Binding of nitric oxide and carbon monoxide to soluble guanylate cyclase as observed with Resonance raman spectroscopy

Inhibition of guanylate cyclase stimulation by NO and bovine arterial relaxation to peroxynitrite and H2O2

The inhibitor of soluble guanylate cyclase (sGC) stimulation by nitric oxide (NO), 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (ODQ), was examined for its effects on the prolonged relaxation of endothelium-removed bovine coronary (BCA) and pulmonary (BPA) arteries to peroxynitrite (ONOO-) and on H2O2-elicited relaxation and sGC stimulation. Our previous studies suggest that ONOO- causes a prolonged relaxation of BPA by regenerating NO and that a 2-min exposure of BCA or BPA to 50 nM NO causes an ONOO--elicited relaxation. The relaxation of K+-precontracted BCA to 50 nM NO or 100 microM ONOO- was essentially eliminated by 10 microM ODQ. ODQ also eliminated relaxation to 0.1 nM-10 microM of NO donor S-nitroso-N-acetyl-penicillamine (SNAP), but it did not alter relaxation to 1-300 microM H2O2. Similar responses were also observed in BPA. ODQ did not increase lucigenin-detectable superoxide production in BCA, and it did not alter luminol-detectable endogenous ONOO- formation observed during a 2-min exposure of BCA to 50 nM NO. In addition, ODQ did not affect tissue release of NO after 2 min exposure of BCA to 50 nM NO. The activity of sGC in BPA homogenate that is stimulated by endogenous H2O2 was not altered by ODQ, whereas sGC activity in the presence of 10 microM SNAP (+fungal catalase) was reduced by ODQ. Thus relaxation of K+-precontracted BCA and BPA to ONOO- appears to be completely mediated by NO stimulation of sGC, whereas the actions of ODQ suggest that NO is not involved in H2O2-elicited relaxation and sGC stimulation. This study did not detect evidence for the participation of additional mechanisms potentially activated by ONOO- in the responses studied.

Effects of nitric oxide and nitric oxide-derived species on prostaglandin endoperoxide synthase and prostaglandin biosynthesis

Prostaglandins and NO. are important mediators of inflammation and other physiological and pathophysiological processes. Continuous production of these molecules in chronic inflammatory conditions has been linked to development of autoimmune disorders, coronary artery disease, and cancer. There is mounting evidence for a biological relationship between prostanoid biosynthesis and NO. biosynthesis. Upon stimulation, many cells express high levels of nitric oxide synthase (NOS) and prostaglandin endoperoxide synthase (PGHS). There are reports of stimulation of prostaglandin biosynthesis in these cells by direct interaction between NO. and PGHS, but this is not universally observed. Clarification of the role of NO. in PGHS catalysis has been attempted by examining NO. interactions with purified PGHS, including binding to its heme prosthetic group, cysteines, and tyrosyl radicals. However, a clear picture of the mechanism of PGHS stimulation by NO. has not yet emerged. Available studies suggest that NO. may only be a precursor to the molecule that interacts with PGHS. Peroxynitrite (from O2.-+NO.) reacts directly with PGHS to activate prostaglandin synthesis. Furthermore, removal of O2.- from RAW 267.4 cells that produce NO. and PGHS inhibits prostaglandin biosynthesis to the same extent as NOS inhibitors. This interaction between reactive nitrogen species and PGHS may provide new approaches to the control of inflammation in acute and chronic settings.

Guanylate cyclase and the .NO/cGMP signaling pathway

Signal transduction with the diatomic radical nitric oxide (NO) is involved in a number of important physiological processes, including smooth muscle relaxation and neurotransmission. Soluble guanylate cyclase (sGC), a heterodimeric enzyme that converts guanosine triphosphate to cyclic guanosine monophosphate, is a critical component of this signaling pathway. sGC is a hemoprotein; it is through the specific interaction of NO with the sGC heme that sGC is activated. Over the last decade, much has been learned about the unique heme environment of sGC and its interaction with ligands like NO and carbon monoxide. This review will focus on the role of sGC in signaling, its relationship to the other nucleotide cyclases, and on what is known about sGC genetics, heme environment and catalysis. The latest understanding in regard to sGC will be incorporated to build a model of sGC structure, activation, catalytic mechanism and deactivation.

Heme-based sensors in biological systems

The past several years have been witness to a staggering rate of advancement in the understanding of how organisms respond to changes in the availability of diatomic molecules that are toxic and/or crucial to survival. Heme-based sensors presently constitute the majority of the proteins known to sense NO, O2 and CO and to initiate the chemistry required to adapt to changes in their availabilities. Knowledge of the three characterized members of this class, soluble guanylate cyclase, FixL and CooA, has grown substantially during the past year. The major advances have resulted from a broad range of approaches to elucidation of both function and mechanism. They include growth in the understanding of the interplay between the heme and protein in soluble guanylate cyclase, as well as alternate means for its stimulation. Insight into the O2-induced structural changes in FixL has been supplied by the single crystal structure of the heme domain of Bradyrhizobium japonicum. Finally, the ligation environment and ligand interchange that facilitates CO sensing by CooA has been established by spectroscopic and mutagenesis techniques.

EPR characterization of axial bond in metal center of native and cobalt-substituted guanylate cyclase

The nature of the metal-proximal base bond of soluble guanylate cyclase from bovine lung was examined by EPR spectroscopy. When the ferrous enzyme was mixed with NO, a new species was transiently produced and rapidly converted to a five-coordinate ferrous NO complex. The new species exhibited the EPR signal of six-coordinate ferrous NO complex with a feature of histidine-ligated heme. The histidine ligation was further examined by using the cobalt protoporphyrin IX-substituted enzyme. The Co2+-substituted enzyme exhibited EPR signals of a broad g perpendicular;1 component and a g;1 component with a poorly resolved triplet of 14N superhyperfine splittings, which was indicative of the histidine ligation. These EPR features were analogous to those of alpha-subunits of Co2+-hemoglobin in tense state, showing a tension on the iron-histidine bond of the enzyme. The binding of NO to the Co2+-enzyme markedly stimulated the cGMP production by forming the five-coordinate NO complex. We found that N3- elicited the activation of the ferric enzyme by yielding five-coordinate high spin N3- heme. These results indicated that the activation of the enzymes was initiated by NO binding to the metals and proceeded via breaking of the metal-histidine bonds, and suggested that the iron-histidine bond in the ferric enzyme heme was broken by N3- binding.

Identification of two important heme site residues (cysteine 75 and histidine 77) in CooA, the CO-sensing transcription factor of Rhodospirillum rubrum

The CO-sensing mechanism of the transcription factor CooA from Rhodospirillum rubrum was studied through a systematic mutational analysis of potential heme ligands. Previous electron paramagnetic resonance (EPR) spectroscopic studies on wild-type CooA suggested that oxidized (FeIII) CooA contains a low-spin heme with a thiolate ligand, presumably a cysteine, bound to its heme iron. In the present report, electronic absorption and EPR analysis of various substitutions at Cys residues establish that Cys75 is a heme ligand in FeIII CooA. However, characterization of heme stability and electronic properties of purified C75S CooA suggest that Cys75 is not a ligand in FeII CooA. Mutational analysis of all CooA His residues showed that His77 is critical for CO-stimulated transcription. On the basis of findings that H77Y CooA is perturbed in its FeII electronic properties and is unable to bind DNA in a site-specific manner in response to CO, His77 appears to be an axial ligand to FeII CooA. These results imply a ligand switch from Cys75 to His77 upon reduction of CooA. In addition, an interaction has been identified between Cys75 and His77 in FeIII CooA that may be involved in the CO-sensing mechanism. Finally, His77 is necessary for the proper conformational change of CooA upon CO binding.

Effect of heme oxygenase inhibitors on soluble guanylyl cyclase activity

NO is the physiological activator of soluble guanylyl cyclase (sGC) thereby acting as a signaling molecule in the nervous and cardiovascular systems. Despite its poor sGC-activating ability, CO, produced by the enzyme heme oxygenase (HO), has also been implicated as a physiological stimulator of sGC in neurotransmission and vasorelaxation. Zinc protoporphyrin IX (ZnPPIX) and tin protoporphyrin IX (SnPPIX) are competitive HO inhibitors and have been used in studies implicating a messenger role for CO in the brain and periphery; however, little is known about the specificity of these metalloporphyrins. In the present study, the effects of ZnPPIX and SnPPIX on sGC activity have been investigated in vitro. Interestingly, purified sGC is markedly activated by SnPPIX (20- to 30-fold) but has a very low affinity for this metalloporphyrin (Ka = 4.9 microM); high concentrations of SnPPIX (25 microM) still activated the enzyme. On the other hand, sGC has a high affinity for ZnPPIX (Ka = 16.1 nM). ZnPPIX activates heme-containing sGC weakly at low (nM) concentrations (3- to 4-fold) but at higher concentrations, ZnPPIX is a potent inhibitor; at 2.5 microM, it inhibits the basal activity of sGC by about 80%. These results imply that HO inhibitors may affect cGMP levels independently of HO activity.

Synergistic activation of soluble guanylate cyclase by YC-1 and carbon monoxide: implications for the role of cleavage of the iron-histidine bond during activation by nitric oxide

BACKGROUND

Nitric oxide (.NO) is used in biology as both an intercellular signaling agent and a cytotoxic agent. In signaling, submicromolar quantities of .NO stimulate the soluble isoform of guanylate cyclase (sGC) in the receptor cell. .NO increases the Vmax of this heterodimeric hemoprotein up to 400-fold by interacting with the heme moiety of sGC to form a 5-coordinate complex. Carbon monoxide (CO) binds to the heme to form a 6-coordinate complex, but only activates the enzyme 5-fold, YC-1 is a recently discovered compound that relaxes vascular smooth muscle by stimulating sGC.

RESULTS

In the presence of YC-1, CO activates sGC to the same specific activity as attained with .NO. YC-1 did not affect the NO-stimulated activity. The on-rate (kon) and off-rate (koff) of CO for binding to sGC in the presence of YC-1 were determined by stopped-flow spectrophotometry. Neither the kon nor the koff varied from values previously obtained in the absence of YC-1, indicating that YC-1 has no effect on the affinity of CO for the heme. In the presence of YC-1, the visible spectrum of the sGC-CO complex has a Soret peak at 423 nm, indicating the complex is 6-coordinate.

CONCLUSIONS

YC-1 has no effect on the affinity of CO for the heme of sGC. In the presence of YC-1, maximal activation of sGC by CO is achieved by formation of a 6-coordinate complex between CO and the heme indicating that cleavage of the Fe-His bond is not required for maximal activation of sGC.

The deactivation of soluble guanylyl cyclase by redox-active agents

Soluble guanylyl cyclase (sGC), an enzyme involved in cGMP signal transduction, is activated by NO binding to the endogenous heme. The mechanism of deactivation is not known. In tissues, cGMP levels decrease within minutes, despite the fact that sGC is activated to levels above the phosphodiesterase activity. Simple dissociation of NO from the heme in sGC has been suggested as a possible deactivation mechanism; however, dissociation rates of NO from ferrous heme proteins are typically very slow. Since oxidants and reductants are known to affect sGC activity, we have tested the effect of a variety of redox-active agents on the activity of NO-activated sGC. All the redox-active compounds tested, covering a wide range of reduction potentials, selectively deactivated the NO-activated sGC while having little or no effect on the basal activity of the enzyme. Among the reagents studied in detail, deactivation of sGC by air occurred slowly, while deactivation by ferricyanide was faster and methylene blue was fastest. The mechanism of deactivation of sGC by dioxygen in the air is straightforward: the heme is oxidized to Fe(III)heme and nitrate is formed. This reaction is similar to that of dioxygen with NOHb and NOMb as occurs in cured meats. Methylene blue and ferricyanide deactivate sGC by a different, as yet undetermined, mechanism.

Nitrosylation of Octaethylporphyrin Osmium Complexes with Alkyl Nitrites and Thionitrites: Molecular Structures of Three Osmium Porphyrin Derivatives

(OEP)Os(CO) reacts with n-butyl nitrite to give, after workup, the (OEP)Os(NO)(O-n-Bu) trans addition product (OEP = octaethylporphyrinato dianion). Similarly, the reaction of (OEP)Os(CO) or [(OEP)Os](2) with isoamyl nitrite gives the corresponding nitrosyl alkoxide, (OEP)Os(NO)(O-i-C(5)H(11)). The related reactions of (OEP)Os(CO) or [(OEP)Os](2) with isoamyl thionitrite gives the (OEP)Os(NO)(S-i-C(5)H(11)) nitrosyl thiolate. The reaction of the [(OEP)Os](2)(PF(6))(2) reagent with isoamyl thionitrite gives the nitrosylation product, [(OEP)Os(NO)]PF(6), which undergoes anion hydrolysis to give the isolable difluorophosphate (OEP)Os(NO)(O(2)PF(2)) derivative. Interestingly, the reaction of O(2)NC(6)H(4)N=NSPh with [(OEP)Os](2) gives the (OEP)Os(SPh)(2) product with loss of the arylazo fragments. The solid-state structures of (OEP)Os(NO)(O-n-Bu), (OEP)Os(NO)(O(2)PF(2)), and (OEP)Os(SPh)(2) have been determined by X-ray crystallography.

New physiological importance of two classic residual products: carbon monoxide and bilirubin

Heme oxygenase the rate-limiting step in the degradation of heme to bilirubin, generates carbon monoxide. This gaseous molecule plays important roles in neuronal signaling and modulation of vascular tone. Additionally, carbon monoxide is involved in some pathological conditions (e.g., ischemia, endotoxic shock, excitotoxicity) as a protective or toxic factor. Bilirubin, another heme metabolite, exhibits intriguing biological activities as an antioxidant, an antimutagen, and an anti-complement agent. Vital functions and the dual nature displayed by these two heme metabolites are discussed.