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.     

Restoration of the responsiveness of purified guanylate cyclase to nitrosoguanidine, nitric oxide, and related activators by heme and hemeproteins. Evidence for involvement of the paramagnetic nitrosyl-heme complex in enzyme activation.

Purification of soluble guanylate cyclase activity from rat liver resulted in loss of enzyme responsiveness to N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), nitroprusside, nitrite, and NO. Responses were restored by addition of heat-treated hepatic supernatant fraction, implying a requirement for heat-stable soluble factor(s) in the optimal expression of the actions of the activators. Addition of free hematin, hemoglobin, methemoglobin, active or heat-inactivated catalase partially restores responsiveness of purified guanylate cyclase to MNNG, NO, nitrite, and nitroprusside. These responses were markedly potentiated by the presence of an appropriate concentration of reducing agent (dithiothreitol, ascorbate, cysteine, or glutathione), which maintains heme iron in the ferro form and favors formation of paramagnetic nitrosyl . heme complexes from the activators. High concentrations of heme or reducing agents were inhibitory, and heme was not required for the expression of the stimulatory effects of Mn2+ or Mg2+ on purified guanylate cyclase. Preformed nitrosyl hemoglobin (10 micron) increased activity of the purified enzyme 10- to 20-fold over basal with Mn2+ as the metal cofactor and 90- to 100-fold with Mg2+. Purified guanylate cyclase was more sensitive to preformed NO-hemoglobin (minimally effective concentration, 0.1 micron) than to MNNG (1 micron), nitroprusside (50 micron), or nitrite (1 mM). A reducing agent was not required for optimal stimulation of guanylate cyclase by NO-hemoglobin. Maximal NO-hemoglobin-responsive guanylate cyclase was not further increased by subsequent addition of NO, MNNG, nitrite, or nitroprusside. Activation by each agent resulted in analogous alterations in the Mn2+ and Mg2+ requirements of enzyme activity, and responses were inhibited by the thiol-blocking agents N-ethylmaleimide, arsenite, or iodoacetamide. The results suggest that NO-hemoglobin, MNNG, NO, nitrite, and nitroprusside activate guanylate cyclase through similar mechanisms. The stimulatory effects of preformed NO-hemoglobin combined with the clear requirements for heme plus a reducing agent in the optimal expression of the actions of MNNG, NO, and related agents are consistent with a role for the paramagnetic nitrosyl . heme complex in the activation of guanylate cyclase.     

Guanylate cyclase from bovine lung. Evidence that enzyme activation by phenylhydrazine is mediated by iron-phenyl hemoprotein complexes

The mechanism of activation of soluble guanylate cyclase purified from bovine lung by phenylhydrazine is reported. Heme-deficient and heme-containing forms of guanylate cyclase were studied. Heme-deficient enzyme was activated 10-fold by NO but was not activated by phenylhydrazine. Catalase or methemoglobin enabled phenylhydrazine to activate guanylate cyclase 10-fold and enhanced activation by NO to over 100-fold. Heme-containing enzyme was activated only 3-fold by phenylhydrazine but over 100-fold by NO. Added hemoproteins enhanced enzyme activation by phenylhydrazine to 12-fold without enhancing activation by NO. Reducing or anaerobic conditions inhibited, whereas oxidants enhanced enzyme activation by phenylhydrazine plus catalase, and KCN had no effect. In contrast, enzyme activation by NO and NaN3 was inhibited by oxidants or KCN. NaN3 required native catalase, whereas phenylhydrazine also utilized heat-denatured catalase for enzyme activation. Thus, the mechanism of guanylate cyclase activation by phenylhydrazine differed from that by NO or NaN3. Guanylate cyclase activation by phenylhydrazine resulted from an O2-dependent reaction between phenylhydrazine and hemoproteins to generate stable iron-phenyl hemoprotein complexes. These complexes activated guanylate cyclase in the absence of O2, but lost activity after acidification, basification, or heating. Gel filtration of prereacted mixtures of [U-14C]phenylhydrazine plus hemoproteins resulted in co-chromatography of radioactivity, protein, and guanylate cyclase stimulating activity, and yielded a phenyl-hemoprotein binding stoichiometry of four under specified conditions (one phenyl/heme). [14C]Phenyl bound to heme-containing but not heme-deficient guanylate cyclase and binding correlated with enzyme activation. Moreover, reactions between enzyme and iron-[14C] phenyl hemoprotein complexes resulted in the exchange or transfer of iron-phenyl heme to guanylate cyclase and this correlated with enzyme activation.     

An endogenous regulator of the guanylate cyclase activity of human platelets

Chromatography of soluble human platelet guanylate cyclase (105,000 g supernatant) on DEAE-cellulose in a linear gradient of NaCl (0-0.5 M) in 50 mM Tris-HCl buffer pH 7.6 gave two protein peaks, I and II, of which only peak II possessed the guanylate cyclase activity (0.18-0.22 M NaCl). The protein fraction I was found to possess an inhibiting activity; its addition to the partially purified enzyme decreased the guanylate cyclase activity by 60-70% in the presence of Mg2+ with no effect on the enzyme activity in the presence of Mn2+. The isolated enzyme lost (by approximately 80%) its ability to be activated by sodium nitroprusside; the latter was reconstituted after addition of the inhibiting fraction. The data obtained testify to the heme origin of the endogenous inhibitor of human platelet guanylate cyclase.     

Activation of soluble guanylate cyclase by NO-hemoproteins involves NO-heme exchange. Comparison of heme-containing and heme-deficient enzyme forms

The mechanism of activation of soluble guanylate cyclase purified from bovine lung by high molecular weight, nitrosyl-hemoprotein complexes is reported. Heme-containing, heme-deficient, and heme-reconstituted forms of guanylate cyclase were studied. Nitric oxide (NO) and nitroso compounds activated heme-containing and heme-reconstituted enzymes (over 50-fold), with an accompanying shift in the Soret absorption peak from 431 to 398 nm, but failed to activate or alter the spectral characteristics of heme-deficient enzyme. In contrast, preformed NO-hemoprotein complexes as well as low molecular weight NO-heme activated all forms of guanylate cyclase. Heme-deficient guanylate cyclase was first reacted with excess amounts of NO-hemoglobin, NO-myoglobin, or NO-catalase and then rapidly separated from the NO-hemoprotein by column chromatography. Spectrophotometric analysis indicated that the NO-heme moiety was transferred from each of the NO-hemoproteins to heme-deficient guanylate cyclase. Approximately 1 mol of NO-heme was bound per mol of holoenzyme and the specific activity of this enzyme form was over 50-fold greater than that of unreacted, heme-deficient enzyme. NO-heme was tightly bound to guanylate cyclase as no transfer of enzyme-bound NO-heme to apohemoglobin was evident. Enzyme activated by NO-hemoproteins closely resembled, kinetically, that activated by NO or NO-heme. In contrast, reactions between heme-deficient guanylate cyclase and hemoproteins did not result in heme transfer, whereas heme alone rapidly reconstituted the enzyme. These observations indicate that soluble guanylate cyclase can be readily reconstituted with, and thereby activated by, NO-heme through an exchange reaction with NO-hemoproteins.     

Activation of mouse splenic lymphocyte guanylate cyclase by calcium ion.

The guanosine 3',5'-cyclic monophosphate (cGMP) level in the mouse splenic lymphocytes was increased about 2- to 3-fold by concanavalin A. This increase was completely dependent on the presence of Ca2+ in the medium. Homogenates of mouse splenic lymphocytes contained significant guanylate cyclase [EC 4.6.1.2] activity in both the 105,000 X g (60 min) particulate and supernatant fractions and both fractions required Mn2+ for full activity. Calcium ion (3mM) activated soluble guanylate cyclase 3-fold at a relatively low concentration of Mn2+ (less than 1mM) but inhibited the particulate enzyme slightly at all Mn2+ concentrations tested. Concanavalin A itself did not stimulate either fraction of guanylate cyclase. Thus these results suggest that elevation of the cGMP level in lymphocytes by concanavalin A might be brought about by stimulation of Ca2+ uptake and activation of soluble guanylate cyclase by the latter.     

Activation of purified guanylate cyclase by nitric oxide requires heme. Comparison of heme-deficient, heme-reconstituted and heme-containing forms of soluble enzyme from bovine lung

Bovine lung soluble guanylate cyclase was purified to apparent homogeneity in a form that was deficient in heme. Heme-deficient guanylate cyclase was rapidly and easily reconstituted with heme by reacting enzyme with hematin in the presence of excess dithiothreitol, followed by removal of unbound heme by gel filtration. Bound heme was verified spectrally and NO shifted the absorbance maximum in a manner characteristic of other hemoproteins. Heme-deficient and heme-reconstituted guanylate cyclase were compared with enzyme that had completely retained heme during purification. NO and S-nitroso-N-acetylpenicillamine only marginally activated heme-deficient guanylate cyclase but markedly activated both heme-reconstituted and heme-containing forms of the enzyme. Restoration of marked activation of heme-deficient guanylate cyclase was accomplished by including 1 microM hematin in enzyme reaction mixtures containing dithiothreitol. Preformed NO-heme activated all forms of guanylate cyclase in the absence of additional heme. Guanylate cyclase activation was observed in the presence of either MgGTP or MnGTP, although the magnitude of enzyme activation was consistently greater with MgGTP. The apparent Km for GTP in the presence of excess Mn2+ or Mg2+ was 10 microM and 85-120 microM, respectively, for unactivated guanylate cyclase. The apparent Km for GTP in the presence of Mn2+ was not altered but the Km in the presence of Mg2+ was lowered to 58 microM with activated enzyme. Maximal velocities were increased by enzyme activators in the presence of either Mg2+ or Mn2+. The data reported in this study indicate that purified guanylate cyclase binds heme and the latter is required for enzyme activation by NO and nitroso compounds.     

Heme deficiency of soluble guanylate cyclase in rat platelets]

Analysis of soluble guanylate cyclase of rat platelets (105,000 g supernatant) revealed no activating effect of sodium nitroprusside on the enzyme activity. Dithiothreitol (2 x 10(-4) H) added to the sample stimulated the basal activity of guanylate cyclase in the presence of Mg2+ but did not induce the enzyme activation by sodium nitroprusside. Hemoglobin added to the enzyme did not influence its basal activity or the activating effect of sodium nitroprusside. DEAE-Cellulose chromatography of the 105,000 g supernatant revealed two protein peaks, I and II, of which only peak II possessed a guanylate cyclase activity. Fraction I added to a partly purified enzyme did not change the enzyme activity, nor did it enhance the sodium nitroprusside-induced activation of guanylate cyclase. Spectral analysis of the 105,000 g supernatant revealed that the presence of a maximum at 415-425 nm (Soret band) depended on the degree of plasma hemolysis. In the absence of hemolysis the Soret band was unobserved either in the 105,000 g supernatant or in fractions I and II. It is suggested that rat platelet guanylate cyclase is present in these cells in a heme-deficient state.     

The role of carnosine in the function of soluble of guanylate cyclase]

The effect of carnosine on activation of human platelet soluble guanylate cyclase has been studied in 105,000 g supernatants and partially purified haem-deficient enzyme preparations. In the 105,000 g supernatant carnosine (1 mM) inhibited (by about 70%) the enzyme activation caused by sodium nitroprusside. In partially purified haem-deficient guanylate cyclase preparations the inhibition of enzyme activation by sodium nitroprusside was 86%; further addition of carnosine had no effect on the enzyme activity. The strength of the activating effect of protoporphyrin IX on partially purified haem-deficient guanylate cyclase did not differ from that for the 105,000 g supernatant; this stimulating effect did not change after carnosine addition. A conclusion is drawn that the inhibiting effect of carnosine on the ability of guanylate cyclase to be activated by sodium nitroprusside is due to the dipeptide interaction with the guanylate cyclase haem.     

Purification and properties of heme-deficient hepatic soluble guanylate cyclase: effects of heme and other factors on enzyme activation by NO, NO-heme, and protoporphyrin IX

Purified hepatic soluble guanylate cyclase (EC 4.6.1.2) had maximal specific activities in the unactivated state of 0.4 and 1 μmol cyclic GMP min^?1 mg protein^?1, when MgGTP and MnGTP, respectively, were used as substrates. The apparent K_m for GTP was 85 or 10 μm in the presence of excess Mg²⁺ or Mn²⁺, respectively. Guanylate cyclase purified as described was deficient in heme but could be readily reconstituted with heme by reacting enzyme with hematin and excess dithiothreitol at 4 °C and pH 7.8. Unpurified guanylate cyclase was activated 20- to 84-fold by NO, nitroso compounds, NO-heme, and protoporphyrin IX. The purified enzyme was only slightly (2- to 3-fold) activated by NO and nitroso compounds but was markedly (50-fold) activated by NO-heme and protoporphyrin IX, achieving maximal specific activities of 10 μmol cyclic GMP min^?1 mg protein^?1. Enzyme activation by NO and nitroso compounds was restored by addition of hematin or by reconstitution of guanylate cyclase with heme. Excess hematin, however, inhibited enzyme activity. A partially purified heat-stable factor (activation-enhancing factor) was found to enhance (2- to 35-fold) enzyme activation without directly stimulating guanylate cyclase. In the presence of optimal concentrations of hematin, enzyme activation was still increased (2-fold) by the activation-enhancing factor but not by bovine serum albumin. Guanylate cyclase was markedly inhibited by SH reactive agents such as cystine, o-iodosobenzoic acid, periodate, and 5,5′-dithiobis (2-nitrobenzoic acid). In addition, CN^? and FMN inhibited enzyme activation by NO-heme, but not by protoporphyrin IX, and did not affect basal enzymatic activity. Hepatic soluble guanylate cyclase appears to possess SH groups required for catalysis and to require heme and/or other unknown factors for the full expression of enzyme activation by NO and nitroso compounds.     

Stimulation of guanylate cyclase by EDTA and other chelating agents

The partially purified soluble guanylate cyclase (GTP pyrophosphatelyase(cyclizing), EC 4.6.1.2) from human caudate nucleus is stimulated from 2 to 4-fold by metal chelating agents. EDTA (K 1/2 - 4.8 microM) is more potent than CDTA (K 1/2 = 13.2 microM) or EGTA (K 1/2 = 21.8 microM) at stimulating activity. Stimulation by chelating agents is apparently not due to removal of inhibitory divalent cations which contaminate the enzyme or reaction mixture. EDTA increases guanylate cyclase activity in part by increasing the affinity of the enzyme for the substrate (MgGTP) 10-fold. Dopamine inhibits partially purified guanylate cyclase in the presence or absence of EDTA. Dopamine increases the Ka of guanylate cyclase for the activator, free Mn2+, more than 50-fold, from 3 to 150 microM.     

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.     

YC-1-like potentiation of nitric oxide-dependent activation of soluble guanylate cyclase by adrenochrom

The influence of adrenochrome and YC-1 activation of human platelet soluble guanylate cyclase was investigated. Adrenochrome (0.1–10.0 μM) had no effect on the basal activity, but it potentiated in a concentration- dependent manner the spermine NONO-induced activation of this enzyme. Adrenochrome also sensitized guanylate towards nitric oxide (NO) and produced the leftward shift of the spermine NONO concentration response curve. Addition of adrenochrome decreased the YC-1-induced leftward shift of the spermine NONO concentration response curve. Adrenochrome also inhibited enzyme activation byYC-1. Thus, synergistic activation of NO-stimulated guanylate cyclase activity by adrenochrome represents a new biochemical effect of this compound and indicates that adrenochrome may act as an endogenous regulator of the NO-dependent stimulation of soluble guanylate cyclase. This new property of adrenochrome, similar to YC-1 but more effective, should be taken into consideration especially under conditions of adrenochrome overproduction in the body.     

Effect of carnosine on the activation of human platelet soluble guanylate cyclase by sodium nitroprusside and protoporphyrin IX

Effect of carnosine on the activation of soluble guanylate cyclase by sodium nitroprusside and protoporphyrin IX was studied using human platelet 105000 g supernatants and partially purified heme-deficient guanylate cyclase preparations. In experiments with 105000 g supernatants, carnosine (1 mM) inhibited the enzyme activation by nitroprusside by about 70%. With the partially purified heme-deficient guanylate cyclase, the enzyme activation by nitroprusside was lowered by 86%, and the remaining insignificant stimulatory effect remained unchanged upon carnosine addition. The stimulatory effect of protoporphyrin IX on the partially purified heme-deficient enzyme preparation did not differ from that observed with the 105000 g supernatant; carnosine addition had no effect on activation of guanylate cyclase by protoporphyrin IX. It was concluded that the inhibitory effect of carnosine on the ability of the enzyme to be activated by nitroprusside is due to the interaction of carnosine with guanylate cyclase, and that it is heme directed.     

Activation of particulate guanylate cyclase by nitroprusside and MNNG after filipin treatment.

Particulate guanylate cyclase from rat lung was stimulated less than 2-fold by agents capable of activating the soluble guanylate cyclase, including sodium nitroprusside, MNNG, azide and hydroxylamine. The action of the first two agents was potentiated by 10 mM 2-mercaptoethanol, and that of the last two by catalase. Pretreatment of the particulate enzyme with the polyene antibiotic, filipin, potentiated the stimulatory effects of the activators, activity with 1 mM nitroprusside in the presence of 2-mercaptoethanol being increased 10.4-fold over basal. The enzyme treated with filipin and nitroprusside showed less specificity for Mn2+, as it was able to use Mg2+ as sole cation more efficiently than the untreated enzyme. Since filipin is known to alter membrane fluidity by interacting with membrane cholesterol, it is proposed that the activity of membrane bound guanylate cylase may be regulated in part by the fluid state of the phospholipid matrix.     

Activation of soluble guanylate cyclase from rat lung by incubation or by hydrogen peroxide.

A 37,000 X g supernatant fraction prepared from fat lung homogenate demonstrated a 2- to 3-fold increase in guanylate cyclase activity after incubation at 30 degrees for 30 min (preincubation). Treatment of the supernatant fraction with Triton X-100 increased activity to approximately the same extent as preincubation, but would not increase the activity after preincubation. By chromatography on Sepharose 2B, before and after preincubation, it was demonstrated that the increase in activity was only associated with the soluble guanylate cyclase, and not the particulate enzyme. Activation by preincubation required O2. It was completely inhibited by thiols such as 2-mercaptoethanol, and by bovine serum albumin, KCN, and sodium diethyldithiocarbamate. These inhibitors suggested a copper requirement for activation, and this was confirmed by demonstrating that 20 to 60 muM CuCl2 could relieve the inhibition by 0.1 mM sodium diethyldithiocarbamate. 2-Mercaptoethanol inhibition could also be reversed by removal of the thiol on a Sephadex G-25 column, however, this treatment partially activated the enzyme. Addition of 2-mercaptoethanol to a preincubated preparation would not reverse the activation. H2O2 was found to activate guanylate cyclase, either by its generation in the lung supernatant with glucose oxidase and glucose, or by its addition to a preparation in which the catalase was inhibited with KCN. KCN or bovine serum albumin was able to partially inhibit activation by glucose oxidase plus glucose, however, larger amounts of glucose oxidase could overcome that inhibition, indicating a catalytic role for Cu2+ at low H2O2 concentrations. No direct evidence for H2O2 formation during preincubation could be found, however, indirect evidence was obtained by the spectrophotometric detection of choleglobin formation from hemoglobin present in the lung supernatant fluid. The H2O2 is believed to result from the reaction of oxyhemoglobin with ascorbate.     

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.     

Soluble guanylate cyclase in molecular mechanisms underlying the therapeutic action of drugs

The influence of ambroxol (a mucolytic agent) on the activity of human platelet soluble guanylate cyclase and rat lung soluble guanylate cyclase and activation of both enzymes by NO-donors (sodium nitroprusside (SNP) and Sin-1) were investigated. Ambroxol in the range of concentrations from 0.1 to 10 ??M had no effect on the basal activity of both enzymes. Ambroxol inhibited in a concentration-dependent manner the SNP-induced human platelet soluble guanylate cyclase and rat lung soluble guanylate cyclase with the IC₅₀ values of 3.9 and 2.1 ??M, respectively. Ambroxol did not influence the stimulation of both enzymes by protoporphyrin IX. The influence of artemisinin (an antimalarial agent) on human platelet soluble guanylate cyclase activity and the enzyme activation by NO-donors were investigated. Artemisinin (0.1?100 ??M) had no effect on the basal activity of the enzyme. Artemisinin inhibited in a concentration-dependent manner the SNP-induced activation of human platelet guanylate cyclase with the IC₅₀ value of 5.6 ??M. Artemisinin (10 ??M) also inhibited (by 71 ± 4.0%) the activation of the enzyme by a thiol-dependent NO-donor, the derivative of furoxan, 3,4-dicyano-1,2,5-oxadiazolo-2-oxide (10 ??M), but did not influence the stimulation of soluble guanylate cyclase by protoporphyrin IX. It was concluded that the signaling system NO-soluble guanylate cyclase-cGMP is involved in the molecular mechanism of the therapeutic action of ambroxol and artemisinin.     

Guanylate cyclase: assay and properties of the particulate and supernatant enzymes in mouse parotid.

A new, very sensitive, rapid and reliable assay for guanylate cyclase has been established based on conversion of [32P]GTP to [32P]guanosine 3':5'-monophosphate and its separation on Dowex 50 and aluminium oxide columns. The optimum conditions for the assay of mouse parotid guanylate cyclase have been established and using this procedure the properties of the enzyme have been investigated. The enzyme was found in both the particulate and supernatant fractions. The particulate enzyme was activated 12-fold by Triton X-100 and the supernatant enzyme activity increased 2-fold. In the presence of detergent guanylate cyclase activity was distributed 85% in the particulate and 15% in the supernatant fractions, respectively. The particulate activity was localised in a plasma membrane fraction. Guanylate cyclase activity was also assayed in a wide variety of other tissues. In all cases enzymatic activity was found in both the particulate and supernatant fractions. The distribution varied with the tissue but only the intestinal mucosa had a greater proportion of total guanylate cyclase activity in the particulate fraction than the parotid. The two enzymes showed some similar properties. Their pH optima were pH 7.4, both enzymes were inhibited by ATP, dATP, dGTP and ITP, required Mn2+ for activity and plots of activity versus Mn2+ concentration were sigmoidal. However, in many properties the enzymes were dissimilar. The ratios of Mn2+ to GTP for optimum activity were 4 and 1.5 for the supernatant and plasma-bound enzymes, respectively. The slope of Hill plots for the supernatant enzyme with varying Mn2+ was 2. The particulate enzyme plots also had a slope of 2 at low Mn2+ concentration but at higher concentrations (above 0.7 mM) the Hill coefficient shifted abruptly to 4. Calcium ions reduced sigmoidicity of the kinetics lowering the Hill coefficient, activated the enzyme at all Mn2+ concentrations but had no effect on the Mn2+:GTP ratio with the supernatant enzyme while with the plasma membrane enzyme Ca2+ had no effect on the sigmoid form of the kinetics at low Mn2+ but prevented the shift to a greater Hill coefficient at higher Mn2+, inhibited the activity at low Mn2+ and shifted the Mn2+:GTP optimum ratio to 4. For the particulate enzyme plots of activity versus GTP concentration were sigmoid (n = 1.3), while the supernatant enzyme exhibited hyperbolic kinetics.     

Properties of the guanylate cyclase-guanosine 3':5'-monophosphate system of rat renal cortex. Activation of guanylate cyclase and calcium-independent modulation of tissue guanosine 3':5'-monophosphate by sodium azide.

The effects of sodium azide on guanylate cyclase activity of homogenates of rat renal cortex and on the guanosine 3':5'-monophosphate (cGMP) content of cortical slices were examined and compared to those of carbamylcholine and NaF. In complete Krebs-Ringer bicarbonate buffer containing 10 mM theophylline, tissue cGMP content was increased 5- to 6-fold by 0.05 mM carbamylcholine or 10 mM NaN3, and 3-fold by 10 mM NaF. Increases in cGMP were maximal in response to these concentrations of the agonists and occurred within 2 min. Exclusion of Ca2+ from the incubation media reduced basal cGMP by 50% in 20 min and abolished responses to carbamylcholine and NaF, while exclusion of Mg2+ was without effect. Analogous reductions in cGMP were observed in complete buffer containing 1 mM tetracaine, an agent which blocks movement of Ca2+ across and binding to biologic membranes. By contrast, exclusion of Ca2+ or addition of tetracaine did not alter relative cGMP responses to NaN3 (6-fold increase over basal), although levels were reduced in slices exposed to these buffers for 20 min. When slices were incubated without Ca2+ or with tetracaine for only 2 min prior to addition of agonists, basal cGMP did not decline. Under these conditions, both absolute and relative increases in cGMP in response to NaN3 were comparable to those of slices incubated throughout in complete buffer, while carbamylcholine and NaF effects on cGMP were abolished. NaN3 increased guanylate cyclase activity of whole homogenates (10- to 20-fold), and of the 100,000 X g soluble (20-fold) and particulate (4-fold) fractions of cortex. Prior incubation of slices with NaN3 in the presence or absence of Ca2+ or with Ca2+ plus tetracaine also markedly enhanced enzyme activity in homogenates and subcellular fractions subsequently prepared from these slices. In the presence of 3 mM excess MnCl2, NaN3 raised the apparent Km for MnGTP of soluble guanylate cyclase from 0.11 mM to 0.20 mM, and reduced enzyme dependence on Mn2+. Thus, when Mg2+ was employed as the sole divalent cation in the enzyme reaction mixture basal and NaN3-responsive activities were 7% and 30% of those seen with optimal concentrations of Mn2+, respectively. Under a variety of assay conditions where responses to NaN3 were readily detectable, alterations in guanylate cyclase activities could not be demonstrated in response to carbamylcholine or NaF. By contrast Ca2+ increased the guanylate cyclase activity 6- to 7-fold over basal under conditions of reduced Mn2+ (0.75 mM Mn2+/1 mM GTP). This latter effect of Ca2+ was shared by Mg2+ and not blocked by tetracaine. Carbamylcholine, NaF, Ca2+, and NaN3 all failed to alter cGMP phosphodiesterase activity in cortex. Thus, while carbamylcholine and NaF enhance renal cortical cGMP accumulation through actions which are dependent upon the presence of extracellular Ca2+, NaN3 stimulates cGMP generation in this tissue through an apparently distinct Ca2+-independent mechanism.