Structure and regulation of soluble guanylate cyclase.

Nitric oxide (NO) is an essential signaling molecule in biological systems. In mammals, the diatomic gas is critical to the cyclic guanosine monophosphate (cGMP) pathway as it functions as the primary activator of soluble guanylate cyclase (sGC). NO is synthesized from l-arginine and oxygen (O(2)) by the enzyme nitric oxide synthase (NOS). Once produced, NO rapidly diffuses across cell membranes and binds to the heme cofactor of sGC. sGC forms a stable complex with NO and carbon monoxide (CO), but not with O(2). The binding of NO to sGC leads to significant increases in cGMP levels. The second messenger then directly modulates phosphodiesterases (PDEs), ion-gated channels, or cGMP-dependent protein kinases to regulate physiological functions, including vasodilation, platelet aggregation, and neurotransmission. Many studies are focused on elucidating the molecular mechanism of sGC activation and deactivation with a goal of therapeutic intervention in diseases involving the NO/cGMP-signaling pathway. This review summarizes the current understanding of sGC structure and regulation as well as recent developments in NO signaling.

Coexistence of guanylate cyclase and atrial natriuretic factor receptor in a 180-kD protein.

Atrial natriuretic factor (ANF) is a peptide hormone that is released from atria and regulates a number of physiological processes, including steroidogenesis in adrenal cortex and testes. The parallel stimulation of membrane guanylate cyclase and corticosterone production in isolated fasciculata cells of rat adrenal cortex has supported the hypothesis of a mediatory role for cyclic guanosine monophosphate (cyclic GMP) in signal transduction. A novel particulate guanylate cyclase tightly coupled with ANF receptor was purified approximately 273,000-fold by two-step affinity chromatography. The enzyme had a molecular size of 180 kilodaltons and was acidic in nature with a pI of 4.7. Its specific activity was 1800 nanomoles of cyclic GMP formed per minute per milligram of protein. The purified enzyme bound ANF with a specific binding activity of 4.01 nanomoles per milligram of protein, a value that is close to the theoretical binding activity of 5.55 nanomoles per milligram of protein for 1 mole of the ligand binding 1 mole of the receptor protein. These results indicate that the guanylate cyclase-coupled ANF receptor exists in a 180-kilodalton protein of rat adrenocortical carcinoma and represent a step toward the elucidation of the basic mechanism of cyclic GMP-mediated transmembrane signal transduction in response to a hormone.

Purification and characterization of recombinant human soluble guanylate cyclase produced from baculovirus-infected insect cells.

Soluble guanylate cyclase (sGC) has been purified from 100 L cell culture infected by baculovirus using the newer and highly effective titerless infected-cells preservation and scale-up (TIPS) method. Successive passage of the enzyme through DEAE, Ni(2+)-NTA, and POROS Q columns obtained approximately 100mg of protein. The sGC obtained by this procedure was already about 90% pure and suitable for various studies which include high throughput screening (HTS) and hit follow-up. However, in order to obtain enzyme of greater homogeneity and purity for crystallographic and high precision spectroscopic and kinetic studies of sGC with select stimulators, the sGC solution after the POROS Q step was further purified by GTP-agarose affinity chromatography. This additional step led to the generation of 26 mg of enzyme that was about 99% pure. This highly pure and active enzyme exhibited a M(r)=144,933 by static light scattering supportive of a dimeric structure. It migrated as a two-band protein, each of equal intensity, on SDS-PAGE corresponding to the alpha (M(r) approximately 77,000) and beta (M(r) approximately 70,000) sGC subunits. It showed an A(430)/A(280)=1.01, indicating one heme per heterodimer, and a maximum of the Soret band at 430 nm indicative of a penta-coordinated ferrous heme with a histidine as the axial ligand. The Soret band shifted to 398 nm in the presence of an NO donor as expected for the formation of a penta-coordinated nitrosyl-heme complex. Non-stimulated sGC had k(cat)/K(m)=1.7 x 10(-3)s(-1)microM(-1) that increased to 5.8 x 10(-1)s(-1)microM(-1) upon stimulation with an NO donor which represents a 340-fold increase due to stimulation. The novel combination of using the TIPS method for co-expression of a heterodimeric heme-containing enzyme, along with the application of a reproducible ligand affinity purification method, has enabled us to obtain recombinant human sGC of both the quality and quantity needed to study structure-function relationships.

High yield purification of soluble guanylate cyclase from bovine lung.

Soluble guanylate cyclase (sGC), the main target of nitric oxide (NO), is a cytosolic, heme-containing, heterodimeric enzyme that catalyzes the conversion of guanosine 5'-triphosphate (GTP) to 3,5'-cyclic guanosine monophosphate (cGMP) and pyrophosphate (PPi) in the presence of Mg2+. Cyclic GMP is then involved in transmitting the NO activating signals to a variety of downstream effectors such as cyclic-nucleotide-gated channels, protein kinases, and phosphodiesterases. In this work, sGC has been purified from bovine lung. The lungs were subjected to grinding and extraction with buffer at physiological pH followed by centrifugation. The resulting solution was subjected to successive column chromatography on DEAE- and Q-Sepharose, Ceramic Hydroxyapatite, Resource Q, and GTP-agarose. The purified enzyme migrated as a two-band protein on SDS-PAGE corresponding to sGC subunits alpha (M(r)=77,532) and beta (M(r)=70,500) and had an A(280 nm)/A(430 nm) of approximately 1 indicating one heme per heterodimer. The yield of enzyme was 8-10mg from 4 to 5 kg bovine lungs. V(max) and K(m) of non-stimulated sGC were 22 nmol/mg/min and 180 microM, respectively. Upon stimulation with the NO donor 3-ethyl-3-(ethylaminoethyl)-1-hydroxy-2-oxo-1-triazene, the V(max) increased to 1330 nmol/mg/min while the K(m) dropped to 43 microM. The quality and quantity of enzyme make it suitable for studies to probe the structure and catalytic mechanism of this enzyme and for research related to drug discovery.

Effect of light on soluble guanylyl cyclase activity in Pharbitis nil seedlings.

Cyclic GMP acts as a chemical switch in plant cells to modulate cellular reactions. However, its metabolism has not been extensively explored and is still poorly understood. Previous experiments suggest that an endogenous cGMP system could participate in the mechanism of phytochrome controlled photoperiodic flower induction in Pharbitis nil. In order to gain further information on the role of cGMP, we have begun to study the enzyme of cGMP synthesis. In this article, the presence of the enzyme with guanylyl cyclase (GC) activity in soluble protein fractions of P. nil is reported. A large portion of the enzymatic activity is present in the cotyledons, where enzyme activity amounted to 0.45 pmol cGMP/min/mg protein. The enzyme exhibited a K(m) 0.5mM for GTP. A plot of 1/v versus 1/[GTP] was linear and V(max) was 0.74 pmol cGMP/min/mg protein. It was shown that the anti-sGC antibody recognise a 40 kDa protein. Moreover, the NO-donor, sodium nitroprusside (SNP) and YC-1, as a NO-independent stimulator, enhanced enzyme activity. The NS 2028 (a potent GC inhibitor) treatments provoked a 3-fold reduction of the enzyme activity in comparison to the untreated fractions. Furthermore, the influence of light on GC activity was analysed. It was noted that cGMP level increased in cool white light, and darkness inhibited enzyme activity. Exposure to blue light acts to stimulate cGMP formation, whereas in red light a rapid decrease in GC activity was observed that returned to the high level when far-red light was applied after the red light treatment. The results presented in this work strongly argue that an enzyme with guanylyl cyclase activity is present in P. nil organs and its activity is controlled by light via the photoreceptors-dependent pathways.

Experimental Approaches for Defining the Role of the Ca2+-Modulated ROS-GC System in Retinal Rods of Mouse.

Our ability to see is based on the activity of retinal rod and cone photoreceptors. Rods function when there is very little light, while cones operate at higher light levels. Photon absorption by rhodopsin activates a biochemical cascade that converts photic energy into a change in the membrane potential of the cell by decreasing the levels of a second messenger, cGMP, that control the gating of cation channels. But just as important as the activation of the cascade are the shut-off and recovery processes. The timing of shutoff and recovery ultimately affects sensitivity, temporal resolution and even the capacity for counting single photons. An important part of the recovery is restoration of cGMP through the action of rod outer segment membrane guanylate cyclases (ROS-GCs) and guanylate cyclase-activating proteins (GCAPs). In darkness, ROS-GCs catalyze the conversion of GTP to cGMP at a low rate, due to inhibition of cyclase activity by GCAPs. In the light, GCAP enhances ROS-GC activity. Mutations in the ROS-GC system can cause problems in vision, and even result in blindness due to photoreceptor death. The mouse has emerged as a particularly useful subject to study the role of ROS-GC because the technology for the manipulation of their genetics is advanced, making production of mice with targeted mutations much easier. Here we describe some experimental procedures for studying the retinal rods of wild-type and genetically engineered mice: biochemical assays of ROS-GC activity, immunohistochemistry, and single cell recording.

Biological activity of designed photolabile metal nitrosyls: light-dependent activation of soluble guanylate cyclase and vasorelaxant properties in rat aorta.

The biological and pharmacological utility of nitric oxide (NO) has led to the development of many classes of NO-donor compounds as both research tools and therapeutic agents. Many donors currently in use rely on thermal decomposition or bioactivation for the release of NO. We have developed several photolabile metal-nitrosyl donors that release NO when exposed to either visible or UV light. Herein, we show that these donors are capable of activating the primary "NO receptor", soluble guanylate cyclase (sGC), in a light-dependent fashion leading to increases in cGMP. Moreover, we demonstrate that these donors are capable of eliciting light-dependent increases of cGMP in smooth muscle cells and vasorelaxation of rat aortic smooth muscle tissue, all effects that are attributed to activation of sGC. The potential utility of these compounds as drugs and/or research tools is discussed.

Contribution of aldehyde dehydrogenase to mitochondrial bioactivation of nitroglycerin: evidence for the activation of purified soluble guanylate cyclase through direct formation of nitric oxide.

Vascular relaxation to GTN (nitroglycerin) and other antianginal nitrovasodilators requires bioactivation of the drugs to NO or a related activator of sGC (soluble guanylate cyclase). Conversion of GTN into 1,2-GDN (1,2-glycerol dinitrate) and nitrite by mitochondrial ALDH2 (aldehyde dehydrogenase 2) may be an essential pathway of GTN bioactivation in blood vessels. In the present study, we characterized the profile of GTN biotransformation by purified human liver ALDH2 and rat liver mitochondria, and we used purified sGC as a sensitive detector of GTN bioactivity to examine whether ALDH2-catalysed nitrite formation is linked to sGC activation. In the presence of mitochondria, GTN activated sGC with an EC50 (half-maximally effective concentration) of 3.77+/-0.83 microM. The selective ALDH2 inhibitor, daidzin (0.1 mM), increased the EC50 of GTN to 7.47+/-0.93 microM. Lack of effect of the mitochondrial poisons, rotenone and myxothiazol, suggested that nitrite reduction by components of the respiratory chain is not essential to sGC activation. However, since co-incubation of sGC with purified ALDH2 led to significant stimulation of cGMP formation by GTN that was completely inhibited by 0.1 mM daidzin and NO scavengers, ALDH2 may convert GTN directly into NO or a related species. Studies with rat aortic rings suggested that ALDH2 contributes to GTN bioactivation and showed that maximal relaxation to GTN occurred at cGMP levels that were only 3.4% of the maximal levels obtained with NO. Comparison of sGC activation in the presence of mitochondria with cGMP accumulation in rat aorta revealed a slightly higher potency of GTN to activate sGC in vitro compared with blood vessels. Our results suggest that ALDH2 catalyses the mitochondrial bioactivation of GTN by the formation of a reactive NO-related intermediate that activates sGC. In addition, the previous conflicting notion of the existence of a high-affinity GTN-metabolizing pathway operating in intact blood vessels but not in tissue homogenates is explained.

Involvement of a macromolecular activating factor in activity of guanylate cyclase partially purified from supernatant of a pig lung extract.

A guanylate cyclase preparation partially purified from supernatant of a pig lung extract was subjected to affinity chromatography on an Agarose-GTP column. The major portion of the cyclase activity was adsorbed on the column and then eluted with 50 mM EDTA and 0.5 M KCl, whereas the fractions non-adsorbed on the column contained a factor which enhanced the cyclase activity. Addition of the activating factor to a cyclase reaction mixture increase the enzyme activity without a time lag, and this enhancement by the factor was dose-dependent. With concomitant presence of cyclase and the factor in the reaction mixture the apparent Km value for GTP-Mn2+ of the enzyme was 56 microM, this value being the same as in absence of the factor, however, here the maximum velocity increased 4-fold. The factor was nondiffusable, heat-labile, partially sensitive to trypsin, and resistant to acid or alkali. As estimated by gel filtration, this factor had an apparent molecular weight of 85 000.

Association of guanylate cyclase with the axoneme of retinal rods.

Axonemes were isolated from purified bovine retinal rod outer segments by dissolving the outer segment membranes in detergent and separating the axonemes by centrifugation on a linear detergent-containing sucrose density gradient. Guanylate cyclase (GTP pyrophosphate-lyase (cyclizing), EC 4.61.2) activity was concentrated in the axoneme fraction. Guanylate cyclase eluted in the void volume when detergent-solubilized rod outer segments were subjected to exclusion chromatography on Sepharose 4B. Attempts to extract guanylate cyclase from isolated axonemes with salt, EDTA, base and other reagents were successful.

A soluble factor and GTP gamma S are required for Dictyostelium discoideum guanylate cyclase activity.

Amoeba of Dictyostelium discoideum show a rapid, transient cGMP synthesis in response to chemotactic stimulation. Using Mg(2+)-GTP as a substrate, guanylate cyclase (E.C. 4.6.1.2.) activity is found exclusively in the particulate fraction of Dictyostelium cells. Here we show that the activity is dependent on the presence of the non-hydrolysable GTP-analogue GTP gamma S, which itself is only a poor substrate for the enzyme under the prevailing conditions. Evidence is presented that a transient exposure of the enzyme to GTP gamma S is sufficient to constitutively activate the enzyme. GTP gamma S-dependent activity is found to require a factor that can be separated from the enzyme by washing the particulate fraction with low salt buffer. Addition of the soluble cell fraction to these washed membranes restores enzyme activity.

Kinetic effects of the concentration-dependent stimulation of soluble guanylate cyclase from rat lung.

Soluble guanylate cyclase (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2) from rat lung demonstrated concentration-dependent stimulation, that is, an increase in specific activity with increasing enzyme (protein) concentration. This phenomenon persisted through several steps of enzyme purification and was apparently due to the presence of a macromolecular activator, similar in size to the enzyme. Treatment of partially purified enzyme with N-ethylmaleimide destroyed catalytic activity, but did not effect the ability of the preparation to stimulate activity. Kinetic analysis demonstrated that the stimulation was due to an increased V value with no change in the apparent Km value for MnGTP. Stimulation occurred without a time lag, the activator apparently interacting reversibly with the enzyme to increase catalytic capability. Some nonionic detergents of the Triton series inhibited enzyme activity by decreasing the V value, with no change in the Km value, and also decreased concentration-dependent stimulation. However, the two phenomena were not directly related. While the physiological significance of the activator is unclear, its presence affects estimations of recovery during enzyme purification, V determinations, and determinations of the effect of hormone or drug treatment on the activity of tissue extracts.

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.

Purification and properties of guanylate kinase from baker's yeast.

Guanylate kinase (ATP:(d)GMP phosphotransferase, EC 2.7.4.8) was purified about 200-fold with 4% yield from baker's yeast. The enzyme preparation showed a single band on polyacrylamide gel electrophoresis and the molecular weight of the enzyme was calculated to be 25 000 by gel filtration. With ATP as a phosphate donor, the kinase used only GMP as a phosphate acceptor. Km values for ATP and GMP were 0.5 and 0.048 mM, respectively. The enzyme reacted optimally at pH 7.5. The enzyme was labile during storage at 4 degrees C and inactivation was prevented by 20% glycerol.

Requirement for heme in the activation of purified guanylate cyclase by nitric oxide.

Guanylate cyclase activity was purified to apparent homogeneity from rat liver (7700-fold) and bovine lung (8600-fold) soluble fractions by ammonium sulfate precipitation, DEAE-cellulose chromatography, agarose gel filtration and isoelectric focussing. The purified enzymes did not contain heme and did not respond to NO, nitroprusside or NO-cysteine in the absence of exogenous hematin. By contrast, preformed NO-hemoglobin increased enzyme activity 10-12-fold or 60-80-fold when 4 mM MnCl2 or 4 mM MgCl2, respectively, were employed as the metal ion co-factor. Addition of hematin to the enzyme preparations restored responsiveness to NO, nitroprusside or NO-cysteine to levels seen with NO-hemoglobin. Partial purification of guanylate cyclase from the soluble fraction of bovine lung (2400-fold) by ammonium sulfate precipitation, DEAE-cellulose chromatography, agarose gel filtration and high pressure liquid chromatography (HPLC) resulted in a preparation which contained endogenous heme as indicated by absorbance at 436 nm and responded to NO, nitroprusside and NO-cysteine in the absence of added hematin. By contrast, guanylate cyclase purified from the hepatic supernatant by the identical procedure, did not contain detectable absorption due to heme and did not respond or responded poorly to NO, nitroprusside or NO-cysteine in the absence of exogenous hematin. Analogous to hepatic guanylate cyclase purified by isoelectric focussing, the HPLC purified hepatic enzyme was activated 14-fold by NO-hemoglobin in assays which contained 4 mM MnCl2 and 60-fold in assays with 4 mM MgCl2. Further, addition of hematin to the HPLC purified enzyme restored responsiveness to NO, nitroprusside and NO-cysteine to levels seen with NO-hemoglobin. These effects of hematin were specific for hematin and were not mimicked by albumin, sucrose or dithiothreitol. Moreover, the failure to observe stimulation of purified hepatic guanylate cyclase was not explained by a shift in the concentration response relationship between NO and guanylate cyclase activity. Several observations indicated that neither NO-thiol complexes nor [Fe(CN)5NO]-3 were the proximate moieties responsible for activation of guanylate cyclase by nitroprusside and related agents, as has been previously suggested. These results strongly support the proposal that activation of guanylate cyclase by NO and related agents specifically requires formation of an NO-heme complex.

Particulate guanylate cyclase of skeletal muscle: effects of Ca2+ and other divalent cations on enzyme activity.

The properties of particulate guanylate cyclase (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2) from purified rabbit skeletal muscle membrane fragments were studied. Four membrane fractions were prepared by sucrose gradient centrifugation and the fractions characterized by analysis of marker enzymes. Guanylate cyclase activity was highest in the fraction possessing enzymatic properties typical of sarcolemma, while fractions enriched with sarcoplasmic reticulum had lower activities. In the presence of suboptimal Mn2+ concentrations, Mg2+ stimulated particulate guanylate cyclase activity both before and after solubilization in 1% Triton X-100. Guanylate cyclase activity was biphasic in the presence of Ca2+. Increasing the Ca2+ concentration from 10(-8) to 10(-5) M decreased the specific activity. As the Ca2+ concentration was further increased to 5 . 10(-4) M enzyme activity again increased. After solubilization of the membranes in 1% Triton X-100, Ca2+ suppressed enzyme activity. Studies utilizing ionophore X537A indicated that the altered effect of Ca2+ upon the solubilized membranes was independent of asymmetric distribution of Ca2+ and Mg2+.

Separation of soluble adenylate and guanylate cyclases from the mature rat testis.

The mature rat testis contains both a soluble guanylate cyclase and a soluble adenylate cyclase. Both these soluble enzymes prefer manganous ion for activity. It is known that guanylate cyclase can, when activated by a variety of agents, catalyze the formation of cyclic AMP. The following experiments were performed to determine whether the testicular soluble adenylate and guanylate cyclase activities were carried on the same molecule. Analysis of supernatants from homogenized rat testis by gel filtration and sucrose density gradient centrifugation showed that the two activities were clearly separable. The molecular weight of guanylate cyclase is 143 000, while that of adenylate cyclase is 58 000. Treatment of the column fractions with 0.1 mM sodium nitroprusside allowed guanylate cyclase activity to be expressed with Mg(2+) as well as with Mn(2+). Sodium nitroprusside did not affect the metal ion or substrate specificity of adenylate cyclase. These experiments show that adenylate and guanylate cyclase activities are physically separable.

Production and properties of antibody to soluble guanylate cyclase purified from bovine brain.

Guanylate cyclase was purified 12,700-fold from bovine brain supernatant, and the purified enzyme exhibited essentially a single protein band on polyacrylamide gel electrophoresis. Repeated injection of the purified enzyme into rabbits produced an antibody to guanylate cyclase. The immunoglobulin G fraction from the immunized rabbit gave only one precipitin line against the purified guanylate cyclase and the crude supernatant of bovine brain on double immunodiffusion and immunoelectrophoreis. The antibody completely inhibited the soluble guanylate cyclase activity from bovine brain, various tissues of rat and mouse and neuroblastoma N1E 115 cells, whereas the Triton-dispersed particulate guanylate cyclase from these tissues was not inhibited by the antibody.

Purification of guanylyl cyclase from rod outer segments.

The particulate form of guanylyl cyclase from bovine rod outer segments has been solubilized and purified to near homogeneity by a combination of liquid chromatography and native gel electrophoresis. The procedure enriches enzyme activity 6700-fold from rod outer segment extracts to a final specific activity of 17.5 mumol/min per mg (when assayed with Mn-GTP as substrate). Purified preparations of guanylyl cyclase contain a single glycoprotein with an apparent molecular mass of 60,000 Da and a native isoelectric point of 7.6. Although crude or partially purified enzyme activity is modulated by sub-micromolar concentrations of Ca2+, the fully purified enzyme is insensitive to this cation. However, the purified enzyme remains sensitive to nitrovasodilators, being stimulated over 10-fold by sodium nitroprusside. These data suggest that retinal rods contain a unique isoform of guanylyl cyclase.

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.