Electron spin resonance study of the role of NO . catalase in the activation of guanylate cyclase by NaN3 and NH2OH. Modulation of enzyme responses by heme proteins and their nitrosyl derivatives.

The role of NO . catalase in the activation of partially purified soluble guanylate cyclase of rat liver by NaN3 and NH2OH was examined by electron spin resonance (ESR) spectroscopy. Equilibration of bovine liver catalase with NO resulted in formation of a paramagnetic species exhibiting a three-line ESR spectrum similar to that of NO . catalase. This paramagnetic complex produced concentration-dependent stimulation of preparations of partially purified guanylate cyclase that were devoid of detectable endogenous heme content. The stimulation of partially purified guanylate cyclase by NO . catalase was similar to that obtained with NO . hemoglobin and with NO . cytochrome P-420 prepared by reaction of hepatic microsomes of phenobarbital-treated rats with NO. By contrast, these same enzyme preparations did not respond to NO or catalase alone. Addition of hematin or hemoglobin plus a reducing agent to purified guanylate cyclase restored enzyme responsiveness to NO and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), but not to NaN3 or NH2OH. Responses to the latter agents were restored by catalase and potentiated by a H2O2-generating system. Formation of the NO . catalase complex was evident by ESR spectroscopy in test solutions containing NaN3 or nh2oh, catalase, and a glucose-glucose oxidase, H2O2-generating system. The presence of NO . catalase correlated well with the ability of test solutions to activate purified guanylate cyclase. These results provide evidence for catalase-dependent NO generation from NaN3 and NH2OH under conditions leading to guanylate cyclase activation. Preformed NO . hemoglobin or NO . cytochrome P-420 also activated heme-deficient partially purified guanylate cyclase. The ability of several preformed NO . heme protein complexes, but not NO, to stimulate heme-deficient guanylate cyclase supports the concept that formation of the paramagnetic nitrosyl . heme complex, mediated by either enzymatic or nonenzymatic reactions, is a common and essential step in the process by which NO or NO-forming compounds activate guanylate cyclase. In the absence of the NO ligand, both hemoglobin and catalase suppress the stimulatory effects of the corresponding NO . heme proteins on guanylate cyclase. Release of each heme protein from the NO . heme protein complex occurs more rapidly under aerobic compared to anaerobic conditions. However, hemoglobin is approximately 2000 times more effective as an inhibitor of NO . hemoglobin stimulation of guanylate cyclase than is catalase as an inhibitor of NO . catalase action. This finding may explain the more pronounced decline in the rate of cGMP generation in air in the presence of NO . hemoglobin compared to NO . catalase. The results imply that guanylate cyclase responses to activators that can form NO are determined by both the stimulatory activity of the endogenous heme acceptors of NO and the relative inhibitory effects of the unliganded heme proteins present.     

Sodium azide as indirect nitric oxide donor: researches on the rat aorta isolated segments

A comparative investigations of heme-containing enzymes inhibitors NaN3 and NaCN effects on the rat aorta isolated segments tone has shown that NaN3 in the range of very low concentrations from 10(-9) to 10(-6) M displays pharmacological activity characteristic of nitric oxide (NO) donors, which is inhibited by NaCN. The value of vasodilatation, caused by NaN3, was also decreased in the presence of soluble guanylate cyclase inhibitor ODQ (10(-5) M). It was found that H2O2 injection to physiological solution containing NaN3 and horseradish peroxidase or catalase lead to NO2- accumulation in it, which was blocked by NaCN. The nonenzymic NaN3 oxidization by hydrogen peroxide was not found in control experiments. NaN3 physiological activity dependent on NO-donating properties of this traditional inhibitor of heme-containing enzymes is discussed.     

Sodium azide dilates coronary arterioles via activation of inward rectifier K+ channels and Na+-K+-ATPase

Sodium azide (NaN(3)), a potent vasodilator, causes severe hypotension on accidental exposure. Although NaN(3) has been shown to increase coronary blood flow, the direct effect of NaN(3) on coronary resistance vessels and the mechanism of the NaN(3)-induced response remain to be established. To address these issues without confounding influences from systemic parameters, subepicardial coronary arterioles were isolated from porcine hearts for in vitro study. Arterioles developed basal tone at 60 cmH(2)O intraluminal pressure and dilated acutely, in a concentration-dependent manner, to NaN(3) (0.1 microM to 50 microM). The NaN(3) response was not altered by the nitric oxide synthase inhibitor N(G)-nitro-L-arginine methyl ester or endothelial removal. Neither inhibition of phosphoinositol 3-kinase and tyrosine kinases nor blockade of ATP-sensitive, Ca(2+)-activated, and voltage-dependent K(+) channels affected NaN(3)-induced dilation. However, the vasomotor action of NaN(3) was significantly attenuated in a similar manner by the inward rectifier K(+) (K(IR)) channel inhibitor Ba(2+), the Na(+)-K(+) ATPase inhibitor ouabain, or the guanylyl cyclase inhibitor 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxalin-1-one (ODQ). Ba(2+), in combination with either ouabain or ODQ, nearly abolished the vasodilatory response. However, there was no additive inhibition by combining ouabain and ODQ. The NaN(3)-mediated vasodilation was also attenuated by morin, an inhibitor of phosphatidylinositolphosphate (PIP) kinase, which can regulate K(IR) channel activity. With the use of whole cell patch-clamp methods, NaN(3) acutely enhanced Ba(2+)-sensitive K(IR) current in isolated coronary arteriolar smooth muscle cells. Collectively, this study demonstrates that NaN(3), at clinically toxic concentrations, dilates coronary resistance vessels via activation of both K(IR) channels and guanylyl cyclase/Na(+)-K(+)-ATPase in the vascular smooth muscle. The K(IR) channels appear to be modulated by PIP kinase.     

Guanylate cyclase from bovine lung. Evidence that enzyme activation by phenylhydrazine is mediated by iron-phenyl hemoprotein complexes

The mechanism of activation of soluble guanylate cyclase purified from bovine lung by phenylhydrazine is reported. Heme-deficient and heme-containing forms of guanylate cyclase were studied. Heme-deficient enzyme was activated 10-fold by NO but was not activated by phenylhydrazine. Catalase or methemoglobin enabled phenylhydrazine to activate guanylate cyclase 10-fold and enhanced activation by NO to over 100-fold. Heme-containing enzyme was activated only 3-fold by phenylhydrazine but over 100-fold by NO. Added hemoproteins enhanced enzyme activation by phenylhydrazine to 12-fold without enhancing activation by NO. Reducing or anaerobic conditions inhibited, whereas oxidants enhanced enzyme activation by phenylhydrazine plus catalase, and KCN had no effect. In contrast, enzyme activation by NO and NaN3 was inhibited by oxidants or KCN. NaN3 required native catalase, whereas phenylhydrazine also utilized heat-denatured catalase for enzyme activation. Thus, the mechanism of guanylate cyclase activation by phenylhydrazine differed from that by NO or NaN3. Guanylate cyclase activation by phenylhydrazine resulted from an O2-dependent reaction between phenylhydrazine and hemoproteins to generate stable iron-phenyl hemoprotein complexes. These complexes activated guanylate cyclase in the absence of O2, but lost activity after acidification, basification, or heating. Gel filtration of prereacted mixtures of [U-14C]phenylhydrazine plus hemoproteins resulted in co-chromatography of radioactivity, protein, and guanylate cyclase stimulating activity, and yielded a phenyl-hemoprotein binding stoichiometry of four under specified conditions (one phenyl/heme). [14C]Phenyl bound to heme-containing but not heme-deficient guanylate cyclase and binding correlated with enzyme activation. Moreover, reactions between enzyme and iron-[14C] phenyl hemoprotein complexes resulted in the exchange or transfer of iron-phenyl heme to guanylate cyclase and this correlated with enzyme activation.     

Pulmonary vasoconstriction by serotonin is inhibited by S-nitrosoglutathione

Nitric oxide (NO) functions as an endothelium-derived relaxing factor by activating guanylate cyclase to increase cGMP levels. However, NO and related species may also regulate vascular tone by cGMP-independent mechanisms. We hypothesized that naturally occurring NO donors could decrease the pulmonary vascular response to serotonin (5-HT) in the intact lung through chemical interactions with 5-HT(2) receptors. In isolated rabbit lung preparations and isolated pulmonary artery (PA) rings, 50-250 microM S-nitrosoglutathione (GSNO) inhibited the response to 0.01-10 microM 5-HT. The vasoconstrictor response to 5-HT was mediated by 5-HT(2) receptors in the lung, since it could be blocked completely by the selective inhibitor ketanserin (10 microM). GSNO inhibited the response to 5-HT by 77% in intact lung and 82% in PA rings. In PA rings, inhibition by GSNO could be reversed by treatment with the thiol reductant dithiothreitol (10 mM). 3-Morpholinosydnonimine (100-500 microM), which releases NO and O simultaneously, also blocked the response to 5-HT. Its chemical effects, however, were distinct from those of GSNO, because 5-HT-mediated vasoconstriction was not restored in isolated rings by dithiothreitol. In the intact lung, neither NO donor altered the vascular response to endothelin, which activates the same second-messenger vasoconstrictor system as 5-HT. These findings, which did not depend on guanylate cyclase, are consistent with chemical modification by NO of the 5-HT(2) G protein-coupled receptor system to inhibit vasoconstriction, possibly by S-nitrosylation of the receptor or a related protein. This study demonstrates that GSNO can regulate vascular tone in the intact lung by a reversible mechanism involving inhibition of the response to 5-HT.     

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.     

Vasomotor control in mice overexpressing human endothelial nitric oxide synthase

Nitric oxide (NO) plays a key role in regulating vascular tone. Mice overexpressing endothelial NO synthase [eNOS-transgenic (Tg)] have a 20% lower systemic vascular resistance (SVR) than wild-type (WT) mice. However, because eNOS enzyme activity is 10 times higher in tissue homogenates from eNOS-Tg mice, this in vivo effect is relatively small. We hypothesized that the effect of eNOS overexpression is attenuated by alterations in NO signaling and/or altered contribution of other vasoregulatory pathways. In isoflurane-anesthetized open-chest mice, eNOS inhibition produced a significantly greater increase in SVR in eNOS-Tg mice compared with WT mice, consistent with increased NO synthesis. Vasodilation to sodium nitroprusside (SNP) was reduced, whereas the vasodilator responses to phosphodiesterase-5 blockade and 8-bromo-cGMP (8-Br-cGMP) were maintained in eNOS-Tg compared with WT mice, indicating blunted responsiveness of guanylyl cyclase to NO, which was supported by reduced guanylyl cyclase activity. There was no evidence of eNOS uncoupling, because scavenging of reactive oxygen species (ROS) produced even less vasodilation in eNOS-Tg mice, whereas after eNOS inhibition the vasodilator response to ROS scavenging was similar in WT and eNOS-Tg mice. Interestingly, inhibition of other modulators of vascular tone [including cyclooxygenase, cytochrome P-450 2C9, endothelin, adenosine, and Ca-activated K(+) channels] did not significantly affect SVR in either eNOS-Tg or WT mice, whereas the marked vasoconstrictor responses to ATP-sensitive K(+) and voltage-dependent K(+) channel blockade were similar in WT and eNOS-Tg mice. In conclusion, the vasodilator effects of eNOS overexpression are attenuated by a blunted NO responsiveness, likely at the level of guanylyl cyclase, without evidence of eNOS uncoupling or adaptations in other vasoregulatory pathways.     

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.     

Ascorbate activates soluble guanylate cyclase via H2O2-metabolism by catalase

Conditions necessary for the activation by ascorbic acid of soluble guanylate cyclase purified from bovine lung have been examined. Ascorbic acid (0.1-10 mM) did not directly activate the enzyme, nonetheless, pronounced activation by ascorbate (3-10 mM) was observed in incubation mixtures containing 1 microM bovine liver catalase. Superoxide dismutase (SOD) and mannitol did not affect the catalase-dependent activation of guanylate cyclase elicited by ascorbate, suggesting that superoxide anion and hydroxyl radical were not mediating the activation of the enzyme. However, SOD enhanced the relatively low level activation of the enzyme elicited by catalase in the absence of added ascorbate. Pronounced inhibition (both with and without added ascorbate) was observed of catalase-dependent activation of guanylate cyclase by either ethanol (100 mM) or a fungal catalase preparation. Neither ethanol nor fungal catalase inhibited activation of guanylate cyclase by S-nitrosyl-N-acetyl-penicillamine (SNAP), a source of the nitric oxide free radical. These observations indicate that autoxidation of ascorbic acid or thiols present with the guanylate cyclase preparation leads to generation of H2O2, and its metabolism by bovine liver catalase mediates the concomitant activation of guanylate cyclase. The mechanism of activation appears to be associated with the presence of Compound I of catalase and to be inhibited by superoxide anion.     

Activation of cerebral guanylate cyclase by nitric oxide.

Mouse cerebral guanylate cyclase was activated by catalase in the presence of sodium azide (NaN₃), which is known to form catalase-NO complex, while nitrosamines and nitric oxide (NO gas) were capable of activating cerebral guanylate cyclase in the absence of catalase. The activation of guanylate cyclase by NaN₃-catalase or nitrosamines was markedly inhibited by ferrohemoglobin which has a high affinity for NO, but not by ferrihemoglobin. These data suggest that NO or NO containing compounds may activate guanylate cyclase, whereas ferrohemoglobin may exhibit an inhibitory effect on the activation of guanylate cyclase, possibly by interacting with NO or NO containing compounds.     

Hydrogen peroxide elicits activation of bovine pulmonary arterial soluble guanylate cyclase by a mechanism associated with its metabolism by catalase

Guanylate cyclase activity in the soluble extract of bovine pulmonary arteries is activated by hydrogen peroxide generated by glucose oxidase only in the presence of catalase. This mechanism of guanylate cyclase activation is not blocked by scavengers for superoxide anion or hydroxyl radical, but is selectively inhibited by methylene blue, inactivation of catalase and ethanol. The time dependency of increases in guanylate cyclase activity in the presence of peroxides that are substrates for catalase are associated with the spectral detection of compound I, a species of catalase formed during the metabolism of peroxide. Thus, activation of soluble guanylate cyclase appears to be elicited by compound I of catalase or by a mediator generated by this species.     

Hypoxia enhances a cGMP-independent nitric oxide relaxing mechanism in pulmonary arteries

Nitric oxide (NO) donors generally relax vascular preparations through cGMP-mediated mechanisms. Relaxation of endothelium-denuded bovine pulmonary arteries (BPA) and coronary arteries to the NO donor S-nitroso-N-acetyl-penicillamine (SNAP) is almost eliminated by inhibition of soluble guanylate cyclase activation with 10 microM 1H-[1,2,4]oxadiazolo-[4,3-a]quinoxalin-1-one (ODQ), whereas only a modest inhibition of relaxation is observed under hypoxia (PO2 = 8-10 Torr). This effect of hypoxia is independent of the contractile agent used and is also observed with NO gas. ODQ eliminated SNAP-induced increases in cGMP under hypoxia in BPA. cGMP-independent relaxation of BPA to SNAP was not attenuated by inhibition of K+ channels (10 mM tetraethylammonium), myosin light chain phosphatase (0.5 microM microcystin-LR), or adenylate cyclase (4 microM 2',5'-dideoxyadenosine). SNAP relaxed BPA contracted with serotonin under Ca2+-free conditions in the presence of hypoxia and ODQ, and contraction to Ca2+ readdition was also attenuated. The sarcoplasmic reticulum Ca2+-reuptake inhibitor cyclopiazonic acid (0.2 mM) attenuated SNAP-mediated relaxation of BPA in the presence of ODQ. Thus hypoxic conditions appear to promote a cGMP-independent relaxation of BPA to NO by enhancing sarcoplasmic reticulum Ca2+ reuptake.     

The permissive role of endothelial NO in CO-induced cerebrovascular dilation

Carbon monoxide (CO) and nitric oxide (NO) are important paracrine messengers in the newborn cerebrovasculature that may act as comessengers. Here, we investigated the role of NO in CO-mediated dilations in the newborn cerebrovasculature. Arteriolar branches of the middle cerebral artery (100-200 microm) were isolated from 3- to 7-day-old piglets and cannulated at each end in a superfusion chamber, and intravascular pressure was elevated to 30 mmHg, which resulted in the development of myogenic tone. Endothelium removal abolished dilations of pressurized pial arterioles to bradykinin and to the CO-releasing molecule Mn(2)(CO)(10) [dimanganese decacarbonyl (DMDC)] but not dilations to isoproterenol. With endothelium intact, N(omega)-nitro-l-arginine (l-NNA), 1H-[1,2,4]oxadiazolo-[4,3-a]quinoxalin-1-one (ODQ), or tetraethylammonium chloride (TEA(+)), inhibitors of NO synthase (NOS), guanylyl cyclase, and large-conductance Ca(2+)-activated K(+) (K(Ca)) channels, respectively, also blocked dilation induced by DMDC. After inhibition of NOS, a constant concentration of sodium nitroprusside (SNP), a NO donor that only dilated the vessel 6%, returned dilation to DMDC. The stable cGMP analog 8-bromo-cGMP also restored dilation to DMDC in endothelium-intact, l-NNA-treated, or endothelium-denuded arterioles, and this effect was blocked by TEA(+). Similarly, in the continued presence of ODQ, 8-bromo-cGMP restored DMDC-induced dilations. These findings suggest that endothelium-derived NO stimulates guanylyl cyclase in vascular smooth muscle cells and, thereby, permits CO to cause dilation by activating K(Ca) channels. Such a requirement for NO could explain the endothelium dependency of CO-induced dilation in piglet pial arterioles.     

Properties of guanylate cyclase from rat kidney cortex and transplantable kidney tumors.

The subcellular distribution and properties of guanylate cyclase was examined in preparations of normal rat renal cortex and Morris renal tumors MK2 and MK3. In normal kidney cortex about two-thirds of guanylate cyclase activity of homogenates was found in soluble fractions. With renal tumors the homogenate activity was less and the enzyme was equally divided between particulate and soluble fractions. The particulate enzyme in kidney cortex and tumors was associated with all particulate fractions. Triton X-100 increased the activity of all preparations. All preparations preferred Mn2+ as the sole cation. The stimulatory effects of Ca2+ on soluble enzyme and inhibitory effects on particulate activity were similar with preparations of renal cortex and tumors. ATP inhibited all preparations. Soluble and particulate guanylate cyclases from renal cortex were activated several-fold with 1 mM NaN3. Preparations of tumor enzymes did not respond to NaN3. Thus, compared to normal renal cortex the subcellular distribution of guanylate cyclase and some of its properties are altered in preparations of renal tumors.     

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.     

Calcitonin gene-related peptide suppresses pacemaker currents by nitric oxide/cGMP-dependent activation of ATP-sensitive K(+) channels in cultured interstitial cells of Cajal from the mouse small intestine

The effects of calcitonin gene-related peptide (CGRP) on pacemaker currents in cultured interstitial cells of Cajal (ICC) from the mouse small intestine were investigated using the whole-cell patch clamp technique at 30 degrees . Under voltage clamping at a holding potential of -70 mV, CGRP decreased the amplitude and frequency of pacemaker currents and activated outward resting currents. These effects were blocked by intracellular GDPbetaS, a G-protein inhibitor and glibenclamide, a specific ATP-sensitive K(+) channels blocker. During current clamping, CGRP hyperpolarized the membrane and this effect was antagonized by glibenclamide. Pretreatment with SQ-22536 (an adenylate cyclase inhibitor) or naproxen (a cyclooxygenase inhibitor) did not block the CGRP-induced effects, whereas pretreatment with ODQ (a guanylate cyclase inhibitor) or L-NAME (an inhibitor of nitric oxide synthase) did. In conclusion, CGRP inhibits pacemaker currents in ICC by generating nitric oxide via G-protein activation and so activating ATP-sensitive K(+) channels. Nitric oxide- and guanylate cyclase- dependent pathways are involved in these effects.     

Relaxation of bovine coronary artery and activation of coronary arterial guanylate cyclase by nitric oxide, nitroprusside and a carcinogenic nitrosoamine.

The principal objective of this study was to test the hypothesis that nitroprusside relaxes vascular smooth muscle via the reactive intermediate, nitric oxide (NO), and that the biologic action of NO is associated with the activation of guanylate cyclase. Nitroprusside, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and NO elicit concentration-dependent relaxation of precontraced helical strips of bovine coronary artery. Nitroprusside, MNNG and NO also markedly activate soluble guanylate cyclase from bovine coronary arterial smooth muscle and, thereby, stimulate the formation of cyclic GMP. Three heme proteins, hemoglobin, methemoglobin and myoglobin, and the oxidant, methylene blue, abolish the coronary arterial relaxation elicited by NO. Similarly, these heme proteins, methylene blue and another oxidant, ferricyanide, markedly inhibit the activation of coronary arterial guanylate cyclase by NO, nitroprusside and MNNG. The following findings support the view that certain nitroso-containing compounds liberate NO in tissue:heme proteins, which cannot permeate cells, inhibit coronary arterial relaxation elicited by NO, but not by nitroprusside or MNNG; the vital stain, methylene blue, inhibits relaxation by NO, nitroprusside and MNNG; heme proteins and oxidants inhibit guanylate cyclase activation by NO, nitroprusside and MNNG in cell-free mixtures. The findings that inhibitors of NO-induced relaxation of coronary artery also inhibit coronary arterial guanylate cyclase activation suggest that cyclic GMP formation may be associated with coronary arterial smooth muscle relaxation.     

Acute relaxant effects of 17-beta-estradiol through non-genomic mechanisms in rabbit carotid artery

Estrogens could play a cardiovascular protective role not only by means of systemic effects but also by means of direct effects on vascular structure and function. We have studied the acute effects and mechanisms of action of 17-beta-estradiol on vascular tone of rabbit isolated carotid artery. 17-Beta-estradiol (10, 30, and 100 microM) elicited concentration-dependent relaxation of 50 mM KCl-induced active tone in male and female rabbit carotid artery. The stereoisomer 17-alpha-estradiol showed lesser relaxant effects in male rabbits. Endothelium removal did not modify relaxation induced by 17-beta-estradiol. The NO synthase inhibitor L-NAME (100 microM) only reduced significantly relaxation produced by 30 microM 17-beta-estradiol. Relaxation was not modified by the estrogen receptor antagonist ICI 182,780 (1 microM), the protein synthesis inhibitor cycloheximide (1 microM), and the selective K(+) channel blockers charybdotoxin (0.1 microM) and glibenclamide (1 microM). CaCl(2) (30 microM -10 mM) induced concentration-dependent contraction in rabbit carotid artery depolarized by 50 mM KCl in Ca(2+) free medium. Preincubation with 17-beta-estradiol (3, 10, 30, or 100 microM) or the L-type Ca(2+) channel blocker nicardipine (0.01, 0.1, 1, or 10 nM) produced concentration-dependent inhibition of CaCl(2)-induced contraction. In conclusion, 17-beta-estradiol induces endothelium-independent relaxation of rabbit carotid artery, which is not mediated by classic estrogen receptor and protein synthesis activation. The relaxant effect is due to inhibition of extracellular Ca(2+) influx to vascular smooth muscle, but activation of K(+) efflux is not involved. Relatively high pharmacological concentrations of estrogen causing relaxation preclude acute vasoactive effects of plasma levels in the carotid circulation.     

Preparation of renal cortex basal-lateral and bursh border membranes. Localization of adenylate cyclase and guanylate cyclase activities.

Luminal brush border and contraluminal basal-lateral segments of the plasma membrane from the same kidney cortex were prepared. The brush border membrane preparation was enriched in trehalase and gamma-glutamyltranspeptidase, whereas the basal-lateral membrane preparation was enriched in (Na+ + K+1)-ATPase. However, the specific activity of (Na+ + K+)-ATPase in brush border membranes also increased relative to that in the crude plasma membrane fraction, suggesting that (Na+ + K+)-ATPase may be an intrinsic constituent of the renal brush border membrane in addition to being prevalent in the basal-lateral membrane. Adenylate cyclase had the same distribution pattern as (Na+ + K+)-ATPase, i.e. higher specific activity in basal-lateral membranes and present in brush border membranes. Adenylate cyclase in both membrane preparations was stimulated by parathyroid hormone, calcitonin, epinephrine, prostaglandins and 5'-guanylylimidodiphosphate. When the agonists were used in combination enhancements were additive. In contrast to the distribution of adenylate cyclase, guanylate cyclase was found in the cytosol and in basal-lateral membranes with a maximal specific activity (NaN3 plus Triton X-100) 10-fold that in brush border membranes. ATP enhanced guanylate cyclase activity only in basal-lateral membranes. It is proposed that guanylate cyclase, in addition to (Na+ + K+)-ATPase, be used as an enzyme "marker" for the renal basal-lateral membrane.     

Carbon monoxide and Ca2+-activated K+ channels in cerebral arteriolar responses to glutamate and hypoxia in newborn pigs

Large-conductance calcium-activated potassium (K(Ca)) channels regulate the physiological functions of many tissues, including cerebrovascular smooth muscle. l-Glutamic acid (glutamate) is the principal excitatory neurotransmitter in the central nervous system, and oxygen tension is a dominant local regulator of vascular tone. In vivo, glutamate and hypoxia dilate newborn pig cerebral arterioles, and both dilations are blocked by inhibition of carbon monoxide (CO) production. CO dilates cerebral arterioles by activating K(Ca) channels. Therefore, the present study was designed to investigate the effects of glutamate and hypoxia on cerebral CO production and the role of K(Ca) channels in the cerebral arteriolar dilations to glutamate and hypoxia. In the presence of iberiotoxin or paxilline that block dilation to the K(Ca) channel opener, NS-1619, neither CO nor glutamate dilated pial arterioles. Conversely, neither paxilline nor iberiotoxin inhibited dilation to acute severe or moderate prolonged hypoxia. Both glutamate and hypoxia increased cerebrospinal fluid (CSF) CO concentration. Iberiotoxin that blocked dilation to glutamate did not attenuate the increase in CSF CO. The guanylyl cyclase inhibitor, 1H-(1,2,4)oxadiazolo(4,3-a)quinoxalin-1-one (ODQ), which blocked dilation to sodium nitroprusside, did not inhibit dilation to hypoxia. These data suggest that dilation of newborn pig pial arterioles to glutamate is mediated by activation of K(Ca) channels, consistent with the intermediary signal being CO. Surprisingly, although 1) heme oxygenase (HO) inhibition attenuates dilation to hypoxia, 2) hypoxia increases CSF CO concentration, and 3) K(Ca) channel antagonists block dilation to CO, neither K(Ca) channel blockers nor ODQ altered dilation to hypoxia, suggesting the contribution of the HO/CO system to hypoxia-induced dilation is not by stimulating vascular smooth muscle K(Ca) channels or guanylyl cyclase.