Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.6.1.2 (guanylate cyclase)
 8,497 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Guanylin and uroguanylin are small, heat-stable peptides that were initially isolated from rat jejunum and opossum urine, respectively. Both peptides bind to and activate a common set of apical membrane receptors that contain a guanylate cyclase catalytic domain within the receptor molecule. The guanylin/uroguanylin receptors are found on the luminal surface of epithelial cells lining the intestinal tract and renal proximal tubules as well as in other organs. Activation of receptor-guanylate cyclase signaling molecules by uroguanylin or guanylin elicits large increases in guanosine cyclic 3'-5' monophosphate (cGMP) production. Intracellular accumulation of this second messenger in target cells leads to the stimulation of intestinal chloride secretion, culminating in the enhancement of salt and water secretion into the intestinal lumen as well as increases in urinary sodium, potassium, and water excretion by actions of cGMP in the renal tubules. Uroguanylin and guanylin are produced throughout the intestinal mucosa and, surprisingly, uroguanylin messenger RNA (mRNA) is also expressed in both atria and ventricles of the heart. Both proguanylin and prouroguanylin are inactive polypeptides, and activation is accomplished by cleavage and release of the COOH-terminal peptides, guanylin and uroguanylin. Uroguanylin is postulated to function as an intestinal natriuretic hormone because: (1) prouroguanylin and uroguanylin both circulate in the plasma of normal animals; (2) uroguanylin is the predominant peptide agonist appearing in the filtrate and, thus, in urine; (3) the receptors for uroguanylin are localized to the apical membranes of renal tubular cells; (4) uroguanylin is substantially more potent than guanylin in eliciting a natriuresis; and (5) uroguanylin is expressed in the duodenum and myocardium, which are appropriate sites in the body for the production and release of a hormone that acts as a natriuretic agonist in vivo. The hypothesis that uroguanylin links the intestine with the kidney in an endocrine axis also predicts that the secretion of uroguanylin from the intestinal mucosa will be influenced by dietary levels of salt. Accordingly, plasma levels of uroguanylin or prouroguanylin should be influenced by oral salt loads. Future investigations will focus on the basic endocrinology of uroguanylin to provide answers to this intriguing question. In conclusion, uroguanylin is a candidate for a physiological role as an intestinal natriuretic hormone. Key features of the biology of uroguanylin provide a putative explanation for the substantial natriuresis that occurs in human subjects and experimental animals after an oral salt load. Moreover, uroguanylin and guanylin participate cooperatively in an intrinsic pathway for regulation of intestinal salt and water transport, thus providing another means of influencing salt and water homeostasis in addition to the renal actions of uroguanylin.
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PMID:Salt and water homeostasis: uroguanylin is a circulating peptide hormone with natriuretic activity. 876 30

Guanylin, a peptide homologue of the bacterial heat-stable enterotoxins, is an endogenous activator of guanylate cyclase C (GC-C). We determined the tissue content and plasma concentration of human guanylin, and its cellular source in the intestine. Human guanylin is distributed widely from the duodenum to the rectum, the highest content being in the ileum and proximal colon. The plasma concentration of immunoreactive guanylin in the normal individuals tested was 30.3 +/- 3.7 fmol/ml (mean +/- SE) and that in patients with chronic renal failure was elevated with increasing serum creatinine concentration. Guanylin immunoreactivity was detected in the villus epithelial cells in the small intestine and these guanylin-containing cells were increased in number along the cephalocaudal axis of the gut. Guanylin was also present in Paneth cells in the small intestine and superficial epithelial cells in the large intestine. Guanylin mRNA was detected in the intestine by the reverse transcription-polymerase chain reaction. Guanylin may have paracrine action on neighboring enterocytes, activating intestinal guanylate cyclase and thereby regulating intestinal fluid as well as electrolyte transport through the second messenger, cyclic GMP.
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PMID:Tissue distribution and plasma concentration of human guanylin. 878 47

Uroguanylin and guanylin are structurally related peptides that activate an intestinal form of membrane guanylate cyclase (GC-C). Guanylin was isolated from the intestine, but uroguanylin was isolated from urine, thus a tissue source for uroguanylin was sought. In these experiments, uroguanylin and guanylin were separated and purified independently from colonic mucosa and urine of opossums. Colonic, urinary, and synthetic forms of uroguanylin had an isoelectric point of approximately 3.0, eluted from C18 reverse-phase high-performance liquid chromatography (RP-HPLC) columns at 8-9% acetonitrile, elicited greater guanosine 3', 5'-cyclic monophosphate (cGMP) responses in T84 cells at pH 5.5 than pH 8, and were not cleaved and inactivated by pretreatment with chymotrypsin. In contrast, colonic, urinary, and synthetic guanylin had an isoelectric point of approximately 6.0, eluted at 15-16% acetonitrile on C18 RP-HPLC columns, stimulated greater cGMP responses in T84 cells at pH 8 than pH 5.5, and were inactivated by chymotrypsin, which hydrolyzed the Phe-Ala or Try-Ala bonds within guanylin. Uroguanylin joins guanylin as an intestinal peptide that may participate in an intrinsic pathway for cGMP-mediated regulation of intestinal salt and water transport. Moreover, uroguanylin and guanylin in urine may be derived from the intestinal mucosa, thus implicating these peptides in an endocrine mechanism linking the intestine with the kidney.
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PMID:Opossum colonic mucosa contains uroguanylin and guanylin peptides. 892 2

Pathogenic strains of enteric bacteria secrete small heat-stable toxins (STs) that activate membrane guanylyl cyclase receptors found in the intestine. The intestinal peptide agonists, guanylin and uroguanylin, are structurally related to STs. Receptors for 125I-ST were found throughout the entire length of the intestinal tract of all the birds examined. These receptors were restricted to intestinal epithelial cells covering villi and forming intestinal glands and were not observed in other strata of the gut wall. The most intense labeling of receptors by 125I-ST occurred in the region of the microvillus border of individual enterocytes. There appeared to be a decrease in receptor density distally along the length of the small intestine, although labeling of receptors by 125I-ST was observed throughout the small intestine and colon. Cellular cGMP accumulation responses to Escherichia coli ST and rat guanylin in the domestic turkey and duck were greater in the proximal small intestine compared to the distal small intestine or colon. Brush border membranes (BBM) isolated from the mucosa of proximal small intestine of turkeys exhibited agonist-stimulated guanylyl cyclase activity. The rank order potency for enzyme activation was E. coli ST > uroguanylin > guanylin. Competitive radioligand binding assays using 125I-ST and turkey intestine BBM revealed a similar rank order affinity for the receptors that was exemplified by the Kd values of ST 2.5 nM, uroguanylin 80 nM and guanylin 2.6 microM. It may be concluded that functional receptors for the endogenous peptides, guanylin and uroguanylin, occur in the apical membranes of enterocytes throughout the avian intestine. The receptor-guanylyl cyclase(s) of proximal small intestine were preferentially activated by uroguanylin relative to guanylin, but both endogenous peptides were less potent than their molecular mimic, E. coli ST.
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PMID:Distribution of Escherichia coli heat-stable enterotoxin/guanylin/uroguanylin receptors in the avian intestinal tract. 898 30

Guanylin, a 15-amino acid peptide, activates intestinal guanylate cyclase C receptor, thereby regulating intestinal fluid and electrolyte transport through the second messenger, cyclic GMP. To examine the role of the kidney in guanylin metabolism, we used a radioimmunoassay (RIA) to measure plasma concentrations of guanylin in 3 groups; normal individuals, patients who had renal disorders with normal or elevated serum creatinine levels (0.4 < Cre < 11.9 mg/dl), and patients who received hemodialysis (HD). The plasma concentration of immunoreactive guanylin in the normal individuals was 32.3 +/- 4.8 fmol/ml. The concentrations in 32 non-HD patients were correlated with their serum creatinine concentrations (r = 0.81, p < 0.0001). In 16 HD patients the plasma concentrations of immunoreactive guanylin before the start of HD were correlated with their dialysis duration (r = 0.63, p < 0.01). The plasma levels of immunoreactive guanylin in HD patients for whom EVAL membranes were used decreased one hour after the start of HD as compared with the prior levels. The plasma levels in HD patients for whom PC membranes were used showed no change. Ten kilodalton guanylin is the main component of guanylin molecules in the plasma and hemofiltrates of HD patients. These findings suggest that the kidney has a major role in the elimination and/or metabolism of guanylin. Uroguanylin, a member of the guanylin family that was recently isolated from human urine, also acts on the guanylate cyclase C receptor. Further studies of guanylin family peptides should provide a better understanding of the physiological roles of the kidney in the control of water and electrolyte balance.
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PMID:Increased plasma guanylin levels in patients with impaired renal function. 902 Dec 38

Nitric oxide (NO) production reportedly regulates guanosine 3', 5'-cyclic monophosphate (cGMP) formation and Ca2+ influx in pancreatic acini. We have investigated the functional roles of the NO/cGMP messenger system in rat pancreatic acini. In dispersed acini, the levels of amylase secretion, cytosolic [Ca2+]([Ca2+]i), NO synthase, and cGMP were measured. The NO synthase inhibitor NG-nitro-L-arginine methyl ester (L-NAME, 0.01-100 microM) had no effect on amylase secretion induced by various concentrations of carbachol, cholecystokinin octapeptide (CCK-8) or the high affinity CCK agonist, JMV-180. Similarly, L-NAME up to 100 microM did not affect the changes in Ca2+ spiking evoked by these secretagogues; nor was Ca2+ entry, refilling or oscillation altered by L-NAME. Sub- and supramaximal concentrations of these secretagogues did not change NO synthase activities compared with basal levels. While sodium nitroprusside (SNP), a NO donor, caused a 9.4-fold increase in cGMP levels compared with basal levels, carbachol, CCK-8 and JMV-180 had no effect. In addition, the guanylate cyclase inhibitor LY 83583 (10 nM to 10 microM) altered neither amylase secretion nor Ca2+ signaling induced by these secretagogues. These findings indicate that the stimulatory action of carbachol or CCK-8 is not mediated by NO or cGMP. To investigate whether cGMP stimulates pancreatic secretion we showed that both SNP and a cell-permeant cGMP analog at 0.1-1 mM stimulated amylase secretion and Ca2+ transients to a level equal to 10-15% and 13-24%, respectively, of those observed with maximal concentrations of secretagogues. The guanylate cyclase activator guanylin (1-10 microM), which increased cGMP levels 2.4-fold compared with basal levels, elicited a small amount of amylase secretion and a small Ca2+ transient. In conclusion, exogenous NO is capable of increasing endogenous cGMP, which results in a modest increase in the [Ca2+]i transient and pancreatic amylase secretion. However, the NO/cGMP system does not appear to be involved significantly in the mediation of Ca2+ signaling and amylase secretion stimulated by carbachol and CCK-8.
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PMID:Effect of uncoupling NO/cGMP pathways on carbachol- and CCK-stimulated Ca2+ entry and amylase secretion from the rat pancreas. 909 53

Guanylin and uroguanylin are intestinal peptides that stimulate chloride secretion by activating a common set of receptor-guanylate cyclase signaling molecules located on the mucosal surface of enterocytes. High mucosal acidity, similar to the pH occurring within the fluid microclimate domain at the mucosal surface of the intestine, markedly enhances the cGMP accumulation responses of T84 human intestinal cells to uroguanylin. In contrast, a mucosal acidity of pH 5.0 renders guanylin essentially inactive. T84 cells were used as a model epithelium to further explore the concept that mucosal acidity imposes agonist selectivity for activation of the intestinal receptors for uroguanylin and guanylin, thus providing a rationale for the evolution of these related peptides. At an acidic mucosal pH of 5.0, uroguanylin is 100-fold more potent than guanylin, but at an alkaline pH of 8.0 guanylin is more potent than uroguanylin in stimulating intracellular cGMP accumulation and transepithelial chloride secretion. The relative affinities of uroguanylin and guanylin for binding to receptors on the mucosal surface of T84 cells is influenced dramatically by mucosal acidity, which explains the strong pH dependency of the cGMP and chloride secretion responses to these peptides. The guanylin-binding affinities for peptide-receptor interaction were reduced by 100-fold at pH 5 versus pH 8, whereas the affinities of uroguanylin for these receptors were increased 10-fold by acidic pH conditions. Deletion of the N-terminal acidic amino acids in uroguanylin demonstrated that these residues are responsible for the increase in binding affinities that are observed for uroguanylin at acidic pH. We conclude that guanylin and uroguanylin evolved distinctly different structures, which enables both peptides to regulate, in a pH-dependent fashion, the activity of receptors that control intestinal salt and water transport via cGMP.
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PMID:Regulation of intestinal uroguanylin/guanylin receptor-mediated responses by mucosal acidity. 912 60

The heat-stable enterotoxin of Escherichia coli binds to an intestinal receptor, guanylyl cyclase-C, and produces cGMP to induce diarrhea. Guanylin is an endogenous ligand of this receptor. In the present in vivo study, the intestinal water and ion secretion induced by mucosal application of 2 nmol/ml guanylin or 5 or 10 units/ml heat-stable enterotoxin into closed loops was compared in the rat. The characteristics of secretion induced by cAMP following intravenous perfusion of 1.2 nmol/100 g per h vasoactive intestinal peptide were compared to those induced by cGMP. Unidirectional Na+ and Cl- fluxes were estimated by addition of 22Na into the loop and i.v. injection of 36Cl. Guanylin induced less water and ion secretion than that produced by heat-stable enterotoxin in the colon, confirming the results of in vitro studies, and also in duodenum and ileum. The cAMP- or cGMP-mediated response had a similar pattern, i.e., an inhibition of Na+ absorption and an increase in anion secretion.
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PMID:Guanylin-, heat-stable enterotoxin of Escherichia coli- and vasoactive intestinal peptide-induced water and ion secretion in the rat intestine in vivo. 921 4

Guanylin and uroguanylin are peptides that activate receptor guanylate cyclases (GCs) and elicit increased intestinal secretion. Bacteria that cause traveler's diarrhea produce heat-stable toxins (STs) that mimic this action. Investigation of the distribution and identity of receptor GCs in the gastrointestinal tract of rats revealed that receptors were localized to epithelial cells in stomach and intestine. Clusters of cells in gastric mucosa and enterocytes lining the intestine exhibited specific binding of 125I-labeled ST. Ligated loops of stomach and intestine treated with intraluminal ST had significant increases in guanosine 3',5'-cyclic monophosphate (cGMP), with duodenum exhibiting the greatest response. Expression of guanylate cyclase C (GCC) mRNA and a truncated, GCC-like mRNA was found in both stomach and intestine. Both mRNAs were isolated as cDNAs encoding the GC catalytic domain. The 0.9-kilobase (kb) cDNA is 99.8% identical to GCC, whereas the truncated, 0.75-kb GCC-like cDNA has a 159-nucleotide deletion and is 96.6% identical to GCC at the protein level. Uroguanylin and guanylin mRNAs were detected in stomach and intestine. Uroguanylin mRNA was most abundant in small intestine, whereas guanylin mRNA was highest in large intestine. Thus the stomach and intestine are targets for regulation of transport by guanylin and uroguanylin via cGMP.
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PMID:Signal transduction pathways via guanylin and uroguanylin in stomach and intestine. 925 14

Guanylin is a recently isolated peptide consisting of 15 amino acid residues with four cysteines, which may form two intramolecular disulfide bridges, and stimulates intestinal membrane guanylate cyclase. The position of the disulfide linkages of guanylin was predicted from its structural similarity to a heat stable enterotoxin which is thought to be responsible for secretory diarrhoea. Both guanylin, with disulfide positions 4-12 and 7-15, and its disulfide isomer, with disulfides positions 4-15 and 7-12, were chemically synthesized by the solid-phase method and purified. Two specific disulfides were selectively formed and confirmed by sequencing, mass spectrometry and high-performance liquid chromatography in combination with enzymatic cleavage. The structure of both isomers has been investigated in solution by 1H nuclear magnetic resonance spectroscopy. Guanylin exists as a mixture of two stable conformations which have compact spiral structures, from comparison with literature data. In contrast, the disulfide isomer of guanylin shows only a single conformation with an elongated curved plate-like structure. Binding assays were performed using labelled guanylin with membranes obtained from rat jejunum. Both disulfide isomers were investigated by the cGMP assay. Both binding and cGMP assays indicated that the relevant form of disulfide bridges in the intact guanylin was as predicted.
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PMID:Synthesis, solution structure, binding activity, and cGMP activation of human guanylin and its disulfide isomer. 927 23


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