Nitric oxide signaling in invertebrates

Nitric oxide (NO) is an unconventional neurotransmitter and neuromodulator molecule that is increasingly found to have important signaling functions in animals from nematodes to mammals. NO signaling mechanisms in the past were identified largely through experiments on mammals, after the discovery of NO's vasodilatory functions. The use of gene knock out mice has been particularly important in revealing the functions of the several isoforms of nitric oxide synthase (NOS), the enzyme that produces NO. Recent studies have revealed rich diversity in NO signaling. In addition to the well-established pathway in which NO activates guanylyl cyclase and cGMP production, redox mechanisms involving protein nitrosylation are important contributors to modulation of neurotransmitter release and reception. NO signaling studies in invertebrates are now generating a wealth of comparative information. Invertebrate NOS isoforms have been identified in insects and molluscs, and the conserved and variable amino acid sequences evaluated. Calcium-calmodulin dependence and cofactor requirements are conserved. NADPH diaphorase studies show that NOS is found in echinoderms, coelenterates, nematodes, annelids, insects, crustaceans and molluscs. Accumulating evidence reveals that NO is used as an orthograde transmitter and cotransmitter, and as a modulator of conventional transmitter release. NO appears to be used in diverse animals for certain neuronal functions, such as chemosensory signalin, learning, and development, suggesting that these NO functions have been conserved during evolution. The discovery of NO's diverse and unconventional signaling functions has stimulated a plethora of enthusiastic investigations into its uses. We can anticipate the discovery of many more interesting and some surprising NO signaling functions.     

NO: an inhibitor of cell death

Nitric oxide (NO) or related molecules of both endogenous and exogenous origin inhibit programmed cell death in a variety of cells and tissues. This general protective function is largely independent of the apoptotic stimulus. S-nitrosylation of the catalytic-site cysteine of caspases is a well-established and possibly widespread mechanism of enzyme inhibition that protects from cell death. However, NO may inhibit apoptosis by additional mechanisms. The physiological and pathological significance of NO's anti-apoptotic activity remains to be determined in most cases.     

Nitric oxide dysfunction in the pathophysiology of preeclampsia.

Researchers disagree as to the importance of nitric oxide (NO) in preeclampsia. Many researchers have alluded to NO's possible primary or secondary role in the development of preeclampsia, but few have correlated the dysfunction of nitric oxide production with the other metabolic derangements seen in this condition. This paper will review the evidence that the primary dysfunction in preeclampsia is a relative deficiency of available NO (secondary to oxidative degradation) and an excess of peroxynitrite (ONOO(-)). The combination of a deficiency of NO and an increase in ONOO(-) can directly or indirectly initiate the vast majority of physiological and serological changes associated with preeclampsia, such as blood pressure, increased glomerular filtration rate, proteinuria, platelet dysfunction, increased thromboxane and endothelin, and a decrease in prostacyclin. Understanding the complex role of nitric oxide in this condition may explain why previous interventions have been unsuccessful and suggest possible strategies for prevention and treatment in the future.     

Methylene blue blocks cGMP production and disrupts directed migration of microglia to nerve lesions in the leech CNS

Migration and accumulation of microglial cells at sites of injury are important for nerve repair. Recent studies on the leech central nervous system (CNS), in which synapse regeneration is successful, have shown that nitric oxide (NO) generated immediately after injury by endothelial nitric oxide synthase (eNOS) stops migrating microglia at the lesion. The present study obtained results indicating that NO may act earlier, on microglia migration, and aimed to determine mechanisms underlying NO's effects. Injury induced cGMP immunoreactivity at the lesion in a pattern similar to that of eNOS activity, immunoreactivity, and microglial cell accumulation, which were all focused there. The soluble guanylate cyclase (sGC) inhibitor methylene blue (MB) at 60 microM abolished cGMP immunoreactivity at lesions and blocked microglial cell migration and accumulation without interfering with axon conduction. Time-lapse video microscopy of microglia in living nerve cords showed MB did not reduce cell movement but reduced directed movement, with significantly more cells moving away from the lesion or reversing direction and fewer cells moving toward the lesion. The results indicate a new role for NO, directing the microglial cell migration as well as stopping it, and show that NO's action may be mediated by cGMP.     

Diazeniumdiolates: pro- and antioxidant applications of the "NONOates"

Diazeniumdiolates are compounds containing the X-[N(O)NO](-) structural unit that as a class offer many advantages as tools for probing the roles of nitric oxide (NO) in biological redox processes. Available examples in which X is a secondary amine group spontaneously generate up to two molecules of NO per [N(O)NO](-) unit when dissolved in aqueous media; their half-lives range from 2 s (for X = L-prolyl) to 20 h [for X = (H(2)NCH(2)CH(2))(2)N] at pH 7. 4 and 37 degrees C, and are in general relatively little influenced by medium effects or metabolism. When X = O(-) (Angeli's salt), first-order dissociation produces NO(-) rather than NO, but the ion becomes an NO source on 1-electron oxidation; diazeniumdiolate-derived NO can also be used to generate reactive nitrogen/oxygen species with higher nitrogen oxidation states (+3 and +4) in the presence of selected oxidizing agents. The advantages of diazeniumdiolates in biomedical research are briefly illustrated with examples from the recent literature probing NO's role in inhibiting oxidative drug metabolism, radical-induced lipid oxidation, the cytotoxicity of reactive oxygen species, and ischemia-induced vascular reoxygenation injury. Future work with this compound class should provide further insight into the mechanisms of NO's involvement in pro- and antioxidant processes, and may well lead to important medicinal advances, including reversal of cerebral vasospasm and radiosensitization of hypoxic tumors.     

The NO world for plants: achieving balance in an open system

Nitric oxide (NO) is a free radical that had been known for many years simply as a toxic air pollutant. The discovery of enzymatic NO production in many living organisms has established a new paradigm: NO being an essential molecule endogenously produced in the cells. In plant science it has been suggested that NO acts as a plant hormone equivalent to ethylene; that is, as a gaseous signal transmitter. Even after experiencing such a scientific breakthrough, however, researchers may still feel difficulty in exploring plant NO signalling systems with conventional approaches. A major difference between plants and animals is that the growth and development of plants is closely linked to the surrounding environment where NO levels vary according to biotic and abiotic activities. This fundamental difference may make the NO-signalling network system of plants larger and more complicated than that of vertebrates. This review intends to show prospects for the future of NO signalling research in plants by introducing a holistic concept to aid in the exploration of complicated systems such as the plant-environment system. Furthermore, the novel ONS hypothesis is proposed to encompass the complexity and simplicity of NO in chemistry, biochemistry and physiology.     

Analytical techniques for assaying nitric oxide bioactivity

Nitric oxide (NO) is a diatomic free radical that is extremely short lived in biological systems (less than 1 second in circulating blood). NO may be considered one of the most important signaling molecules produced in our body, regulating essential functions including but not limited to regulation of blood pressure, immune response and neural communication. Therefore its accurate detection and quantification in biological matrices is critical to understanding the role of NO in health and disease. With such a short physiological half life of NO, alternative strategies for the detection of reaction products of NO biochemistry have been developed. The quantification of relevant NO metabolites in multiple biological compartments provides valuable information with regards to in vivo NO production, bioavailability and metabolism. Simply sampling a single compartment such as blood or plasma may not always provide an accurate assessment of whole body NO status, particularly in tissues. The ability to compare blood with select tissues in experimental animals will help bridge the gap between basic science and clinical medicine as far as diagnostic and prognostic utility of NO biomarkers in health and disease. Therefore, extrapolation of plasma or blood NO status to specific tissues of interest is no longer a valid approach. As a result, methods continue to be developed and validated which allow the detection and quantification of NO and NO-related products/metabolites in multiple compartments of experimental animals in vivo. The established paradigm of NO biochemistry from production by NO synthases to activation of soluble guanylyl cyclase (sGC) to eventual oxidation to nitrite (NO(2)(-)) and nitrate (NO(3)(-)) may only represent part of NO's effects in vivo. The interaction of NO and NO-derived metabolites with protein thiols, secondary amines, and metals to form S-nitrosothiols (RSNOs), N-nitrosamines (RNNOs), and nitrosyl-heme respectively represent cGMP-independent effects of NO and are likely just as important physiologically as activation of sGC by NO. A true understanding of NO in physiology is derived from in vivo experiments sampling multiple compartments simultaneously. Nitric oxide (NO) methodology is a complex and often confusing science and the focus of many debates and discussion concerning NO biochemistry. The elucidation of new mechanisms and signaling pathways involving NO hinges on our ability to specifically, selectively and sensitively detect and quantify NO and all relevant NO products and metabolites in complex biological matrices. Here, we present a method for the rapid and sensitive analysis of nitrite and nitrate by HPLC as well as detection of free NO in biological samples using in vitro ozone based chemiluminescence with chemical derivitazation to determine molecular source of NO as well as ex vivo with organ bath myography.     

NO/cGMP Signaling and the Flexible Organization of Motor Behavior in Crustaceans

The basic elements of the NO/cGMP signaling pathway have beenidentified in the nervous systems of animals from nearly allof the major phyla. In crustaceans, the NO/cGMP pathway is associatedwith certain fundamental neuronal processes, including sensoryintegration and the organization and production of motor behavior.Here I review the evidence for NO synthesis and action in crustaceanneural networks, with an emphasis on the rhythmic motor circuitsof the crab stomatogastric ganglion (STG). In the STG, NO appearsto be released as an orthograde transmitter from descendingprojection neurons. NO's receptor, a cytopasmic isoform of guanylatecyclase (sGC), is expressed in a subset of the cells that participatein the gastric mill and pyloric central pattern generating networks.In spontaneously-active, in vitro preparations of the STG, pharmacologicalinhibitors of the NO/cGMP pathway cause the two rhythmic motorpatterns to collapse into a single conjoint rhythm. Parallelmotor output is restored when the ganglion is returned to normalsaline. Although precise mechanisms have yet to be determined,these data suggest that NO and cGMP play an important role inthe functional organization of STG networks. The STG, as wellas other crustacean models, provides a promising context forstudying the physiological and behavioral aspects of NO-mediatedsignaling in the nervous system.     

Venular endothelium-derived NO can affect paired arteriole: a computational model

Venular endothelial cells can release nitric oxide (NO) in response to intraluminal flow both in isolated venules and in vivo. Experimental studies suggest that venular endothelium-released NO causes dilation of the adjacent paired arteriole. In the vascular wall, NO stimulates its target hemoprotein, soluble guanylate cyclase (sGC), which relaxes smooth muscle cells. In this study, a computational model of NO transport for an arteriole and venule pair was developed to determine the importance of the venular endothelium-released NO and its transport to the adjacent arteriole in the tissue. The model predicts that the tissue NO levels are affected within a wide range of parameters, including NO-red blood cell reaction rate and NO production rate in the arteriole and venule. The results predict that changes in the venular NO production affected not only venular endothelial and smooth muscle NO concentration but also endothelial and smooth muscle NO concentration in the adjacent arteriole. This suggests that the anatomy of microvascular tissue can permit the transport of NO from arteriolar to venular side, and vice versa, and may provide a mechanism for dilation of proximal arterioles by venules. These results will have significant implications for our understanding of tissue NO levels in both physiological and pathophysiological conditions.     

Application of pharmaceuticals to nitric oxide

Nitric oxide (NO) is an important and widespread physiological mediator. Both excess tissue NO and its deficiency have been implicated in the development of several disease states. It is therefore of great therapeutic value that appropriate pharmacological treatments are made available to either promote or inhibit NO production. This review will focus on the main areas of pharmaceutical development and application; these include the different types of NO donor treatments currently in use, inhibition of nitric oxide synthase and gene therapy. Furthermore, the recent pharmaceutical developments for the promotion of NO production and the problems associated with NO inhibitors will also be discussed. During the next few years it will become apparent whether manipulation of NO has multiple therapeutic applications or whether the diversity of effects renders intervention too non-specific.     

Intervention by nitric oxide, NO, and its oxide derivatives particularly in mammals

Nitric oxide (NO) is a natural and stable free radical produced in soil and water by the bacteriological reduction of nitrites and nitrates and in animals by the enzyme oxidation of L-arginine. NO is biosynthesised by finely regulated enzymatic systems called NO-synthases and readily diffuses through tissues. It reacts rapidly with hemoproteins and iron-sulphur centers to form nitrosylated compounds. It oxidises more slowly to form nitrogen oxides that nitrosate thiols into thionitrite. NO is transported in these various forms and released spontaneously or through yet unclear mechanisms into most cells; it also regulates oxygen consumption at the mitochondrial respiratory chain level through interaction with cytochrome oxidase. In the cardiovascular system, NO lowers blood pressure by activating a hemoprotein, the guanylate cyclase present in muscle cells; through such interaction it acts also as a neuromediator and neuromodulator in the nervous system. However, many of NO's roles result from rapid coupling to other radicals; for example, it reacts with the superoxide anion (O2-) to form oxoperoxinitrate (ONOO-, also known as peroxynitrite). This strong oxidant of metallic centers, thiols, and antioxidants is also able to convert tyrosine to 3-nitrotyrosine and to act upon tyrosine residues contained in proteins. The biological aspects of the roles of NO are presented with particular respect to the rapid interactions of NO with hemoproteins' iron and other radicals. Concurrently, NO oxidation enables nitrosation reactions primarily of thiols but ultimately of nucleic bases. The thionitrite function (R-S-NO) thus formed and the dimerisation and nitration of tyrosine residues are protein post-translational modifications that are being investigated in animals.     

Regulation of neuronal growth cone filopodia by nitric oxide

Nitric oxide (NO) has been proposed to play an important role during neuronal development. Since many of its effects occur during the time of growth cone pathfinding and target interaction, we here test the hypothesis that part of NO's effects might be exerted at the growth cone. We found that low concentrations of the NO-donors DEA/NO, SIN-1, and SNP caused a rapid and transient elongation of filopodia as well as a reduction in filopodial number. These effects resulted from distinct changes in filopodial extension and retraction rates. Our novel findings suggest that NO could play a physiological role by temporarily changing a growth cone's morphology and switching its behavior from a close-range to a long-range exploratory mode. We subsequently dissected the pathway by which NO acted on growth cones. The effect of NO donors on filopodial length could be blocked by 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one, an inhibitor of soluble guanylyl cyclase (sGC), indicating that NO acted via sGC. Supporting this idea, injection of cyclic GMP (cGMP) mimicked the effect of NO donors on growth cone filopodia. Moreover, application of NO-donors as well as injection of cGMP elicited a rapid and transient rise in intracellular calcium in growth cones, indicating that NO acted via cGMP to elevate calcium. This calcium rise, as well as the morphological effects of SIN-1 on filopodia, were blocked by preventing calcium entry. Given the role of filopodia in axonal guidance, our new data suggest that NO could function at the neuronal growth cone as an intracellular and/or intercellular signaling molecule by affecting steering decisions during neuronal pathfinding.     

Role of heme oxygenase in preserving vascular bioactive NO

Beyond its vasodilator role, vascular nitric oxide (NO), which is synthesized by endothelial NO synthase (eNOS) via its activation, has been shown to play a number of other beneficial roles in the vascular system; it inhibits proliferation of vascular smooth muscle cells, prevents platelet aggregation, and regulates endothelial apoptosis. Such beneficial roles have been shown to be implicated in the regulation of endothelial functions. A loss of NO bioavailability that may result either from decreased eNOS expression and activity or from increased NO degradation is associated with endothelial dysfunction, a key factor in the development of vascular diseases. Heme oxygenase-1 (HO-1), an inducible enzyme, catalyzes the oxidative degradation of heme to free iron, carbon monoxide, and biliverdin, the latter being subsequently converted into bilirubin. In the vascular system, HO-1 and heme degradation products perform important physiological functions, which are ultimately linked to the protection of vascular cells. Studies have shown that HO-1 and heme degradation products exert vasodilatory, antioxidant, anti-inflammatory, antiproliferative and anti-apoptotic effects on vascular cells. Interestingly, these effects of HO-1 and its by-products are similar, at least in part, to those of eNOS-derived NO; this similarity may prompt investigators to study a possible relationship between eNOS-derived NO and HO-1 pathways. Many studies have been reported, and accumulating evidence suggests that HO-1 and heme degradation products can improve vascular function, at least in part, by compensating for the loss of NO bioavailability. This paper will provide the possible pathway explaining how HO-1 and heme degradation products can preserve vascular NO.     

Role of renal NO production in the regulation of medullary blood flow

The unique role of nitric oxide (NO) in the regulation of renal medullary function is supported by the evidence summarized in this review. The impact of reduced production of NO within the renal medulla on the delivery of blood to the medulla and on the long-term regulation of sodium excretion and blood pressure is described. It is evident that medullary NO production serves as an important counterregulatory factor to buffer vasoconstrictor hormone-induced reduction of medullary blood flow and tissue oxygen levels. When NO synthase (NOS) activity is reduced within the renal medulla, either pharmacologically or genetically [Dahl salt-sensitive (S) rats], a super sensitivity to vasoconstrictors develops with ensuing hypertension. Reduced NO production may also result from reduced cellular uptake of l-arginine in the medullary tissue, resulting in hypertension. It is concluded that NO production in the renal medulla plays a very important role in sodium and water homeostasis and the long-term control of arterial pressure.     

Methods using stable isotopes to measure nitric oxide (NO) synthesis in the L-arginine/NO pathway in health and disease

Nitric oxide (NO) is an important gaseous radical involved in many physiological processes. It is produced from the amino acid L-arginine by the action of nitric oxide synthases (NOS) in what is called the L-arginine/NO pathway. Tracking its metabolic fate in biological fluids is of particular interest as it may indicate how the human body responds in health and disease. However, due to its short life span (a few seconds) it is very difficult to accurately monitor any up- or down-regulation in body fluids in vivo. As a consequence, methods have been developed based on the measurement of the NO-derived products nitrite and nitrate or on the substrate of NO, L-arginine and its simultaneously generated product, L-citrulline. Considering only a fraction of the endogenous L-arginine pool is used for the synthesis of NO, NO-production cannot be estimated by measuring changes in the concentrations of L-arginine and/or L-citrulline alone. Instead, to estimate NO-related changes in the L-arginine and/or L-citrulline pools a form of tagging these metabolites for the NOS-mediated reaction is required. The application of stable isotopes is an elegant way to track NOS-mediated changes. The present paper is focussed on the application of various combinations of chromatography and mass spectrometry to measure isotopic enrichments resulting from the conversion of L-arginine to NO and L-citrulline in a one-to-one stoichiometry. In addition, the various aspects and principles involved in the application of stable isotopes in metabolic studies in general and the study of the activity of NOS in particular are discussed.     

The chemical dynamics of NO and reactive nitrogen oxides: a practical guide

Nitric oxide has emerged as one of the most important and diverse players in physiology. This small diatomic radical stunned researchers because of its existence and unique biological properties in human physiology. Over the last two decades it was found that NO often has fickle behavior in pathophysiological mechanisms. Where benefiting the host in one case yet inducing and augmenting injury in another. This has lead to confusion in is NO good or bad? Much of the answers to this dichotomy lies in the chemistry of NO and its related nitrogen oxide species. To help understand the complex chemistry with perspective to biology, a discussion on the chemical biology of NO is useful. The chemical biology defines the relevant chemical reaction of NO and nitrogen monoxide in the context of the biological conditions. We discuss in this article the chemistry of nitrogen oxide with different types of biological motifs. Reaction of NO with metal complexes and radicals require low concentration, where formation of reactive nitrogen oxide species require considerably higher amounts and generally are isolated to specific microenvironments in vivo. Though many reactive nitrogen oxide species are formed from chemical reactions with NO, there are several which appear to not require NO to be present, HNO and NO(2). These two species have unique physiological effects and represent additional complexity to this biological picture. From this discussion, a picture can be formed concerning the possible chemical dynamics, which can be plausible in different biological mechanisms.     

Nitric oxide signalling in plants: interplays with Ca2+ and protein kinases

Much attention has been paid to nitric oxide (NO) research since its discovery as a physiological mediator of plant defence responses. In recent years, newer roles have been attributed to NO, ranging from root development to stomatal closure. The molecular mechanisms underlying NO action in plants are just begun to emerge. The currently available data illustrate that NO can directly influence the activity of target proteins through nitrosylation and has the capacity to act as a Ca2+-mobilizing intracellular messenger. The interplay between NO and Ca2+ has important functional implications, expanding and enriching the possibilities for modulating transduction processes. Furthermore, protein kinases regulated through NO-dependent mechanisms are being discovered, offering fresh perspective on processes such as stress tolerance.     

Nitric oxide's role in the heart: control of beating or breathing?

Beneficial actions of nitric oxide (NO) in failing myocardium have frequently been overshadowed by poorly documented negative inotropic effects mainly derived from in vitro cardiac preparations. NO's beneficial actions include control of myocardial energetics and improvement of left ventricular (LV) diastolic distensibility. In isolated cardiomyocytes, administration of NO increases their diastolic cell length consistent with a rightward shift of the passive length-tension relation. This shift is explained by cGMP-induced phosphorylation of troponin I, which prevents calcium-independent diastolic cross-bridge cycling and concomitant diastolic stiffening of the myocardium. Similar improvements in diastolic stiffness have been observed in isolated guinea pig hearts, in pacing-induced heart failure dogs, and in patients with dilated cardiomyopathy or aortic stenosis and have been shown to result in higher LV preload reserve and stroke work. NO also controls myocardial energetics through its effects on mitochondrial respiration, oxygen consumption, and substrate utilization. The effects of NO on diastolic LV performance appear to be synergistic with its effects on myocardial energetics through prevention of myocardial energy wastage induced by LV contraction against late-systolic reflected arterial pressure waves and through prevention of diastolic LV stiffening, which is essential for the maintenance of adequate subendocardial coronary perfusion. A drop in these concerted actions of NO on diastolic LV distensibility and on myocardial energetics could well be instrumental for the relentless deterioration of failing myocardium.     

一氧化氮对植物细胞基因表达和代谢产物合成的影响机制

一氧化氮(NO)作为一种气体信号分子,在植物体内具有多种生理功能,许多研究逐步揭示了NO在植物发育、新陈代谢和疾病响应等方面的分子机制。内源和外源NO都可以使植物组织或悬浮细胞基因表达发生变化,高通量的基因表达的研究,如转录分析等,为信号网络通路分析提供了有力的证据。我们简要综述了NO的合成途径,并讨论了次生代谢产物及细胞程序性死亡过程中依赖NO调控的相应基因及蛋白的变化,揭示了NO是一种重要的植物信号分子,有较高的研究价值。     

Nitrite anion stimulates ischemic arteriogenesis involving NO metabolism

Nitric oxide (NO) is a potential regulator of ischemic vascular remodeling, and as such therapies augmenting its bioavailability may be useful for the treatment of ischemic tissue diseases. Here we examine the effect of administering the NO prodrug sodium nitrite on arteriogenesis activity during established tissue ischemia. Chronic hindlimb ischemia was induced by permanent unilateral femoral artery and vein ligation. Five days postligation; animals were randomized to control PBS or sodium nitrite (165 μg/kg) therapy twice daily. In situ vascular remodeling was measured longitudinally using SPY angiography and Microfil vascular casting. Delayed sodium nitrite therapy rapidly increased ischemic limb arterial vessel diameter and branching in a NO-dependent manner. SPY imaging angiography over time showed that nitrite therapy enhanced ischemic gracillis collateral vessel formation from the profunda femoris to the saphenous artery. Immunofluorescent staining of smooth muscle cell actin also confirmed that sodium nitrite therapy increased arteriogenesis in a NO-dependent manner. The NO prodrug sodium nitrite significantly increases arteriogenesis and reperfusion of established severe chronic tissue ischemia.