NO Signaling Pathway Research Articles

CGMP-Dependent Protein Kinases and cGMP Phosphodiesterases in Nitric Oxide and cGMP Action

To date, studies suggest that biological signaling by nitric oxide (NO) is primarily mediated by cGMP, which is synthesized by NO-activated guanylyl cyclases and broken down by cyclic nucleotide phosphodiesterases (PDEs). Effects of cGMP occur through three main groups of cellular targets: cGMP-dependent protein kinases (PKGs), cGMP-gated cation channels, and PDEs. cGMP binding activates PKG, which phosphorylates serines and threonines on many cellular proteins, frequently resulting in changes in activity or function, subcellular localization, or regulatory features. The proteins that are so modified by PKG commonly regulate calcium homeostasis, calcium sensitivity of cellular proteins, platelet activation and adhesion, smooth muscle contraction, cardiac function, gene expression, feedback of the NO-signaling pathway, and other processes. Current therapies that have successfully targeted the NO-signaling pathway include nitrovasodilators (nitroglycerin), PDE5 inhibitors [sildenafil (Viagra and Revatio), vardenafil (Levitra), and tadalafil (Cialis and Adcirca)] for treatment of a number of vascular diseases including angina pectoris, erectile dysfunction, and pulmonary hypertension; the PDE3 inhibitors [cilostazol (Pletal) and milrinone (Primacor)] are used for treatment of intermittent claudication and acute heart failure, respectively. Potential for use of these medications in the treatment of other maladies continues to emerge.

Muscarinic acetylcholine receptor dependent pulmonary arterial contractility is reduced by chronic hypoxia in fetal sheep

Muscarinic acetylcholine (ACh) receptor (mAChR) activation relaxes arteries through endothelium‐dependent NO signaling pathways and endothelium removal from most systemic arteries alleviates ACh mediated relaxation. However, Ach induces “paradoxical” contractility in endothelium disrupted pulmonary arteries (PA) through mAChR activation, such as may occur with chronic hypoxia (CH). Given the intimacy between endothelial and myocyte function, and the potential for CH altering PA vasodilation, we tested the hypothesis that CH also reduces mAChR‐dependent PA contractility. This hypothesis was tested on endothelium‐denuded PA rings from near term fetal or adult sheep at low altitude or following 100+ days at 3801 m (CH). Ach or carbachol (10–100 μM) contracted PAs and CH reduced contractility in fetuses. In PA from CH adults, dose‐dependent carbachol elicited contractions were inhibited with the non‐selective mAChR antagonist atropine, and by selective inhibition of M2 mAChRs with 1 μM AF‐DX 116 or M3 mAChRs with 0.1 μM Dau 5884 or 4‐DAMP, but not M1 mAChRs with 0.1 μM pirenzipine. The studies suggest M3 and possibly M2 mAChR are important to ACh‐mediated PA contractility, and that CH reduces this contractility in fetuses. Presumably, mAChR activity helps match ventilation to perfusion and in CH fetus the loss of mAChR‐related contractility may help preserve this function. NIH P01HD031226, R01HD003807 (LDL)

PECAM‐1 Gene Ablation Impairs Endothelium‐Dependent Relaxation

Platelet endothelial cell adhesion molecule‐1 (PECAM‐1 or CD31), a 130 kDa type I glycoprotein, is a complex molecule that has been widely implicated in the pathogenesis of cardiovascular conditions. Current evidence indicates this molecule serves as a mechanosensor that is integral to flow mediated vascular remodeling. We hypothesize that PECAM‐1 may regulate vascular function through the NO signaling pathway. Contractile responses to the receptor‐independent agonist, KCl, and the receptor‐dependent agonist, phenylephrine, were measured in aortic rings from wild‐type (WT) and PECAM‐1 knockout (KO) mice. Force generation was analyzed with respect to agonist sensitivity and force/cross‐sectional area. Relaxation responses to the endothelium‐dependent agonist, acetylcholine, and the endothelium‐independent agonist, sodium nitroprusside (SNP), were also measured. Contractile sensitivity and maximum force to phenylephrine or KCl was comparable in WT and KO rings. Although aortic rings from WT and KO mice responded similarly to SNP, rings from KO mice were less sensitive to acetylcholine‐mediated relaxation (p<0.01; n=5). These findings indicate that PECAM‐1 plays a significant role in acetylcholine‐mediated vascular relaxation and suggest that alterations in PECAM expression or function may contribute to vascular dysregulation. Supported by HL070892 (RLS); HL079090 (HMD) and the Atlanta VA Research Service (CMH)

Sphingosine 1‐Phosphate (S1P) Prevents Platelet Activating Factor (PAF)‐ Induced Permeability Increases by Activation of Rac‐1 Signaling in Intact Venules

S1P has been shown to enhance endothelial (EC) barrier function in vitro and prevent hyperpermeability in vivo. Our present study aims to identify the signaling mechanisms of S1P in regulation of microvessel permeability in intact microvessels using combined permeability measurements with confocal vascular structural analysis. Microvessel permeability was determined by measuring hydraulic conductivity (Lp). Rac‐1‐dependent signaling was examined using Rac 1 inhibitor NSC23766 (NSC, 200 μM). NO was measured in DAF‐2 loaded microvessels. EC gap formation and changes in VE‐cadherin was examined with confocal microscopy using fluorescence microspheres or antibody staining. Results showed that preperfusing vessels with S1P abolished PAF‐induced gap formation and VE‐cadherin redistribution without affecting PAF‐induced increases in EC [Ca2+]i and NO production. Perfusing vessels with NSC did not affect basal Lp and VE‐cadherin but abolished the inhibition of S1P on PAF‐induced Lp increases, EC gap formation, and VE‐cadherin disruption. In the presence of NSC and S1P, the peak Lp in response to PAF was restored to 7.2 ± 2 times that of the control and VE‐cadherin showed no significant difference from that with PAF alone. These results provide the first evidence in intact microvessels that S1P inhibits permeability increases by Rac1 signaling on EC AJ, which is either downstream from or independent of the initial EC Ca2+ and NO signaling pathways. Supported by HL56237 and HL084338.

Progressive endothelial cell damage in an inflammatory model of pulmonary hypertension

ABSTRACTMonocrotaline (MCT)-induces progressive disruption of endothelial cell membrane and caveolin-1 leading to pulmonary arterial hypertension (PAH). Treatment instituted early rescues caveolin-1 and attenuates PAH. To test the hypothesis that the poor response to therapy in established PAH is due to progressive deregulation of multiple signaling pathways, the authors investigated time-dependent changes in the expression of caveolin-1, gp130, PY-STAT3, Bcl-xL, and the molecules involved in NO signaling pathway (endothelial nitric oxide synthase [[eNOS]], heat sock protein 90 [[HSP90]], Akt, soluble guanylate cyclase [[sGC]] α1 and β1 subunits). PAH and right ventricular hypertrophy (RVH) were observed at 2 and 3 weeks. Progressive loss of endothelial caveolin-1 and sGC (α1, β1), PY-STAT3 activation, and Bcl-xL expression were observed at 1 to 3 weeks post-MCT. The expression of gp130 increased at 48 hours and 1 week, with a subsequent loss at 2 and 3 weeks. The expression of eNOS increased at 48 hours and 1 week post-MCT, with a significant loss at 3 weeks. The expression of HSP90 and Akt decreased at 2 and 3 weeks post-MCT concomitant with PAH. Thus, MCT induces progressive loss of membrane and cytosolic proteins, resulting in the activation of proliferative and antiapoptotic factors, and deregulation of NO signaling leading to PAH. An attractive therapeutic approach to treat PAH may be an attempt to rescue endothelial cell membrane integrity.

Efficient expression of human soluble guanylate cyclase in Escherichia coli and its signaling-related interaction with nitric oxide

Soluble guanylate cyclase (sGC), as a nitric oxide (NO) sensor, is a critical heme-containing enzyme in NO-signaling pathway of eukaryotes. Human sGC is a heterodimeric hemoprotein, composed of a alpha-subunit (690 AA) and a heme-binding beta-subunit (619 AA). Upon NO binding, sGC catalyzes the conversion of guanosine 5'-triphosphate (GTP) to 3',5'-cyclic guanosine monophosphate (cGMP). cGMP is a second messenger and initiates the nitric oxide signaling, triggering vasodilatation, smooth muscle relaxation, platelet aggregation, and neuronal transmission etc. The breakthrough of the bottle neck problem for sGC-mediated NO singling was made in this study. The recombinant human sGC beta1 subunit (HsGC beta 619) and its truncated N-terminal fragments (HsGC beta 195 and HsGC beta 384) were efficiently expressed in Escherichia coli and purified successfully in quantities. The three proteins in different forms (ferric, ferrous, NO-bound, CO-bound) were characterized by UV-vis and EPR spectroscopy. The homology structure model of the human sGC heme domain was constructed, and the mechanism for NO binding to sGC was proposed. The EPR spectra showed a characteristic of five-coordinated heme-nitrosyl species with triplet hyperfine splitting of NO. The interaction between NO and sGC was investigated and the schematic mechanism was proposed. This study provides new insights into the structure and NO-binding of human sGC. Furthermore, the efficient expression system of E. coli will be beneficial to the further studies on structure and activation mechanism of human sGC.

Early observations of nitric oxide synthase in the intact brain and regenerating tentacle of the snail, Helix pomatia

Event Abstract Back to Event Early observations of nitric oxide synthase in the intact brain and regenerating tentacle of the snail, Helix pomatia Zoltán Serfözö1* and Károly Elekes1 1 Balaton Limnological Research Institute, HAS, Department of Experimental Zoology, Hungary In the present study, the regeneration dynamics of the Helix tentacle which is an established model for neuronal as well as organ regeneration was investigated by NADPH-diaphorase (NADPH-d) reaction which is the histochemical marker for nitric oxide synthase (NOS). The NOS activity and expression, as well as its possible impact on cysteine and tyrosine nitrosylation were also followed in intact brain and tentacle. In a period of 15 weeks, the terminal part of the right tentacle of ten animals was cut by every odd week; meanwhile the left tentacle of these groups remained intact for control. Neurons of the tentacular ganglion, their projections in the tentacular nerve innervating the lateral neuropil and the globuli cells of the procerebrum, showed NADPH-d reactivity. After 1 week of tentacle extirpation a faint NADPH-d reactivity was still seen in the distal part of injured axons of the tentacular nerve. At 10 weeks of regeneration NADPH-d reactivity reappeared in the newly forming tentacular ganglion, and a similar distribution to the control was obtained by 13 weeks. NOS activity of the brain was found 1422±42 dpm 14C citrulline/mg/ml protein/min/5 animals (n=4), whereas it was 2212±50 dpm in the tentacular ganglia. A fivefold dilution of the extracts resulted in an approx. five times higher activity in the brain (6691±193 dpm; n=4). L-NAME substrate analogue inhibitor proved not to be effective. From total brain extract a 140-150 kDa protein was detected by an anti-universal NOS antibody that was also labeled by an anti-S-nitrosocysteine antibody. In addition, cysteine nitrosylation was also found in other 5 proteins of 180, 170, 80, 50, and 40 kDa mw, respectively, whereas tyrosine nitration was not present in the intact Helix brain. These preliminary results show the presence of the NO signaling pathway in the snail CNS and tentacle and also suggest a possible involvement of NO in the tentacle regeneration. Supported by the OTKA PD75276 and K78224 grants. Conference: IBRO International Workshop 2010, Pécs, Hungary, 21 Jan - 23 Jan, 2010. Presentation Type: Poster Presentation Topic: Sensory and motor systems Citation: Serfözö Z and Elekes K (2010). Early observations of nitric oxide synthase in the intact brain and regenerating tentacle of the snail, Helix pomatia. Front. Neurosci. Conference Abstract: IBRO International Workshop 2010. doi: 10.3389/conf.fnins.2010.10.00267 Copyright: The abstracts in this collection have not been subject to any Frontiers peer review or checks, and are not endorsed by Frontiers. They are made available through the Frontiers publishing platform as a service to conference organizers and presenters. The copyright in the individual abstracts is owned by the author of each abstract or his/her employer unless otherwise stated. Each abstract, as well as the collection of abstracts, are published under a Creative Commons CC-BY 4.0 (attribution) licence (https://creativecommons.org/licenses/by/4.0/) and may thus be reproduced, translated, adapted and be the subject of derivative works provided the authors and Frontiers are attributed. For Frontiers’ terms and conditions please see https://www.frontiersin.org/legal/terms-and-conditions. Received: 06 May 2010; Published Online: 06 May 2010. * Correspondence: Zoltán Serfözö, Balaton Limnological Research Institute, HAS, Department of Experimental Zoology, Tihany, Hungary, serfozo@tres.blki.hu Login Required This action requires you to be registered with Frontiers and logged in. To register or login click here. Abstract Info Abstract The Authors in Frontiers Zoltán Serfözö Károly Elekes Google Zoltán Serfözö Károly Elekes Google Scholar Zoltán Serfözö Károly Elekes PubMed Zoltán Serfözö Károly Elekes Related Article in Frontiers Google Scholar PubMed Abstract Close Back to top Javascript is disabled. Please enable Javascript in your browser settings in order to see all the content on this page.

A structural basis for H-NOX signaling in Shewanella oneidensis by trapping a histidine kinase inhibitory conformation

Heme nitric oxide/oxygen (H-NOX) proteins are found in eukaryotes where they are typically part of a larger protein such as soluble guanylate cyclase and in prokaryotes where they are often found in operons with a histidine kinase, suggesting that H-NOX proteins serve as sensors for NO and O(2) in signaling pathways. The Fe(II)-NO complex of the H-NOX protein from Shewanella oneidensis inhibits the autophosphorylation of the operon-associated histidine kinase, whereas the ligand-free H-NOX has no effect on the kinase. NMR spectroscopy was used to determine the structures of the Fe(II)-CO complex of the S. oneidensis H-NOX and the Fe(II)-CO complex of the H103G H-NOX mutant as a mimic of the ligand-free and kinase-inhibitory Fe(II)-NO H-NOX, respectively. The results provide a molecular glimpse into the ligand-induced conformational changes that may underlie kinase inhibition and the subsequent control of downstream signaling.

Cardiovascular Consequences When Nitric Oxide and Lipid Signaling Converge

The identification of nitric oxide ((*)NO) as an endogenously produced free radical mediator of endothelial-dependent relaxation and host defense has fundamentally changed concepts of cell signal transduction. Ligand-receptor oriented paradigms of cell signaling were originally centered on the concept of a high affinity and specific interaction between a ligand and its receptor, resulting in the activation of secondary signaling events such as gene expression or modulation of catalytic protein function. While (*)NO ligation of the heme iron of soluble guanylate cyclase is consistent with this perspective, the readily diffusible and broadly reactive (*)NO is increasingly appreciated to react with a vast array of target molecules that mediate paracrine vasodilator actions, inhibition of thrombosis and neointimal proliferation, and both pro- and antiinflammatory signaling reactions that are not affected by inhibitors of soluble guanylate cyclase. There is an expanding array of functionally significant "off target" collateral reactions mediated by (*)NO that are guanylate cyclase-independent and rather are dictated by anatomic distribution and the formation of secondary (*)NO-derived species. These reactions are a critical element of redox-regulated signaling and are addressed herein in the context of the oxidation of unsaturated fatty acids to vascular and inflammatory signaling mediators. Because of their abundance and the intrinsic reactivity of unsaturated lipid intermediates and eicosanoid metabolism enzymes with (*)NO and other oxides of nitrogen, lipid signaling mechanisms are a significant target for regulation by (*)NO in the vascular compartment. This convergence of (*)NO and lipid signaling pathways thus adds another level of regulation to physiological responses such as vasodilation, thrombosis, and inflammation. Herein, interactions between (*)NO and lipid signaling events are placed in the context of cardiovascular regulation.

Exercising an option to prevent age related decline of vascular BH4 and uncoupling of eNOS

It is well documented that skeletal muscle vascular conductance and endothelium-dependent vasodilatation are reduced with ageing. Studies utilizing isolated skeletal muscle arterioles reveal that age-related deficits involve, at least in part, alterations in the NO signalling pathway (Muller-Delp et al. 2002; Delp et al. 2008). Although manifold factors could contribute to age-related declines in NO-mediated function, recent studies highlight the potential importance of tetrahydrobiopterin (BH4), a nitric oxide synthase (NOS) cofactor. When BH4 is limited, eNOS can become uncoupled and produce superoxide instead of NO. Thus, BH4 is potentially of junctional importance in the link between NO, reactive oxygen species (ROS) and vascular function. In humans, a single oral dose of BH4 restored endothelium-dependent dilatation in the conduit brachial artery of sedentary older men (Eskurza et al. 2005). Furthermore, Delp et al. (2008) demonstrated that age-related declines in flow-mediated dilatation of rat soleus muscle arterioles resulted, at least in part, from limitations in availability of the eNOS cofactor tetrahydrobiopterin (BH4), and that administration of the BH4 precursor sepiapterin improved flow-induced dilatation in vessels from aged rats. These results collectively support the argument that interventions to preserve vascular BH4 may be a therapeutic option for age-related vascular dysfunction (Pierce & LaRocca, 2008). In the current issue of The Journal of Physiology, Sindler et al. proposed to determine if age-related declines in vascular BH4 were associated with eNOS uncoupling and ROS production, and whether these age-related changes could be reversed by a therapeutic exercise training intervention. Aerobic exercise training has previously been shown to blunt or eliminate age-dependent declines in NO-mediated endothelium-dependent dilatation and to improve skeletal muscle blood flow in a variety of models (Seals et al. 2008), and the study of Sindler et al. proposes to add novel understanding of the underlying mechanisms related to BH4. The approach is integrative, combining functional assessment of vasodilatation with biochemical measurements of BH4, NO and ROS production, all in isolated arterioles from the soleus muscle under a number of controlled pharmacological conditions. As expected, flow-mediated dilatation was impaired with ageing and restored by exercise training; novel observations point to potential underlying mechanisms: age-related reduction in BH4 occurred in conjunction with decline in flow-induced NO signalling, and increase in superoxide production (eNOS uncoupling); and exercise training prevented the age-related loss of BH4 and improved NO bio-availability by balancing accelerated NO and ROS production. These results extend the appreciation of oxidative stress impacting NO bio-availability and vasomotor function beyond the traditional, but insufficient, concept of NO destruction by ROS (Rush et al. 2005). The findings of the study of Sindler et al. are timely, reported roughly contemporaneously with identification of the need for pharmacological therapies directed toward a similar result, the restoration of BH4 in aged blood vessels. This creates a discovery environment in which potential pharmacological- and exercise-oriented approaches to the problem will undoubtedly co-evolve. The findings of Sindler et al. additionally serve as a progenitor for many hypotheses regarding BH4 in vascular adaptations to age and exercise. Fundamental questions raised include those related to identifying the cellular mechanisms accounting for age-related declines and exercise-related restoration of vascular BH4. In this regard, emerging data suggest that H2O2 is a regulatory factor controlling BH4 synthesis in vascular cells via induction of the enzyme GTP-cyclohydrolase I (GTPCH; Shimizu et al. 2003). The data of Sindler et al. indicate that H2O2 contributes to flow-induced dilatation of skeletal muscle arterioles of young sedentary animals and that, like the flow-induced dilatation functional response itself, this H2O2 signalling declines with age but is restored by exercise training. Is it possible that this same pattern of H2O2 signalling could contribute to maintenance of BH4 in young arterioles, its loss with age, and its restoration with exercise in aged arterioles, consistent with the indicated effect of H2O2 on GTPCH expression and BH4 synthesis? If so, H2O2 takes on another important role in the acute and chronic regulation of vascular function. A recurring theme in vascular biology is heterogeneity in phenotype and function depending on vessel type (conduit vs. resistance), location (vascular bed), and physiological circumstances (e.g. other conditions in vivo). While these considerations are in part cautionary regarding the global interpretation of the results of Sindler et al., they can more appropriately be seen as an invitation for additional studies designed to create a more integrative understanding of cellular mechanisms of vascular ageing and the therapeutic effects of exercise. The study of Sindler et al. creates a new paradigm justifying such an invitation with respect to BH4, vasomotor function and the regulation of skeletal muscle blood flow.

Extensive Endothelial Damage in an Inflammatory Model of Pulmonary Arterial Hypertension

Pulmonary arterial hypertension (PAH) is a progressive disease associated with right heart failure and premature death. Diagnosis of PAH is often made late and available therapy fails to reverse the disease process. To test the hypothesis that the poor response to therapy in PAH is due to the involvement of multiple signaling pathways, we investigated time‐dependent changes in the expression of caveolin‐1, PY‐STAT3, Bcl‐xL, and the molecules involved in NO signaling pathway (eNOS, HSP90, Akt) in rats at 48 hr, 1, 2, and 3 wks post‐monocrotaline (MCT). Progressive PAH, right ventricular hypertrophy and pulmonary vascular remodeling were observed at 2 and 3 wks post‐MCT. Progressive loss of endothelial caveolin‐1 coupled with activation of PY‐STAT3 and upregulation of Bcl‐xL preceded the onset of PAH. There was an early and progressive loss of Tie2 which colocalizes with caveolin‐1 and has been implicated in PAH. Expression of eNOS increased at 48 hr and 1 wk post‐MCT with a significant loss at 3 wks post‐MCT. At 2 wks post‐MCT concomitant with PAH, the expression of eNOS activating molecules HSP90 and Akt was significantly reduced, which is consistent with impaired NO availability as observed previously. We conclude that there is progressive deregulation of multiple signaling pathways leading to cell proliferation, inhibition of apoptosis and NO impairment in PAH. This may in part, explain the difficulties encountered in the treatment of PAH.

Nitric oxide inhibits platelet adhesion to collagen through cGMP-dependent and independent mechanisms: The potential role for S-nitrosylation

Nitric oxide (NO)-mediated inhibition of platelet function occurs primarily through elevations in cGMP, although cGMP-independent mechanisms such as S-nitrosylation have been suggested as alternative NO-signaling pathways. In the present study we investigated the potential for S-nitrosylation to act as a NO-mediated cGMP-independent signaling mechanism in platelets. The NO-donor, S-nitrosoglutathione (GSNO), induced a concentration-dependent inhibition of platelet adhesion to immobilized collagen. In the presence of the soluble guanylyl cyclase inhibitor, ODQ, NO-mediated activation of the cGMP/protein kinase G signaling pathway was ablated. However, ODQ failed to completely abolish the inhibitory effect of NO on collagen-mediated adhesion, confirming that cGMP-independent signaling events contribute to the regulation of platelet adhesion by NO. Biotin-switch analysis of platelets demonstrated the presence of several S-nitrosylated proteins under basal conditions. Treatment of platelets with exogenous NO-donors, at concentrations that inhibited platelet adhesion, increased the number of S-nitrosylated bands and led to hyper-nitrosylation of basally S-nitrosylated proteins. The extent of S-nitrosylation in response to exogenous NO was unaffected by platelet activation. Importantly, platelet activation in the absence of exogenous NO failed to increase S-nitrosylation beyond basal levels, indicating that platelet-derived NO was unable to induce this type of protein modification. Our data demonstrate that S-nitrosylation of platelet proteins in response to exogenous NO may act as a potentially important cGMP-independent signaling mechanism for controlling platelet adhesion.

Teleantagonism: A pharmacodynamic property of the primary nociceptive neuron

Previous work from our group showed that intrathecal (i.t.) administration of substances such as glutamate, NMDA, or PGE 2 induced sensitization of the primary nociceptive neuron (PNN hypernociception) that was inhibited by a distal intraplantar (i.pl.) injection of either morphine or dipyrone. This pharmacodynamic phenomenon is referred to in the present work as “teleantagonism”. We previously observed that the antinociceptive effect of i.t. morphine could be blocked by injecting inhibitors of the NO signaling pathway in the paw (i.pl.), and this effect was used to explain the mechanism of opioid-induced peripheral analgesia by i.t. administration. The objective of the present investigation was to determine whether this teleantagonism phenomenon was specific to this biochemical pathway (NO) or was a general property of the PNNs. Teleantagonism was investigated by administering test substances to the two ends of the PNN (i.e., to distal and proximal terminals; i.pl. plus i.t. or i.t. plus i.pl. injections). We found teleantagonism when: ( i ) inhibitors of the NO signaling pathway were injected distally during the antinociception induced by opioid agonists; ( ii ) a nonselective COX inhibitor was tested against PNN sensitization by IL-1β; ( iii ) selective opioid-receptor antagonists tested against antinociception induced by corresponding selective agonists. Although the dorsal root ganglion seems to be an important site for drug interactions, the teleantagonism phenomenon suggests that, in PNNs, a local sensitization spreads to the entire cell and constitutes an intriguing and not yet completely understood pharmacodynamic property of this group of neurons.

Binding of YC-1 or BAY 41-2272 to soluble guanylyl cyclase induces a geminate phase in CO photolysis.

Soluble guanylyl/guanylate cyclase (sGC), a heme-containing heterodimeric protein of approximately 150 kDa, is the primary receptor for nitric oxide, an endogenous molecule of immense physiological importance to animals. Recent studies have identified compounds such as YC-1 and BAY 41-2272 that stimulate sGC independently of NO binding, properties of importance for the treatment of endothelial dysfunction and other diseases linked to malfunctioning NO signaling pathways. We have developed a novel expression system for sGC from Manduca sexta (the tobacco hornworm) that retains the N-terminal two-thirds of both subunits, including heme, but is missing the catalytic domain. Here, we show that binding of compounds YC-1 or BAY 41-2272 to the truncated protein leads to a change in the heme pocket such that photolyzed CO cannot readily escape from the protein matrix. Geminate recombination of the trapped CO molecules with heme takes place with a measured rate of 6 x 10(7) s(-1). These findings provide strong support for an allosteric regulatory model in which YC-1 and related compounds can alter the sGC heme pocket conformation to retain diatomic ligands and thus activate the enzyme alone or in synergy with either NO or CO.

Multiple signaling pathways controls nitrogen-mediated root elongation in maize

Response of root system architecture to nutrient availability is an essential way for plants to adapt to soil environments. Nitrogen can affect root development either as a result of changes in the external concentration, or through changes in the internal nutrient status of the plant. Low soil N stimulates root elongation in maize. Recent evidence suggests that plant hormones auxin and cytokinin, as well as NO signaling pathway, are involved in the regulation of root elongation by low nitrogen nutrition.Addendum to Tian Q, Chen F, Liu J, Zhang F, Mi G. Inhibition of maize root growth by high nitrate supply is correlated to reduced IAA levels in roots. J Plant Physiol 2008; 165:942-51.

Differential role of the nNOS gene in the development of behavioral sensitization to cocaine in adolescent and adult B6;129S mice

Previous studies have suggested the involvement of neuronal nitric oxide synthase (nNOS) in the development of sensitization to psychostimulants. Ontogeny-dependent differences in the response to psychostimulants have been reported. The objectives were to investigate (a) the short- and long-term consequences of adolescent and adult cocaine exposure on behavioral sensitization and (b) the role of the nNOS gene in behavioral sensitization in adolescent and adult mice. Adolescent and adult wild type (WT) and nNOS knockout (KO) mice received saline or cocaine (20 mg/kg) for 5 days and then were challenged with cocaine (20 mg/kg) after a drug-free period of 10 or 30 days. Locomotor activity was recorded by infrared beam interruptions. nNOS immunoreactive (ir) neurons in the dorsal and ventral striatum were quantified 24 h after repeated administration of cocaine to adolescent and adult WT mice. Repeated administration of cocaine to either WT or nNOS KO mice during adolescence resulted in locomotor sensitization, which persisted into adulthood. WT but not KO adult mice developed long-term sensitization to cocaine. Repeated cocaine administration resulted in a 96% increase in the expression of nNOS-ir neurons in the dorsal striatum of adult but not adolescent WT mice. The nNOS gene is essential for the induction of behavioral sensitization to cocaine in adulthood but not in adolescence. The increased expression of nNOS-ir neurons in the dorsal striatum may underlie the induction of behavioral sensitization in adulthood. Thus, the NO-signaling pathway has an ontogeny-dependent role in the neuroplasticity underlying cocaine behavioral sensitization.

Nitrosative Stress Leads to Protein Glutathiolation, Increased S-Nitrosation, and Up-regulation of Peroxiredoxins in the Heart

Nitric oxide (NO) is produced by different isoforms of nitric oxide synthases (NOSs) and operates as a mediator of important cell signaling pathways, such as the cGMP signaling cascade. Another mechanism by which NO exerts biological effects is mediated through S-nitrosation of target proteins. To explore thiol-based protein modifications in a situation of defined nitrosative stress, we used a transgenic mouse model with cardiac specific overexpression of inducible nitric oxide synthase (iNOS) and concomitant myoglobin deficiency (iNOS(+)/myo(-/-)). In comparison with the wild type hearts, protein glutathiolation detected by immunoblotting was significantly enhanced in iNOS(+)/myo(-/-) hearts, whereas protein S-nitrosation as measured by the biotin switch assay and two-dimensional PAGE revealed that nearly all of the detected proteins ( approximately 60) remained unchanged with the exception of three proteins. Tandem mass spectrometry revealed these proteins to be peroxiredoxins (Prxs), which are known to possess peroxidase activity, whereby hydrogen peroxide, peroxynitrite, and a wide range of organic hydroperoxides are reduced and detoxified. Immunoblotting with specific antibodies revealed up-regulation of Prx VI in the iNOS(+)/myo(-/-) hearts, whereas expression of Prx II and Prx III remained unchanged. Furthermore, the analysis of the cardiac S-nitrososubproteome identified several new proteins possibly being involved in NO-signaling pathways. Our data indicate that S-nitrosation and glutathiolation of cardiac proteins may contribute to the phenotype of NO-induced heart failure. The up-regulation of antioxidant proteins like Prx VI appears to be an additional mechanism to antagonize an excess of reactive oxygen/nitrogen species. Furthermore, S-nitrosation of Prxs may serve a new function in the signaling cascade of nitrosative stress.

Increased adhesive properties of neutrophils in sickle cell disease may be reversed by pharmacological nitric oxide donation

Increased leukocyte adhesion to vascular endothelium contributes to vaso-occlusion in sickle cell disease. Since nitric oxide bioavailability is decreased in sickle cell disease and nitric oxide may inhibit leukocyte adhesion, we investigated whether stimulation of NO-signaling pathways can reduce the adhesive properties of neutrophils from sickle cell disease individuals (sickle cell diseaseneu). sickle cell diseaseneu presented greater adhesion in vitro to both fibronectin and ICAM-1 than control neutrophils. Co-incubation of sickle cell diseaseneu with the nitric oxide-donor agents, sodium nitroprusside and dietheylamine NONOate (DEANO), and the guanylate cyclase stimulator, BAY41-2272, all significantly reduced the increased adhesion to fibronectin/ICAM-1. Oxadiazolo[4,3-a]quinoxalin-1-one, a guanylate cyclase inhibitor, reversed sodium nitroprusside/DEANO-diminished adhesion to fibronectin, implicating cGMP-dependent signaling in this mechanism. Interestingly, intracellular cGMP was significantly higher in neutrophils from sickle cell disease individuals on hydroxyurea (sickle cell diseaseHUneu). Accordingly, sickle cell diseaseHUneu adhesion to fibronectin/ICAM-1 was significantly lower than that of sickle cell diseaseneu. Agents that stimulate the nitric oxide/cGMP-dependent pathway may have beneficial effects on leukocyte function if used in these subjects.

Nitric oxide (NO) signaling modulates intracellular calcium [Ca2+]i and prevents alcohol‐induced neuronal death in cerebellar granule cell (CGN) cultures

One of alcohol's most damaging effects on the developing CNS is severe neuronal loss. For unknown reasons, the cerebellum and hippocampus are more vulnerable to alcohol‐induced neuronal loss than other regions. One possibility is that alcohol‐resistant regions have protective mechanism(s), which mitigate alcohol toxicity. Our prior studies revealed that NO is protective, reducing alcohol‐induced neuronal loss by activating a NO‐signaling pathway (NO activates guanylyl cyclase; the increase in cGMP activates cGMP‐dependent protein kinase, PKG). A current goal is to identify a downstream target for PKG. We are exploring interactions among PKG, alcohol‐induced neuronal death, and [Ca2+]¡ for several reasons. Alcohol disrupts [Ca2+]¡ homeostasis, and neurons are sensitive to calcium disruption. PKG regulates the inositol 1,4,5‐triphosphate receptor (IP3R), modulating [Ca2+]¡ release. Ethanol (400 mg/dl) has two effects on CGN cultures: 1) A 25% reduction in neuronal numbers; 2) A rapid (< one min) increase in [Ca2+]¡. Calcium chelators (BAPTA‐AM; EGTA‐AM) decrease alcohol‐induced neuronal loss (<10%). An inhibitor of the IP3R (2‐APB) and a PKG activator (8‐Br‐cGMP) reduce both the alcohol‐induced [Ca2+]¡ surge and neuronal death (<5%). In summary, modulating [Ca2+]¡ reduces alcohol toxicity. NO may protect neurons by preventing alcohol's disruption of [Ca2+]¡. Support: NIAAA grant AA011577

CONSTITUTIVE NITRIC OXIDE SYNTHASES IN THE HEART FROM HYPERTROPHY TO FAILURE

1. Endogenous myocardial nitric oxide (NO) may modulate the transition from adaptive to maladaptive hypertrophy leading to heart failure. This review summarizes the information on the interrelations between the precise localization of NO synthases (NOS) and their regulatory functions within different compartments of the heart. 2. In rodent models of pressure overload or myocardial infarction, the three NOS isoforms (NOS1, NOS2, NOS3) were shown to play a neutral, protective, or even adverse role in myocardial remodelling, depending on the NOS activity, the location of each NOS and their regulators. 3. The analysis of conditions that modulate the expression of NOS1 and NOS3 in the heart according to physiopathological situations, indicated that, beside the level of total NOS activity, unique changes in NO compartmentation secondary to NOS1 or NOS3 subcellular location might be involved in the development of cardiac hypertrophy and failure. 4. Thus, different circuits in NO-signalling pathways in myocardium might be activated and this principle is a key to understand contradictions existing in NO biology in the heart. Unravelling the mechanisms behind the NO, NOS and cardiac function is still an ongoing challenge.