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)

The action of ANF is, at least in part, mediated by the activation of particulate guanylate cyclase. Increases in plasma ANF levels induce a marked increase in the plasma levels and urinary excretion of cyclic GMP. In contrast to agents that stimulate particulate guanylate cyclase, activators of soluble guanylate cyclase, such as the bioactive molsidomine metabolite, SIN 1, induce only a modest, not significant, increase in plasma cyclic GMP levels. Thus, increases in plasma cyclic GMP levels appear to be specific for the activation of particulate guanylate cyclase. Cyclic GMP is stable in whole blood in the presence of EDTA and can easily be measured in plasma and urine. It may therefore be a valuable alternative for ANF measurement in the clinical routine. In contrast to urinary ANF excretion, the urinary excretion of cyclic GMP sensitively reflects increases in plasma ANF levels. Measurement of cyclic GMP excretion may therefore be an alternative for plasma ANF and plasma cyclic GMP measurement especially in situations where blood drawing is difficult, e.g. in newborns. Measurement of basal cyclic GMP followed by determination of increases in cyclic GMP levels after injection of a small ANF bolus dose tests the cellular sensitivity to ANF. This may give further insight in the mechanism of the regulation of ANF effects. Therefore, cyclic GMP in many cases appears to be a sensitive marker for the action of ANF in man.
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PMID:Is cyclic GMP a clinically useful marker for ANF action? 284 15

The action of a synthetic 'atrial natriuretic factor' (sANF) on induced tone in isolated rat renal resistance vessels (lumen diameter about 200 microns) was examined and compared with the effects of sANF on resistance vessels of similar size taken from the cerebral, mesenteric and femoral vasculature. Synthetic ANF caused a relaxation of the renal vessels when these were submaximally activated with noradrenaline or serotonin, but had no effect on the responses of the other vessels to these agonists. In contrast to previous reports concerning rabbit aortic vessels, methylene blue (which is thought to cause inhibition of guanyl cyclase) did not reduce the dilator response to sANF in the renal vessels. The results demonstrate that sANF has a specific relaxing effect on renal resistance vessels, and are consistent with its effect being mediated through specific receptors. The mechanism of this relaxant effect remains unknown.
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PMID:Synthetic atrial natriuretic factor is a specific dilator of noradrenaline and serotonin activated renal resistance vessels. 285 24

Particulate guanylate cyclase from bovine adrenal cortex can be stimulated by ANF. A 2-fold stimulation of the enzyme was obtained with 100 nM ANF and a half-maximal stimulation, with a 5 nM dose. The stimulation by ANF persisted for at least 30 min. Various detergents, such as Triton X-100, Lubrol PX, cholate, CHAPS, digitonin and zwittergent, stimulated several-fold the activity of particulate guanylate cyclase. However, only Triton X-100 dispersed particulate guanylate cyclase without affecting its response to ANF. The dose-response curve of ANF stimulation of the particulate and the Triton X-100 dispersed enzyme was similar. The dispersion of a fully responsive guanylate cyclase to ANF will help us to uncover the type of interactions between guanylate cyclase and ANF. It will also be used as a first step for the purification of an ANF-sensitive particulate guanylate cyclase.
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PMID:ANF stimulation of detergent-dispersed particulate guanylate cyclase from bovine adrenal cortex. 286 81

The elution profile of solubilized rat glomerular membranes from a gel filtration column showed two peaks of 125I-ANF (atrial natriuretic factor) binding (367 +/- 21, 156 +/- 12 KDa). Over 85% of the total binding for the extract was in the 367 KDa peak. Guanylate cyclase activity was correlated with 125I-ANF specific binding. ANF activation of guanylate cyclase was also observed. As observed previously with particulate membrane, Scatchard-analysis of ANF binding data with the solubilized extract was consistent with a two-site model. Both affinities (Kd's), 4 pM and 1 nM, are within the range of blood concentrations reported for ANF. These observations suggest that most rat glomerular ANF receptors are large molecular complexes coupled with guanylate cyclase in the 300-350 KDa size range.
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PMID:Association of the atrial natriuretic factor receptor with guanylate cyclase in solubilized rat glomerular membranes. 288 94

The addition of ANF to Percoll-purified liver plasma membranes produced a slight activation of guanylate cyclase; the ANF-stimulated cyclase activity was further increased upon the addition of ATP to the enzyme assay mixture. The effect of ATP to potentiate the cyclase activation was concentration-dependent, required Mg2+ as a divalent cation, and was seen with membranes from various tissues and cells. ATP increased the maximal velocity of the cyclase without a change in the affinity for GTP or ANF. Phosphorylation by ATP might not be involved since ANF-stimulated guanylate cyclase was enhanced by non-phosphorylating ATP analogues as well. Thus, an allosteric ATP binding site is suggested to participate in ANF-induced regulation of membrane-bound guanylate cyclase.
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PMID:Participation of adenosine 5'-triphosphate in the activation of membrane-bound guanylate cyclase by the atrial natriuretic factor. 288 66

Since the seminal discovery by deBold that atria contain factors that produce diuresis and natriuresis, the biologic effects attributed to ANF have expanded to the point where the name "atrial natriuretic factor" seems inappropriate. In addition to promoting diuresis and natriuresis, ANF has been shown to produce vascular smooth muscle relaxation and to inhibit the secretion of aldosterone from the adrenal cortex, renin from the juxtaglomerlular apparatus, vasopressin from the hypothalamus, and salt and water intake after central administration. ANF also promotes intestinal secretion and stimulates testosterone synthesis in Leydig cells. However, the cellular mechanisms whereby ANF elicits these diverse effects are poorly understood. ANF has been reported to inhibit adenylate cyclase in a number of tissues. However, the significance of ANF inhibition of adenylate cyclase is unknown. This effect cannot be associated with vascular relaxation since decreased cyclic AMP would be expected to promote contraction rather than relaxation. ANF inhibition of adenylate cyclase may mediate the inhibitory effects of ANF on hormone secretion from the anterior pituitary gland. The inhibition of adenylate cyclase could also explain the inhibitory effect of ANF on aldosterone synthesis, since agents that stimulate cyclic AMP increase aldosterone synthesis. However, ANF also inhibits the dibutyryl-cyclic AMP-induced stimulation of aldosterone secretion, suggesting that an inhibition of adenylate cyclase cannot account fully for the inhibitory effects of ANF on aldosterone synthesis. There is no evidence to support a role for cyclic AMP in the diuretic and natriuretic action of ANF. An inhibition of membrane phosphoinositide breakdown by ANF and the subsequent formation of IP3 and intracellular calcium release could explain the inhibitory effects of ANF on vascular contraction and steroid synthesis. However, there is very little evidence to suggest that ANF regulates phosphoinositide metabolism, while some recent studies suggest that ANF may regulate calcium fluxes in vascular tissue. Clearly, cyclic GMP has emerged as the most likely intracellular mediator of ANF effects. ANF increases cyclic GMP in a wide range of tissues by selectively activating particulate guanylate cyclase. However, it is not known which effects of ANF are mediated by cyclic GMP. The discovery that ANF increases cyclic GMP in vascular tissue clearly suggests that cyclic GMP mediates the vascular relaxation effect of ANF, since other classes of vasodilators also increase cyclic GMP. There is preliminary evidence that cyclic GMP may inhibit renin secretion and sodium transport in kidney cells.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Atrial natriuretic factor receptor heterogeneity and stimulation of particulate guanylate cyclase and cyclic GMP accumulation. 289 71

Incubation of the adrenal membranes at pH 3.5-5.6 resulted in apparent proteolysis of 140 kDa protein to yield a 70 kDa polypeptide containing an ANF-binding site, which could be photoaffinity labeled by [125I]4-azidobenzoyl monoiodo ANF-(4-28). This 70 kDa fragment was found to be disulfide-linked to the remaining segment(s) of the molecule, giving a total apparent Mr of 140,000 when not reduced. The acidic pH-dependent proteolysis was rapid even at 0 degree C, suggesting close association of an endopeptidase with ANF receptor. The proteolysis was inhibited by EDTA, but not by phenylmethanesulfonyl fluoride, N-ethylmaleimide or pepstatin, indicating that the enzyme is a metalloendopeptidase. The inhibition was reversed by ZnCl2 or MnCl2, but not CaCl2 or MgCl2. The adrenal membranes contained guanylate cyclase activity of 1.1 nmol/min/mg protein using Mn-GTP as a substrate, which could be stimulated by 0.1 microM ANF to 2.7 nmol/min/mg. The membranes showed high affinity to ANF-(1-28) and ANF-(4-28), but little affinity to the truncated peptides ANF-(5-25) and ANF-(7-23). After treatment at pH 3.5 and 0 degrees C for 15 min, the membranes retained ANF-binding activity but with broader specificity, exhibiting high affinity to all four peptides above. It was suggested that an acidic metalloendopeptidase in the adrenal membranes may be involved in ANF receptor cleavage.
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PMID:Acidic pH- and metal ion (Zn++ or Mn++)-dependent proteolysis of 140 kDa atrial natriuretic factor receptor in bovine adrenal cortex plasma membranes: evidence for membrane-bound acidic metalloendopeptidase. 289 2

Studies with isolated adrenal cells and mouse testicular cells have supported a mediatory role of cyclic GMP in ANF (atrial natriuretic factor)-dependent steroidogenic signal transduction. This concept has been strengthened by the purification and biochemical characterization of a 180 kDa protein, which appears to contain both ANF receptor and guanylate cyclase activities, from rat adrenocortical carcinoma cells. Utilizing the antibody to 180 kDa membrane guanylate cyclase as a probe, we now demonstrate the direct presence of ANF-dependent membrane guanylate cyclase in mouse and rat testes. The antibody blocks the ANF-dependent guanylate cyclase activity in isolated membranes, and Western-blot analysis of the partially purified enzyme reveals a single 180 kDa protein. The presence of this enzyme in mouse and rat testes, together with its previous demonstration in rat adrenocortical carcinoma, represent an important potential biochemical role for this enzyme in receptor-mediated steroidogenic signal transduction.
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PMID:Characterization of atrial-natriuretic-factor-receptor-coupled membrane guanylate cyclase from rat and mouse testes. 289 40

The present investigation was designed to determine if atrial natriuretic factor relaxes non-vascular smooth muscle. Rather than cause a relaxation, atrial natriuretic factor induced a two-to-four fold enhancement in the amplitude of the spontaneous phasic contractions of duodenal longitudinal muscle. Dose-response curves revealed that ANF enhanced these contractions over a concentration range of 10 picomoles to 100 nanomoles with the ED50 at 1 nanomolar. The increased amplitude of contraction began within 30 seconds and was calcium-dependent. The increased force of contraction was associated with a three-fold increase in cyclic GMP levels and activation of particulate guanylate cyclase [E.C.4.5.1.2.]. Atrial natriuretic factor had its half-maximal [ED50] activation of guanylate cyclase at its 1 nM concentration while maximal enhancement was at its 100 nM concentration in duodenum, jejunum, and ileum. Atrial natriuretic factor did not stimulate adenylate cyclase [E.C.4.6.1.1.]. Thus, atrial natriuretic factor increases the force of the spontaneous phasic contractions of the small intestine which are calcium-dependent and associated with activation of the guanylate cyclase-cyclic GMP system.
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PMID:Atrial natriuretic factor increases the magnitude of duodenal spontaneous phasic contractions. 290 55

Two independent series of biomedical investigations have led to the discovery that the atria are a peptide-secreting endocrine gland. The first is mainly morphological and starts with the finding that mammalian atrial but not ventricular cardiocytes contain "dense bodies". These "dense bodies" later called "specific granules" were found to be different from lysosomes, to be made up of proteins and to incorporate both 3H-leucine and 3-H-fucose in a pattern typical of peptide-secreting endocrine cells. The finding that rat atrial granulation varied with the sodium and water balance led to the crucial observation that atrial extracts have natriuretic and diuretic effects. In less than 4 years, this new natriuretic hormone has been purified, sequenced and synthetized, and its cDNA and gene have been cloned. The ANF gene has been assigned to the distal short arm of chromosome 1 in band 1P36 while the mouse gene is localized in chromosome 4. The native and synthetic hormones exert identical wide ranging effects (possibly through particulate guanylate cyclase stimulation and adenylate cyclase inhibition) on the kidney, blood vessels, adrenal cortex and pituitary. Physiopathologic implications of the hormone in experimental hypertension, congestive heart failure and expansion of blood volume are already beginning to emerge. On the other hand, the search for natriuretic hormones or factors by studies of negative pressure breathing, atrial distention experiments, head-out water immersion, expansion of blood volume, Na+/K-ATPase inhibition and parabiosis experiments in Dahl rats has provided a general framework within which to interpret this new cardiac function.
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PMID:[The heart, an endocrine gland]. 301 75


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