Effects of cations on guanylate cyclase of sea urchin sperm.

Mn2+ and to some degree Fe2+, but not Mg+, Ca2+, ba2+, Sr2+, Co2+, Ni2+, La3+, or Fe3+ were able to serve as effective metal cofactors for sea urchin sperm guanylate cyclase. The apparent Michaelis constant for Mn2+ in the presence of 0.25 mM MnGTP was 0.23 mM. In the presence of a fixed free mn2+ concentration, variation in mngTP resulted in sigmoid velocity-substrate plots and in reciprocal plots that were concave upward. These positive cooperative patterns were observed at both pH 7.0 and 7.8 and in the presence or absence of Triton X-100. When Mn2+ and GTP were equimolar, Ca2+, Ba2+, Sr2+, and Mg2+ increased apparent guanylate cyclase activity. This increase in enzyme activity at least could be accounted for partially by an increase in free Mn2+ concentration caused by the complex formation of GTP with the added metals. However, even at relatively low GTP concentrations and with Mn2+ concentrations in excess of GTP, Ca2+, Sr2+, and Ba2+ significantly increased guanosine 3':5'-monophosphate production. As the total GTP concentration was increased, the degree of stimulation in the presence of Ca2+ decreased, despite maintenance of a fixed total concentration of Ca2+ and a fixed free concentration of Mn2+, suggesting that the concentration of CaGTP and MnGTP were determining factors in the observed response. The concave upward reciprocal plots of velocity against MnGTP concentration were changed to linear plots in the presence of CaGTP or SrGTP. These results suggest that sea urchin sperm guanylate cyclase contains multiple nucleotide binding sites and that stimulation of guanosine 3':5'-monophosphate synthesis by Ca2+, Sr2+, and perhaps other metals may reflect interaction of a metal-GTP complex with enzyme as either an effector or a substrate.     

Interactions of divalent cations and nucleotides with solubilized cardiac guanylate cyclase.

Some properties of guanylate cyclase, which was solubilized from the rabbit heart washed particles by the treatment with Triton X-100, were investigated. The solubilized enzyme activity was stimulated by Mg2+ in the presence of low (subsaturating) Mn2+ (GTP is greater than Mn2+); under these conditions, Ga2+ was inhibitory. At subsaturating MnGTP and free Mn2+, the solubilized enzyme was markedly stimulated by MnGDP and MnATP; CaGTP on the other hand, was inhibitory. These results are consistent with the view that the particulate guanylate cyclase may exist in the cell as a metalloenzyme with tightly bound Mn2+ and that Mg2+ supports its catalysis while Ca2+ as well as nucleotides may exert regulatory effects on its activity.     

Regulation of synthesis of guanosine 3'':5''-cyclic monophosphate in neuroblastoma cells.

The increase in intracellular cyclic GMP concentrations in response to muscarinic-receptor activation in N1E-115 neuroblastoma cells is dependent on extracellular Ca2+ ion. The calcium ionophore A23187 can also evoke an increase in cyclic GMP in the presence of Ca2+ ion. Most (about 85%) of the guanylate cyclase activity of broken-cell preparations is found in the soluble fraction. The soluble enzyme can utilize MnGTP (Km = 55 micrometer), MgGTP (Km = 310 micrometer) and CaGTP (Km greater than 500 micrometer) as substrates. Free GTP is a strong competitive inhibitor (Ki approximately 20 micrometer). The enzyme possesses an allosteric binding site for free metal ions (Ca2+, Mg2+ and Mn2+). The membrane-bound guanylate cyclase is qualitatively similar to the soluble form, but has lower affinity for the metal-GTP substrates. Entry of Ca2+ into cells may increase cyclic GMP concentration by activating guanylate cyclase through an indirect mechanism.     

Properties of particulate, membrane-associated and soluble guanylate cyclase from cardiac muscle, skeletal muscle, cerebral cortex and liver.

1. Guanylate cyclase of washed particles and plasma membranes showed S-shaped progress curves when titrated with either GTP or Mn2+ ions; similar results were obtained with Triton X-100-solubilized enzyme preparation from washed particles. Hill plots of these data revealed multiple metal-nucleotide and free-metal binding sites. 2. Guanylate cyclase of supernatant fractions displayed typical Michaelis-Menten properties when enzyme required excess of (free) Mn2+ (over GTP) for maximal activities; Ka (free Mn2+) was about 0.15-0.25 mM at subsaturating concentrations of GTP. 4 MnATP, MnADP, and MnGDP were found to increase the activities of both particulate and superantant enzyme, when MnGTP concentration was below saturation and free Mn2+ ion concentration was low (less than 100 muM); MnATP (50muM-1 mM) inhibited both these activities at high free Mn2+ concentration (1.5 mM) and inhibition of the particulate enzyme was greater than that of supernatant enzyme. 5. Ca2+ ions stimulated supernatant-enzyme activity; the stimulatory concentration of Ca2+ ions depended on the concentration of Mn2+ and GTP. 6. A modest stimulation of particulate guanylate cyclase by pyrophosphate (0.02-1 mM) was observed; the pyrophosphate effect appeared to be competitive with respect to GTP. At a higher concentration (2 mM), pyrophosphate produced a marked inhibition of particulate enzyme; the nature of inhibitory effect appeared complex. 7. Inorganic salts (e.g. NaCl, KCl, LiBr, NaF) produced inhibition of particulate enzyme; the degree of inhibition of Triton X-100-stimulated activity was less than that of unstimulated activity. 9. Treatment of sarcolemmal or microsomal membranes with either phospholipase C or trypsin decreased, whereas phospholipase A increased, the activity of guanylate cyclase.     

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.     

Guanylate cyclase of isolated bovine retinal rod axonemes.

The guanylate cyclase activity of axoneme--basal apparatus complexes isolated from bovine retinal rods has been investigated. The Mg2+ and Mn2+ complexes of GTP4- serve as substrates. Binding of an additional mole of Mg2+ or Mn2+ per mole of enzyme is required. Among cations which are ineffective are Ca2+, Ni2+, Fe2+, Fe3+, Zn2+, and Co2+. The kinetics are consistent with a mechanism in which binding of Mg2+ or Mn2+ to the enzyme must precede binding of MgGTP or MnGTP. The apparent dissociation constants of the Mg--enzyme complex and the Mn--enzyme complex are 9.5 x 10(-4) and 1.1 x 10(-4) M, respectively. The apparent dissociation constants for binding of MgGTP and MnGTP to the complex of the enzyme with the same metal are 7.9 x 10(-4) and 1.4 x 10(-4) M, respectively. The cyclase activity is maximal and independent of pH between pH 7 and 9. KCl and NaCl are stimulatory, especially at suboptimal concentrations of Mg2+ or Mn2+. Ca2+ and high concentrations of Mg2+ and Mn2+ are inhibitory. Ca2+ inhibition appears to require the binding of 2 mol of Ca2+ per mol of enzyme. The dissociation constant of the Ca2--enzyme complex is estimated to be 1.4 x 10(-6) M2. The axoneme--basal apparatus preparations contain adenylate cyclase activity whose magnitude is 1--10% that of the guanylate cyclase activity.     

Immobilization of rat lung soluble guanylate cyclase on alkyl-agarose gels.

The soluble guanylate cyclase from rat lung was immobilized by absorption rather than covalent attachment on hexyl-, octyl-, or decyl-agarose. The enzyme retained activity after being bound to these matrices and could be compared to the soluble, mobile form of the enzyme. Compared to the soluble enzyme, the immobilized guanylate cyclase had a lower apparent maximal velocity and a higher apparent Km for MeGTP in the presence of Mg2+, Ca2+, or Mn2+. The apparent maximum velocity was reduced to the same extent by hexyl-, octyl-, or decyl-agarose, but the reduction in activity was greater with Mg2+ than with Ca2+ or Mn2+. Both the soluble and immobilized guanylate cyclase displayed concave downward patterns on double reciprocal polots as a function of Mn2+, and Ca2+ caused apparent activation of either form of the enzyme. MnATP appeared to be a linear competitive inhibitor with respect to MnGTP for both forms of the enzymes but the ki was 3 micron for the soluble form and 30 micron for the immobilized form. These results demonstrate that the soluble form of guanylate cyclase from rat lung retains many of its basic properties after being immobilized on a hydrophobic matrix; however, rather pronounced decreases in the maximum velocity and increases in the apparent Michaelis constant for MeGTP, particularly for MgGTP, are observed upon immobilization.     

Sea urchin sperm guanylate cyclase. Purification and loss of cooperativity.

The Lubrol-dispersed guanylate cyclase from sea urchin sperm was purified and isolated essentially free of detergent by GTP affinity chromatography, DEAE-Sephadex chromatography, and gel filtration. After removal of the detergent, the enzyme remained in solution in the presence of 20% glycerol. The specific activity of the purified enzyme was about 12 mumol of guanosine 3':5'-monophosphate (cyclic GMP) formed - min-1 - mg of protein-1 at 30 degrees, an activity about 4600 times that of a soluble guanylate cyclase purified recently from Escherichia coli (Macchia V., Varrone, S., Weissbach, H., Miller, D.L., and Pastan, I. (1975) J. Biol. Chem. 250, 6214-6217). The cyclic GMP phosphodiesterase activity was negligible and adenosine 3':5'-monophosphate (cyclic AMP) phosphodiesterase was not detectable in the purified preparation. Cyclic AMP formation from ATP occurred at a rate of 0.002% of that of guanylate cyclase. In the absence of phosphodiesterase or guanosine triphosphatase inhibitors, 100% of the added GTP was converted to cyclic GMP. The purified enzyme required Mn2+ for maximum activity, the relative rates in the presence of Mg2+ or Ca2+ being less than 0.6% of the rates with Mn2+. The purified enzyme displayed classical Michaelis-Menten kinetics with respect to MnGTP (apparent Km is approximately equal to 170 muM) in contrast to the positively cooperative kinetic behavior displayed by the unpurified, detergent-dispersed, or particulate guanylate cyclase. The molecular weight of the purified enzyme was approximately 182,000 as estimated on Bio-Gel A-0.5m columns equilibrated in the presence or absence of 0.1 M NaCl. The unpurified, detergent-dispersed enzyme also migrated with an apparent molecular weight of 182,000 on columns equilibrated with 0.5% Lubrol WX and 0.1 M NaCl, but it migrated as a large aggregate (molecular weight is greater than 5 X 10(5)) on columns equilibrated in the absence of either the detergent of NaCl. After gel filtration, the unpurified, dispersed enzyme still yielded positive cooperative kinetic patterns as a function of MnGTP. Na dodecyl-SO4 gel electrophoresis of the enzyme after the DEAE-Sephadex or the gel filtration steps resulted in two major protein bands with estimated molecular weights of 118,000 and 75,000. Whether or not these protein bands represent the subunit molecular weights of guanylate cyclase is unknown at present.     

Characterization of a Ca2+-dependent guanylate cyclase in the excitable ciliary membrane from Paramecium

The membraneous guanylate cyclase of cilia from Paramecium tetraurelia used MgGTP and MnGTP as substrate with Michaelis constants for GTP of 71.5 microM and 36 microM, respectively. A linear Arrhenius plot indicated that a single enzyme entity exists not sensitive to possible phase transitions of membrane lipids. Guanylate cyclase is activated by low concentrations (less than 100 microM) and inhibited by high concentrations (greater than 100 microM) of calcium, half-maximal effects were obtained with 8 microM and 500 microM Ca2+, respectively. Only strontium ions displayed partial activating and inhibiting potency, all other divalent cations tested, Ba2+, Fe2+, Co2+, Mn2+, Sn2+ and Ni2+ had no effect on guanylate cyclase activity. Ca2+ activation increased V; Km remained identical. The Ca2+ stimulated activity was not inhibited by trifluoperazine, tentatively suggesting that the stimulation may not be mediated by calmodulin. Ca2 inhibition was due to a single binding site of Ca2+ at the guanylate cyclase as evidence by a Hill coefficient h = -1 and was noncompetitive. The lanthanides La3+, Ce3+ and Tb3+ were powerful inhibitors of guanylate cyclase, with La3+ the half-maximal effect was obtained with 0.6 microM, it was kinetically a mixed-type inhibition. La3+ and CA2+ competed for the same binding site on the guanylate cyclase as determined by detailed kinetic analysis. Addition of EDTA reversed the activation and inhibition by Ca2+ and the inhibition by La3+. It is discussed that guanylate cyclase may be the initial target enzyme in the cilia for the calcium transient of the calcium-potassium action potential of Paramecium.     

Characterization of guanylate cyclase of rod outer segments of the bovine retina.

Guanylate cyclase (GTP pyrophosphate-lyse (cyclizing), EC 4.6.1.2.) of bovine retinal rod outer segments is almost completely particulate, i.e. associated with rod outer segment membranes. In contrast to particulate guanylate cyclase in other tissues, treatment of rod outer segments with Triton X-100 does not solublize the enzyme but inhibits it. Enzyme activity is dependent on the presence of divalent cation, especially Mn2+ with only poor activation by Mg2+ (10-fold lower) and no activation seen with other cation. Ezpression of maximal activity required Nm2+ and GTP in equimolar concentrations with an apparent Km of 8 . 10(-4) M and V of 10 nmol/min per mg protein. Excess of Mn2+ over that required for the formation of the Mn . GTP complex was inhibitory. Ca2+, Ba2+ and Co2+ inhibited enzyme activity when assayed with the Mn . GTP substrate complex. In the presence of a fixed concentration of 1mM Mn2+, the enzyme exhibited strong negative cooperative interactions with GTP, characterized by an intermediary plateau region in the substrate vs. enzyme activity curve, a curve of downward concavity in the double reciprocal plot and a Hill coefficient of 0.5. Nucleotides such as ITP, ATP and UTP at higher concentrations (1 mM) stimulates activity by 40%. NaN3 has no effect on the guanylate cyclase. It is thus possible that the guanylate cyclase may be regulated in vivo by both the metal : GTP substrate ratio and the free divalent cation concentration as well as by the ATP concentration and thus play an important but yet undefined role in the visual process.     

Appearance of magnesium guanylate cyclase activity in rat liver with sodium azide activation.

Native soluble and particulate guanylate cyclase from several rat tissues preferred Mn2+ to Mg2+ as the sole cation cofactor. Wtih 4mM cation, activities with Mg2+ were less than 25% of the activities with Mn2+. The 1 mM NaN3 markedly increased the activity of soluble and particulate preparations from rat liver. Wtih NaN3 activation guanylate cyclase activities wite similar with Mn2+ and Mg2+. Co2+ was partially effective as a cofactor in the presence of NaN3, while Ca2+ was a poor cation with or without NaN3. Activities with Ba, Cu2+, or Zn2+ were not detectable without or with 1 mM NaN3. With soluble liver enzyme both manganese and magnesium activities were dependent upon excess Mn2+ or Mg2+ at a fixed MnGTP or MgGTP concentration of 0.4 mm; apparent Km values for excess Mn2+ and Mg2+ were 0.3 and 0.24 mM, respectively. After NaN3 activation, the activity was less dependent upon free Mn2+ and retained its dependence for free Mg2+, at 0.4 mM MgGTP the apparent Km for excess Mg2+ was 0.3 mM. The activity of soluble liver guanylate cyclase assayed with Mn2+ or Mg2+ was increased with Ca2+. After NaN3 activiation, Ca2+ had no effect or was somewhat inhibitory with either Mn2+. After NaN activation, Ca2+ had no effect or was somewhat inhibitory with either Mn2+ or Mg2+. The stimulatory effect of NaN2 on Mn2+-and Mg2+-dependent guanylate cyclase activity from liver or cerebral cortex supernatant fractions required the presence of the sodium azide-activator factor. With partially purified soluble liver guanylate cyclase and azide-activator factor, the concentration (1 mjM) of NaN3 that gave half-maximal activation with Mn2+ or Mg2+ was imilar. Thus, under some conditions guanylate cyclase can effectively use Mg2+ as a sole cation cofactor.     

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.     

Guanylate cyclase. Existence of different forms and their regulation by nucleotides in calf uterus.

The activity of calf uterus guanylate cyclase (EC 4.6.1.2) exists in at least two and most probably three distinct forms. The cytosolic enzyme exhibits hyperbolic substrate curves with respect to GTP and Mn2+, while the particulate cyclases (nuclear and microsomal)display sigmoidal (GTP) and hyperbolic (Mn2+) relationships. The Hill coefficient for the GTP dependence is 0.9 for the cytosolic, 1.5 for the nuclear, and 1.4 for the microsomal enzyme. The cytosolic enzyme has a Km for GTP of 70 muM while half maximal velocity occurs at 90 and 100 muM GTP for the nuclear and microsomal enzymes, respectively. The Ka for Mn2+ is 0.57, 0.71 or 0.75 mM for the cytosolic, nuclear, or microsomal enzyme, respectively.     

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.     

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     

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

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

Lipids associated with bovine kidney glomerular basement membranes.

1. The activities of the enzymes involved in the metabolism of cyclic nucleotides were studied in sarcolemma prepared front guinea-pig heart ventricle; the enzyme activities reported here were linear under the assay conditions. 2. Adenylate cyclase was maximally activated by 3mM-NaF; NaF increased the Km for ATP (from 0.042 to 0.19 mM) but decreased the Ka for Mg2+ (from 2.33 to 0.9 mM). In the presence of saturating Mg2+ (15 mM), Mn2+ enhanced adenylate cyclase, whereas Co2+ was inhibitory. beta-Adrenergic amines (10-50 muM) stimulated adenylate cyclase (38+/-2%). When added to the assay mixture, guanyl nucleotides (GTP and its analogue, guanylyl imidophosphate) stimulated basal enzyme activity and enhanced the stimulation by isoproterenol. By contrast, preincubation of sarcolemma with guanylyl imidodiphosphate stimulated the formation of an 'activated' form of the enzyme, which did not reveal increased hormonal sensitivity. 3. The guanylate cyclase present in the membranes as well as in the Triton X-100-solubilized extract of membranes exhibited a Ka for Mn 2+ of 0.3 mM; Mn2+ in excess of GTP was required for maximal activity. Solubilized guanylate cyclase was activated by Mg2+ only in the presence of low Mn2+ concentrations; Ca2+ was inhibitory both in the absence and presence of low Mn2+. Acetylcholine as well as carbamolycholine stimulated membrane-bound guanylate cyclase. 4. Cylic nucleotide phosphodiesterase activities of sarcolemma exhibited both high-and low-Km forms with cyclic AMP and with cyclic GMP as substrate. Ca2+ ions increased the Vmax. of the cyclic GMP-dependent enzyme.     

Guanylate cyclase in olfactory cilia from rat and pig

A guanylate cyclase was identified in cilia from rat and pig olfactory epithelia. Enzyme activities were 200-250 and 90-100 pmol/min.mg-1, respectively. Activity required the presence of non-ionic detergents, e.g., 0.1% Lubrol PX. MnGTP, not MgGTP was used as a substrate. Furthermore, 0.9 mM free Mn2+ was necessary for optimal activity indicating a regulatory site for a divalent cation. The guanylate cyclase displayed sigmoidal Michaelis-Menten kinetics suggesting cooperativity between MnGTP and enzyme. S0.5 was 160 microM MnGTP. The Hill coefficient of 1.7 indicates that more than one class of substrate-binding sites interact in a positive cooperative manner. ATP inhibited the enzyme and linearized plots of substrate kinetics with MnGTP. SH-Blocking agents reversibly inhibited enzyme activity. Sodium azide and nitroprusside were without effect as were several odorants. A guanylate cyclase activity in cilia from tracheal tissue had properties similar to the olfactory enzyme.     

Properties and subcellular distribution of guanylate cyclase activity in rat renal medulla: correlation with tissue content of guanosine 3',5'-monophosphate.

The properties of the guanylate cyclase systems of outer and inner medulla of rat kidney were examined and compared with those of the renal cortex. A gradation in steady-state cyclic guanosine 3',5'-monophosphate (cGMP) levels was observed in incubated slices of these tissues (inner medula greater than outer medulla greater than cortex). This correlated with the proportion of total guanyl cyclase activity in the 100 000 g particulate fraction of each tissue, but was discordant with the relative activities of guanylate cyclase (highest in cortex) and of cGMP-phosphodiesterase (lowest in cortex) in whole tissue homogenates. Soluble guanylate cyclase of cortex and inner medulla exhibited typical Michaelis-Menten kinetics with an apparent Km for MnGTP of 0.11 mM, while the particulate enzyme from inner medulla exhibited apparent positive cooperative behavior and a decreased dependence on Mn2+. Thus, the particulate enzyme could play a key role in regulating cGMP levels inthe intact cell where Mn2+ concentrations are low. The soluble and particulate enzymes from inner medulla were further distinguished by their responses to several test agents. The soluble enzyme was activated by Ca2+, NaN3, NaNo2 and phenylhydrazine, whereas particulate activity was inhibited by Ca2+ and was unresponsive to the latter agents. In the presence of NaNo2, Mn2+ requirement of the soluble enzyme was reduced and equivalent to that of the particulate preparation. Moreover, relative responsiveness of the sollble enzyme to NaNO2 was potentiated when Mg2+ replaced Mn2+ as the sole divalent cation. These changes in metal requirements may be involved in the action of NaNO2 to increase cGMP in intact kidney. Soluble guanylate cyclase of cortex was clearly more responsive to stimulation by NaN3, Nano2, and phenylhydrazine that was soluble activity from either medullary tissue. The effectiveness of the agonists on soluble activity from outer and inner medulla cound also be distinguished. Accordingly, regulation and properties of soluble guanylate cyclase, as well as subcellular enzyme distribution, and distinct in the three regions of the kidney.     

Trypsin solubilization of rat liver membrane-bound guanylate cyclase results in a form kinetically distinct from the cytosolic enzyme

We have previously reported that treatment of rat liver plasma membranes with various proteases led to activation and solubilization of membrane-bound guanylate cyclase. We report here that the guanylate cyclase solubilized by proteolysis differed from the cytosolic cyclase and rather was similar to the membrane-bound form of the enzyme in that it exhibited a sigmoidal MnGTP concentration dependence and was not activated by an excess Mn2+ or by nitrosocompounds. Also, whereas the cytosolic guanylate cyclase activity was completely abolished by 10 to 100 microM Cd2+, a dithiol reagent, no inhibitory effect was observed on the trypsin-solubilized enzyme. Therefore, the differences in kinetic properties between cytosolic and membrane-bound rat liver guanylate cyclase reside in structural differences between both forms of the enzyme rather than in differences in their environment.