Expression of soluble guanylate cyclase activity requires both enzyme subunits.

Soluble guanylate cyclase purified from rat lung exists as a heterodimer of two subunits (70 kDa and 82 kDa). Recent cloning and sequencing of both subunit entities have revealed their primary structures. Transient expression in COS-7 cells by transfection with expression vectors containing the coding regions of the 70 kDa or the 82 kDa subunit cDNA showed no guanylate cyclase activity when cells were transfected with either subunit cDNA alone. However, a marked enzymatic activity was found after transfection with both subunits that was activated by sodium nitroprusside. The combination of separately expressed guanylate cyclase subunits could not reconstitute enzymatic activity in vitro. Furthermore, cotransfection with antisense oligonucleotides against the 70 kDa subunit or the 82 kDa subunit mRNA inhibited the guanylate cyclase activity. These data indicate that both the 70 kDa and the 82 kDa subunits must be present and interactive with each other in order to see basal guanylate cyclase activity and activation with sodium nitroprusside.     

Immunolocalization of soluble guanylyl cyclase subunits in rat kidney

Stimulation of soluble guanylyl cyclase (SGC) by nitric oxide (NO) results in the generation of cyclic guanosine monophosphate (cGMP). We recently described expression of abundant nitric oxide synthase, the enzyme by which NO is generated froml-arginine, in macula densa cells of rat kidney at the protein and mRNA level. In the present study we looked for possible targets of NO in the kidney. By light and electron microscopy, we applied polyclonal antisera against four subunits (₁,₂, ₁₂) of SGC in immunocytochemical studies of frozen sections of rat kidney. We demonstrate the presence of ₁-subunit in glomerular podocytes and of ₂-subunit in principal cells of the collecting duct. In both cell types a cytosolic localization was evident from ultrastructural analysis. Regarding the collecting duct, NO was shown by other authors to inhibit sodium reabsorption in cultured mouse cortical collecting duct principal cells. In podocytes NO may relax the contractile system of podocyte foot processes, the tone of which has been suggested to counteract the elastic distension of the capillary wall.     

Nucleotidyl cyclase activity of soluble guanylyl cyclase in intact cells

Soluble guanylyl cyclase (sGC) is activated by nitric oxide (NO) and generates the second messenger cyclic GMP (cGMP). Recently, purified sGC α₁β₁ has been shown to additionally generate the cyclic pyrimidine nucleotides cCMP and cUMP. However, since cyclic pyrimidine nucleotide formation occurred only the presence of Mn²⁺ but not Mg²⁺, the physiological relevance of these in vitro findings remained unclear. Therefore, we studied cyclic nucleotide formation in intact cells. We observed NO-dependent cCMP- and cUMP formation in intact HEK293 cells overexpressing sGC α₁β₁ and in RFL-6 rat fibroblasts endogenously expressing sGC, using HPLC–tandem mass spectrometry. The identity of cCMP and cUMP was unambiguously confirmed by HPLC–time-of-flight mass spectrometry. Our data indicate that cCMP and cUMP play second messenger roles and that Mn²⁺ is a physiological sGC cofactor.     

Sensitizing soluble guanylyl cyclase to become a highly CO-sensitive enzyme.

It took at least a decade to realize that the toxic gas NO is the physiological activator of soluble guanylyl cyclase (sGC), thereby acting as a signaling molecule in the nervous and cardiovascular systems. Despite its rather poor sGC-activating property, CO has also been implicated as a physiological stimulator of sGC in neurotransmission and vasorelaxation. Here, we establish YC-1 as a novel NO-independent sGC activator that potentiates both CO- and NO-induced sGC stimulation. As this potentiating effect is also observed with protoporphyrin IX which activates sGC independently of a gaseous ligand, we conclude that stabilization of the enzyme's active configuration is the underlying mechanism of YC-1's action. Moreover, the results obtained with YC-1 reveal that CO is capable of stimulating sGC to a degree similar to NO, and thus provide the molecular basis for CO functioning as a signaling molecule.     

The primary structure of the larger subunit of soluble guanylyl cyclase from bovine lung. Homology between the two subunits of the enzyme

The primary structure of the larger subunit of the soluble guanylyl cyclase from bovine lung, which catalyzes the formation of cyclic GMP from GTP, has been determined. Two clones, isolated from two bovine libraries yielded a total of 3261 bp with a coding region of 2073 bp. The open reading frame encodes a protein of 691 amino acids and a molecular mass of 77,500. The deduced amino acid sequence reveals regions which are, to a large extent, homologous to the sequence of the smaller subunit of the enzyme as well as to the sequences of other gyanylyl and adenylyl to a large extent, homologous to the sequence of the smaller subunit of the enzyme as well as to the sequences of other gyanylyl and adenylyl cyclases.     

Molecular cloning of the cDNAs coding for the two subunits of soluble guanylyl cyclase from human brain.

Complementary DNA clones corresponding to the 70 and 82 kDa subunits of soluble guanylyl cyclase from human adult brain have been isolated and sequenced. Their respective open reading frames correspond to 619 amino acids (M(r) 70,469) and 717 amino acids (M(r) 81,324). Southern blots of human genomic DNA using these clones as probes give patterns which might be compatible with the presence of more than one copy per gene, or pseudogenes, for each subunit in the human genome. Comparison of the protein sequence of the large subunit from adult brain with the subunit cloned from human fetal brain (Harteneck, C., Wedel, B., Koesling, D., Malekewitz, J., B?hme, E., and Schultz, G. (1991) FEBS Lett. 292, 217-222) revealed only 34% homology. This result demonstrates the existence of a novel large subunit isoform for soluble guanylyl cyclase in human tissues.     

Dark-dependent soluble guanylyl cyclase activity in locust photoreceptor cells

The enzyme soluble guanylyl cyclase (SGC) mediates physiological effects of the gaseous signalling molecule nitric oxide by generating the second messenger molecule cyclic-GMP (cGMP). Here we have demonstrated that SGC is expressed in photoreceptor cells of locust compound eyes. However, stimulation of SGC activity in the eyes was observed only in the dark, indicating that light may cause inhibition of SGC activity in locust photoreceptor cells. Because light causes elevation of cytosolic Ca²⁺ in insect photoreceptor cells, we investigated the involvement of Ca²⁺ in mediating the inhibitory effect of light on SGC activity in the locust eye. Light-adapted locust eyes incubated with Ca²⁺-free physiological saline displayed a similar level of stimulated SGC activity to that normally seen only in dark-adapted eyes. These data indicate for the first time that Ca²⁺ may regulate SGC activity in cells. Moreover, the dark dependence of SGC activity in the locust eye suggests that SGC and cGMP may participate in dark-adaptation mechanisms in insect photoreceptor cells.     

Homodimerization of soluble guanylyl cyclase subunits. Dimerization analysis using a glutathione s-transferase affinity tag.

Soluble guanylyl cyclase (sGC) is an alpha/beta-heterodimeric hemoprotein that, upon interaction with the intercellular messenger molecule NO, generates cGMP. Although the related family of particulate guanylyl cyclases (pGCs) forms active homodimeric complexes, it is not known whether homodimerization of sGC subunits occurs. We report here the expression in Sf9 cells of glutathione S-transferase-tagged recombinant human sGCalpha1 and beta1 subunits, applying a novel and rapid purification method based on GSH-Sepharose affinity chromatography. Surprisingly, in intact Sf9 cells, both homodimeric GSTalpha/alpha and GSTbeta/beta complexes were formed that were catalytically inactive. Upon coexpression of the respective complementary subunits, GSTalpha/beta or GSTbeta/alpha heterodimers were preferentially formed, whereas homodimers were still detectable. When subunits were mixed after expression, e.g. GSTbeta and beta or GSTalpha and beta, no dimerization was observed. In conclusion, our data suggest the previously unrecognized possibility of a physiological equilibrium between homo- and heterodimeric sGC complexes.     

The effect of peroxynitrite on the catalytic activity of soluble guanylyl cyclase.

Soluble guanylyl cyclase (sGC) is a key enzyme of the *NO/cGMP pathway. Many cardiovascular disorders are associated with reduced *NO-mediated effects, while vascular superoxide (O(2)*(-)) production is increased. Both radicals rapidly react to peroxynitrite. We investigated whether peroxynitrite affects the activity and protein expression of sGC in intact vascular preparations. Catalytic sGC activity and expression of the sGC-beta(1) subunit was measured by conversion of radiolabeled GTP and western blot, respectively, using cytosolic extracts from rat aorta that had been incubated for 4 h with *NO/O(2)*(-) systems (devoid of free *NO) generating either 0.13 microM or 7.5 microM peroxynitrite/min. Incubation of rat aorta with 0.13 microM peroxynitrite/min had no effect. In striking contrast, incubation with 7.5 microM peroxynitrite/min resulted in a shift of the concentration-response curve obtained with a *NO donor (p =.0004) and a reduction of maximal specific activity from 3579 +/- 495 to 2422 +/- 265 pmol cGMP/mg/min (p =.036). The expression of the sGC-beta(1) subunit was unchanged. Exposure of aorta to the O(2)*(-) component had no effect, while exposure to the *NO-component reduced sGC expression to 58.8 +/- 7% (p <.001) and maximal sGC activity from 4041 +/- 992 to 1429 +/- 491 pmol cGMP/mg/min (p =.031). These data suggest that continuous generation of extracellular peroxynitrite might interfere with the *NO/cGMP signaling in vascular cells.     

Spontaneous and receptor-controlled soluble guanylyl cyclase activity in anterior pituitary cells

Nitric oxide (NO)-dependent soluble guanylyl cyclase (sGC) is operative in mammalian cells, but its presence and the role in cGMP production in pituitary cells have been incompletely characterized. Here we show that sGC is expressed in pituitary tissue and dispersed cells, enriched lactotrophs and somatotrophs, and GH(3) immortalized cells, and that this enzyme is exclusively responsible for cGMP production in unstimulated cells. Basal sGC activity was partially dependent on voltage-gated calcium influx, and both calcium-sensitive NO synthases (NOS), neuronal and endothelial, were expressed in pituitary tissue and mixed cells, enriched lactotrophs and somatotrophs, and GH(3) cells. Calcium-independent inducible NOS was transiently expressed in cultured lactotrophs and somatotrophs after the dispersion of cells, but not in GH(3) cells and pituitary tissue. This enzyme participated in the control of basal sGC activity in cultured pituitary cells. The overexpression of inducible NOS by lipopolysaccharide + interferon-gamma further increased NO and cGMP levels, and the majority of de novo produced cGMP was rapidly released. Addition of an NO donor to perifused pituitary cells also led to a rapid cGMP release. Calcium-mobilizing agonists TRH and GnRH slightly increased basal cGMP production, but only when added in high concentrations. In contrast, adenylyl cyclase agonists GHRH and CRF induced a robust increase in cGMP production, with EC(50)s in the physiological concentration range. As in cells overexpressing inducible NOS, the stimulatory action of GHRH and CRF was preserved in cells bathed in calcium-deficient medium, but was not associated with a measurable increase in NO production. These results indicate that sGC is present in secretory anterior pituitary cells and is regulated in an NO-dependent manner through constitutively expressed neuronal and endothelial NOS and transiently expressed inducible NOS, as well as independently of NO by adenylyl cyclase coupled-receptors.     

Dependence of soluble guanylyl cyclase activity on calcium signaling in pituitary cells

The role of nitric oxide (NO) in the stimulation of soluble guanylyl cyclase (sGC) is well established, but the mechanism by which the enzyme is inactivated during the prolonged NO stimulation has not been characterized. In this paper we studied the interactions between NO and intracellular Ca(2+) in the control of sGC in rat anterior pituitary cells. Experiments were done in cultured cells, which expressed neuronal and endothelial NO synthases, and in cells with elevated NO levels induced by the expression of inducible NO synthase and by the addition of several NO donors. Basal sGC-dependent cGMP production was stimulated by the increase in NO levels in a time-dependent manner. In contrast, depolarization of cells by high K(+) and Bay K 8644, an L-type Ca(2+) channel agonist, inhibited sGC activity. Depolarization-induced down-regulation of sGC activity was also observed in cells with inhibited cGMP-dependent phosphodiesterases but not in cells bathed in Ca(2+)-deficient medium. This inhibition was independent from the pattern of Ca(2+) signaling (oscillatory versus nonoscillatory) and NO levels, and was determined by averaged concentration of intracellular Ca(2+). These results indicate that inactivation of sGC by intracellular Ca(2+) serves as a negative feedback to break the stimulatory action of NO on enzyme activity in intact pituitary cells.     

Hemoglobin mediated nitrite activation of soluble guanylyl cyclase

Nitrite has long been known to be vasoactive when present at large concentrations but it was thought to be inactive under physiological conditions. Surprisingly, we have recently shown that supraphysiological and near physiological concentrations of nitrite cause vasodilation in the human circulation. These effects appeared to result from reduction of nitrite by deoxygenated hemoglobin. Thus, nitrite was proposed to play a role in hypoxic vasodilation. We now discuss these results in the context of nitrite reacting with hemoglobin and effecting vasodilation and present new data modeling the nitric oxide (NO) export from the red blood cell and measurements of soluble guanylate cyclase (sGC) activation. We conclude that NO generated within the interior of the red blood cell is not likely to be effectively exported directly as nitric oxide. Thus, an intermediate species must be formed by the nitrite/deoxyhemoglobin reaction that escapes the red cell and effects vasodilation.     

Regulation of nitric oxide-responsive recombinant soluble guanylyl cyclase by calcium.

Calcium (Ca2+) and cyclic GMP (cGMP) subserve antagonistic functions that are reflected in their coordinated reciprocal regulation in physiological systems. However, molecular mechanisms by which Ca2+ regulates cGMP-dependent signaling remain incompletely defined. In this study, the inhibition of recombinant nitric oxide (NO)-stimulated soluble guanylyl cyclase (SGC) by Ca2+ was demonstrated. The alpha- and beta-subunits of recombinant rat SGC were heterologously coexpressed in HEK 293 cells which do not express NO synthase, whose Ca2+-stimulated activity can confound the effects of that cation on SGC. Ca2+ inhibited basal and NO-stimulated SGC in a concentration- and guanine nucleotide-dependent fashion. This cation inhibited SGC in crude cell extracts and immunopurified preparations. Ca2+ lowered both the Vmax and Km of SGC via an uncompetitive mechanism through direct interaction with the enzyme. In intact HEK 293 cells, increases in the intracellular Ca2+ concentration induced by ionomycin, a Ca2+ ionophore, and thapsigargin, which releases intracellular stores of that cation, inhibited NO-stimulated intracellular cGMP accumulation. Similarly, carbachol-induced elevation of the intracellular Ca2+ concentration inhibited NO-stimulated intracellular cGMP accumulation in HEK 293 cells. These data demonstrate that SGC behaves as a sensitive Ca2+ detector that may play a central role in coordinating the reciprocal regulation of Ca2+- and cGMP-dependent signaling mechanisms.     

Studying the structure and regulation of soluble guanylyl cyclase

Soluble guanylyl cyclase acts as the receptor for the signaling molecule nitric oxide. The enzyme consists of two different subunits. Each subunit shows the cyclase catalytic domain, which is also conserved in the membrane-bound guanylyl cyclases and the adenylyl cyclases. The N-terminal regions of the subunits are responsible for binding of the prosthetic heme group of the enzyme, which is required for the stimulatory effect of nitric oxide (NO). The five-coordinated ferrous heme displays a histidine as the axial ligand; activation of soluble guanylyl cyclase by NO is initiated by binding of NO to the heme iron and proceeds via breaking of the histidine-to-iron bond. Recently, a novel pharmacological and possibly physiological principle of guanylyl cyclase sensitization was demonstrated. The substance YC-1 has been shown to activate the enzyme independent of NO, to potentiate the effect of submaximally effective NO concentrations, and to turn carbon monoxide into an effective activator of soluble guanylyl cyclase.     

The Dictyostelium homologue of mammalian soluble adenylyl cyclase encodes a guanylyl cyclase

A new Dictyostelium discoideum cyclase gene was identified that encodes a protein (sGC) with 35% similarity to mammalian soluble adenylyl cyclase (sAC). Gene disruption of sGC has no effect on adenylyl cyclase activity and results in a >10-fold reduction in guanylyl cyclase activity. The scg- null mutants show reduced chemotactic sensitivity and aggregate poorly under stringent conditions. With Mn(2+)/GTP as substrate, most of the sGC activity is soluble, but with the more physiological Mg(2+)/GTP the activity is detected in membranes and stimulated by GTPgammaS. Unexpectedly, orthologues of sGC and sAC are present in bacteria and vertebrates, but absent from Drosophila melanogaster, Caenorhabditis elegans, Arabidopsis thaliana and Saccharomyces cerevisiae.     

Amphipathic alpha-helix mediates the heterodimerization of soluble guanylyl cyclase

Soluble guanylyl cyclase (soluble GC) is an enzyme consisting of alpha and beta subunits and catalyzes the conversion of GTP to cGMP. The formation of the heterodimer is essential for the activity of soluble GC. Each subunit of soluble GC has been shown to comprize three functionally different parts: a C-terminal catalytic domain, a central dimerization domain, and an N-terminal regulatory domain. The central dimerization domain of the beta(1) subunit, which contains an N-terminal binding site (NBS) and a C-terminal binding site (CBS), has been postulated to be responsible for the formation of alpha/ beta heterodimer. In this study, we analyzed heterodimerization by the pull-down assay using the affinity between a histidine tag and Ni(2+) Sepharose after co-expression of various N- and C-terminally truncated FLAG-tagged mutants of the alpha(1) subunit and the histidine-tagged wild type of the beta(1) subunit in the vaculovirus/Sf9 system, and demonstrated that the CBS-like sequence of the alpha(1) subunit is critical for the formation of the heterodimer with the beta(1) subunit and the NBS-like sequence of the alpha(1) subunit is essential for the formation of the enzymatically active heterodimer, although this particular sequence was not involved in heterodimerization. The analysis of the secondary structure of the alpha(1) subunit predicted the existence of an amphipathic alpha-helix in residues 431-464. Experiments with site-directed alpha(1) subunit mutant proteins demonstrated that the amphipathicity of the alpha-helix is important for the formation of the heterodimer, and Leu(463) in the alpha-helix region plays a critical role in the formation of a properly arranged active center in the dimer.     

Mapping of heme-binding domains in soluble guanylyl cyclase beta1 subunit.

Soluble guanylyl cyclase (sGC) is activated upon the interaction of NO with heme in the sGC beta1 subunit. To identify the domains contributing to heme-binding, we constructed a series of deletion mutants of the beta1 subunit, and evaluated their heme-binding capability. Deletion mutants consisting of residues 1-120 [beta1(1-120)] and 80-385 [beta1(80-385)] were the shortest mutants exhibiting heme binding among the C-terminal and N-terminal-truncated mutants, respectively. The region common to both beta1(1-120) and beta1(80-385), i.e., residues 80-120, is therefore essential for heme binding, although the residues 341-385 play an auxiliary role in heme binding. Two deletion mutants, beta1(80-195) and beta1(60-195), which include only the essential region, exhibited strong heme binding and spectral properties similar to those of the nitrosyl complex of native sGC. Thus, these heme-binding core proteins may serve as model proteins for future studies on the tertiary structure of the nitrosyl complex of sGC.     

Allostery in recombinant soluble guanylyl cyclase from Manduca sexta

Soluble guanylyl/guanylate cyclase (sGC), the primary biological receptor for nitric oxide, is required for proper development and health in all animals. We have expressed heterodimeric full-length and N-terminal fragments of Manduca sexta sGC in Escherichia coli, the first time this has been accomplished for any sGC, and have performed the first functional analyses of an insect sGC. Manduca sGC behaves much like its mammalian counterparts, displaying a 170-fold stimulation by NO and sensitivity to compound YC-1. YC-1 reduces the NO and CO off-rates for the approximately 100-kDa N-terminal heterodimeric fragment and increases the CO affinity by approximately 50-fold to 1.7 microm. Binding of NO leads to a transient six-coordinate intermediate, followed by release of the proximal histidine to yield a five-coordinate nitrosyl complex (k(6-5) = 12.8 s(-1)). The conversion rate is insensitive to nucleotides, YC-1, and changes in NO concentration up to approximately 30 microm. NO release is biphasic in the absence of YC-1 (k(off1) = 0.10 s(-1) and k(off2) = 0.0015 s(-1)); binding of YC-1 eliminates the fast phase but has little effect on the slower phase. Our data are consistent with a model for allosteric activation in which sGC undergoes a simple switch between two conformations, with an open or a closed heme pocket, integrating the influence of numerous effectors to give the final catalytic rate. Importantly, YC-1 binding occurs in the N-terminal two-thirds of the protein. Homology modeling and mutagenesis experiments suggest the presence of an H-NOX domain in the alpha subunit with importance for heme binding.