Purification and characterization of particulate guanylate cyclase from sea urchin spermatozoa

The particulate form of guanylate cyclase from sea urchin spermatozoa was purified to apparent homogeneity by chromatography on GTP-Sepharose and DEAE-Sepharose and by preparative gel electrophoresis. The sedimentation coefficient (S20,w) was 6.8 and the Stokes radius was 5.1 nm, from which a native molecular weight of 157,000 was calculated. A single protein or periodic acid-Schiff staining band of 135,000 Da was observed after Na dodecyl SO4 gel electrophoresis. Antibody was produced to guanylate cyclase and was shown by electrophoretic transfer experiments (Western blot) to interact with only the Mr = 135,000 band in cases where all of the detergent-extracted protein from spermatozoa was added to the Na dodecyl SO4 gels. Although guanylate cyclase was normally bound to concanavalin A-Sepharose, after endoglycosidase H treatment it failed to bind. Treatment of the enzyme with endoglycosidase H did not alter guanylate cyclase activity, but the apparent size of the enzyme decreased to 72,000 Da on Na dodecyl SO4 gels. An analysis of carbohydrate composition indicated that the oligosaccharides contained N-acetylglucosamine, mannose, galactose, and 2-aminoerythritol in molar ratios (1:3:0.75:2); after endoglycosidase H treatment the enzyme contained essentially no carbohydrate. Major amino acids in the enzyme were aspartic (Asn) and glutamic (Gln) which accounted for approximately 25 mol % of the enzyme amino acid composition. The purified enzyme displayed linear kinetics on double reciprocal plots and had a KMnGTP = 133 microM, KM2+ = 138 microM, KiMnGTP = 122 microM, KiMn2+ = 127 microM, and a V max in excess of 15 mumol of cyclic GMP formed/min/mg of protein at 30 degrees C. Sodium nitroprusside did not stimulate the enzyme in either the presence or absence of added hemeproteins. These results indicate that the particulate form of guanylate cyclase from sea urchin spermatozoa is a glycoprotein which is distinctly different than the soluble form of the enzyme found in mammalian tissues.     

Soluble adenylate cyclase activity in Neurospora crassa.

A soluble form of adenylate cyclase was extracted from mycelia of Neurospora crassa wild-type strains. This enzyme activity was purified by chromatography on hexyl-amino-Sepharose, agarose and Blue Sepharose and preparative polyacrylamide-gel electrophoresis. On sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, peak fractions from the later purification steps showed a main polypeptide band with an apparent molecular weight of about 66 000. The following hydrodynamic and molecular parameters were established for the Neurospora soluble adenylate cyclase activity: sedimentation coefficient, 6.25 S; Stokes radius, 7.3 nm; partial specific volume, 0.74 ml/g; molecular weight, 202 000; frictional ratio, 1.65. The isoelectric point of this enzyme activity was 4.65. The enzyme was not activated by GTP, [beta gamma-imido]GTP, fluoride or cholera toxin.     

The size of adenylate cyclase and guanylate cyclase from the rat renal medulla

The size distribution of adenylate cyclase from the rate renal medulla solubilized with the nonionic detergents Triton X-100 and Lubrol PX was determined by gel filtration and by centrifugation in sucrose density gradients made up in H₂O or D₂O. The physical parameters of the predominant from in Triton X-100 are ²20,w, 5.9 S; Stokes radius, 62 A; partial specific volume (v ), 0.74 ml/g; mass, 159,000 daltons; f/f₀, 1.6; axial ratio (prolate ellipsoid), 11. For the minor form the values are : ²20,w, 3.0; Stokes radius, 28 A; mass, 38,000 daltons; f/f₀, 1.2. The corresponding values determined in Lubrol PX are similar. The value of v for the enzyme indicates that it binds less than 0.2 mg detergent/mg protein. Since interactions with detergents probably substitute for interactions with lipids and hydrophobic amino acid side chains, these findings suggest that no more than 5% of the surface of adenylate cyclase is involved in hydrophobic interactions with other membrance components. Thus, most of the mass of the enzyme is not deeply embedded in the lipid bilayer of the plasma membrance. Similar studies have been performed on the soluble guanylate cyclase of the rate renal medulla. In the absence of detergent, the molecular properties of this enzyme are: ^s20,w, 6.3 S; Stokes radius, 54 A, v , 0.75 ml/g; mass, 154,000 daltons f/f₀, 1.4; axial ratio, 7. The addition of 0.1% Lubrol PX to this soluble enzyme increases its activity two- to fourfold and changes the physical properties to : ^s20,w, 5.5 S; Stokes radius, 62 A; v , 0.74 ml/g; mass, 148,000 daltons; f/f₀, 1.6; axial ratio, 11. These results show that Lubrol PX activates the enzyme by causing a conformational change with unfolding on the polypeptide chain. Guanylate cyclase from the particulate cell fraction can be solubilized with Lubrol PX but has properties quite different from those of the enzyme in the soluble cell fraction. It is a heterogeneous aggregrate with ^s20,w, 10 S; Stokes radius, 65 A; mass about 300,000 daltons. The conditions which solubilize guanylate cyclase also solubilize adenylate cyclase and the two activities can be separated on the same sucrose gradient.     

The guanylate cyclase/receptor family of proteins

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

Guanylate cyclase from the rat renal medulla. Physical properties and comparison with adenylate cyclase.

Guanylate cyclase from the rat renal medulla is found in both the soluble and particulate fractions of the cell. Sucrose density gradient centrifugation and gel filtration in H2O and D2O indicate that the enzyme from the soluble cell fraction has the following properties: S20w, 6.3 S; Stokes radius, 54 A; partial specific volume, 0.75 ml/g; mass, 154,000 daltons; f/fo, 1.4; axial ratio (prolate ellipsoid), 7. The addition of 0.1% Lubrol PX to this fraction activates the enzyme and changes thartial specific volume, 0.74 ml/g; mass, 148,000 daltons; f/fo, 1.6; axial ratio (prolate ellipsoid), 11. These findings show that detergent activates the enzyme by changing its conformation and not simply by dispersing nonsedimentable membrane fragments. The dimensions of this guanylate cyclase in detergent are very similar to those of detergent-solubilized adenylate cyclase from the same tissue (Neer, E.J. (1974) J. Biol. Chem. 249, 6527-6531). Guanylate cyclase can be solubilized from the particulate cell fraction with 1% Lubrol PX but has properties quite different from those of the guanylate cyclase in the soluble cell fraction. It is a large aggregate with a value of S20,w of about 10 S, Stokes radius of 65 A, and a mass of approximately 300,000 daltons. However, the peaks of guanylate cyclase activity in column effluents and sucrose density gradients are very broad indicating a mixture of different size proteins. The conditions used to solubilize guanylate cyclase from the particulate fraction also solubilize adenylate cyclase, and the two activities can be separated on the same sucrose gradient. Studies of this sort require a rapid, accurate guanylate cyclase assay. We have developed an assay for guanylate cyclase activity which meets these criteria by adapting the competitive protein binding assay for guanosine cyclic 3':5' monophosphate originally described by Murad et al. (Murad, F., Manganiello, V., and Vaughn, M. (1971) Proc. Natl. Acad. Sci. U.S.A. 68, 736-739).     

Soluble guanylate cyclase from rat lung exists as a heterodimer

The soluble form of guanylate cyclase (EC 4.6.1.2) from rat lung has been purified to homogeneity by a one-step immunoaffinity chromatographic procedure. The purified soluble guanylate cyclase has specific activities of 432 and 49.1 nmol of cyclic GMP formed per min/mg protein with manganese and magnesium ions as a cofactor, respectively. This represents a purification of approximately 2,000-fold with a 50% recovery. The native enzyme has a molecular weight of 150,000 and a Stokes radius of 4.8 nm as determined on Spherogel TSK-G3000SW gel permeation chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis results in two protein-staining bands with molecular weights of 82,000 and 70,000. The purified soluble guanylate cyclase was also subjected to native polyacrylamide gel electrophoresis, isoelectric focusing electrophoresis, ion exchange chromatography, and GTP-agarose affinity chromatography. These additional purification procedures confirmed the presence of a single protein peak coincident with enzyme activity. The two subunits separated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis were shown to have different primary structures by immunoblotting with monoclonal and polyclonal antibodies prepared against purified soluble guanylate cyclase and by peptide mapping with papain or Staphylococcus aureus V8 protease treatment. These data demonstrate that soluble guanylate cyclase purified from rat lung is a heterodimer composed of 82,000- and 70,000-dalton subunits with different primary structures.     

Sea urchin sperm guanylate cyclase antibody. Cross-reactivity various rat tissue guanylate cyclases.

After the repeated injection of sea urchin sperm guanylate cyclase into rabbits, antibodies to the enzyme were formed. These antibodies inhibited the particulate or the Triton-dispersed forms of the sperm enzyme by greater than 97%. The sperm adenylate cyclase, cyclic GMP phosphodiesterase, adenosine triphosphatase, guanosine triphosphatase, and 5'-nucleotidase enzymes were not affected by the antiserum. The antiserum inhibited the Triton-dispersed guanylate cyclase from rat heart, liver, lung, spleen, and kidney but did not inhibit the soluble form of the enzyme from any of these tissues. The inhibition of the Triton-dispersed enzyme in these tissues was partial, however, ranging from 30% (liver) to 70% (heart). These results provide evidence that adenylate cyclase is antigenically different from guanylate cyclase, and that the soluble form of guanylate cyclase is antigenically different from a particulate form of the enzyme in various rat tissues.     

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 guanylate cyclase in cerebral cortex of rat by hydroxylamine.

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

Comparison of particulate guanylate cyclase in cells with and without atrial natriuretic peptide receptor binding activity

Summary A line of kidney cells (PK,) which does not possess measurable ANP binding but has an active particulate guanylate cyclase has been identified. The physical characteristics of this enzyme were compared with those of particulate guanylate cyclase and ANP receptors isolated from rat lung. Although receptor and enzyme appear to reside on the same protein in the lung while the cyclase from PK₁ cells does not possess ANP binding activity, these proteins exhibit identical physical characteristics. Guanylate cyclase from PK₁ cells and rat lung and ANP receptor from lung co-eluted during gel filtration chromatography, with a Stokes radius of 6.1 nm. Also, these activities co-migrated through sucrose density gradients with S_20,w values of 10.4 to 10.9. Using these parameters, a molecular weight of about 270 kD was estimated for all three activities. Furthermore, these enzyme activities exhibited similar mobilities in isoelectric focusing gels, with a pI of 6.1. Thus, although particulate guanylate cyclase from lung presumably possesses receptor binding activity, it is physically identical to a form of this enzyme associated with no measurable binding activity. Possible explanations for these observations are discussed.     

Purified guanylate cyclase: characterization, iodination and preparation of monoclonal antibodies

Guanylate cyclase was purified from the soluble fraction of rat lung using a modification of procedures published previously. The purified enzyme exhibited specific activities, at pH 7.6, of 219-438 nmoles/mg protein/min and 34-60 nmoles/mg protein/min with Mn2+ and Mg2+ as cation cofactors, respectively. The specific activity changed as a function of the protein concentration due to a change in Vmax with no alteration of the Km for GTP. The enzyme migrated as a single band coincident wih guanylate cyclase activity on nondenaturing polyacrylamide and isoelectric focusing gels (isoelectric point = 5.9). Purified guanylate cyclase had an apparent molecular weight of 150,000 daltons as determined by gel filtration chromatography and polyacrylamide gel electrophoresis. Electrophoresis in the presence of sodium dodecyl sulfate revealed a single subunit of 72,000 daltons, suggesting that the enzyme is a dimer of an identical subunit. The purified enzyme could be activated by nitric oxide, indicating that this compound interacts directly with the enzyme.     

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%.     

Purification and properties of guanylate cyclase from the synaptosomal soluble fraction of rat brain.

Guanylate cyclase (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2) was purified 2250-fold from the synaptosomal soluble fraction of rat brain. The specific activity of the purified enzyme reached 41 nmol cyclic GMP formed per min per mg protein at 37 degrees C. In the purified preparation, GTPase activity was not detected and cyclic GMP phosphodiesterase activity was less than 4% of guanylate cyclase activity. The molecular weight was approx. 480 000. Lubrol PX, hydroxylamine, or NaN3 activated the guanylate cyclase in crude preparations, but had no effect on the purified enzyme. In contrast, NaN3 plus catalase, N-methyl-N'-nitro-N-nitrosoguanidine or sodium nitroprusside activated the purified enzyme. The purified enzyme required Mn2+ for its activity; the maximum activity was observed at 3-5 mM. Cyclic GMP activated guanylate cyclase activity 1.4-fold at 2 mM, whereas inorganic pyrophosphate inhibited it by about 50% at 0.2 mM. Guanylyl-(beta,gamma-methylene)-diphosphonate and guanylyl-imidodiphosphate, analogues of GTP, served as substrates of guanylate cyclase in the purified enzyme preparation. NaN3 plus catalase or N-methyl-N'-nitro-N-nitrosoguanidine also remarkably activated guanylate cyclase activity when the analogues of GTP were used as substrates.     

Purification of soluble guanylate cyclase from rat lung.

The soluble form of guanylate cyclase from rat lung has been purified approximately 23,000-fold to homogeneity by isoelectric precipitation, GTP-Sepharose chromatography, and preparative gel electrophoresis. A single protein-staining band is observed after analytical gel electrophoresis on either 4 or 7.5% polyacrylamide gels. The final purified enzyme has a specific activity of about 700 nmol of cyclic GMP formed/min/mg of protein at 37 degrees C in the presence of 4.8 mM MnCl2 and 100 micrometer GTP. Bovine serum albumin appears to slightly increase guanylate cyclase activity, but mainly stabilizes the purified enzyme; in its presence, specific activities in excess of 1 mumol of cyclic GMP formed/min/mg of enzyme protein can be obtained. When Mg2+ or Ca2+ are substituted for Mn2+, specific activities decrease to approximately 21 and 40 nmol of cyclic GMP formed/min/mg of protein, respectively. The apparent Michaelis constant for MnGTP in the presence of 4.8 mM MnCl2 is 10.2 micrometer. Kinetic patterns on double reciprocal plots as a function of free Mn2+ are concave downward. The native enzyme has a molecular weight of approximately 151,000 as determined on Sephacryl S-200; sodium dodecyl sulfate-polyacrylamide gel electrophoresis results in two protein-staining bands with approximate molecular weights of 79,400 and 74,000. Thus, it appears that the soluble form of guanylate cyclase from rat lung exists as a dimer.     

Characterization of particulate and soluble guanylate cyclases from rat lung.

Rat lung homogenates contained significant amounts of guanylate cyclase activity in both 100,000 times g (60 min) particulate and supernatant fractions. In the presence of detergent, the particulate fraction contained 40% as much activity as did the supernatant fraction. Detergent-dispersed particulate and partially purified soluble guanylate cyclase preparations were characterized with respect to divalent cation requirements, divalent cation interactions, kinetic behavior, and gel filtration profiles. Both soluble and particulate guanylate cyclases required divalent cation for activity. The soluble preparation was 10 times more active in the presence of Mn-2plus than in the presence of Mg-2plus or Ca-2plus and no detectable activity was seen with Ba-2plus or Sr-2plus. Particulate guanylate cyclase activity was detectable only in the presence of Mn-2plus. Both enzyme preparations required Mn-2plus in excess of GTP for optimal activity at subsaturating amounts of GTP. At near-saturating GTP, the soluble enzyme required excess Mn-2plus, but the particulate enzyme did not. For kinetic analyses the enzymes were considered to require two substrates: metal-GTP and Me-2plus. Apparent negative cooperative behavior was seen with the soluble enzyme when excess Mn-2plus (in excess of GTP) was varied from 0.01 to 0.2 mM; above 0.2 mM excess Mn-2plus classical kinetic behavior was seen with an apparent KMn-2plus of 0.2 mM at near-saturating MnGTP. Similar studies using the particulate preparation yielded only classical kinetic behavior, but the apparent KMn-2plus decreased to near zero when MnGTP was near-saturating. Kinetic patterns for the particulate and soluble enzymes also differed when reciprocal initial velocities were plotted as a function of reciprocal MnGTP concentrations; classical kinetic behavior was seen with the soluble enzyme with an apparent KMnGTP of about 12 muM (at near-saturating excess Mn-2plus), whereas apparent positive cooperative behavior was seen with the particulate preparation (Hill coefficient equals 1.6, S0.5 EQUALS 70 MUM. Ca-2plus "activation" of soluble guanylate cyclase was related to the Mn-2plus:GTP ratio. Activation was most apparent when saturating amounts of Mn-2plus and MnGTP. At relatively high concentrations of Ca-2plus (0.1 to 4 mM), the addition of 10 muM Mn-2plus resulted in a 3- to 5-fold increase in soluble guanylate cyclase activity. In contrast, Ca-2plus sharply inhibited particulate guanylate cyclase activity. Gel filtration profiles of particulate and soluble preparations indicated differences in physical properties of the enzymes. As estimated by gel filtration, particulate (detergent-dispersed)evels. Here, removal of renal tissue is contraindicated. In all renal hy     

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.     

Myocardial guanylate cyclase: properties of the enzyme and effects of cholinergic agonists in vitro.

The characteristics of myocardial guanylate cyclase (GTP pyrophosphatelyase, EC 4.6.1.2) were studied. Specific activity of the myocardial enzyme in five vertebrate species was guinea pig greater than man greater than cat greater than dog greater than rat. In the guinea pig, guanylate cyclase activity was uniformly distributed throughout the anatomical regions of the heart. The major portion of the enzyme activity was retrieved in the supernatant fraction after centrifugation at 12 000 times g. The Km for GTP was similar in supernatant (0.12 mM) and particulate (0.21 mM) preparations, although the Ka for Mn2+ in particulate preparations (0.3-0.6 mM) was less than that observed for guanylate cyclase in the supernatant fraction (0.8-2.0 mM). ATP competitively inhibited supernatant and particulate activity. Addition of 0.005-10.0 mM Ca2+ to assay incubations did not enhance guanylate cyclase activity. Suspension of 105 000 times g supernatant guanylate cyclase preparations with membrane lipids or phosphatidylserine stimulated activity 1.4-4.3 fold, whereas similar treatment of particulate preparations caused little alteration of enzyme activity. Addition of the cholinergic agonists acetylcholine, carbachol or methacholine (10-4-10-8 M) to homogenate, supernatant, particulate and disrupted tissue slice preparations in the presence of 0.0012-1.2 mM GTP, 0.3-10.0 mM Mn2+ and 0.005-10.0 mM Ca2+ or 0.0012-1.2 mM ATP did not stimulate guanylate cyclase activity. Similarly, further stimulation of guanylate cyclase activity was not elicited when enzyme-lipid suspensions were assayed in the presence of cholinergic agents.     

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.     

Renal cortex guanylate cyclase. Preferential enrichment in glomerular membranes.

1. The localisation and some of the properties of rabbit kidney cortex guanylate cyclase (GTP pyrophosphatase lyase (cyclizing) EC 4.6.1.2) have been studied. Upon fractionation of dissociated renal cortex, guanylate cyclase activity was preferentially enriched in fractions of pure glomeruli, where its specific activity was 44.5 times that measured in tubular fragments. Most, if not all, of the glomerular activity was found to be firmly membrane-bound, whereas the guanylate cyclase activity of the tubules was mainly soluble. Therefore, particulate guanylate cyclase activity could serve as marker enzyme for kidney glomeruli. 2. All hormones or hormone-like agents tested were without effect on kidney guanylate cyclase activity. Triton X-100 stimulated both glomerular and tubular activity. 3. Considering the high cyclic GMP forming capacity of kidney glomeruli, part of the cyclic GMP found in urine might be synthetized locally in these structures.     

Characterization of rat testicular guanylate cyclase during development

The biochemical characteristics of rat testicular guanylate cyclase were investigated and the activity and subcellular distribution of the enzyme was determined during testicular development. Examination of the effects of metal ions, nucleotides, detergents and other in vitro activators on the activity of guanylate cyclase revealed that the testicular enzyme is similar in most respects to guanylate cyclase isolated from other mammalian tissues. Changes in the total activity of guanylate cyclase during testicular development paralleled changes in the tissue concentration of cyclic GMP; i.e. guanylate cyclase activity and tissue cyclic GMP were highest during the early stages of development. Subcellular fractionation revealed that the activity of the soluble form of guanylate cyclase was best correlated with tissue cyclic GMP. Bichemical analysis of the soluble enzyme prepared from testes of neonatal and adult rats did not reveal any significant differences in the characteristics of the enzyme during ontogeny with the exception of a 2.5 fold increase in V noted in the neonatal testis. The results of this study are consistent with a molecular mechanism that allows independent regulation of the different forms of guanylate cyclase.