in bovine fetal life suggests that they may be important in intra- and extra-islet metabolism in the fetus.     

Turnover of Acinar and Islet Cells in the Pancreas of Monosodium Glutamate‐Treated Obese Mice

Objective: Subcutaneous administrations of monosodium glutamate (MSG) to neonatal animals result in obesity and induce the toxicity on the central nervous system, and furthermore, have an effect on entero‐pancreatic hormone. The effect of MSG on the cell turnover of organs, especially the pancreas, has received little attention until now. This study was designed to examine the effect of MSG on pancreatic cell turnover by immunohistochemistry and [³H]thymidine autoradiography. Research Methods and Procedures: Male JcI‐ICR strain mice were SC injected with MSG (2 mg/g body weight daily) for 5 days after birth, received 112 repeated injections of [³H]thymidine at 6‐hour intervals for 28 days after birth, and then were killed immediately thereafter, or 30, 60, or 120 days after the last injection. Autoradiography was performed on sections immunostained for glucagon, insulin, and somatostatin. Results: After continuous labeling, most pancreatic cells were labeled, and thereafter, labeling of cells decreased in control and MSG‐treated mice. The mean grain counts of acinar cells in MSG‐treated mice decreased more slowly than those in control mice. On the other hand, those of islet cells, including glucagon, insulin, and somatostatin cells, decreased more rapidly in MSG‐treated mice than those in control mice. Discussion: Cell turnover of acinar cells was decelerated and that of islet cells including glucagon, insulin, and somatostatin cells was accelerated in MSG‐treated mice pancreas. MSG‐induced hypothalamic lesions exert the contrary influences on the cell turnover of acinar and islet cells.     

Ultrastructural studies of the ontogeny of fetal human and porcine endocrine pancreas, with special reference to colocalization of the four major islet hormones.

Most, if not all, endocrine cells seem capable of synthesizing and storing more than one hormone. Such cellular colocalization of hormones can be due either to the presence of two or more specific granules within the cells or to colocalization of the hormones within a single granule. The present study was performed to clarify the subcellular localization of insulin, glucagon, somatostatin, and pancreatic polypeptide within the endocrine cells of the human and porcine pancreas during fetal development, with special reference to possible colocalization of the hormones. The tissue specimens were processed for ultrastructural cytochemistry using Lowicryl as embedding medium. An immunogold labeling technique was used with two parallel, but not interacting, antibody chains. Sections from each specimen were double labeled in different combinations giving a complete covering of the four major islet hormones. During fetal life (50-90 days prenatally in porcine pancreas, 14 weeks gestation in the human pancreas) several hormones were demonstrated, not only in the same endocrine cells, but also in the same secretory granules (polyhormonal granules). Costorage of insulin, glucagon, somatostatin, and pancreatic polypeptide was demonstrated in granules in pancreatic endocrine fetal cells. At an early fetal stage, the endocrine cells contained either dense, round granules or pale, heteromorphous granules. With increasing age and maturation of the endocrine cells, structural differentiation of the secretory granules was found to be associated with a gradual disappearance of the polyhormonal granules. The first genuine monohormonal cell to appear in the porcine fetus was the pancreatic polypeptide cell (at 70 days gestation); it was followed by the somatostatin-producing endocrine cell. Mature insulin- and glucagon-producing cells were only demonstrated after birth. Thus, in the adult pancreatic endocrine cells, each specific endocrine cell type produced only one of the four classical hormones. The present investigation demonstrated that the endocrine cells of the fetal, but not the adult, pancreas are able to synthesize all the major islet hormones, and that these peptides are costored in the same granule. The data obtained support the concept of a common precursor stem cell for pancreatic hormone-producing cells.     

Lack of glucose-induced functional maturation during long-term culture of human fetal islet cells

To investigate the long-term effects of glucose on the function of human fetal islets we cultured islet-like cell clusters (ICC) obtained from 12 human fetuses with a mean age of 16.1 weeks in media containing 2.8, 11.1 or 16.7 mM glucose. On the 8th day of culture, the ICC that had been maintained in 16.7 mM glucose contained 60% less insulin than the ICC cultured in 2.8 mM glucose. However, insulin release was similar in both groups, and was not affected by a 24-h incubation in high vs. low glucose. Also (pro) insulin biosynthesis was not significantly affected. During a 24-day culture period, the total release of insulin and glucagon was similar in all glucose concentrations. The ICC released about 75% of their insulin content but only 15% of their glucagon content during the last 48 h of the 24-day culture period, again regardless of glucose concentration in media. Insulin release was insensitive to acute glucose and leucine challenges in perifusion experiments after culture for 1, 5, 8 or 16 days in 11.1 mM glucose, whereas glucagon was always a potent stimulus. In conclusion, the function of cultured young human fetal islet cells is remarkably independent of glucose, even during prolonged exposure. Moreover, the primary role of glucagon in fetal life may be that of a paracrine stimulator of beta-cell function.     

Involvement of cellular calcium in exocrine pancreatic insufficiency during streptozotocin-induced diabetes mellitus

This study investigates the effects of the islet hormones insulin (Ins), glucagon (Glu), and somatostatin (Som) with nerve stimulation (EFS) acetylcholine (ACh) and cholecytokinin-octapeptide (CCK-8) on amylase secretion and intracellular free calcium concentration [Ca(2+)](i) in the pancreas of age-matched control and diabetic rats. Either Ins, Glu or Som elicited small increases in amylase secretion from the pancreas of age-matched control animals compared to a much larger increase in amylase secretion with either EFS, ACh or CCK-8. Combining the islet hormones with either EFS, ACh or CCK-8 resulted in marked potentiation of amylase output. In the diabetic pancreas, the islet hormones had no effect on amylase secretion compared to diabetic control. Moreover, either EFS, ACh or CCK-8 evoked a much smaller increase in amylase output compared to age-matched control. In addition, the islet hormones failed to potentiate the secretory effects of either EFS, ACh or CCK-8. In fura-2 loaded acinar cells from age-matched control pancreas either Ins or Glu elicited a small increase in [Ca(2+)](i) whereas Som had no effect. Both ACh and CCK-8 evoked large increases in [Ca(2+)](i) compared to control. Combining either Ins, Glu or Som with either ACh or CCK-8 resulted in a marked elevation in [Ca(2+)](i) compared to the responses obtained with either the islet hormones, ACh or CCK-8 alone. In diabetic fura-2 loaded pancreatic acinar cells, the islet hormones had no effect on [Ca(2+)](i) compared to control and moreover, the responses were much smaller than those obtained in acinar cells from age-matched control. Both ACh and CCK-8 induced large increases in [Ca(2+)]( i) in diabetic acinar cells. However, combining the islet hormones with either ACh or CCK-8 failed to enhance [Ca(2+)](i) compared to the reponses obtained in acinar cells from age-matched control. The results suggests that [Ca(2+)](i) homeostasis is deranged during diabetes mellitus and this in turn is probably associated with reduced pancreatic amylase secretion.     

A, B, D cells and a fourth cell type in long-term cultures of fetal rat pancreas.

Whole pancreases from fetal rats of 13 days and 18 days gestation were explanted onto rayon grids and grown in organ culture. Cultures were fixed in Bouin's fluid, sectioned and stained with the fluorescent antibody techniques for glucagon and insulin, aldehyde fuchsin for B cells, pseudoisocyanin for D cells and a silver technique for the fourth cell type. The 13-day explants were fixed after 10 days in culture. A, B and D and the fourth cell type were seen, indicating that precursors of all four endocrine cell types must be present in the fetal pancreas shortly after the formation of the pancreatic bud (11 days). Further, the presence of these four cell types in the walls of tubules in these cultures indicates the tubules as the site of origin of all the endocrine tissue. The 18-day explants were collected every other day of culture from 2 to 30 days in a long-term experiment. A number of large islets with well granulated B cells was still present after 30 days of culture. The relative abundance of cell types at different stages was estimated as follows: 18-day fetal controls, A greater than B=4 greater than D; after 2 to 10 days in culture, B greater than A greater than or equal to D; after 18 to 30 days in culture, B greater than D greater than A greater than 4.     

A,B, D cells and A fourth cell type in longterm cultures of fetal rat pancreas

Summary Whole pancreases from fetal rats of 13 days and 18 days gestation were explanted onto rayon grids and grown in organ culture. Cultures were fixed in Bouin’s fluid, sectioned and stained with the fluorescent antibody techniques for glucagon and insulin, aldehyde fuchsin for B cells, pseudoisocyanin for D cells and a silver technique for the fourth cell type. The 13-day explants were fixed after 10 days in culture. A, B and D and the fourth cell type were seen, indicating that precursors of all four endocrine cell types must be present in the fetal pancreas shortly after the formation of the pancreatic bud (11 days). Further, the presence of these four cell types in the walls of tubules in these cultures indicates the tubules as the site of origin of all the endocrine tissue. The 18-day explants were collected every other day of culture from 2 to 30 days in a long-term experiment. A number of large islets with well granulated B cells was still present after 30 days of culture. The relative abundance of cell types at different stages was estimated as follows: 18-day fetal controls, A>B=4>D; after 2 to 10 days in culture, B>A⩾4>D; after 18 to 30 days in culture, B>D>A>4.     

Polyhormonal aspect of the endocrine cells of the human fetal pancreas

Histological studies were performed on 30 pancreases obtained from normal human fetuses aged between the 9th and 38th week. For immunocytochemistry, the avidin-biotin-peroxidase method was used to identify and colocalise insulin, glucagon, somatostatin, pancreatic polypeptide and proliferating cell nuclear antigen. In the 9th week, cells containing all investigated peptides were present. During the fetal period, two populations of endocrine cells have been distinguished, Langerhans islets and freely dispersed cells. The free cells were polyhormonal, containing insulin, glucagon, somatostatin and pancreatic polypeptide, and were localised in the walls of pancreatic ducts throughout the whole gland. During the development of the islets we have observed four stages: (1) the scattered polyhormonal cell stage (9th–10th week), (2) the immature polyhormonal islet stage (11th–15th week), (3) the insulin monohormonal core islet stage (16th–29th week), in which zonular and mantle islets are observed, and (4) the polymorphic islet stage (from the 30th week onwards), which is characterised by the presence of monohormonal cells expressing glucagon or somatostatin. Bigeminal and polar islets also appeared during this last stage. The islets consisted of an insulin core surrounded by a thick (in the part developing from the dorsal primordium) or thin rim (part of the pancreas concerned with the ventral primordium) of intermingled mono- or dihormonal glucagon-positive or somatostatin-positive cells. The most externally located polyhormonal cells exhibited a reaction for glucagon, somatostatin and pancreatic polypeptide. Apart from the above-mentioned types of islets, all arrangements observed in earlier stages were present. Proliferating cell nuclear antigen-positive cells (single in the large islets and more numerous in the smaller ones) were predominantly observed in the outermost layer. Taken together our data indicate that, during the human prenatal development of the islet, endocrine cells are able to synthesise several different hormones. Maturation of these cells involved or depended on a change from a polyhormonal to a monohormonal state and is concerned with decreasing proliferative capacity. This supports the concept of a common precursor stem cell for the hormone-producing cells of the fetal human pancreas. Accepted: 1 June 1999     

The duct-ligated pancreas transplant and its effect on the islet cellular composition of the host pancreas

Summary Rats rendered diabetic by streptozotocin were subjected to pancreas transplantation. After twenty weeks, the duct-ligated pancreas transplant was studied morphometrically to determine the effect of duct occlusion on the various cell populations of the islets. Concomitantly, the streptozotocin-treated host pancreas was examined for a possible influence of the graft on the diabetic pattern of islet cell population. Twenty weeks after pancreas transplantation, the volume fractions of insulin, glucagon, somatostatin and pancreatic polypeptide cells in the graft islets did not differ from those of the normal control pancreas. In the pancreas of nontransplanted diabetic rats, insulin-positive B cells were reduced from 60–65% to less than 10% of the islet volume, whereas non-B cells were significantly increased in volume density. The changes in fractional volume of the various islet cells correlated fairly well with changes in plasma concentration of the corresponding pancreas hormones. In the recipient's own pancreas, the relative volumes of glucagon and somatostatin cells were unaffected by the pancreas transplant. However, the insulin cell mass was significantly increased, and comprised about 20% of the islet volume, while cells containing pancreatic polypeptide were found only sporadically.Supported by Nordic Insulin Fund, The Swedish Diabetes Association, and MFR, proj. no. 4499. The technical assistance by M. Maxe and M. Carlesson is gratefully acknowledged     

Organ Culture of Foetal Rat Pancreas

The differentiation and growth of the foetal rat pancreas (20 days postcoitum) was studied in parabiotic organ culture with foetal adrenal tissue. In such co-cultures, characteristic pancreatic morphology was preserved and further acinar cell differentiation was fostered. Acinar cells continued to represent about 65% of the total explant volume following short-term incubation. The selective islet cell proliferation, previously observed in control pancreatic explants cultured alone, did not occur when adrenals were co-cultured. In addition, the amylase content of the incubation media and of the explanted pancreatic tissue remained high with adrenal co-culture, while the insulin content of the media and of the explanted tissue was markedly suppressed when compared to control pancreatic explants cultured alone. The effects of the adrenal in maintaining the differentiated acinar component of the pancreas and suppressing media insulin concentration diminished over extended incubation. The addition of adrenals to culture of foetal pancreatic explants after 6 days of control culture (at a time when differentiated acinar cells were not identifiable in the explant) did not result in redifferentiation of the acinar component, but did markedly depress media insulin content. Removal of adrenals after 4 days of co-culture resulted in an immediate rise in media insulin concentration and a rapid decline in pancreatic acinar mass. An adrenal-exocrine pancreatic axis is proposed and it is suggested that foetal adrenal secretions may play an important role in the development of the exocrine pancreas in vivo as well as in vitro.     

Mechanisms involved in the depleting effect of cysteamine on pancreatic somatostatin

We investigated the effects of cysteamine on the pancreatic islet hormones and found that pancreatic somatostatin contents depleted 60 min after the oral administration of cysteamine (300 mg/kg) to rats, yet the insulin and glucagon contents remained unchanged. When pancreatic islets isolated by collagenase digestion were incubated for 60 min in Krebs-Ringer bicarbonate buffer containing 0.1, 1, or 10 mM cysteamine, cysteamine dose-dependently decreased the somatostatin content, however, only a high concentration (10 mM) decreased the insulin level, and cysteamine exerted no effect on the glucagon content. The islet hormones (synthetic somatostatin-14, synthetic somatostatin-28, extracted pork insulin and extracted pork glucagon) were incubated for 60 min with cysteamine (0.1, 1, or 10 mM) and somatostatin-14 was found to be markedly decreased by 1 mM cysteamine. Pork insulin but not pork glucagon was dose-dependently decreased by 0.1-10 mM cysteamine. Cysteamine, 0.1-1 mM, did not interfere with the radio-immunoassay system for somatostatin or insulin, although 10 mM cysteamine did so. This compound exerted no effect on the radioimmunoassay system for glucagon. Our studies support earlier findings that cysteamine administered to experimental animals plays a role of relatively specific depletor of somatostatin. The possibility that the depletion of somatostatin is in part due to the remarkable sensitivity of the intracellular compartments of the D cells to the drug and in part due to the remarkable sensitivity of the molecular structure of somatostatin has to be considered.     

Insulin, glucagon and somatostatin in fetal rat islets maintained free-floating in culture: immunocytochemistry and radioimmunoassay.

Fetal rat islets maintained free-floating in tissue culture represent a source of B-cells. Because we recently noted the occurrence of other cell types during long-term tissue culture, this in vitro model was used to examine the possible development of non B-cells. The changes in the numbers and percentages of B, A and D-cells in vitro were estimated by counting the hormone-positive cells after immunocytochemical staining. Insulin, glucagon, and somatostatin contents were determined in extracts of the cultured tissue. The experiments described here showed that the cultured islets maintained their viability over a two-week culture period, as evidenced by the increase of both the number of B-cells per islet and the DNA content per islet. During the first few days of culture, immunocytochemically stained free-floating islets indicated the presence of rare A- and D-cells at the periphery of B-cells; thereafter, numerous A- and D-cells were seen interdigitating with B-cells. Expressed per islet, the number of A- and D-cells increased during the culture; within the endocrine cell population, the percentage of these cells increased with time, at the expense of the percentage of B-cells. The glucagon and somatostatin contents of the free-floating islets were also increased. These converging observations suggest that additional non B-cells may have been produced by free-floating islets during long-term tissue culture.     

The effect of hypophysectomy on pancreatic islet hormone and insulin-like growth factor I content and mRNA expression in rat

The growth arrest after hypophysectomy in rats is mainly due to growth hormone (GH) deficiency because replacement of GH or insulin-like growth factor (IGF) I, the mediator of GH action, leads to resumption of growth despite the lack of other pituitary hormones. Hypophysectomized (hypox) rats have, therefore, often been used to study metabolic consequences of GH deficiency and its effects on tissues concerned with growth. The present study was undertaken to assess the effects of hypophysectomy on the serum and pancreatic levels of the three major islet hormones insulin, glucagon, and somatostatin, as well as on IGF-I. Immunohistochemistry (IHC), in situ hybridization (ISH), radioimmunoassays (RIA), and Northern blot analysis were used to localize and quantify the hormones in the pancreas at the peptide and mRNA levels. IHC showed slightly decreased insulin levels in the cells of hypox compared with normal, age-matched rats whereas glucagon in cells and somatostatin in cells showed increase. IGF-I, which localized to cells, showed decrease. ISH detected a slightly higher expression of insulin mRNA and markedly stronger signals for glucagon and somatostatin mRNA in the islets of hypox rats. Serum glucose concentrations did not differ between the two groups although serum insulin and C-peptide were lower and serum glucagon was higher in the hypox animals. These changes were accompanied by a more than tenfold drop in serum IGF-I. The pancreatic insulin content per gram of tissue was not significantly different in hypox and normal rats. Pancreatic glucagon and somatostatin per gram of tissue were higher in the hypox animals. The pancreatic IGF-I content of hypox rats was significantly reduced. Northern blot analysis gave a 2.6-, 4.5-, and 2.2-fold increase in pancreatic insulin, glucagon, and somatostatin mRNA levels, respectively, in hypox rats, and a 2.3-fold decrease in IGF-I mRNA levels. Our results show that the fall of serum IGF-I after hypophysectomy is accompanied by a decrease in pancreatic IGF-I peptide and mRNA but by partly discordant changes in the serum concentrations of insulin and glucagon and the islet peptide and/or mRNA content of the three major islet hormones. It appears that GH deficiency resulting in a low IGF-I state affects translational efficiency of these hormones as well as their secretory responses. The maintenance of normoglycemia in the presence of reduced insulin and elevated glucagon serum levels, both of which would be expected to raise blood glucose, may result mainly from the enhanced insulin sensitivity, possibly due to GH deficiency and the subsequent decrease in IGF-I production.     

In vitro paracrine regulation of islet B-cell function by A and D cells

In monolayer cultures of islet cells from neonatal rats, incubation of cells for 1 hour with either anti-somatostatin serum or anti-glucagon serum enhanced insulin release. The former appears to be due to neutralization of endogenously secreted somatostatin. The latter may be due to removal of a stimulatory effect of endogenously released glucagon upon somatostatin secretion. Thus, although exogenously added glucagon stimulates insulin secretion, the effect of endogenously released glucagon upon islet B cells is a restraining one which may be mediated through an effect upon D cells and their release of endogenous somatostatin.     

Insulin, glucagon, and somatostatin secretion by cultured rat islet cell tumor and its clones

Cells derived from rat islet tumor and grown in culture (parent cells-RIN-m) and two clones obtained from them were used to study the effect of various secretagogues on insulin, glucagon, and somatostatin secretion. Parent cells secreted all three hormones in various quantities, while clone 5F secreted predominantly insulin and clone 14B secreted predominantly somatostatin. The secretory behavior of these cells were compared to each other and to that of normal islets. In general, as in the case of normal islets, insulin secretion was stimulated by calcium, potassium, tolbutamide, theophylline, and glucagon. It was inhibited by somatostatin. Glucagon secretion was stimulated by calcium, arginine, and theophylline. Somatostatin secretion was stimulated in clone 14B by arginine, tolbutamide, theophylline, and insulin. These cells differ from normal islets, in that they do not respond to glucose or arginine with increased insulin secretion. Also somatostatin failed to inhibit glucagon secretion. The similarity in insulin secretory responses of parent cells and clone 5F suggests that local or paracrine islet hormone secretion plays only a negligible role in the control of other hormone secretion in these cells.