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.     

Alternative pathways of nitric oxide formation in Lactobacilli: Evidence for nitric oxide synthase activity by EPR

The study of the ability of Lactobacillus plantarum 8P-A3 to synthesize nitric oxide (NO) showed that this strain lacks nitrite reductase. However, analysis by the EPR method revealed the presence of nitric oxide synthase activity in this strain. Like mammalian nitric oxide synthase, lactobacillar NO synthase is involved in the formation of nitric oxide from L-arginine. L. plantarum 8P-A3 does not produce NO in the denitrification process. The regulatory role of NO in symbiotic bacteria is emphasixed.     

N-acetyl cysteine enhances imatinib-induced apoptosis of Bcr-Abl+ cells by endothelial nitric oxide synthase-mediated production of nitric oxide

Introduction  Imatinib, a small-molecule inhibitor of the Bcr-Abl kinase, is a successful drug for treating chronic myeloid leukemia (CML). Bcr-Abl kinase stimulates the production of H₂O₂, which in turn activates Abl kinase. We therefore evaluated whether N-acetyl cysteine (NAC), a ROS scavenger improves imatinib efficacy. Materials and methods  Effects of imatinib and NAC either alone or in combination were assessed on Bcr-Abl⁺ cells to measure apoptosis. Role of nitric oxide (NO) in NAC-induced enhanced cytotoxicity was assessed using pharmacological inhibitors and siRNAs of nitric oxide synthase isoforms. We report that imatinib-induced apoptosis of imatinib-resistant and imatinib-sensitive Bcr-Abl⁺ CML cell lines and primary cells from CML patients is significantly enhanced by co-treatment with NAC compared to imatinib treatment alone. In contrast, another ROS scavenger glutathione reversed imatinib-mediated killing. NAC-mediated enhanced killing correlated with cleavage of caspases, PARP and up-regulation and down regulation of pro- and anti-apoptotic family of proteins, respectively. Co-treatment with NAC leads to enhanced production of nitric oxide (NO) by endothelial nitric oxide synthase (eNOS). Involvement of eNOS dependent NO in NAC-mediated enhancement of imatinib-induced cell death was confirmed by nitric oxide synthase (NOS) specific pharmacological inhibitors and siRNAs. Indeed, NO donor sodium nitroprusside (SNP) also enhanced imatinib-mediated apoptosis of Bcr-Abl⁺ cells. Conclusion  NAC enhances imatinib-induced apoptosis of Bcr-Abl⁺ cells by endothelial nitric oxide synthase-mediated production of nitric oxide.     

Formation of nitrosothiols from gaseous nitric oxide at pH 7.4

Nitric oxide (NO) is generated in biological systems and plays important roles as a regulatory molecule. Its ability to bind to haem iron is well known. Moreover, it may lose an electron, forming the nitrosonium ion, involved in the synthesis of S-nitrosothiols (SNOs). It has been suggested that S-nitrosohaemoglobin (-SNO Hb) and low molecular weight SNOs may act as reservoirs of NO. SNOs are formed in vitro, at strongly acidic pH values; however, the mechanism of their formation at neutral pH values is still debated. In this paper we report the anaerobic formation of SNOs (both high- and low-molecular weight) from low concentrations of NO at pH 7.4, provided Hb is also present. We propose a reaction mechanism entailing the participation of Fehaem in the formation of NO(+) and the transfer of NO(+) either to Cysbeta(93) of Hb or to glutathione; we show that this reaction also occurs in human RBCs.     

An integrated network analysis reveals that nitric oxide reductase prevents metabolic cycling of nitric oxide by Pseudomonas aeruginosa

Nitric oxide (NO) is a chemical weapon within the arsenal of immune cells, but is also generated endogenously by different bacteria. Pseudomonas aeruginosa are pathogens that contain an NO-generating nitrite (NO₂⁻) reductase (NirS), and NO has been shown to influence their virulence. Interestingly, P. aeruginosa also contain NO dioxygenase (Fhp) and nitrate (NO₃⁻) reductases, which together with NirS provide the potential for NO to be metabolically cycled (NO→NO₃⁻→NO₂⁻→NO). Deeper understanding of NO metabolism in P. aeruginosa will increase knowledge of its pathogenesis, and computational models have proven to be useful tools for the quantitative dissection of NO biochemical networks. Here we developed such a model for P. aeruginosa and confirmed its predictive accuracy with measurements of NO, O₂, NO₂⁻, and NO₃⁻ in mutant cultures devoid of Fhp or NorCB (NO reductase) activity. Using the model, we assessed whether NO was metabolically cycled in aerobic P. aeruginosa cultures. Calculated fluxes indicated a bottleneck at NO₃⁻, which was relieved upon O₂ depletion. As cell growth depleted dissolved O₂ levels, NO₃⁻ was converted to NO₂⁻ at near-stoichiometric levels, whereas NO₂⁻ consumption did not coincide with NO or NO₃⁻ accumulation. Assimilatory NO₂⁻ reductase (NirBD) or NorCB activity could have prevented NO cycling, and experiments with ΔnirB, ΔnirS, and ΔnorC showed that NorCB was responsible for loss of flux from the cycle. Collectively, this work provides a computational tool to analyze NO metabolism in P. aeruginosa, and establishes that P. aeruginosa use NorCB to prevent metabolic cycling of NO.     

The language of nitric oxide signalling

Nitric oxide (NO) has recently joined the select circle of the ubiquitous molecules of plant signalling networks. Indeed, the last decade has produced a tremendous amount of data that evidence the diversity of physiological situations in which NO is involved in plants and the complexity of NO biology. These data also underline our difficulties in providing simple answers to the cardinal questions of where NO comes from and how the NO message is converted into a physiological response. The identification of NO primary targets and NO-regulated genes provides new opportunities to connect NO biochemistry and NO biology. This review summarises our current understanding of NO signalling, from the generation of the NO message to its execution into a cellular response. The review particularly considers whether and how NO may be responsible for specific signalling in different physiological processes.     

Inducible nitric oxide synthase aggresome formation is mediated by nitric oxide

Nitric oxide (NO) generated by inducible NO synthase (iNOS) contributes critically to inflammatory injury and host defense. While previously thought as a soluble protein, iNOS was recently reported to form aggresomes inside cells. But what causes iNOS aggresome formation is unknown. Here we provide evidence demonstrating that iNOS aggresome formation is mediated by its own product NO. Exposure to inflammatory stimuli (lipopolysaccharide and interferon-γ) induced robust iNOS expression in mouse macrophages. While initially existing as a soluble protein, iNOS progressively formed protein aggregates as a function of time. Aggregated iNOS was inactive. Treating the cells with the NOS inhibitor N-nitro-l-arginine methyl ester (L-NAME) blocked NO production from iNOS without affecting iNOS expression. However, iNOS aggregation in cells was prevented by L-NAME. The preventing effect of NO blockade on iNOS aggresome formation was directly observed in GFP-iNOS-transfected cells by fluorescence imaging. Moreover, iNOS aggresome formation could be recaptured by adding exogenous NO to L-NAME-treated cells. These studies demonstrate that iNOS aggresome formation is caused by NO. The finding that NO induces iNOS aggregation and inactivation suggests aggresome formation as a feedback inhibition mechanism in iNOS regulation.     

外源一氧化氮对梨叶片感染轮纹病菌后膜脂过氧化的影响

研究了0.3 mmol·L^-1一氧化氮供体硝普钠（SNP）对梨叶片感染轮纹病菌（Physalospora piricola Nose）后抗氧化酶及活性氧的影响.结果表明,经0.3 mmo1·L^-1SNP处理后,梨叶片过氧化物酶（POD）、超氧化物歧化酶（SOD）、过氧化氢酶（CAT）、多酚氧化酶（PPO）活性及抗坏血酸（ASA）、还原型谷胱甘肽（GSH）和脯氨酸(Pro)含量分别比接种对照组（喷清水接种处理,CK₁）提高了39.41%、21.11%、41.61%、13.04%、44.45%、48.32%和33.80%;丙二醛（MDA）、过氧化氢（H₂O₂)含量及超氧阴离子（O₂^-）产生速率分别比CK₁组降低了20.45%、6.93%和6.27%.表明较低浓度的SNP可缓解轮纹病菌对梨叶片的伤害作用.     

Short‐term calorie restriction reverses vascular endothelial dysfunction in old mice by increasing nitric oxide and reducing oxidative stress

To determine if short‐term calorie restriction reverses vascular endothelial dysfunction in old mice, old (O, n = 30) and young (Y, n = 10) male B6D2F1 mice were fed ad libitum (AL) or calorie restricted (CR, approximately 30%) for 8 weeks. Ex vivo carotid artery endothelium‐dependent dilation (EDD) was impaired in old ad libitum (OAL) vs. young ad libitum (YAL) (74 ± 5 vs. 95 ± 2% of maximum dilation, P < 0.05), whereas old calorie‐restricted (OCR) and YCR did not differ (96 ± 1 vs. 94 ± 3%). Impaired EDD in OAL was mediated by reduced nitric oxide (NO) bioavailability associated with decreased endothelial NO synthase expression (aorta) (P < 0.05), both of which were restored in OCR. Nitrotyrosine, a cellular marker of oxidant modification, was markedly elevated in OAL (P < 0.05), whereas OCR was similar to Y. Aortic superoxide production was 150% greater in OAL vs. YAL (P < 0.05), but normalized in OCR, and TEMPOL, a superoxide dismutase (SOD) mimetic that restored EDD in OAL (to 97 ± 2%), had no effect in Y or OCR. OAL had increased expression and activity of the oxidant enzyme, NADPH oxidase, and its inhibition (apocynin) improved EDD, whereas NADPH oxidase in OCR was similar to Y. Manganese SOD activity and sirtuin1 expression were reduced in OAL (P < 0.05), but restored to Y in OCR. Inflammatory cytokines were greater in OAL vs. YAL (P < 0.05), but unaffected by CR. Carotid artery endothelium‐independent dilation did not differ among groups. Short‐term CR initiated in old age reverses age‐associated vascular endothelial dysfunction by restoring NO bioavailability, reducing oxidative stress (via reduced NADPH oxidase–mediated superoxide production and stimulation of anti‐oxidant enzyme activity), and upregulation of sirtuin‐1.     

The occurrence and control of nitric oxide generation by the plant mitochondrial electron transport chain

The plant mitochondrial electron transport chain (ETC) is bifurcated such that electrons from ubiquinol are passed to oxygen via the usual cytochrome path or through alternative oxidase (AOX). We previously showed that knockdown of AOX in transgenic tobacco increased leaf concentrations of nitric oxide (NO), implying that an activity capable of generating NO had been effected. Here, we identify the potential source of this NO. Treatment of leaves with antimycin A (AA, Q_i‐site inhibitor of Complex III) increased NO amount more than treatment with myxothiazol (Myxo, Q_o‐site inhibitor) despite both being equally effective at inhibiting respiration. Comparison of nitrate‐grown wild‐type with AOX knockdown and overexpression plants showed a negative correlation between AOX amount and NO amount following AA. Further, Myxo fully negated the ability of AA to increase NO amount. With ammonium‐grown plants, neither AA nor Myxo strongly increased NO amount in any plant line. When these leaves were supplied with nitrite alongside the AA or Myxo, then the inhibitor effects across lines mirrored that of nitrate‐grown plants. Hence the ETC, likely the Q‐cycle of Complex III generates NO from nitrite, and AOX reduces this activity by acting as a non‐energy‐conserving electron sink upstream of Complex III.     

Multimodality imaging of nitric oxide and nitric oxide synthases

Nitric oxide (NO) and NO synthases (NOSs) are crucial factors in many pathophysiological processes such as inflammation, vascular/neurological function, and many types of cancer. Noninvasive imaging of NO or NOS can provide new insights in understanding these diseases and facilitate the development of novel therapeutic strategies. In this review, we will summarize the current state-of-the-art multimodality imaging in detecting NO and NOSs, including optical (fluorescence, chemiluminescence, and bioluminescence), electron paramagnetic resonance (EPR), magnetic resonance (MR), and positron emission tomography (PET). With continued effort over the last several years, these noninvasive imaging techniques can now reveal the biodistribution of NO or NOS in living subjects with high fidelity which will greatly facilitate scientists/clinicians in the development of new drugs and/or patient management. Lastly, we will also discuss future directions/applications of NO/NOS imaging. Successful development of novel NO/NOS imaging agents with optimal in vivo stability and desirable pharmacokinetics for clinical translation will enable the maximum benefit in patient management.     

Suppression of nitric oxide oxidation to nitrite by curcumin is due to the sequestration of the reaction intermediate nitrogen dioxide, not nitric oxide

Curcumin, a phytochemical with antioxidant and other cytoprotective properties, has been reported to reduce nitrite formation during nitric oxide (NO) oxidation in solution. This decrease in nitrite production was attributed to the direct sequestration of NO by curcumin. In this report, we confirm that curcumin inhibits nitrite formation from DEA/NO-derived NO in a concentration-dependent manner. However, curcumin over a concentration range of 3-50 microM had no effect on the concentration of free NO (0.5 microM) in solution at 37 degrees C as assessed using an NO electrode. We conclude that the inhibitory effect of curcumin on the oxidation of NO to nitrite is due to its known sequestration of the reaction intermediate nitrogen dioxide (NO(2)). The ability of curcumin to sequester NO(2), but not NO, suggests that curcumin may be useful for separating the actions of NO(2) from those of NO in various biological systems.     

Autocrine interferon-beta stimulation augments nitric oxide production by mouse macrophage J774A.1 cells infected with herpes simplex virus type 1

The pathogenic roles of nitric oxide (NO) in mouse models have been reported for herpes simplex virus type 1 (HSV-1)-induced pneumonia as well as endotoxin shock. We compared the mechanism of NO production induced by HSV-1 with that induced by lipopolysaccharide (LPS) using a mouse macrophage cell line, J774A.1. Both HSV-1 and LPS induced NO production as well as antiviral activity, which were attenuated by anti-interferon (IFN)-beta treatment. These results suggest that autocrine IFN-beta plays a role in NO release by J774A.1 cells stimulated with HSV-1 or LPS.     

Transport of L-cystine in human umbilical vein endothelial cells in culture

The uptake of L-cystine into cultured human umbilical vein endothelial cells has been shown to occur by a Na⁺-independent system which is inhibited by L-glutamate and L-homocysteine, but not by other amino acids. It is likely that the system transporting L-cystine is shared by L-glutamate. Thiol groups associated with membrane bound components appear to be essential for L-cystine uptake but it is not yet evident whether these constitute an integral part of the transporterper se.     

Electric fields caused by blood flow modulate vascular endothelial electrophysiology and nitric oxide production

Endothelial cells are exposed to a ubiquitous, yet unexamined electrical force caused by blood flow: the electrokinetic vascular streaming potential (EVSP). In this study, the hypothesis that extremely low frequency (ELF) electric fields parameterized by the EVSP have significant biological effects on endothelial cell properties was studied by measuring membrane potential and nitric oxide production under ELF stimulation between 0 and 2 Hz and 0–6.67 V/m. Using membrane potential and nitric oxide sensitive fluorescent dyes, bovine aortic endothelial cells (BAECs) in culture were studied in the presence and absence of EVSP‐modeled electric fields. The transmembrane potential of BAECs was shown to depolarize between 1 and 7 mV with a strong dependency on both the magnitude and frequency of the isolated ELF field. The findings also support a field interaction with a frequency‐dependent tuning curve. The ELF field complexly modulates the nitric oxide response to adenosine triphosphate stimulation with potentiation seen with up to a sevenfold increase. This potentiation was also frequency and magnitude dependent. An early logarithmic phase of NO production is enhanced in a field strength‐dependent manner, but the ELF field does not modify a later exponential phase. This study shows that using electric fields on the order of those generated by blood flow influences the essential biology of endothelial cells. The inclusion of ELF electric fields in the paradigm of vascular biology may create novel opportunities for advancing both the understanding and therapies for treatment of vascular diseases. Bioelectromagnetics 34:22–30, 2013. © 2012 Wiley Periodicals, Inc.     

Estimation of salivary nitric oxide in oral precancer patients

Abstract

The role of nitric oxide (NO) in the initiation, promotion and progression of cancer has been the subject of speculation and conflicting reports in the literature. The high incidence of oral cancer and precancer has been linked to tobacco chewing and smoking habits; NO is considered an indicator of tobacco-related diseases. We compared salivary NO levels in oral precancer and normal patients. Unstimulated whole saliva was collected from 15 patients with oral precancer (group 1) and 15 healthy age and sex matched subjects (group 2). Salivary nitrite levels were estimated using a colorimetric method and a spectrophotometer. The salivary nitrite concentration of group 2 (median = 4.21 μg/ml) was significantly less than for group 1 (median = 12.91 μg/ml). We have added evidence concerning involvement of NO in the pathogenesis of oral cancer, but whether it is a potentially carcinogenic agent at the concentration at which it is present in oral precancer patients requires further evaluation.     

诱导型一氧化氮合酶对内毒素休克小肠微循环的影响

采用静脉注射脂多糖(1ipopolysaccharide,LPS)的方法建立小鼠内毒素休克模型,探讨内毒素休克时小肠微循环的变化以及诱导型一氧化氮合酶(iNOS)对小肠微循环的影响。实验过程中连续监测小鼠平均动脉血压(mean afterial pressure,MAP)变化情况。利用FTTC标记红细胞和活体显微镜方法直接观察并计算小鼠小肠绒毛尖端小动脉和毛细血管内红细胞的流速和流量,并观察敲除小鼠iNOS基因和选择性iNOS抑制剂S-methylthiourea sulfate(SMT)对实验过程中小肠微循环的影响。结果显示,对于野生型小鼠,应用SMT处理和敲除iNOS基因对基线的MAP、小肠绒毛尖端小动脉和毛细血管的红细胞流速和流量没有显著性差别。给予LPS后,小鼠的MAP进行性下降。给予LPS前,应用SMT和敲除小鼠iNOS基因可以显著提高MAP：给予LPS后,小鼠小肠绒毛尖端小动脉和毛细血管内红细胞流速和流量显著下降。给予LPS前,应用SMT和敲除小鼠iNOS基因可以显著提高小肠绒毛尖端小动脉和毛细血管的红细胞流速和流量。结果表明,iNOS在内毒素休克小肠微循环衰竭的过程中发挥重要作用。一能性     

Up-regulation of nitric oxide synthase by estradiol in human aorticendothelial cells

We have examined the effects of sex hormones on calcium-dependent NO production and protein levels of NO synthase in cultured human aortic endothelial cells, which were treated with various doses of 17β-estradiol and testosterone for 8–48 h. Treatment with 17β-estradiol enhanced calcium-dependent NO production, but testosterone had exerted no effect. Western blot using monoclonal anti-human endothelial NO synthase antibody clarified that increased NO production by 17β-estradiol treatment was accompanied by increased NO synthase protein. Our results provide evidence that human endothelial NO synthase can be regulated by estrogens.