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 human platelet guanylate cyclase by fatty acids.

Guanylate cyclase from human platelets was over 90% soluble, even when assayed in the presence of Triton X-100. A time-dependent increase in activity occurred when the enzyme was incubated at 37 degrees and this spontaneous activation was prevented by dithiothreitol. Arachidonic acid stimulated the soluble enzyme activity approximately 2- to 3-fold. Linear double reciprocal plots of guanylate cyclase activation as a function of arachidonic acid concentration were obtained with a Ka value of 2.1 muM. A Hill coefficient of 0.98 was obtained indicating that one fatty acid binding site is present for each catalytic site. Concentrations of arachidonic acid in excess of 10 muM caused less than maximal stimulation. Dihomo-gamma-linolenic acid and two polyunsaturated 22 carbon fatty acids stimulated the activity of guanylate cyclase to the same degree as did arachidonic acid. The methyl ester of arachidonic acid was much less effective. Diene, monoene, and saturated fatty acids of various carbon chain lengths as well as prostaglandins E1, E2, and F2alpha, had little or no effect. These data indicate that the structural determined required for stimulation by fatty acids of soluble platelet guanylate cyclase is a 1,4,7-octatriene group with its first double bond in the omega6 position. This structural group is similar to the substrate specificity determinants of fatty acid cyclooxygenase, the first enzyme of the prostaglandin synthetase complex. However, conversion of arachidonic acid to a metabolite of the cyclooxygenase pathway did not appear to be required for activation of the cyclase since activation occurred in the 105,000 X g supernatant fraction and pretreatment of this fraction with aspirin did not alter the ability of arachidonic acid to activate guanylate cyclase. Kinetic studies showed that the stimulation of guanylate cyclase by arachidonic acid is primarily an effect on maximal velocity. Arachidonic acid did not alter the concentration of free Mn2+ required for optimal activity. It is concluded that the activity of the soluble form of guanylate cyclase in cell-free preparations of human platelets can be increased by a lipid-protein interaction involving specific polyunsaturated fatty acids.     

Activation of purified soluble guanylate cyclase by arachidonic acid requires absence of enzyme-bound heme

The mechanism by which arachidonic acid activates soluble guanylate cyclase purified from bovine lung is partially elucidated. Unlike enzyme activation by nitric oxide (NO), which required the presence of enzyme-bound heme, enzyme activation by arachidonic acid was inhibited by heme. Human but not bovine serum albumin in the presence of NaF abolished activation of heme-containing guanylate cyclase by NO and nitroso compounds, whereas enzyme activation by arachidonic acid was markedly enhanced. Addition of heme to enzyme reaction mixtures restored enzyme activation by NO but inhibited enzyme activation by arachidonic acid. Whereas heme-containing guanylate cyclase was activated only 4- to 5-fold by arachidonic or linoleic acid, both heme-deficient and albumin-treated heme-containing enzymes were activated over 20-fold. Spectrophotometric analysis showed that human serum albumin promoted the reversible dissociation of heme from guanylate cyclase. Arachidonic acid appeared to bind to the hydrophobic heme-binding site on guanylate cyclase but the mechanism of enzyme activation was dissimilar to that for NO or protoporphyrin IX. Enzyme activation by arachidonic acid was insensitive to Methylene blue or KCN, was inhibited competitively by metalloporphyrins, and was abolished by lipoxygenase. Whereas NO and protoporphyrin IX lowered the apparent Km and Ki for MgGTP and uncomplexed Mg2+, arachidonic and linoleic acids failed to alter these kinetic parameters. Thus, human serum albumin can promote the reversible dissociation of heme from soluble guanylate cyclase and thereby abolish enzyme activation by NO but markedly enhance activation by polyunsaturated fatty acids. Arachidonic acid activates soluble guanylate cyclase by heme-independent mechanisms that are dissimilar to the mechanism of enzyme activation caused by protoporphyrin IX.     

Activation of soluble guanylate cyclase by arachidonic acid and 15-lipoxygenase products

The activity of soluble guanylate cyclase can be increased by exposure of the enzyme to arachidonic acid or to some oxidized metabolites of the fatty acid. We have tried to determine whether activation of the enzyme by arachidonate requires that the fatty acid be converted to an oxidized metabolite, either by a possible trace contaminant of a lipoxygenase or by guanylate cyclase itself, which contains a heme moiety. Soluble guanylate cyclase purified from bovine lung was activated 4-6-fold by arachidonic acid. This activation was not dependent on the presence of oxygen in the incubation medium. No detectable metabolites of arachidonic acid were formed during incubation with soluble guanylate cyclase. Addition of soybean lipoxygenase to the incubation did not increase activation by arachidonic acid. The inhibitors of lipoxygenase activity, nordihydroguaiaretic acid and eicosatetraynoic acid, had direct effects on soluble guanylate cyclase and interfered with its activation by arachidonate, whereas another lipoxygenase inhibitor, BW 755 C, did not. The data suggest that arachidonic acid increases the activity of guanylate cyclase by direct interaction with the enzyme rather than by being converted to an active metabolite.     

Role of lipoxygenase in the O2-dependent activation of soluble guanylate cyclase from rat lung.

Guanylate cyclase activity in rat lung supernatant fractions is stimulated 3-4 fold by aerobic incubation at 30 degrees C for approx. 30 min ('O2-dependent activation'). This stimulation was blocked by 20 microM-eicosa-5,8,11,14-tetraynoic acid (ETYA), an inhibitor of lipoxygenase and cyclo-oxygenase, but not by aspirin or indomethacin, which are cyclo-oxygenase inhibitors. The enzyme activator(s) is presumed to be the fatty acid hydroperoxide(s) formed by lipoxygenase. Removal of lipoxygenase from the supernatant fraction by chromatography on Amberlite XAD-4 also prevented activation, which was restored by the addition of soya-bean lipoxygenase. Bovine serum albumin prevented O2-dependent activation or activation by soya-bean lipoxygenase, through its ability to bind the unsaturated fatty acid substrate of lipoxygenase. The lipoxygenase in the supernatant fraction is inhibited by endogenous glutathione peroxidase plus reduced glutathione (GSH); removal of GSH de-inhibits lipoxygenase and activates guanylate cyclase. This was effected by autoxidation, by cumene hydroperoxide (with GSH peroxidase) and by titration with N-ethylmaleimide (NEM). Activation by NEM was inhibited by serum albumin or ETYA, as was activation by low concentrations (less than 50 microM) of cumene hydroperoxide. Activation by higher concentrations was not so inhibited; therefore, cumene hydroperoxide can also activate by a direct effect on guanylate cyclase. A hypothesis for physiological activation is proposed.     

Activation of guanylate cyclase in cerebral cortex of rat by hydroxylamine.

Hydroxylamine actived guanylate cyclase in particulate fraction of cerebral cortex of rat. Activation was most remarkable in crude mitochondrial fraction. When the crude mitochondrial fraction was subjected to osmotic shock and fractionated, guanylate cyclase activity recovered in the subfractions as assayed with hydroxylamine was only one-third of the starting material. Recombination of the soluble and the particulate fractions, however, restored guanylate cyclase activity to the same level as that of the starting material. When varying quantities of the particulate and soluble fractions were combined, enzyme activity was proportional to the quantity of the soluble fraction. Heating of the soluble or particulate fraction at 55 degrees for 5 min inactivated guanylate cyclase. The heated particulate fraction markedly activated guanylate cyclase activity in the native soluble fraction, while the heated soluble fraction did not stimulate enzyme activity in the particulate. The particulate fraction preincubated with hydroxylamine at 37 degrees for 5 min followed by washing activated guanylate cyclase activity in the soluble fraction in the absence of hydroxylamine. Further fractionation of the crude mitochondrial fraction revealed that the factor(s) needed for the activation by hydroxylamine is associated with the mitochondria. The mitochondrial fraction of cerebral cortex activated guanylate cyclase in supernatant of brain, liver, or kidney in the presence of hydroxylamine. The mitochondrial fraction prepared from liver or kidney, in turn, activated soluble guanylate cyclase in brain. Activation of guanylate cyclase by hydroxylamine was compared with that of sodium azide. Azide activated guanylate cyclase in the synaptosomal soluble fraction, while hydroxylamine inhibited it. The particulate fraction preincubated with azide followed by washing did not stimulate guanylate cyclase activity in the absence of azide. The activation of guanylate cyclase by hydroxylamine is not due to a change in the concentration of the substrate GTP, Addition of hydroxylamine did not alter the apparent Km value of guanylate cyclase for GTP. Guanylate cyclase became less dependent on manganese in the presence of hydroxylamine. Thus the activation of guanylate cyclase by hydroxylamine is due to the change in the Vmax of the reaction.     

Proof of guanylate cyclase activity in the coronary artery of cattle]

Guanylate cyclase activities were identified in a soluble fraction and a particular fraction obtained from the Arteria coronaria of cattle. The Km-value was 1.0 +/- 0.7 - 10(-4) M for the enzyme substrate complex of the guanylate cyclase of the soluble fraction and 9.2 +/- 1.5 - 10(-4) M for the particular fraction. For the enzyme activity of the soluble fraction Mn++ cannot be replaced by Ca++ or Mg++, whereas for the enzyme activity of the particulate fraction Mn++ can be replaced by Mg++ but not by Ca++. The guanylate cyclase of the particulate fraction can be activated by acetylcholine. This activation can be cancelled by atropine. Acetylcholine exerts no influence on the guanylate cyclase activity of the soluble fraction. ATP inhibits the enzyme activities of both fractions whereas cAMP shows no influence on the guanylate cyclase activity.     

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.     

Guanylate cyclase activity in rat liver and other tissues with starvation and streptozotocin-induced diabetes mellitus.

Guanylate cyclase activities in supernatant and particulate fractions of homogenates from various rat tissues were examined in fed and fasted normal animals and in those with diabetes mellitus induced with streptozotocin. With fasting guanylate cyclase activity in supernatant fractions increased in liver and epididymal fat, decreased in kidney and lung, and was unchanged in cerebral cortex and skeletal muscle. Lung particulate activity also decreased with fasting while particulate activities in other tissues were unchanged. In diabetic animals soluble but not particulate activity was less in several tissues and the effect of fasting on soluble liver guanylate cyclase was absent. The effect of fasting on soluble liver guanylate cyclase reversed with refeeding animals and was associated with a decrease in the apparent K_m for GTP as well as an increase in V. An inhibitory material was found in livers from fed but not fasted animals. The inhibitory material had properties of a nucleotide and inhibited guanylate cyclase in a competitive manner. Thus, soluble and particulate guanylate cyclase activities can be influenced independently of one another in the same and different tissues with fasting, refeeding, and diabetes mellitus. Some of these effects may be attributable to altered levels of small heat-stable inhibitory materials such as nucleotides.     

Effect of Bicuculline-Induced Status Epilepticus on Prostaglandins and Hydroxyeicosatetraenoic Acids in Rat Brain Subcellular Fractions

Abstract: Rat cerebrum, prelabeled in vivo by intraventric-ular injection of [1-¹⁴C]arachidonic acid, was used to assess cyclooxygenase and lipoxygenase reaction products in total homogenates, cytosol, synaptosomes, and microsomes. Effects of bicuculline-induced status epilepticus on arachi-donic acid metabolism in synaptosomes and microsomes were also measured. Lipoxygenase activity, resulting in the synthesis of hydroxyeicosatetraenoic acids (HETEs), and cyclooxygenase activity, resulting in the synthesis of prostaglandins (PGs), were measured by reverse-phase and normal-phase HPLC with flow scintillation detection. Endogenous lipoxygenase products in synaptosomes were identified by capillary gas chromatography-mass spectrometry. PGs and HETEs were detected in all subcellular fractions. The synaptosomal fraction showed the highest lipoxygenase activity, with 5-HETE, 12-HETE, and leukotriene B₄ as the major products. Following bicuculline-induced status epilepticus, endogenous free arachidonic acid and other fatty acids accumulated in synaptosomes, but not in microsomes. Incorporation of [1-^l4C]arachidonic acid into synaptosomal and microsomal phospholipids was decreased after bicuculline treatment. Bicuculline-induced status epilepticus resulted in increased synthesis of HETEs in synaptosomes. PG synthesis increased in the microsomal fraction. When [1-¹⁴C]arachidonic acid-labeled synaptosomes and microsomes were incubated for 1 h at 37°C the synthesis of eicosa-noids, particularly PGD₂, was increased significantly in bi-cuculline-treated rats, as compared with untreated rats. Depolarization (45 mM K⁺) of synaptosomes induced a loss of [1-¹⁴C]arachidonic acid from phosphatidylinositol, and increased the synthesis of PGD₂ and HETEs, an effect that was enhanced in bicuculline-treated rats. This study localizes changes in arachidonic acid metabolism and lipoxygenase activity resulting from bicuculline-induced status epilepticus in the brain subcellular fraction enriched in nerve endings.     

A decrease in guanylate cyclase activity in some tissues of C3H/HeJ mice with retinal dystrophy

Guanylate cyclase activity was assayed in homogenates, in particulate and soluble fractions from retina, cerebellum, cerebral cortex and adrenal gland of adult C3H/HeJ mice with a dystrophic retinopathy. In comparison to control mice (DBA/1J), in C3H/HeJ strain a significant decrease in guanylate cyclase activity occurred in homogenates from retina, cerebellum and adrenal gland. In particular a significant decrease was found in particulate fraction of retina, in the soluble fraction of cerebral cortex and cerebellum and in both fractions of the adrenal gland. In contrast to the retina and cerebellum where guanylate cyclase activity in homogenates was found significantly decreased both in the male and female, in the cerebral cortex guanylate cyclase decreased in both sexes although in female this was more marked.     

The guanylate cyclase/receptor family of proteins

Guanylate cyclase, which catalyzes the formation of cGMP from GTP, exists in both the soluble and particulate fractions of cells. At least two different cellular compartments for the particulate enzyme exist: the plasma membrane and cytoskeleton. The enzyme form found in the soluble fraction is a heterodimer that can be regulated by free radicals and nitrovasodilators, whereas the membrane form exists as a single-chain polypeptide that can be regulated by various peptides. These peptides include resact and speract obtained from eggs and atrial natriuretic peptides (ANP). The species of guanylate cyclase present in cytoskeletal fractions resists solubilization with non-ionic detergents; its structural properties are not yet known. cDNAs encoding the membrane form of guanylate cyclase have been isolated from different tissues and species, and in all cases the DNA sequences predict a protein containing a single transmembrane domain. The carboxyl (intracellular) domain is highly conserved from sea urchins through mammals, whereas the extracellular domain (amino terminus) varies considerably. The predicted amino acid sequences demonstrate that the membrane form of guanylate cyclase is a member of a diverse and complex family of proteins that includes a low molecular weight ANP receptor, protein kinases, and the cytoplasmic form of guanylate cyclase. cDNA encoding a membrane form of the enzyme from mammalian tissues has been expressed in cultured cells, and the expressed guanylate cyclase specifically binds ANP and is activated by ANP. The membrane form of guanylate cyclase, then, serves as a cell surface receptor, representing the first recognized protein to directly catalyze formation of a low molecular weight second messenger in response to ligand binding.     

Inhibition of pulmonary thromboxane A2 synthase activity and airway responses by CGS 13080

The effects of CGS 13080, a thromboxane (TXA₂) synthase inhibitor, on airway responses to arachidonic acid (AA) were investigated in the anesthetized cat. Feline and human lung microsomal fraction exhibited prostaglandin I₂ (PGI₂, prostacyclin), and TXA₂ synthase activities, and human platelet microsomal fractions exhibited TXA₂ synthase activity. Cat and human lung microsomal fractions, but not human platelets, exhibited the presence of GSH-dependent PGE₂ isomerase activity. CGS 13080 inhibited TXA₂ synthase activity in all three microsomal fractions in a concentration-dependent manner. The increases in transpulmonary pressure and lung resistance and decreases in dynamic compliance in response to AA were decreased significantly by CGS 13080. These data suggest that the bronchoconstrictor actions of AA are mediated in large part by the formation of TXA₂. The data further indicate that cyclooxygenase products other than TXA₂ are involved in the bronchoconstrictor response to AA since meclofenamate had greater inhibitory activity than did CGS 13080. Moreover, the effects of CGS 13080 were due to inhibition of TXA₂ synthase rather than an effect on TXA₂ receptors, since airway responses to the TXA₂ mimic, U46619, were not altered. The present data show that CGS 13080 inhibits TXA₂ synthase activity without altering cyclooxygenase, PGI₂ synthase, or GSH-dependent PGE₂ isomerase activities. The data further indicate that in vivo administration of CGS 13080 may selectively increase PGI₂ synthase activity.     

Selective activation of particulate guanylate cyclase by a specific class of porphyrins

Guanylate cyclase was activated 3- to 10-fold by hemin in a dose-dependent manner in membranes prepared from homogenates of rat lung, C6 rat glioma cells, or B103 rat neuroblastoma cells. Maximum activation was observed with 50 to 100 microM hemin with higher concentrations being inhibitory. Activation was observed when Mg2+-GTP but not when Mn2+-GTP was used as the substrate. Increased enzyme activity reflected selective activation of the particulate form of guanylate cyclase; hemin inhibited the soluble form of guanylate cyclase 70 to 90% over a wide range of concentrations. Activation was not secondary to proteolysis since a variety of protease inhibitors failed to alter stimulation by hemin. Protophorphyrin IX had little effect on particulate guanylate cyclase activity and sodium borohydride almost completely abolished hemin-dependent activation. These data suggest a requirement for the ferric form of the porphyrin-metal chelate for activation. However, agents which interact with the iron nucleus of porphyrins, such as cyanide, had little effect on the ability of hemin to activate guanylate cyclase. The stimulatory effects of hemin were observed in the presence of detergents such as Lubrol-PX, and highly purified particulate enzyme could be activated to the same extent as enzyme in native membranes. These data suggest that the interaction of porphyrins with particulate guanylate cyclase is complex in nature and different from that with the soluble enzyme.     

Subcellular distribution and activation by non-ionic detergents of guanylate cyclase in cerebral cortex of rat

Non-ionic detergents stimulated particulate guanylate cyclase activity in cerebral cortex of rat 8- to 12-fold while stimulation of soluble enzyme was 1.3- to 2.5-fold. Among various detergents, Lubrol PX was the most effective one. The subcellular distribution of guanylate cyclase activity was examined with or without 0.5% Lubrol PX. Without Lubrol PX two-thirds of the enzyme activity was detected in the soluble fraction. In the presence of Lubrol PX, however, two-thirds of guanylate cyclase activity was recovered in the crude mitochondrial fraction. Further fractionation revealed that most of the particulate guanylate cyclase activity was associated with synaptosomes. The sedimentation characteristic of the particulate guanylate cyclase activity was very close to those of choline acetyltransferase and acetylcholine esterase activities, two synaptosomal enzymes. When the crude mitochondrial fraction was subfractionated after osmotic shock, most of guanylate cyclase activity as assayed in the absence of Lubrol PX was released into the soluble fraction while the rest of the enzyme activity was tightly bound to synaptic membrane fractions. The total guanylate cyclase activity recovered in the synaptosomal soluble fraction was 6 to 7 times higher than that of the starting material. The specific enzyme activity reached more than 1000 pmol per min per mg protein, which was 35-fold higher than that of the starting material. The membrane bound guanylate cyclase activity was markedly stimulated by Lubrol PX. Guanylate cyclase activity in the synaptosomal soluble fraction, in contrast, was suppressed by the addition of Lubrol PX. The observation that most of guanylate cyclase activity was detected in synaptosomes, some of which was tightly bound to the synaptic membrane fraction upon hypoosmotic treatment, is consistent with the concept that cyclic GMP is involved in neural transmission.     

The activity of guanylate cyclase and cyclic GMP phosphodiesterase during synchronous growth of the acellular slime mould Physarum polycephalum.

Guanylate cyclase (EC 4.6.1.2.) and cyclic GMP phosphodiesterase (EC 3.1.4.-.) activity were measured in three subcellular fractions of Physarum polycephalum macroplasmodia isolated at intervals during synchronous growth. In a particulate fraction prepared by high-speed centrifugation guanylate cyclase activity was twice to ten times that of other fractions and highest in mid S and late G2. Two-thirds of the cyclic GMP phosphodiesterase activity was in a soluble fraction but there was no significant change in enzyme activity or distribution during the mitotic cycle.     

Superoxide dismutase requires ascorbate for activation of cerebral soluble guanylate cyclase

Guanylate cyclase in 100,000 × g supernatant fraction prepared from the rat brain was markedly activated by superoxide dismutase. Although guanylate cyclase in pH 5.0 precipitated fraction prepared from the supernatant fraction failed to be stimulated by superoxide dismutase, the addition of ascorbate restored the responsiveness. Guanylate cyclase in the supernatant fraction which was preincubated with ascorbate oxidase also showed no response to superoxide dismutase. The superoxide dismutase-induced activation of guanylate cyclase in the supernatant fraction as well as in the ascorbate-added pH 5.0 precipitated fraction was completely eliminated by the addition of KCN, diethyldithiocarbamate, Tiron, retinol or hemoglobin.     

Alteration of arachidonic acid metabolism with spleen microsomes of irradiated rats

Arachidonic acid is metabolized by a rat spleen microsomes cyclooxygenase into prostaglandin D₂, thromboxane B₂, 12-hydroxy-5, 8, 10-heptadecadienoic acid and by a lipoxygenase into 12-hydroxy-5, 8, 10, 14-eicosatetraenoic acid and other unidentified compounds as analyzed by a radiometric thin-layer chromatography method and by gas-chromatography-mass spectrometry. This conversion is modified when spleen microsomes are obtained from whole body irradiated rats. Furthermore, if exogenous cofactors are added to the incubation medium, other changes appear that are different for the lipoxygenase and the cyclooxygenase activities. The results suggest a regulatory role of cofactors on both enzymes and/or a modification of sensitivity of the microsomal fraction from irradiated rats to effectors.     

Magnesium-sensitive guanylate cyclase and its endogenous activating factor in Tetrahymena pyriformis.

Guanylate cyclase [EC 4.6.1.2] activity in Tetrahymena pyriformis cells was associated with particulate fractions, but not with soluble fractions. Mg2+ was much more effective than Mn2+ in activating the cyclase activity. Both specific and total cyclase activities with Mg2+ in the particulate fraction were very much lower than those in the original homogenate. The addition of the soluble fraction resulted in a marked enhancement of the particulate-bound cyclase activity, while the adenylate cyclase [EC 4.6.1.1] activity was not enhanced. The enhancement was dependent on Ca2+, and the activating factor is suggested to be a protein.     

Stimulation of guanylate cyclase activity by several fatty acids.

Guanylate cyclase of plasma membrane of isolated rat fat cells was activated 7 to 11 fold by oleic acid, linoleic acid, linolenic acid or arachidonic acid. The activation of the enzyme by linoleic acid or oleic acid was influenced by the concentration of enzyme protein and that of the fatty acid. At 158 μg/ml of enzyme protein, 0.6 mM linoleic acid produced maximal activation of 12 fold which was partially reversed by washing. Particulate guanylate cyclase of cerebral cortex and liver was also activated by linoleic acid.