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.     

Characterization of adenylate and guanylate cyclases in rat peritoneal mast cells

Adenylate and guanylate cyclase activities were confirmed in crude homogenates from rat peritoneal mast cells. Both enzyme activities were associated with the 105, 000 X g particulate fractions, but not detected in the supernatant fractions. The optimal pH for both cyclase activities was 8.2. Mn⁺⁺ was essentially required for guanylate cylcase activity, while adenylate cyclase activity was observed in the presence of either Mg⁺⁺ or Mn⁺⁺. The apparent Km values of adenylate cyclase for Mn⁺⁺-ATP and Mg⁺⁺-ATP were 160 μM and 340 μM, respectively, whereas the value of guanylate cyclase for Mn⁺⁺-GTP was 100 μM. Adenylate cyclase was activated by 10 mM NaF. However, both adenylate and guanylate cyclase activities were neither stimulated nor inhibited by the addition of various kinds of agents which stimulate or inhibit the release of histamine from mast cells.     

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.     

Enzymatic formation of inosine 3',5'-monophosphate and of 2'-deoxyguanosine 3',5'-monophosphate. Inosinate and deoxyguanylate cyclase activity.

Enzymes in particulate fractions from sea urchin sperm and in soluble fractions from rat lung were shown to catalyze the formation of inosine 3',5'-monophosphate (cyclic IMP) and of 2'-deoxyguanosine 3',5'-monophosphate (cyclic dGMP) from ITP and dGTP, respectively. With sea urchin sperm particulate fractions, Mn2+ was an essential metal cofactor for inosinate, deoxyguanylate, guanylate and adenylate cyclase activities. Heat-inactivation studies differentiated inosinate and deoxyguanylate cyclase activities from adenylate cyclase, but indicated an association of these activities with guanylate cyclase. Preincubation of sea urchin sperm particulate fractions with trypsin altered in a very similar manner guanylate, inosinate, and deoxyguanylate cyclase activities, and various metals and metal-nucleotide combinations protected the three cyclase activities to comparable degrees against trypsin. The relative guanylate, deoxyguanylate and inosinate cyclase activities at 0.1 mM nucleoside triphosphate were 1.0, 0.5 and 0.08, respectively. With these three cyclase activities, plots of reciprocal velocities against reciprocal Mn2+-nucleoside triphosphate concentrations were concave upward, suggesting positive homotropic effects. With rat lung soluble preparations, relative guanylate, deoxyguanylate, inosinate and adenylate cyclase activities at 0.09 mM nucleoside triphosphate were 1.0, 1.7, 0.1 and 0, respectively. MnGTP was a competitive inhibitor of deoxyguanylate cyclase activity (Ki equals 12.2 muM) and MndGTP was a competitive inhibitor of guanylate cyclase activity (Ki equals 16.2 muM). Inhibition studies using ITP were not conducted. When soluble fractions from rat lung were applied to Bio-Gel A 1.5 m columns, elution profiles of guanylate, deoxyguanylate and inosinate cyclase activities were similar. These results suggest that deoxyguanylate, guanylate and inosinate cyclase activities reside within the same protein molecule.     

Postmortem Stability of Dopamine-Sensitive Adenylate Cyclase, Guanylate Cyclase, ATPase, and GTPase in Rat Striatum

The stability of dopamine-sensitive adenylate cyclase, guanylate cyclase, ATPase, and GTPase was measured in homogenates of rat striatal tissue frozen from 0 to 24 h postmortem. ATPase, GTPase, and Mg2+-dependent guanylate cyclase activities showed no significant change over this period. Mn2+-dependent guanylate cyclase activity was stable for 10 h postmortem. Basal and dopamine-stimulated adenylate cyclase activity decreased markedly during the first 5 h. However, when measured in washed membrane preparations, these adenylate cyclase activities remained stable for at least 10 h. Therefore, the postmortem loss of a soluble activator, such as GTP, may decrease the adenylate cyclase activity in homogenates. These results are not consistent with an earlier suggestion that there is a postmortem degradation of the enzyme itself. Other kinetic parameters of dopamine-sensitive adenylate cyclase can also be measured independently of postmortem changes. Thus, it is possible to investigate kinetic parameters of dopamine-sensitive adenylate cyclase, guanylate cyclase, ATPase, and GTPase in human brain obtained postmortem.     

Calcium ion effects on guanylate cyclase of brain.

Soluble guanylate cyclase activity of brain is stimulated by Ca²⁺ in the presence of low concentrations of Mn²⁺. Unlike Ca²⁺ stimulation of adenylate cyclase, the effect does not depend upon interaction of guanylate cyclase with a specific high-affinity Ca²⁺-binding protein. In the presence of Mg²⁺, Ca²⁺ inhibits soluble guanylate cyclase as well as the particulate enzyme. The concept that stimulation of brain cells results in increased cyclic GMP concentration secondary to Ca²⁺ influx merits additional critical study.     

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.     

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.     

Particulate and soluble adenylate cyclase activities of mouse male germ cells

Germ cells from the mouse testis possess both a particulate and a soluble form of adenylate cyclase (EC 4.6.1.1). Germ cell adenylate cyclase activity is Mn⁺⁺ dependent and is not stimulable with either NaF or 5′guanylylimidodiphosphate. Both particulate and soluble adenylate cyclase specific activities increase as germ cells progress through their differentiative stages, but epididymal spermatozoa seem to lack a significant amount of soluble activity. Somatic cells of the seminiferous tubule possess only a membrane bound activity, which is Mg⁺⁺ and Mn⁺⁺ dependent, NaF and 5′guanylylimidodiphosphate stimulable. It is suggested that germ cell adenylate cyclases represent incomplete forms of the enzyme, devoid of regulative subunits.     

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.     

Adenosine 3',5'-monophosphate formation by preparations of rat liver soluble guanylate cyclase activated with nitric oxide, nitrosyl ferroheme, S-nitrosothiols, and other nitroso compounds

Cyclic AMP formation from ATP was stimulated by unpurified and partially purified soluble hepatic guanylate cyclase in the presence of nitric oxide (NO) or compounds containing a nitroso moiety such as nitroprusside, N-methyl-N-nitro-N-nitrosoguanidine (MNNG), nitrosyl ferroheme, and S-nitrosothiols. Cyclic AMP formation was undetectable in the absence of NO or nitroso compounds and was not stimulated by fluoride or glucagon, indicating the absence of adenylate cyclase activity. The nitroso compounds failed to activate, whereas fluoride or glucagon activated, adenylate cyclase in washed rat liver membrane fractions. Cyclic GMP formation from GTP was markedly stimulated by the soluble hepatic fraction in the presence of NO or nitroso compounds. Cyclic AMP formation by partially purified guanylate cyclase was competitively inhibited by GTP and cyclic GMP formation is well-known to be competitively inhibited by ATP. Therefore, it appears that activated guanylate cyclase, rather than adenylate cyclase, was responsible for the formation of cyclic AMP from ATP. Formation of cyclic AMP of cyclic GMP was enhanced by thiols, inhibited by hemoproteins and oxidants, and required the addition of either Mg2+ or Mn2+. Further, several nitrosyl ferroheme compounds and S-nitrosothiols stimulated the formation of both cyclic AMP and cyclic GMP by the soluble hepatic fraction. These observations support the view that soluble guanylate cyclase is capable, under certain well-defined conditions, of catalyzing the conversion of ATP to cyclic AMP.     

Molecular cloning and expression of cDNAs coding for soluble guanylate cyclase from rat lung.

Complementary DNA clones corresponding to the 70- and 82-kDa subunits of soluble guanylate cyclase of rat lung have been isolated. Blot hybridization of total poly(A)+ RNA from rat tissues detected mRNA of about 3.4 kilobases for the 70-kDa subunit and about 5.5 kilobases for the 82-kDa subunit. Messenger RNA levels of both subunits were abundant in lung and cerebrum, moderate in cerebellum, heart, and kidney, and low in liver and muscle, consistent with previously described enzyme activities in these tissues. Southern blot analysis of high molecular weight genomic DNA from rat liver indicated that the genes for the 70- and 82-kDa subunits are different. The carboxyl-terminal region of the 70- and 82-kDa subunits showed a high degree of homology and also had a partial homology with the putative catalytic domain of particulate guanylate cyclase and adenylate cyclase, indicating that both the 70- and 82-kDa subunits have catalytic domains. The cDNAs were subcloned to an expression vector and transfected to L cells. The cells transfected with cDNA of the 70-kDa subunit or the 82-kDa subunit showed no guanylate cyclase activity, whereas the cells transfected with both the 70- and 82-kDa subunit cDNAs showed significant guanylate cyclase activity that was activated markedly by sodium nitroprusside. These data suggest that both subunits are required for both the basal catalytic and regulatory activity of soluble guanylate cyclase. Presumably both catalytic subunits must be present and interactive to permit synthesis of cyclic GMP and nitrovasodilator activation.     

The involvement of catalytic site thiol groups in the activation of soluble guanylate cyclase by sodium nitroprusside

Sodium nitroprusside, a potent activator of soluble guanylate cyclase, potentiated mixed disulfide formation between cystine, a potent inhibitor of the cyclase, and enzyme purified from rat lung. Incubation of soluble guanylate cyclase with nitroprusside and [35S]cystine resulted in a twofold increase in protein-bound radioactivity compared to incubations in the absence of nitroprusside. Purified enzyme preincubated with nitroprusside and then gel filtered (activated enzyme) was activated 10- to 20-fold compared to guanylate cyclase preincubated in the absence of nitroprusside and similarly processed (nonactivated enzyme). This activation was completely reversed by subsequent incubation at 37 degrees C (activation-reversed enzyme). Incorporation of [35S]cystine into guanylate cyclase was increased twofold with activated enzyme, while no difference was observed with activation-reversed enzyme, compared to nonactivated enzyme. Cystine decreased the activity of nonactivated and activation-reversed enzyme about 40% while it completely inhibited activated guanylate cyclase. Mg+2- or Mn+2-GTP inhibited the incorporation of [35S]cystine into nonactivated or activated guanylate cyclase. Also, diamide, a potent thiol oxidant that converts juxtaposed sulfhydryls to disulfides, completely blocked incorporation of [35S]cystine into nonactivated or activated guanylate cyclase. These data indicate that activation of soluble guanylate cyclase by nitroprusside results in an increased availability of protein sulfhydryl groups for mixed disulfide formation with cystine. Protection against mixed disulfide formation with diamide or substrate suggests that these groups exist as two or more juxtaposed sulfhydryl groups at the active site or a site on the enzyme that regulates catalytic activity. Differential inhibition by mixed disulfide formation of nonactivated and activated enzyme suggests a mechanism for amplification of the on-off signal for soluble guanylate cyclase within cells.     

Phorbol myristate acetate stimulation of lymphocyte guanylate cyclase

Human lymphocyte guanylate cyclase activities are increased in a dose-dependent fashion by incubation of intact cells with phorbol myristate acetate, a tumor promoter and lymphocyte mitogen. Increased activity is detectable after 1 minute, and peak membrane-bound and soluble forms of guanylate cyclase occur after 10- and 30-minute exposure to phorbol myristate acetate, respectively. The soluble form is stimulated much more than the membrane form. Enzyme activities measured in the presence of either Ca²⁺, Mg²⁺, or Mn²⁺ are elevated to similar degrees. Comparisons of phorbol and a series of its diesters revealed a good correlation between the capacities for guanylate cyclase stimulation, lymphocyte mitogenesis, and tumor promotion.     

Localization of particulate guanylate cyclase in plasma membranes and microsomes of rat liver.

The subcellular localization of guanylate cyclase was examined in rat liver. About 80% of the enzyme activity of homogenates was found in the soluble fraction. Particulate guanylate cyclase was localized in plasma membranes and microsomes. Crude nuclear and microsomal fractions were applied to discontinuous sucrose gradients, and the resulting fractions were examined for guanylate cyclase, various enzyme markers of cell components, and electron microscopy. Purified plasma membrane fractions obtained from either preparation had the highest specific activity of guanylate cyclase, 30 to 80 pmol/min/mg of protein, and the recovery and relative specific activity of guanylate cyclase paralleled that of 5'-nucleotidase and adenylate cyclase in these fractions. Significant amounts of guanylate cyclase, adenylate cyclase, 5'-nucleotidase, and glucose-6-phosphatase were recovered in purified preparation of microsomes. We cannot exclude the presence of guanylate cyclase in other cell components such as Golgi. The electron microscopic studies of fractions supported the biochemical studies with enzyme markers. Soluble guanylate cyclase had typical Michaelis-Menten kinetics with respect to GTP and had an apparent Km for GTP of 35 muM. Ca-2+ stimulated the soluble activity in the presence of low concentrations of Mn-2+. The properties of guanylate cyclase in plasma membranes and microsomes were similar except that Ca-2+ inhibited the activity associated with plasma membranes and had no effect on that of microsomes. Both particulate enzymes were allosteric in nature; double reciprocal plots of velocity versus GTP were not linear, and Hill coefficients for preparations of plasma membranes and microsomes were calculated to be 1.60 and 1.58, respectively. The soluble and particulate enzymes were inhibited by ATP, and inhibition of the soluble enzyme was slightly greater. While Mg-2+ was less effective than Mn-2+ as a sole cation, all enzyme fractions were markedly stimulated with Mg-2+ in the presence of a low concentration of Mn-2+. Triton X-100 increased the activity of particulate fractions about 3- to 10-fold and increased the soluble activity 50 to 100%.     

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.     

Activation of the renal cortical and hepatic guanylate cyclase-guanosine 3′,5′-monophosphate systems by nitrosoureas divalent cation requirements and relationship to thiol reactivity

Streptozotocin, 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) and N-methyl nitrosourea, compounds with both oncogenic and cytotoxic properties, increased guanylate cyclase activity in the 100 000 × g soluble fractions of rat renal cortex and liver 35- to 65-fold over basal values. Particulate enzyme activities of these tissues were increased 2- to 4-fold by a maximally effective concentration of the nitrosoureas. In the presence of the cyclic nucleotide phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine, maximally effective concentrations of these nitrosoureas increased cyclic GMP accumulation of hepatic and renal cortical slices to peak levels 7- to 10-fold over control in 30 min. By contrast, with the structurally related carcinogen N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) peak increases occurred in 5–10 min and were 40- to 70-fold over control levels in renal cortex and liver, respectively. Unlike the Ca²⁺-dependent actions of cholinergic stimuli on cyclic GMP, the nitrosoureas and MNNG increased cyclic GMP in either the presence or absence of extracellular Ca²⁺. Moreover, while basal soluble guanylate cyclase of renal cortex was highly Mn²⁺-dependent and decreased 85% when either Mg²⁺ or Ca²⁺ was employed as sole divalent cation in reaction mixtures, the actions of nitrosoureas on enzyme activity were well expressed with either Mn²⁺ or Mg²⁺, but not with Ca²⁺, as sole divalent cation. Improved utilization of Mg²⁺ by guanylate cyclase in the presence of nitrosoureas would favor enhanced enzyme activity under cellular conditions where Mg²⁺ is abundant. In the presence of maximally stimulatory concentrations of streptozotocin or BCNU, high concentrations of Mg²⁺ or Mn²⁺ further increased soluble guanylate cyclase, suggesting important differences in metal and nitrosourea stimulation of enzyme activity.Preincubation of supernatant fractions with nitrosoureas plus dithiothreitol inhibited the action of the N-nitroso compounds to increase renal cortical guanylate cyclase. Glutathione and cysteine were also inhibitory, but less effective than dithiothreitol. Initial incubation of nitrosoureas with dithiothreitol in buffer alone similarly suppressed the subsequent action of the N-nitroso compounds on guanylate cyclase, and implicated direct chemical interactions. Prior incubation of renal cortical supernatant fractions with the SH blockers N-ethylmaleimide or maleimide significantly suppressed guanylate cyclase activation mediated by streptozotocin or BCNU. Direct drug interactions seemed unlikely, since effects of the inhibitors were optimally expressed by initial exposure of the supernatant fraction of tissue to the SH blockers and were not potentiated by a 30 min preincubation of the SH blockers and nitrosoureas in buffer alone.Thus, nitrosoureas activate and alter the metal requirements of soluble guanylate cyclase and increase cellular cyclic GMP in the presence or absence of extracellular Ca²⁺. Activation of soluble guanylate cyclase by nitrosoureas may involve an interaction of these agents with tissue SH groups, and possibly SH to SS transformation. Stimulation of the guanylate cyclase system by nitrosoureas could be related to the oncogenic actions of these agents.     

Role of heme in the regulation of human and rat platelet soluble guanylate cyclases.

The chromatography of soluble human and rat platelet guanylate cyclases (105000 g supernatants) on DEAE-cellulose in 50 mM Tris HCl buffer, containing 0.22 M NaCl, has yielded virtually identical elution profiles, each with two protein peaks (I and II). Only peak II was found to have guanylate cyclase activity. Experiments with human platelets showed that inactive protein peak I inhibited the activity of guanylate cyclase preparation (peak II) and restored the already lost ability of the enzyme to be activated by sodium nitroprusside. In experiments with rat platelets, inactive fraction I had no effect on guanylate cyclase activity (peak II), and the enzyme was not activated by sodium nitroprusside either before or after DEAE-cellulose. 105000g supernatant of human platelets had an absorbance maximum at 415 nm (Soret band), which disappeared from the spectrum of the active fraction (II) but was found in the spectrum of the inactive (inhibitory) fraction I. Experiments with rat platelets demonstrated the absence of Soret band in the corresponding spectra. It was concluded that, contrary to the generally accepted notion, heme is not a prosthetic group of the soluble rat platelet guanylate cyclase.     

Guanylate cyclase. Subcellular distribution in cardiac muscle, skeletal muscle, cerebral cortex and liver.

1. Guanylate cyclase of every fraction studied showed an absolute requirement for Mn2+ ions for optimal activity; with Mg2+ or Ca2+ reaction was barely detectable. Triton X-100 stimulated the particulate enzyme much more than the supernatant enzyme and solubilized the particulate-enzyme activity. 2. Substantial amounts of guanylate cyclase were recovered with the washed particulate fractions of cardiac muscle (63-98%), skeletal muscle (77-93%), cerebral cortex (62-88%) and liver (60-75%) of various species. The supernatants of these tissues contained 7-38% of total activities. In frog heart, the bulk of guanylate cyclase was present in the supernatant fluid. 3. Plasma-membrane fractions contained 26, 21, 22 and 40% respectively of the total homogenate guanylate cyclase activities present in skeletal muscle (rabbit), cardiac muscle (guinea pig), liver (rat) and cerebral cortex (rat). In each case, the specific activity of this enzyme in plasma membranes showed a five- to ten-fold enrichment when compared with homogenate specific activity. 4. These results suggest that guanylate cyclase, like adenylate cyclase, and ouabain-sensitive Na+ + K+-dependent ATPase (adenosine triphosphatase), is associated with the surface membranes of cardiac muscle, skeletal muscle, liver and cerebral cortex; however, considerable activities are also present in the supernatant fractions of these tissues which contain very little adenylate cyclase or ouabain-sensitive Na+ + K+-dependent ATPase activities.     

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

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