Butadiene diepoxide activation of guanylate cyclase.

A variety of nitroso chemical carcinogens increase the activity of guanylate cyclase (EC 4.6.1.2), the enzyme catalyzing the production of guanosine 3',5'-monophosphate. In the present report, the first non-nitroso chemical carcinogen, butadiene diepoxide, was shown to activate guanylate in a variety of tissues over the concentration range 1-100 mmol/l. At 20 mmol/l concentration, increases were 2- to 17-fold above control. These observations have potential importance since guanosine 3',5'-monophosphate may be involved in cell growth and malignant transformation.     

Conditions of activation of guanylate cyclase from human platelets

Preincubation (50 min, 0 degree C) with nitroprusside increases 12-fold the activity of human platelet guanylate cyclase. The stimulating effect of nitroprusside is enhanced two-fold by dithiothreitol (2 mM) and by 60% by hemoglobin (20 micrograms/ml). Storage of guanylate cyclase preparations (105000 g supernatant) for 2-3 days at 4 degrees C causes a progressive increase of the enzyme activity and diminishes the stimulating effect of nitroprusside. After storage of guanylate cyclase preparations for 3 days, hemoglobin (20 micrograms/ml) augments the stimulating effect of nitroprusside by 130%. It is concluded that the degree of activation of guanylate cyclase by nitroprusside reflects the functional state of the enzyme.     

Receptor-mediated activation of spermatozoan guanylate cyclase

The sea urchin egg peptides speract (Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) and resact (Cys-Val-Thr-Gly-Ala-Pro-Gly-Cys-Val-Gly-Gly-Arg-Leu-NH2) bind to spermatozoa of the homologous species (Lytechinus pictus or Arbacia punctulata, respectively) and cause transient elevations of cyclic GMP concentrations (Hansbrough, J. R., and Garbers, D. L. (1981) J. Biol. Chem. 256, 1447-1452). The addition of these peptides to spermatozoan membrane preparations caused a rapid and dramatic (up to 25-fold) activation of guanylate cyclase. The peptide-induced activation of guanylate cyclase was transient, and the subsequent decline in enzyme activity coincided with conversion of a high Mr (phosphorylated) form of guanylate cyclase to a low Mr (dephosphorylated) form. When membranes were incubated at pH 8.0, the high Mr form was converted to the low Mr form without substantial changes in basal enzyme activity. However, the peptide-stimulated activity of the low Mr form of guanylate cyclase was much less than the peptide-stimulated activity of the high Mr form. Activation of the low Mr form by peptide was not transient and persisted for at least 10 min. In addition, the pH 8.0 treatment that caused the Mr conversion of guanylate cyclase also caused an increase in the peptide-binding capacity of the membranes. We propose a model in which activation of the membrane form of guanylate cyclase is receptor-mediated; the extent of enzyme activation is modulated by its phosphorylation state.     

Cation-dependent prolactin activation of guanylate cyclase

Prolactin enhanced guanylate cyclase [E.C.4.6.1.2] two- to threefold in ovary, testis, mammary gland, liver and kidney. Dose response relationships revealed that maximal activation of this enzyme was at a concentration of one nanomolar and that increasing prolactin's concentration to the millimolar range caused no further increase in activity. There was an absolute cation requirement for prolactin's enhancement of guanylate cyclase. Calcium or manganese allowed prolactin to increase guanylate cyclase activity. Greater enhancement of this enzyme's activity by prolactin was observed when manganese was the co-factor. The data in this investigation suggest that guanylate cyclase may play a role in the mechanism of action of prolactin.     

Receptor-mediated activation of detergent-solubilized guanylate cyclase

Here for the first time we report the successful detergent-solubilization of the speract (Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) receptor and the subsequent activation of guanylate cyclase in response to receptor occupation. Sea urchin sperm membranes treated with a solution containing 0.5% LubrolR PX and 0.5% EmulphogeneR in the presence of MgCl2 and NaF released both the speract receptor and guanylate cyclase activity into solution. The solubilized apparent receptor was not sedimented at 400,000 x g x 15 min and was not retained by glass microfiber filters. In the presence of 125I-GGG(Y2)speract and dissuccinimidyl suberate, a major radioactive band at about Mr = 77,000 and minor bands at Mr = 35,000 and 150,000 were cross-linked. Speract but not resact (Cys-Val-Thr-Gly-Ala-Pro-Gly-Cys-Val-Gly-Gly-Gly-Arg-LeuNH2) competed in the cross-linking reaction. The amount of 125I-GGG(Y2)speract bound to solubilized receptor did not increase in a linear manner as a function of added protein but instead was concave upward. The addition of speract but not resact to the solubilized preparation resulted in the activation of the enzyme guanylate cyclase; the extent of stimulation was dependent on the amount of enzyme protein added and also was concave upward. Approximately 900 nM speract half-maximally activated guanylate cyclase. These data suggest that the speract receptor and guanylate cyclase are closely apposed, even in detergent, or that they are the same molecule.     

Appearance of magnesium guanylate cyclase activity in rat liver with sodium azide activation.

Native soluble and particulate guanylate cyclase from several rat tissues preferred Mn2+ to Mg2+ as the sole cation cofactor. Wtih 4mM cation, activities with Mg2+ were less than 25% of the activities with Mn2+. The 1 mM NaN3 markedly increased the activity of soluble and particulate preparations from rat liver. Wtih NaN3 activation guanylate cyclase activities wite similar with Mn2+ and Mg2+. Co2+ was partially effective as a cofactor in the presence of NaN3, while Ca2+ was a poor cation with or without NaN3. Activities with Ba, Cu2+, or Zn2+ were not detectable without or with 1 mM NaN3. With soluble liver enzyme both manganese and magnesium activities were dependent upon excess Mn2+ or Mg2+ at a fixed MnGTP or MgGTP concentration of 0.4 mm; apparent Km values for excess Mn2+ and Mg2+ were 0.3 and 0.24 mM, respectively. After NaN3 activation, the activity was less dependent upon free Mn2+ and retained its dependence for free Mg2+, at 0.4 mM MgGTP the apparent Km for excess Mg2+ was 0.3 mM. The activity of soluble liver guanylate cyclase assayed with Mn2+ or Mg2+ was increased with Ca2+. After NaN3 activiation, Ca2+ had no effect or was somewhat inhibitory with either Mn2+. After NaN activation, Ca2+ had no effect or was somewhat inhibitory with either Mn2+ or Mg2+. The stimulatory effect of NaN2 on Mn2+-and Mg2+-dependent guanylate cyclase activity from liver or cerebral cortex supernatant fractions required the presence of the sodium azide-activator factor. With partially purified soluble liver guanylate cyclase and azide-activator factor, the concentration (1 mjM) of NaN3 that gave half-maximal activation with Mn2+ or Mg2+ was imilar. Thus, under some conditions guanylate cyclase can effectively use Mg2+ as a sole cation cofactor.     

Protoporphyrin IX generation from delta-aminolevulinic acid elicits pulmonary artery relaxation and soluble guanylate cyclase activation

Protoporphyrin IX is an activator of soluble guanylate cyclase (sGC), but its role as an endogenous regulator of vascular function through cGMP has not been previously reported. In this study we examined whether the heme precursor delta-aminolevulinic acid (ALA) could regulate vascular force through promoting protoporphyrin IX-elicited activation of sGC. Exposure of endothelium-denuded bovine pulmonary arteries (BPA) in organoid culture to increasing concentrations of the heme precursor ALA caused a concentration-dependent increase in BPA epifluorescence, consistent with increased tissue protoporphyrin IX levels, associated with decreased force generation to increasing concentrations of serotonin. The force-depressing actions of 0.1 mM ALA were associated with increased cGMP-associated vasodilator-stimulated phosphoprotein (VASP) phosphorylation and increased sGC activity in homogenates of BPA cultured with ALA. Increasing iron availability with 0.1 mM FeSO(4) inhibited the decrease in contraction to serotonin and increase in sGC activity caused by ALA, associated with decreased protoporphyrin IX and increased heme. Chelating endogenous iron with 0.1 mM deferoxamine increased the detection of protoporphyrin IX and force depressing activity of 10 microM ALA. The inhibition of sGC activation with the heme oxidant 10 muM 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (ODQ) attenuated the force depressing actions of an NO donor without altering the actions of ALA. Thus control of endogenous formation of protoporphyrin IX from ALA by the availability of iron is potentially a novel physiological mechanism of controlling vascular function through regulating the activity of sGC.     

Arachidonic acid activation of guinea pig lung guanylate cyclase by two independent mechanisms.

The purpose of this study was to elucidate the mechanisms by which arachidonic acid activates guanylate cyclase from guinea pig lung. Guanylate cyclase activities in both homogenate and soluble fractions of lung were examined. Guanylate cyclase activity was determined by measuring formtion of [32-P] cyclic GMP from alpha-[32-P] GTP in the presence of Mn2+, a phosphodiesterase inhibitor and a suitable GTP regenerating system. Arachidonic acid, and to a slight extent dihomo-gamma-linolenic acid, activated guanylate cyclase in homogenate but not soluble fractions. Similarly, phospholipase A2 activated homogenate but not soluble guanylate cyclase. Methyl arachidonate, linolenic, linoleic and oleic acids did not activate guanylate cyclase in either fraction. High concentrations of indomethacin, meclofenamate and aspirin inhibited activation of homogenate guanylate cyclase by arachidonic acid and phospholipase A2, without altering basal enzyme activity. These data suggested that a product of cyclooxygenase activity, present in the microsomal fraction, may have accounted for the capacity of arachidonic acid to activate homogenate guanylate cyclase. This view was supported by the findings that addition of the microsomal fraction to be soluble fraction enabled arachidonic acid to activate soluble guanylate cyclase, an effect which was reduced with cycloooxygenase inhibitors. Lipoxygenase activated guanylate cyclase in homogenate and soluble fractions. Arachidonic acid potentiated the activation of soluble guanylate cyclase by lipoxygenase, and this effect was inhibited with nordihydroguairetic acid, 1-phenyl-3-pyrazolidone and hydroquinone, but not with high concentrations of indomethacin, meclofenamate or aspirin. These data suggest that arachidonic acid activates guinea pig lung guanylate cyclase indirectly, via two independent mechanisms, one involving the microsomal fraction and the other involving lipoxygenase.     

Stimulation of guanylate cyclase of fibroblasts by free fatty acids.

The membranous guanylate cyclase of Balb 3T3 fibroblasts was stimulated by a fraction of calf serum extracted by ether. Stimulation was observed with Mg2+ as the only bivalent cation in the presence of Lubrol PX. The activator co-chromatographed with free fatty acids, and several of these were found to stimulate guanylate cyclase. Among the saturated fatty acids, myristic acid had the highest activity. Stimulating activity diminished as the hydrocarbon chain of the fatty acid was lengthened or shortened. Introduction of an unsaturated bond enhanced the activation by the longer fatty acids. This pattern of specificity is similar to that observed for the effect of fatty acids on many other membranous functions. Under appropriate conditions fatty acids were found to stimulate guanylate cyclase activity in the absence of Lubrol PX. The relationship among the effects of Mg2+, Mn2+, Lubrol PX, and fatty acids on enzyme activity was examined. On the basis of these studies, it appears that fatty acids stimulate the enzyme by a mechanism different from nonionic detergents or Mn2+.     

Activation of rat liver guanylate cyclase by proteolysis.

Guanylate cyclase activity (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2.), measured in purified rat liver plasma membranes, was markedly increased by treatment with various purified proteases. The effect was maximal with trypsin, alpha-chymotrypsin, papain, and thermolysin (6- to 8-fold increase with 5 to 20 microgram of protease/ml) and lower with subtilisin and elastase (3- to 4-fold increase). The activation was due to an increase in the maximal velocity of the cyclizing reaction. No modification was observed either in the apparent affinity for the substrate MnGTP or in the cooperative behavior of the enzyme kinetics which displayed Hill coefficients of 1.6 for both basal and activated states. The Triton X-100-dispersed guanylate cyclase remained sensitive to papain, which suggests that the action of proteases was not restricted to an indirect action upon the membranous environment of the guanylate cyclase. In contrast, the cytosolic soluble guanylate cyclase, assayed in the presence or absence of sodium azide, was absolutely insensitive to papain. Thus, proteolysis represents a previously undescribed mechanism for activating membranous guanylate cyclase systems, which might be of importance in the physiological regulation of this enzyme.     

Reversible activation of soluble guanylate cyclase by oxidizing agents.

Soluble guanylate cyclase of human platelets was stimulated by thiol oxidizing compounds like diamide and the reactive disulfide 4, 4'-dithiodipyridine. Activation followed a bell-shaped curve, revealing somewhat different optimum concentrations for each compound, although in both cases, higher concentrations were inhibitory. Diamide at a concentration of 100 microM transiently activated the enzyme. In the presence of moderate concentrations of diamide and 4,4'-dithiodipyridine, causing a two- to fourfold activation by themselves, the stimulatory activity of NO-releasing compounds like sodium nitroprusside was potentiated. In contrast, higher concentrations of thiol oxidizing compounds inhibited the NO-stimulated activation of soluble guanylate cyclase. Activation of guanylate cyclase was accompanied by a reduction in reduced glutathione and a concomitant formation of protein-bound glutathione (protein-SSG). Both compounds showed an activating potency as long as reduced glutathione remained, leading to inhibition of the enzyme just when all reduced glutathione was oxidized. Activation was reversible while reduced glutathione recovered and protein-SSG disappeared. We propose that diamide or reactive disulfides and other thiol oxidizing compounds inducing thiol-disulfide exchange activate soluble guanylate cyclase. In this respect partial oxidation is associated with enzyme activation, whereas massive oxidation results in loss of enzymatic activity. Physiologically, partial disulfide formation may amplify the signal toward NO as the endogenous activator of soluble guanylate cyclase.     

Activation of guanylate cyclase from rat liver and other tissues by sodium azide.

Sodium azide, hydroxylamine, and phenylhydrazine at concentrations of 1 mM increased the activity of soluble guanylate cyclase from rat liver 2- to 20-fold. The increased accumulation of guanosine 3':5'-monophosphate in reaction mixtures with sodium azide was not due to altered levels of substrate, GTP, or altered hydrolysis of guanosine 3':5'-monophosphate by cyclic nucleotide phosphodiesterase. The activation of guanylate cyclase was dependent upon NaN3 concentration and temperature; preincubation prevented the time lag of activation observed during incubation. The concentration of NaN3 that resulted in half-maximal activation was 0.04 mM. Sodium azide increased the apparent Km for GTP from 35 to 113 muM. With NaN3 activation the enzyme was less dependent upon the concentration of free Mn2+. Activation of enzyme by NaN3 was irreversible with dilution or dialysis of reaction mixtures. The slopes of Arrhenius plots were altered with sodium azide-activated enzyme, while gel filtration of the enzyme on Sepharose 4B was unaltered by NaN3 treatment. Triton X-100 increased the activity of the enzyme, and in the presence of Triton X-100 the activation by NaN3 was not observed. Trypsin treatment decreased both basal guanylate cyclase activity and the responsiveness to NaN3. Phospholipase A, phospholipase C, and neuraminidase increased basal activity but had little effect on the responsiveness to NaN3. Both soluble and particulate guanylate cyclase from liver and kidney were stimulated with NaN3. The particulate enzyme from cerebral cortex and cerebellum was also activated with NaN3, whereas the soluble enzyme from these tissues was not. Little or no effect of NaN3 was observed with preparations from lung, heart, and several other tissues. The lack of an effect with NaN3 on soluble GUANYLATE Cyclase from heart was probably due to the presence of an inhibitor of NaN3 activation in heart preparations. The effect of NaN3 was decreased or absent when soluble guanylate cyclase from liver was purified or stored at -20degrees. The activation of guanylate cyclase by NaN3 is complex and may be the result of the nucleophilic agent acting on the enzyme directly or what may be more likely on some other factor in liver preparations.     

Arachidonic acid activation of guinea pig lung guanylate cyclase by two independent mechanisms

The purpose of this study was to elucidate the mechanisms by which arachidonic acid activates guanylate cyclase from guinea pig lung. Guanylate cyclase activities in both homogenate and soluble fractions of lung were examined. Guanylate cyclase activity was determined by measuring formation of [32-P] cyclic GMP from α-[32-P] GTP in the presence of Mn²⁺, a phosphodiesterase inhibitor and a suitable GTP regenerating system. Arachidonic acid, and to a slight extent dihomo-γ-linolenic acid, activated guanylate cyclase in homogenate but not soluble fractions. Similarly, phospholipase A₂ activated homogenate but not soluble guanylate cyclase. Methyl arachidonate, linolenic, linoleic and oleic acids did not activate guanylate cyclase in either fraction. High concentrations of indomethacin, meclofenamate and aspirin inhibited activation of homogenate guanylate cyclase by arachidonic acid and phospholipase A₂, without altering basal enzyme activity. These data suggested that a product of cyclooxygenase activity, present in the microsomal fraction, may have accounted for the capacity of arachidonic acid to activate homogenate guanylate cyclase. This view was supported by the findings that addition of the microsomal fraction to the soluble fraction enabled arachidonic acid to activate soluble guanylate cyclase, an effect which was reduced with cyclooxygenase inhibitors. Lipoxygenase activated guanylate cyclase in homogenate and soluble fractions. Arachidonic acid potentiated the activation of soluble guanylate cyclase by lipoxygenase, and this effect was inhibited with nordihydroguaiaretic acid, 1-phenyl-3-pyrazolidone and hydroquinone, but not with high concentrations of indomethacin, meclofenamate or aspirin. These data suggest that arachidonic acid activates guinea pig lung guanylate cyclase indirectly, via two independent mechanisms, one involving the microsomal fraction and the other involving lipoxygenase.     

Cation-dependent gonadotropin releasing hormone activation of guanylate cyclase

Summary Gonadotropin releasing hormone enhanced guanylate cyclase [E.C.4.6.1.2] two- to threefold in pituitary, testis, liver and kidney. Dose response relationships revealed that at a concentration of 1 nanomolar, gonadotropin releasing hormone caused a maximal augmentation of guanylate cyclase activity and that increasing its concentration to the millimolar range caused no further enhancement of this enzyme. There was an absolute cation requirement for gonadotropin releasing hormone's enhancement of guanylate cyclase activity as there was no increase without any cation present. Gonadotropin releasing hormone could increase guanylate cyclase activity with either calcium or manganese in the incubation medium but more augmentation was observed with manganese. The data in this investigation suggest that guanylate cyclase may play a role in the mechanism of action of gonadotropin releasing hormone.     

Purification of guanylate cyclase from human platelets and effect of arachidonic acid peroxide.

Guanylate cyclase of human platelets was separated from cyclic nucleotide and GTP hydrolytic activities with a 104-fold purification over the homogenate. The purified guanylate cyclase preparation requires neither the GTP regenerating system nor cyclic GMP but is stimulated by about 2-fold by 2.5 mM cyclic GMP. The molecular weight of the enzyme was estimated as 180,000 and the Km value for GTP was 95 μM. Arachidonic acid peroxide stimulated the purified enzyme by increasing maximum velocity without changing Km value.     

Visual transduction in vertebrate photoreceptors. Light activation of guanylate cyclase

Light activation of guanylate cyclase at different calcium concentrations was studied in the rod outer segments of the toad retina. The enzyme becomes sensitive to calcium ions after a flash of light, showing an enhancement of its activity when Ca2+ concentration is lowered from 10(-4) M to 10(-8) M. A possible pathway of guanylate cyclase activation by light was also investigated by means of the antibody 4A to transducin. When added in excess to transducin, the antibody inhibits light activation of phosphodiesterase as well as of cyclase, suggesting a possible coupling of the two enzymes.