Exogenous administration of octanoic acid accelerates octanoylated ghrelin production in the proventriculus of neonatal chicks

Ghrelin is modified by fatty acid at the third serine residue. In this study, derivation of fatty acid for acylation of ghrelin was investigated using a hatchling chicken model. We first studied ghrelin gene expression and production in the neonatal chick proventriculus and then investigated the effect of exogenous octanoic acid (OA) administration on acylated ghrelin production. In a free-feeding condition on day 2.5 after hatching, the density of ghrelin mRNA-expressing (ghrelin-ex) cells was greater than that of ghrelin-immunopositive (ghrelin-ip) cells, but no difference was found between those densities in adult chickens. Intraperitoneal or oral administration of OA for a few days significantly increased the density of ghrelin-ip cells without any changes in ghrelin-ex cells and elevated only octanoylated ghrelin levels in the proventriculus. The results indicate that fatty acid absorbed from food is directly utilized in acylated ghrelin production in the chicken.     

Distribution and morphology of ghrelin-immunopositive cells in the cerebellum of the African ostrich

Ghrelin, the endogenous ligand for the growth hormone secretagogue receptor, has been found in the cerebellum of many vertebrates and in the gastrointestinal tract of African ostrich chicks, but little is known about its distribution in the cerebellum of the African ostrich. In the present study, the distribution and morphological characteristics of ghrelin-producing cells in the cerebellum of the African ostrich were investigated using immunohistochemistry. The results indicate that the cerebellum is divided into two sections: the outer cerebellar cortex and the inner medulla of cerebellum. The cerebellar cortex comprises a molecular layer, a Purkinje cell layer and a granular layer; ghrelin-immunopositive (ghrelin-ip) cells were localized throughout the entire cerebellum, but sparsely in the medulla. The greatest number of ghrelin-ip cells was found in the stratum granulosum, and the density decreased gradually from the molecular layer to the Purkinje cell layer in the cerebellar cortex. The ghrelin-ip cells were fusiform or irregular polygons and their cytoplasm was stained intensely. These results clearly demonstrate the presence of ghrelin-ip cells in the cerebellum of the African ostrich. It is speculated that ghrelin may have a physiological function in the cerebellum.     

Contractile effects of ghrelin-related peptides on the chicken gastrointestinal tract in vitro

Ghrelin is an endogenous ligand for growth hormone secretagogue receptor (GHS-R), and it stimulates growth hormone (GH) release, food intake and gastrointestinal motility in mammals. Ghrelin has also been identified in the chicken, but this peptide inhibits food intake in the chicken. We examined the effects of ghrelin and related peptides on contractility of the isolated chicken gastrointestinal tract in vitro. Among ghrelin-related peptides examined (1 microM of rat ghrelin, human ghrelin, chicken ghrelin and growth hormone releasing peptide-6 (GHRP-6)), only chicken ghrelin was effective on contraction of the chicken gastrointestinal tract. Des-acyl chicken ghrelin was ineffective, suggesting that octanoylation at Ser3 residue of chicken ghrelin was essential for inducing the contraction. Amplitude of chicken ghrelin-induced contraction was region-specific: highest in the crop and colon, moderate in the esophagus and proventriculus, and weak in the small intestine. The contractile response to chicken ghrelin in the crop was not affected by tetrodotoxin (TTX), but that in the proventriculus was decreased by TTX and atropine to the same extents. D-Lys3-GHRP-6 (a GHS-R antagonist) caused a transient contraction and inhibited the effect of chicken ghrelin without affecting the high-K+-induced contraction. Chicken ghrelin potentiated electrical field stimulation-induced cholinergic contraction without affecting the responsiveness to bath-applied carbachol in the proventriculus. The location of GHS-R differs in the crop (smooth muscle) and proventriculus (smooth muscle and enteric neurons). These results indicate that ghrelin has contractile activity on gastrointestinal tract in the chicken in vitro, and the effect was region-specific. The action would be mediated through the GHS-R, which is highly sensitive to chicken ghrelin.     

Age-dependent reduction of ghrelin- and motilin-induced contractile activity in the chicken gastrointestinal tract

Ghrelin is an endogenous ligand for growth hormone secretagogue-receptor 1a (GHS-R1a) and stimulates gastrointestinal (GI) motility in the chicken. Since ghrelin stimulates GH release, which regulates growth, it might be interesting to compare ghrelin-induced responses in GI tract of different-aged chickens. Motilin is a ghrelin-related gut peptide that induces strong contraction in the small intestine. Aim of this study was to clarify age-dependent changes in ghrelin- and motilin-induced contractions of the chicken GI tract and expression of their receptor mRNAs. Chicken ghrelin caused contraction of the crop and proventriculus. Ghrelin-induced contraction in the proventriculus decreased gradually up to 100 days after hatching, but the responses to ghrelin in the crop were the same during the growth period. GHS-R1a mRNA expression in the crop tended to increase, but that in the proventriculus decreased depending on the age. Chicken motilin caused contraction of the chicken GI tract. Atropine decreased the responses to motilin in the proventriculus but not in the ileum. Motilin-induced contraction in the proventriculus but not that in the ileum decreased depending on post-hatching days. On the other hand, motilin receptor mRNA expression in every region of the GI tract decreased with age, but the decrease was more marked in the proventriculus than in the ileum. In conclusion, ghrelin- and motilin-induced GI contractions selectively decreased in the chicken proventriculus depending on post-hatching days, probably due to the age-related decrease in respective receptors expression. The results suggest an age-related contribution of ghrelin and motilin to the regulation of chicken GI motility.     

Localization of ghrelin-producing cells in the stomach of the rainbow trout (Oncorhynchus mykiss)

Ghrelin, an endogenous ligand for the growth hormone secretagogue receptor (GHS-R), was isolated from the rat stomach and determined to be n-octanoylated 28-amino-acid peptide. In this study, we studied the distribution of ghrelin-producing cells (ghrelin cells) in the gastrointestinal tract of male and female rainbow trout (Oncorhynchus mykiss) by immunohistochemistry using N-terminal region-recognizing antibody and also by in situ hybridization using a trout ghrelin-specific cRNA probe. Ghrelin cells were found in the mucosal layer of the stomach but not in the myenteric plexus, and no ghrelin cells were observed in other regions of the gastrointestinal tract. Ghrelin cells could be classified into two types: closed- and opened-type cells. The density of ghrelin cells increased gradually in the direction from the cardiac to pyloric portions of the stomach in both sexes. The number of ghrelin cells per unit area seemed to be higher in females than in males. In conclusion, trout ghrelin cells exist in the stomach and are classified into two types of cells, closed- and opened-type cells.     

Ghrelin-producing cells exist as two types of cells, closed- and opened-type cells, in the rat gastrointestinal tract

Ghrelin was recently isolated from the rat stomach as an endogenous ligand for the growth-hormone secretagogue receptor (GHS-R) and is known to exist in the gastrointestinal tract and hypothalamus. In this study, we investigated in detail the distribution and morphologic characteristics of ghrelin-containing cells (ghrelin cells) in the gastrointestinal tract by immunohistochemistry and in situ hybridization. Ghrelin cells were found to be localized in the mucous membrane of the stomach, duodenum, ileum, cecum and colon but not in myenteric plexus, and they can be classified into open- and closed-type cells. The greatest number of ghrelin cells was found in the stomach, and it was found that the number of the opened-type cells gradually increased in the direction from stomach to the lower gastrointestinal tract. These results suggest that the two types of ghrelin cells may be distinctly regulated and play different physiological roles in various regions of the gastrointestinal tract.     

Molecular cloning of growth hormone secretagogue-receptor and effect of quail ghrelin on gastrointestinal motility in Japanese quail

We identified a growth hormone secretagogue-receptor (GHS-R) for ghrelin (GRLN) in the Japanese quail, and examined relationship between its receptor distribution and the effects of ghrelin on the gastrointestinal tract of the quail. GHS-R expression and GRLN-induced response were also investigated in the chicken and compared with quail. Several types of GHS-R, namely GHS-R1a-L, GHS-R1a-S, GHS-R1aV, GHS-R1b, GHS-R1bV and GHS-R1tv-like receptor, were identified in quail cerebellum cDNA. Amino acid sequence of quail GHS-R1a-L was 98% identical to that of chicken GHS-R1a. GHS-R1a mRNA was expressed heterogeneously in the quail gastrointestinal tract with a high expression level in the colon, moderate levels in the esophagus and crop, and low levels in the proventriculus, gizzard and small intestine. The region-specific expression pattern was almost the same as that in the chicken. Chicken and quail GRLN caused contraction in the crop, proventriculus and colon of both the quail and chicken, whereas the small intestine was less sensitive. However, the contractile efficacy was more potent in the chicken than in the quail. Chicken motilin (MTL), another gut peptide, structurally resemble to GRLN, caused marked contraction in the small intestine of both the quail and chicken, and the region-specific effect of MTL was opposite to that of GRLN. In conclusion, GRLN mainly induces the contractile responses of the upper and lower gastrointestinal tract and MTL stimulates motility of the middle intestine in both the quail and chicken. Regions in which GRLN acts were consistent with the distribution of GHS-R1a mRNA, but the contractile efficacy was different in the quail and chicken. These results suggest a species-specific contribution of GRLN in the regulation of avian gastrointestinal contractility.     

Involvement of ghrelin-growth hormone secretagogue receptor system in pathoclinical profiles of digestive system cancer

Ghrelin receptor has been shown to be expressed along the human gastrointestinal tract. Recent studies showed that ghrelin and a synthetic ghrelin receptor agonist improved weight gain and lean body mass retention in a rat model of cancer cachexia by acting on ghrelin receptor, that is, growth hormone secretagogue receptor （GHS-R）. This study aims to explore the expression and the distribution of ghrelin receptor in human gastrointestinal tract cancers and to investigate the possible involvement of the ghrelin- GHS-R system in human digestive cancers. Surgical human digestive cancer specimens were obtained from various portions of the gastrointestinal tract from different patients. The expression of ghrelin receptor in these tissues was detected by tissue microarray technique. Our results showed that ghrelin receptor was expressed in cancers throughout the gastrointestinal tract, mainly in the cytoplasm of mucosal layer cells. Its expression level possibly correlated with organ type, histological grade, tumor-nodes-metastases stage, and nutrition status （weight loss） of the patients. For the first time, we identified the distribution of ghrelin receptor in digestive system cancers. Our results implied that the ghrelin-GHS-R system might be involved in the pathoclinical profiles of digestive cancers.     

Correlation of ghrelin concentration and ghrelin,ghrelin-O-acetyltransferase (GOAT) and growth hormone secretagogue receptor 1a mRNAs expression in the proventriculus and brain of the growing chicken

To determine mechanisms for age-related decrease of GHS-R1a expression in the chicken proventriculus, changes in mRNA expression of ghrelin and ghrelin-O-acetyltransferase (GOAT) as well as ghrelin concentrations in the proventriculus and plasma were examined in growing chickens. Changes in expression levels of ghrelin, GOAT and GHS-R1a mRNAs were also examined in different brain regions (pituitary, hypothalamus, thalamus, cerebellum, cerebral cortex, olfactory bulb, midbrain and medulla oblongata). Ghrelin concentrations in the proventriculus and plasma increased with aging and reached plateaus at 30–50 days after hatching. High level of ghrelin mRNA decreased at 3 days after hatching, and it became stable at half of the initial level. Expression levels of GHS-R1a and GOAT decreased 3 or 5 days after hatching and became stable at low levels. Significant negative correlations were found between plasma ghrelin and mRNA levels of GOAT and GHS-R1a. Expression levels of ghrelin mRNA were different in the brain regions, but a significant change was not seen with aging. GHS-R1a expression was detected in all brain regions, and age-dependent changes were observed in the pituitary and cerebellum. Different from the proventriculus, the expression of GOAT in the brain increased or did not change with aging. These results suggest that decreased GHS-R1a and GOAT mRNA expression in the proventriculus is due to endogenous ghrelin-induced down-regulation. Expression levels of ghrelin, GOAT and GHS-R1a in the brain were independently regulated from that in the proventriculus, and age-related and region-dependent regulation pattern suggests a local effect of ghrelin system in chicken brain.     

Ghrelin expression in fetal, infant, and adult human lung.

Ghrelin is a recently identified hormone with potent growth hormone (GH)-releasing activity. It is produced by rat and human gastric endocrine cells and by the pituitary, hypothalamus, placenta, and by gastroenteropancreatic tumors. No evidence of ghrelin production by foregut-derived organs other than stomach has been provided to date. The aim of the present study was to investigate ghrelin expression by human fetal (20 cases), infant (13 cases), and adult (seven cases) lungs by immunohistochemistry, in situ hybridization, and RT-PCR. Expression of the GH secretagogue receptor, the endogenous receptor for ghrelin, was also investigated by RT-PCR. Ghrelin protein was found in the endocrine cells of the fetal lung in decreasing amounts from embryonic to late fetal periods. Its expression was maintained in newborns and children under 2 years but was virtually absent in older individuals. Scattered positive cells were also found in the trachea and the esophagus. Ghrelin mRNA was detected in adult lung by the more sensitive RT-PCR technique. GHS receptor mRNA was detected in nine cases of infant and adult lungs, possibly indicating the existence of local autocrine circuits. We conclude that the fetal lung is an additional source of circulating ghrelin, whose functions at the respiratory tract level remain to be clarified.     

Ghrelin expression and actions: a novel peptide for an old cell type of the diffuse endocrine system

Ghrelin is a gastric peptide involved in food intake control and growth hormone release. Its cell localization has been defined in distinct ghrelin cells of the gastric mucosa in humans and other mammals. Ghrelin production was also described in a number of other sites of the diffuse endocrine system, including the pituitary, thyroid, lung, pancreas, adrenal gland, and intestine. In addition, ghrelin cells were identified early during fetal life and in the placenta and gonads. Finally, endocrine growths and tumors of the diffuse endocrine system may present ghrelin-producing cells, and in a few cases high levels of circulating ghrelin were reported. Besides its well-defined orexigenic role, ghrelin is likely to exert a local paracrine role similar to other brain-gut axis hormones. This review aims to summarize recent data on ghrelin cell distribution in the diffuse endocrine system and discuss local and general ghrelin function during development, adulthood, and endocrine tumor development.     

Distribution and morphology of ghrelin immunostained cells in the adrenal gland of the African ostrich

Ghrelin is the endogenous ligand for the growth hormone secretagogue receptor. We investigated the distribution and morphological characteristics of ghrelin-immunopositive (ghrelin-ip) cells in the African ostrich adrenal gland. We found that the adrenal gland of the African ostrich consisted of three parts: capsule, inter-renal tissue and chromaffin cells. The inter-renal tissue and chromaffin cells interdigitated irregularly. The inter-renal tissue consisted of a peripheral zone and a central inner zone. The peripheral zone could be divided into an outer subcapsular zone and an inner zone. The subcapsular zone cells were arranged as a bow, while the inner area cells formed cords that were perpendicular to the capsule. The central inner zone exhibited irregular clumps and the cells were morphologically similar to chromaffin cells. Ghrelin-ip cells were located throughout the adrenal gland except the capsule. The majority of ghrelin-ip cells were found among the chromaffin cells. The number of ghrelin-ip cells in the inter-renal tissue decreased gradually from the central inner zone, to the inner zone to the subcapsular zone. The ghrelin-ip cells were oval or irregular in shape and exhibited cytoplasmic staining. Our findings suggest that ghrelin may play a role in regulating adrenal hormone secretion in the African ostrich.     

Iron-loaded cardiac myocytes stimulate cardiac myofibroblast DNA synthesis

Zinc is an essential nutrient with a wide range of functions and closely involved in a variety of enzymatic processes of importance in glucose, protein and lipid metabolism. Ghrelin is the endogenous ligand of the G protein coupled growth hormone secretagogue receptor. The regulatory mechanism that explain the biosynthesis and secretion of ghrelin in the gastrointestinal tract has not been clarified. This study was undertaken to examine the effect of zinc supplementation on the streptozotocin (STZ)-induced diabetic rats, which exhibits ghrelin production and secretion, and lipid metabolism on the gastrointestinal tract. The animals were divided into four groups. Group I: Non-diabetic untreated animals. Group II: Zinc-treated non-diabetic rats. Group III: STZ-induced diabetic untreated animals. Group IV: Zinc-treated diabetic animals. Zinc sulfate was given to some of the experimental animals by gavage at a dose of 100 mg/kg body weight every day for 60 days. In the zinc-treated diabetic group, the blood glucose levels decreased and body weight increased as compared to the diabetic untreated group. Zinc supplementation to STZ-diabetic rats revealed the protective effect of zinc on lipids parameters such as total lipid, cholesterol, HDL-cholesterol and atherogenic index. There is no statistically change in ghrelin-immunoreactive cells in gastrointestinal tissue. But, it has found that zinc supplementation caused a significant reduction in densities of ghrelin-producing cells of fundic mucosa of zinc-treated diabetic animals as compared to untreated, non-diabetic controls. Zinc supplementation may contribute to prevent some complications of diabetic rats, biochemically.     

The ghrelin cell: a novel developmentally regulated islet cell in the human pancreas

OBJECTIVES: Ghrelin, an endogenous ligand of the growth hormone secretagogue receptor (GHS-R), was recently identified in the stomach. Ghrelin is produced in a population of endocrine cells in the gastric mucosa, but expression in intestine, hypothalamus and testis has also been reported. Recent data indicate that ghrelin affects insulin secretion and plays a direct role in metabolic regulation and energy balance. On the basis of these findings, we decided to examine whether ghrelin is expressed in human pancreas. Specimens from fetal to adult human pancreas and stomach were studied by immunocytochemistry, for ghrelin and islet hormones, and in situ hybridisation, for ghrelin mRNA. RESULTS: We identified ghrelin expression in a separate population of islet cells in human fetal, neonatal, and adult pancreas. Pancreatic ghrelin cells were numerous from midgestation to early postnatally (10% of all endocrine cells). The cells were few, but regularly seen in adults as single cells at the islet periphery, in exocrine tissue, in ducts, and in pancreatic ganglia. Ghrelin cells did not express any of the known islet hormones. In fetuses, at midgestation, ghrelin cells in the pancreas clearly outnumbered those in the stomach. CONCLUSIONS: Ghrelin is expressed in a quite prominent endocrine cell population in human fetal pancreas, and ghrelin expression in the pancreas precedes by far that in the stomach. Pancreatic ghrelin cells remain in adult islets at lower numbers. Ghrelin is not co-expressed with any known islet hormone, and the ghrelin cells may therefore constitute a new islet cell type.     

Ghrelin: a metabolic signal affecting the reproductive system

Ghrelin, an acylated 28 amino acid gastric peptide, was isolated from the stomach as an endogenous ligand for growth hormone (GH) secretagogue receptor in 1999. Circulating ghrelin is mainly produced by specific cells in the stomach's oxyntic glands. Ghrelin potently stimulates GH release and food intake and exhibits diverse effects, including ones on glucose metabolism and on secretion and motility of the gastrointestinal tract. Besides these effects on food intake and energy homeostasis, ghrelin is also involved in controlling reproductive functions, and a role for it as a novel regulator of the hypothalamic-pituitary gonadal axis is clearly emerging.We review recent ghrelin research with emphasis on its roles in the reproductive axis.     

Occurrence of ghrelin-producing cells,the ghrelin receptor and Na<Superscript>+</Superscript>,K<Superscript>+</Superscript>-ATPase in tissues of Atlantic halibut (<Emphasis Type="Italic">Hippoglossus hippoglossus</Emphasis>) during early development

Ghrelin is a pituitary growth hormone (GH)-secretagogue that also has metabolic, reproductive, proliferative, immunological and brain functions in mammals. Far less is known about its role in fish. We have therefore performed an immunohistochemical determination of its tissue distribution in the developing Atlantic halibut (Hippoglossus hippoglossus) to gain insights into its potential function. Ghrelin immunoreactivity was detected in first-feeding halibut larvae in the skin, urinary bladder, gastrointestinal (GI) tract and olfactory lobe of the brain. In subsequent stages up to metamorphosis, ghrelin immunoreactivity declined in the skin and became evident in the gills. When the stomach developed, ghrelin immunoreactivity declined throughout the GI tract with the exception of the stomach, which exhibited an intense signal. Immunoreactive ghrelin cells were also present in the olfactory lobe, nerve and epithelium and in occasional cells of the buccal cavity and oesophagus. Ghrelin immunoreactivity had an overlapping distribution with that for Na⁺,K⁺-ATPase, colocalisation also being observed in some ionocytes of the gill. The co-expression of ghrelin and the GH-secretagogue receptor in the same tissue indicates that ghrelin can exert both endocrine and paracrine actions in the developing halibut. The presence of immunoreactive ghrelin in several osmoregulatory tissues, the GI tract and sensory tissue provides strong evidence that ghrelin has multiple functions during development and also suggests targets for future investigations.     

Ghrelin expression in neuroendocrine tumours of the gastrointestinal tract with multiple endocrine neoplasia type 1.

Ghrelin is a novel gastrointestinal-brain hormone that was first described by Kojima et al. as a growth-hormone-releasing peptide. It can be isolated and purified from different tissues. Evidence of antiproliferative effects in neoplastic cells (binding to normal and neoplastic tissues) supports the hypothesis that ghrelin also plays an important role in endocrine regulation. Whether ghrelin may be involved in formation of neuroendocrine tumours (NET) of the gastrointestinal tract (GIT) in cases of MEN-1 is under discussion. Over the last sixteen years, 227 patients with GIT NET were treated at our institution. Mutations of the menin gene were identified in twelve patients. Eleven of these tumours (islet cell tumours) were localized in the pancreas and one in the stomach. Tissues from these tumours were resected, fixed in formalin and embedded in paraffin. Sections were examined by immunohistochemistry with a primary antibody for ghrelin. Three out of twelve NET in MEN-1 patients (25%) showed ghrelin expression by immunohistochemistry. Comparison between ghrelin-positive and ghrelin-negative tumours regarding biological activity, morphological aspects and clinicopathological parameters shows no substantial differences. The reported incidence of ghrelin expression in NET of the gastrointestinal tract by MEN-1 was not seen in our patients. Whether or not ghrelin has an influence on neuroendocrine tumour development related to deficient menin-genes is unknown.     

Expression of Serum Retinol Binding Protein and Transthyretin within Mouse Gastric Ghrelin Cells

Ghrelin is an orexigenic peptide hormone produced mainly by a distinct group of dispersed endocrine cells located within the gastric oxyntic mucosa. Besides secreted gene products derived from the preproghrelin gene, which include acyl-ghrelin, desacyl-ghrelin and obestatin, ghrelin cells also synthesize the secreted protein nesfatin-1. The main goal of the current study was to identify other proteins secreted from ghrelin cells. An initial gene chip screen using mRNAs derived from highly enriched pools of mouse gastric ghrelin cells demonstrated high levels of serum retinol-binding protein (RBP4) and transthyretin (TTR), both of which are known to circulate in the bloodstream bound to each other. This high expression was confirmed by quantitative RT-PCR using as template mRNA derived from the enriched gastric ghrelin cell pools and from two ghrelin-producing cell lines (SG-1 and PG-1). RBP4 protein also was shown to be secreted into the culture medium of ghrelin cell lines. Neither acute nor chronic caloric restriction had a significant effect on RBP4 mRNA levels within stomachs of C57BL/6J mice, although both manipulations significantly decreased stomach TTR mRNA levels. In vitro studies using PG-1 cells showed no effect on RBP4 release of octanoic acid, epinephrine or norepinephrine, all of which are known to act directly on ghrelin cells to stimulate ghrelin secretion. These data provide new insights into ghrelin cell physiology, and given the known functions of RBP4 and TTR, support an emerging role for the ghrelin cell in blood glucose handling and metabolism.