Reversible inactivation of guanylate cyclase by mixed disulfide formation

Highly purified preparations of guanylate cyclase from rat lung were inactivated by several disulfide compounds in a time- and dose-dependent manner. Cystamine and cystine were the most potent disulfides tested, but other compounds which contained the cysteamine moiety (NH2CH2CH2S-), including pantethine and oxidized coenzyme A, were also able to partially inactivate the enzyme. In addition to the decrease in basal activity (measured with either Mg2+-GTP or Mn2+-GTP), disulfide-inhibited enzyme was activated to a lesser extent by nitric oxide. Treatment with dithiothreitol or other reducing agents restored basal activity and increased the level of cGMP production following nitric oxide activation. Control enzyme samples exhibited a single GTP Km of 25 microM or 150 microM with Mn2+ or Mg2+, respectively. However, cystamine-treated enzyme showed these same Km values as well as an additional GTP Km of 2 to 3 microM using either metal ion as cofactor. When [35S]cystine was incubated with purified enzyme, radioactivity was incorporated into the trichloroacetic acid-precipitable protein, and the counts were released following dithiothreitol treatment. In addition, [35S]cystine-labeled enzyme co-migrated with native guanylate cyclase on nondenaturing polyacrylamide gels. These data indicate that mixed disulfides can be formed between guanylate cyclase and certain naturally occurring compounds, and that disulfide formation leads to a reversible loss of enzyme activity.     

Stimulation of guanylate cyclase by sodium nitroprusside, nitroglycerin and nitric oxide in various tissue preparations and comparison to the effects of sodium azide and hydroxylamine.

Sodium nitroprusside, nitroglycerin, sodium azide and hydroxylamine increased guanylate cyclase activity in particulate and/or soluble preparations from various tissues. While sodium nitroprusside increased guanylate cyclase activity in most of the preparations examined, the effects of sodium azide, hydroxylamine and nitroglycerin were tissue specific. Nitroglycerin and hydroxylamine were also less potent. Neither the protein activator factor nor catalase which is required for sodium azide effects altered the stimulatory effect of sodium nitroprusside. In the presence of sodium azide, sodium nitroprusside or hydroxylamine, magnesium ion was as effective as manganese ion as a sole cation cofactor for guanylate cyclase. With soluble guanylate cyclase from rat liver and bovine tracheal smooth muscle the concentrations of sodium nitroprusside that gave half-maximal stimulation with Mn2+ were 0.1 mM and 0.01 mM, respectively. Effective concentrations were slightly less with Mg2+ as a sole cation cofactor. The ability of these agents to increase cyclic GMP levels in intact tissues is probably due to their effects on guanylate cyclase activity. While the precise mechanism of guanylate cyclase activation by these agents is not known, activation may be due to the formation of nitric oxide or another reactive material since nitric oxide also increased guanylate cyclase activity.     

Maxi-circles and mini-circles in kinetoplast DNA from trypanosoma cruzi

Glyceryl trinitrate specifically required cysteine, whereas NaNO2 at concentrations less than 10 mM required one of several thiols or ascorbate, to activate soluble guanylate cyclase from bovine coronary artery. However, guanylate cyclase activation by nitroprusside or nitric oxide did not require the addition of thiols or ascorbate. Whereas various thiols enhanced activation by nitroprusside, none of the thiols tested enhanced activation by nitric oxide. S-Nitrosocysteine, which is formed when cysteine reacts with either NO-2 or nitric oxide, was a potent activator of guanylate cyclase. Similarly, micromolar concentrations of the S-nitroso derivatives of penicillamine, GSH and dithiothreitol, prepared by reacting the thiol with nitric oxide, activated guanylate cyclase. Guanylate cyclase activation by S-nitrosothiols resembled that by nitric oxide and nitroprusside in that activation was inhibited by methemoglobin, ferricyanide and methylene blue. Similarly, guanylate cyclase activation by glyceryl trinitrae plus cysteine, and by NaNO2 plus either a thiol or ascorbate, was inhibited by methemoglobin, ferricyanide and methylene blue. These data suggest that the activation of guanylate cyclase by each of the compounds tested may occur through a common mechanism, perhaps involving nitric oxide. Moreover, these findings suggest that S-nitrosothiols could act as intermediates in the activation of guanylate cyclase by glyceryl trinitrate, NaNO2 and possibly nitroprusside.     

Activation of guanylate cyclase and the regulatory role of cyclic 3',5'-guanosine monophosphate

The effect of dithiothreitol on the activity of soluble guanylate cyclase and on enzyme activation by sodium nitroprusside and free stable radical was studied. A higher degree of oxidation of guanylate cyclase from rat platelets in comparison with that of the enzyme from human platelets was found, which influences both the value of the enzyme activity and its regulation. It was shown that dithiothreitol enhanced the stimulating effect of nitroprusside but inhibited the activation of guanylate cyclase by free radical, which was suggestive of a difference in the mechanisms of the activating effect of these agents. A scheme of the biological role of cyclic 3',5'-guanosine monophosphate was proposed. On the basis of this scheme, different pathological states caused by disturbances in the functions of guanylate cyclase were identified and investigated.     

Requirement of thiols for activation of coronary arterial guanylate cyclase by glyceryl trinitrate and sodium nitrite possible involvement of S-nitrosothiols

Glyceryl trinitrate specifically required cysteine, whereas NaNO₂ at concentrations less than 10 mM required one of several thiols or ascorbate, to activate soluble guanylate cyclase from bovine coronary artery. However, guanylate cyclase activation by nitroprusside or nitric oxide did not require the addition of thiols or ascorbate. Whereas various thiols enhanced activation by nitropruside, none of the thiols tested enhanced activation by nitric oxide. S-Nitrosocysteine, which is formed when cysteine reacts with either NO₂^? or nitric oxide, was a potent activator of guanylate cyclase. Similarly, micromolar concentrations of the S-nitroso derivatives of penicillamine, GSH and dithiothreitol, prepared by reacting the thiol with nitric oxide, activated guanylate cyclase. Guanylate cyclase activation by S-nitrosothiols resembled that by nitric oxide and nitroprusside in that activation was inhibited by methemoglobin, ferricyanide and methylene blue. Similarly, guanylate cyclase activation by glyceryl trinitrate plus cysteine, and by NaNO₂ plus either a thiol or ascorbate, was inhibited by methemoglobin, ferricyanide and methylene blue. These data suggest that the activation of guanylate cyclase by each of the compounds tested may occur through a common mechanism, perhaps involving nitric oxide. Moreover, these findings suggest that S-nitrosothiols could act as intermediates in the activation of guanylate cyclase by glyceryl trinitrate, NaNO₂ and possibly     

Effects of thiols, sugars, and proteins on nitric oxide activation of guanylate cyclase.

Purification of soluble guanylate cyclase from rat liver resulted in an apparent loss of enzyme activation by nitric oxide that could be restored by dithiothreitol. methemoglobin, bovine serum albumin, or sucrose. Although hemoglobin also permitted some activation with nitric oxide, the effect of other agents to restore enzyme activation was prevented with hemoglobin. As a result of enzyme purification, there is an alteration of the dose-response relationship for nitric oxide activation. After partial enzyme purification, relatively high concentrations of nitric oxide that were stimulatory in crude enzyme preparations had no effect on enzyme activity. However, partially purified or homogeneous enzyme was activated by lower concentrations of nitric oxide. The bell-shaped dose-response curve for nitric oxide was shifted to the left with guanylate cyclase purification. The addition of dithiothreitol, methemoglobin, bovine serum albumin, or sucrose to enzyme markedly broadens the dose-response curve for nitric oxide. Thus, the apparent loss of responsiveness to nitric oxide with purification is a function of increased sensitivity of guanylate cyclase to nitric oxide. Increased sensitivity to nitric oxide with enzyme purification probably results from the removal of heme, proteins, and small molecules that can serve as scavengers or sinks for nitric oxide and prevent excessive oxidation of the enzyme.     

Synthesis of adenosine 3',5'-monophosphate by guanylate cyclase, a new pathway for its formation.

The 105 000 X g gupernatant fractions from homogenates of various rat tissues catalyzed the formation of both cyclic GMP and cyclic AMP from GTP and ATP, respectively. Generally cyclic AMP formation with crude or purified preparations of soluble guanylate cyclase was only observed when enzyme activity was increased with sodium azide, sodium nitroprusside, N-methyl-N'-nitro-N-nitrosoguanidine, sodium nitrite, nitric oxide gas, hydroxyl radical and sodium arachidonate. Sodium fluoride did not alter the formation of either cyclic nucleotide. After chromatography of supernatant preparations on Sephadex G-200 columns or polyacrylamide gel electrophoresis, the formation of cyclic AMP and cyclic GMP was catalyzed by similar fractions. These studies indicate that the properties of guanylate cyclase are altered with activation. Since the synthesis of cyclic AMP and cyclic GMP reported in this study appears to be catalyzed by the same protein, one of the properties of activated guanylate cyclase is its ability to catalyze the formation of cyclic AMP from ATP. The properties of this newly described pathway for cyclic AMP formation are quite different from those previously described for adenylate cyclase preparations. The physiological significance of this pathway for cyclic AMP formation is not known. However, these studies suggest that the effects of some agents and processes to increase cyclic AMP accumulation in tissue could result from the activation of either adenylate cyclase or 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.     

Activation of a cytosolic ADP-ribosyltransferase by nitric oxide-generating agents

Sodium nitroprusside is a vasodilator and an inhibitor of platelet activation. It is thought that these effects are mediated by the spontaneous release of nitric oxide and stimulation of cytosolic guanylate cyclase. We have found that sodium nitroprusside (5-200 microM) greatly increased a cytosolic ADP-ribosyltransferase that ADP-ribosylates a soluble 39-kDa protein. This activity causes the mono-ADP-ribosylation of the 39-kDa protein, since digestion with snake venom phosphodiesterase releases 5'-AMP. This enzyme is present in platelets, brain, heart, intestine, liver, and lung. The effect of sodium nitroprusside is not related to stimulation of soluble guanylate cyclase and the production of cyclic GMP because cyclic GMP, dibutyryl cyclic GMP, and 8-bromo-cyclic GMP are ineffective. 3-Morpholinosydnonimine (commonly known as SIN-1) (20-1000 micrograms/ml), another compound that acts through the spontaneous formation of nitric oxide as does sodium nitroprusside, also stimulates ADP-ribosylation of the 39-kDa protein. Hemoglobin, which binds nitric oxide, inhibits sodium nitroprusside's activation of the cytosolic ADP-ribosyltransferase. These studies demonstrate a novel action of nitric oxide related to the activation of an endogenous ADP-ribosyltransferase. The physiological role of this ADP-ribosylation needs further exploration.     

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.     

Synthesis of adenosine 3′,5′-monophosphate by guanylate cyclase,a new pathway for its formation

The 105 000 × g supernatant fractions from homogenates of various rat tissues catalyzed the formation of both cyclic GMP and cyclic AMP from GTP and ATP, respectively. Generally cyclic AMP formation with crude or purified preparations of soluble guanylate cyclase was only observed when enzyme activity was increased with sodium azide, sodium nitroprusside, N-methyl-N′-nitro-N-nitrosoguanidine, sodium nitrite, nitric oxide gas, hydroxyl radical and sodium arachidonate. Sodium fluoride did not alter the formation of either cyclic nucleotide. After chromatography of supernatant preparations on Sephadex G-200 columns or polyacrylamide gel electrophoresis, the formation of cyclic AMP and clycic GMP was catalyzed by similar fractions. These studies indicate that the properties of guanylate cyclase are altered with activation. Since the synthesis of cyclic AMP and cyclic GMP reported in this study appears to be catalyzed by the same protein, one of the properties of activated guanylate cyclase is its ability to catalyze the formation of cyclic AMP from ATP. The properties of this newly described pathway for cyclic AMP formation are quite different from those previously described for adenylate cyclase preparations. The physiological significance of this pathway for cyclic AMP formation is not known. However, these studies suggest that the effects of some agents and processes to increase cyclic AMP accumulation in tissue could result from the activation of either adenylate cyclase or guanylate cyclase.     

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.     

Adenine nucleotide regulation of particulate guanylate cyclase from rat lung.

Adenine nucleotides activate basal particulate guanylate cyclase in rat lung membranes. Activation is specific for adenine and not guanine, cytidine or uridine nucleotides. The concentration of adenine nucleotides yielding half-maximum activation of particulate guanylate cyclase is 0.1 mM and this nucleotide activates the enzyme by increasing maximum velocity 11-fold without altering affinity for substrate. Activation is specific for particulate guanylate cyclase, since soluble enzyme is inhibited by adenine nucleotides. Similarly, activation is specific for magnesium as the enzyme substrate cation cofactor, since adenine nucleotides inhibit particulate guanylate cyclase when manganese is used. Adenine nucleotide regulation of particulate guanylate cyclase may occur by a different molecular mechanism compared to other activators, since the effects of these nucleotides are synergistic with those of detergent, hemin and atrial natriuretic peptides. Cystamine inhibits adenine nucleotide activation of particulate guanylate cyclase at concentrations having minimal effects on basal enzyme activity suggesting a role for critical sulfhydryls in mechanisms underlying nucleotide regulation of particulate guanylate cyclase. Purification and quantitative recovery of particulate guanylate cyclase by substrate affinity chromatography results in the loss of adenine nucleotide regulation. These data suggest that adenine nucleotides may be important in the regulation of basal and activated particulate guanylate cyclase and may be mediated by an adenine nucleotide-binding protein which is separate from that enzyme.     

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.     

Benzodifuroxan as an NO-dependent activator of soluble guanylate cyclase and a novel highly effective inhibitor of platelet aggregation

The ability of benzodifuroxan (BDF) to activate human platelet guanylate cyclase was investigated. The maximal stimulatory effect (1160 +/- 86%) was observed at 0.01 mM concentration. Sodium nitroprusside produced the same stimulatory effect (1220 +/- 100%) but at a higher concentration (0.1 mM). 1-H-[1,2,4,]-Oxadiazolo[4, 3-alpha]quinoxalin-1-one (ODQ), an inhibitor of NO-dependent guanylate cyclase activation, attenuated the stimulatory effect of BDF (0.01 mM) by 75% and that of sodium nitroprusside (0.1 mM) by 80%. Increasing dithiothreitol concentration in the sample from 2. 10-6 to 2.10-4 M increased the stimulatory effect of BDF 2.7-fold. The possible involvement of sulfhydryl groups of low-molecular-weight thiols and guanylate cyclase in thiol-dependent activation of the enzyme is discussed. We have also found that BDF is a highly effective inhibitor of ADP-induced human platelet aggregation with IC50 of 6.10-8 M. The effect of sodium nitroprusside was much weaker (IC50, 5.10-5 M).     

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.     

Activation of soluble guanylate cyclase by nitrovasodilators is inhibited by oxidized low-density lipoprotein

In the presence of oxidized low-density lipoprotein the stimulatory effects of nitric oxide, sodium nitroprusside and S-nitrosoglutathione on soluble guanylate cyclase partially purified from bovine platelets were diminished in a concentration-dependent manner with IC50 values around 100 micrograms total cholesterol/ml. This inhibitory effect was potentiated about 10-fold when the enzyme was pre-incubated with the lipoprotein for 10 minutes at 37 degrees C which indicates a direct interaction of the lipoprotein with the guanylate cyclase. As oxidized low-density lipoprotein is present in the wall of atherosclerotic arteries, we suggest that the impaired response of atherosclerotic blood vessels to vasodilators may be due to a diminished activation of smooth muscle guanylate cyclase.     

Protoporphyrin IX activates the Mg dependent guanylate cyclase from rat liver plasma membranes

In the presence of Mg-GTP, the rat liver guanylate cyclase, in either intact membranes or trypsin solubilized form, was stimulated by protoporphyrin IX 6 to 10-fold. However, when Mn-GTP was the substrate, protoporphyrin IX activated the membrane-bound guanylate cyclase only 50%, in contrast to the marked activation reported for the cytosolic enzyme. Meso- and deuteroporphyrin IX, hematoporphyrin and coproporphyrin III also activated membrane guanylate cyclase while uroporphyrin III, and hemin had no effect. Basal, Mg2+-dependent activity exhibited two classes of catalytic sites with apparent Km values of 2 mM and 0.12 mM. Activation by protoporphyrin resulted in the disappearance of the low affinity sites. The activated enzyme exhibited Michaelis-Menten kinetics and no alteration in its requirement for excess Mg2+. These data indicate that, in the presence of Mg2+, a heme-like structure can interact with the membrane-bound guanylate cyclase and regulate its activity.     

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 activators hemin and sodium nitroprusside stimulate cell growth in serum-free medium

Hemin and sodium nitroprusside, which strongly activate purified rat brain guanylate cyclase in vitro, were also found to stimulate glioma C6 and neuroblastoma M1 and N1E-115 cells to divide in serum-free medium. Hemin and sodium nitroprusside each stimulate C6 cell growth to a comparable extent. Sodium nitroprusside was less potent than hemin for inducing growth of neuroblastoma cells. Moreover, both agents when added together caused a synergic cell growth enhancement which is comparable to the synergism observed in their guanylate cyclase stimulation in vitro. These results suggest that activation of guanylate cyclase may play a role in the proliferative response to these compounds.