NO detection in biological samples: Differentiation of NO and NO using infrared laser spectroscopy

Accurate characterization of the biochemical pathways of nitric oxide (NO) is essential for investigations in the field of NO research. To analyze the different reaction pathways of enzymatic and non-enzymatic NO formation, determination of the source of NO is crucial. Measuring NO-related products in biological samples distinguishing between ¹⁴NO and ¹⁵NO offers the opportunity to specifically analyze NO signaling in blood and tissue. The aim of this study was to establish a highly sensitive technique for the specific measurement of NO in an isotopologue-selective manner in biological samples.With the cavity leak-out spectroscopy setup (CALOS) a differentiation between ¹⁴NO and ¹⁵NO is feasible. We describe here the employment of this method for measurements in biological samples. Certified gas mixtures of ¹⁴NO/N₂ and ¹⁵NO/N₂ were used to calibrate the system. and of aqueous and biological samples were reduced in a triiodide solution, and the NO released was detected via CALOS. Gas-phase chemiluminescence detection (CLD) was used for evaluation.The correlation received for both methods for the detection of NO in the gas phase was r = 0.999, p < 0.0001. Results obtained using aqueous and biological samples verified that CALOS enables NO measurements with high accuracy (detection limit for 0.3 pmol and 0.5 pmol; correlation ¹⁴NO: p < 0.0001, r = 0.975, ¹⁵NO: p < 0.0001, r = 0.969).The CALOS assay represents an extension of NO measurements in biological samples, allowing specific investigations of enzymatic and non-enzymatic NO formation and metabolism in a variety of samples.     

Cytokine-induced production of NO by macrophages induces apoptosis and immunological rejection of AK-5 histiocytic tumor

The immunological rejection of the AK-5 histiocytoma in syngeneic hosts involves the participation of NK cells and the upregulation of Th1 type cytokine response. The tumor cells are killed by necrosis and apoptosis. We have studied the role of host peritoneal macrophages in tumor regression. Activated macrophages from tumor- bearing animals produce cytokines like IL-1, TNF-, IL-12 and free radicals like nitric oxide during tumor regression. IL-12 and IFN- played a crucial role in the induction of NO production by the host macrophages, since administration of anti IL-12 and anti IFN- antibodies in AK-5 tumor-bearing animals suppressed NO production by the macrophages. Similarly the cytotoxic activity of the host macrophages which is dependent on NO production was also affected in antibody injected animals. These studies indicate an important role for cytokines in the activation of host macrophages which in turn produce nitric oxide that is involved in the induction of apoptosis in AK-5 cells, leading to the regression of the tumor.     

NO, NO, NO! Nitrosyl siblings from [IrCl5(NO)]

Pentachloronitrosyliridate(III) ([IrCl₅(NO)]⁻), the most electrophilic NO⁺ known to date, can be reduced chemically and/or electrochemically by one or two electrons to produce the NO and HNO/NO⁻ forms. The nitroxyl complex can be formed either by hydride attack to the NO⁺ in organic solvent, or by decomposition of iridium-coordinated nitrosothiols in aqueous solutions, while NO is produced electrochemically or by reduction of [IrCl₅(NO)]⁻ with H₂O₂. Both NO and HNO/NO⁻ complexes are stable under certain conditions but tend to labilize the trans chloride and even the cis ones after long periods of time. As expected, the NO⁺ is practically linear, although the IrNO moiety is affected by the counterions due to dramatic changes in the solid state arrangement. The other two nitrosyl redox states comprise bent structures.     

Nitric oxide in plants. To NO or not to NO

The current knowledge on the occurrence and activity of NO in plants is reviewed. The multiplicity of nitrogen monoxide species and implications for differentiated reactivity are indicated. Possible sources of NO are evaluated, and the evidence for the presence of nitric oxide synthase in plants is summarised. The regulatory role of NO. in plant development and in plant interactions with microorganisms, involving an interplay with other molecules, like ethylene or reactive oxygen species is demonstrated. Finally, some other suggestions on potential functions of NO. in plants are indicated.     

Regulation of the endogenous NO pathway by prolonged inhaled NO in rats

Nitric oxide(NO) modulates the endogenous NO-cGMP pathway. We determined whetherprolonged inhaled NO downregulates the NO-cGMP pathway, which mayexplain clinically observed rebound pulmonary hypertension. Rats wereplaced in a normoxic (N; 21%O₂) or hypoxic (H; 10%O₂) environment with and withoutinhaled NO (20 parts/million) for 1 or 3 wk. Subsequently, nitric oxidesynthase (NOS) and soluble guanylate cyclase (GC) activity andendothelial NOS (eNOS) protein levels were measured. Perfusate cGMPlevels and endothelium-dependent and -independent vasodilation weredetermined in isolated lungs. eNOS protein levels and NOS activity werenot altered by inhaled NO in N or H rats. GC activity was decreased by60 ± 10 and 55 ± 11% in N and H rats, respectively, after 1 wkof inhaled NO but was not affected after 3 wk. Inhaled NO had no effecton perfusate cGMP in N lungs. Inhaled NO attenuated the increase incGMP levels caused by 3 wk of H by 57 ± 11%, but there was norebound in cGMP after 24 h of recovery. Endothelium-dependentvasodilation was not altered, and endothelium-independent vasodilationwas not altered (N) or slightly increased (H, 10 ± 3%) byprolonged inhaled NO. In conclusion, inhaled NO did not alter theendogenous NO-cGMP pathway as determined by eNOS protein levels, NOSactivity, or endothelium-dependent vasodilation under N and Hconditions. GC activity was decreased after 1 wk; however, GC activitywas not altered by 3 wk of inhaled NO and endothelium-independentvasodilation was not decreased.

     

NO flowering

The complex control of flowering time ensures that plants flower in conditions favourable for reproductive success. A recent study adds another dimension to this established complexity by revealing that nitric oxide (NO) represses flowering in Arabidopsis. The analysis of recently identified mutants that either overproduce or are compromised in endogenous NO production has identified NO-sensitive features of the circuitry of flowering time control: NO acts to repress the amplification of gene expression dependent on the circadian clock and promotes the accumulation of mRNA encoding a key repressor of flowering, FLC.     

Inhibition of Net Photosynthesis in Tomato in Air Polluted with NO and NO2

A 4 x 4 factorial experiment was conducted to examine the effectsof air polluted with 0, 10, 25, and 50 parts 10^–8 of NOand NO₂ on the rate of photosynthesis in tomato. Both gasesreduced net photosynthesis to approximately the same extent,from a mean rate of 13·03 in the controls to 9·40in 50 parts 10^–8 NO and 8·84 in 50 parts 10^–8NO₂ (all values in mg CO₂ dm^–2 h^–1). There was noevidence of any interaction between the two pollutants, buttheir effects were nearly additive over parts of the concentrationrange tested. Tomato appears to be more sensitive to the presence of nitrogenoxides in the atmosphere than other species so far investigated.NO and NO₂ are generated by hydrocarbon burners used to provideCO₂ enrichment for glasshouses, and can accumulate in concentrationswithin the range employed in this experiment.     

NO donors mimic and NO inhibitors inhibit cytokinin action in betalaineaccumulation in Amaranthus caudatus

A classical biotest for cytokinin is based on the accumulation of betalainesin Amaranthus species. We have shown that inhibitorsof nitric oxide synthase from animals inhibit this response and that chemicaldonors of nitric oxide (NO) stimulate betalaine biosynthesis in Amaranthuscaudatus. NO could be an intermediate in cytokinin signalling.     

NO Synthesis in Human Saliva

Human saliva contains nitrate that is converted into nitrite by the activity of facultative, anaerobic bacteria of the oral cavity. Nitrite can be reduced to NO in the acidic gastric milieu; some NO may also form in the mouth at acidic pH values. In this paper, we show that bacteria ( S. salivarius, S. mitis and S. bovis ) isolated from saliva, may contribute to NO production in human saliva. NO formation by bacteria occurs at neutral pH values and may contribute to the antibacterial activity of saliva.     

NO synthesis in human saliva

Human saliva contains nitrate that is converted into nitrite by the activity of facultative, anaerobic bacteria of the oral cavity. Nitrite can be reduced to NO in the acidic gastric milieu; some NO may also form in the mouth at acidic pH values. In this paper, we show that bacteria ( S. salivarius , S. mitis and S. bovis ) isolated from saliva, may contribute to NO production in human saliva. NO formation by bacteria occurs at neutral pH values and may contribute to the antibacterial activity of saliva.     

Distal Val346Ile mutation in inducible NO synthase promotes substrate-dependent NO confinement

The function of inducible NO synthase (WT iNOS) depends on the release of NO from the ferric heme before the enzyme is reduced. Key parameters controlling ligand dynamics include the distal and proximal heme pocket amino acids, as well as the inner solvent molecules. In this work, we tested how a point mutation in the distal heme side of WT iNOS affected the geminate rebinding of NO by ultrafast kinetics and molecular dynamics simulations. The mutation sequestered much of the photodissociated NO close to the heme compared to WT iNOS, with a main picosecond phase accounting for 78% of the rebinding to the arginine-bound Val346Ile protein. Consequently, the probability of NO release from Val346Ile decreased as compared to that from WT iNOS, provided the substrate binding site is filled. These data are rationalized by a steric effect of the Ile methyl group inducing events mediated by the substrate, transmitted via the propionates to the NO and the protein. This model is consistent with the role of the H-bonding network involving the heme, the substrate, and the BH4 cofactor in controlling NO release, with a key role of the heme propionates [Gautier et al. (2006) Nitric Oxide 15, 312]. These data support the effect of Val346Ile mutation in decreasing NO release and slowing down NO synthesis compared to WT iNOS determined by single turnover catalysis [Wang et al. (2004) J. Biol. Chem. 279, 19018].     

Heat-induced increases in endothelial NO synthase expression and activity and endothelial NO release

Endothelial nitric oxide (NO) synthase (eNOS) is regulated by heat shock protein 90 (HSP90), a heat-inducible protein; however, the effect of heat shock on eNOS expression and eNO release is unknown. Bovine aortic endothelial cells were incubated for 1 h at 37 degrees C, 42 degrees C, or 45 degrees C and cell lysates were evaluated with the use of Western blotting. We observed a 2.1 +/- 0.1-fold increase in eNOS protein content, but no change in HSP90 content, HSP70 content, or HSP90/eNOS association, 24 h after heat shock at 42 degrees C. We also observed a 7.7 +/- 1.5-fold increase in HSP70 protein content, but did not observe a change in eNOS or HSP90 24 h after heat shock at 45 degrees C. eNOS activity and maximal bradykinin-stimulated NO release was significantly increased 24 h after heat shock at 42 degrees C. Heat shock in rats (core temperature: 42 degrees C, 15 min) resulted in a significant increase in aortic eNOS, HSP90, and HSP70 protein content. The aorta from heat-shocked rats exhibited a decreased maximal contractile response to phenylephrine, which was abolished by preincubation with NG-nitro-l-arginine. We conclude that prior heat shock is a physical stimulus of increased eNOS expression and is associated with an increase in eNOS activity, agonist-stimulated NO release, and a decreased vasoconstrictor response.     

Comparison of NO production level and proliferation of MCF-7 breast tumor cells under conditions of microenvironment modification

Connection between the level of NO generation and its cytotoxic influence was investigated on two models of tumor cells (breast adenocarcinoma MCF-7) culture: monolayer and spheroids. Conditions of microenvironment were modified by Ca2+ channels blockers: EGTA, nitrendipine and Cl-lanthan. It was discovered in the work that deviation in concentration of extracellular Ca2+ under the influence of EGTA leads to reducing of the level of extracellular NO to 50% (P < or = 0.05) of control and increasing of the number of live cells by 10-40% (P < or = 0.05). Nitrendipin has the properties selective Ca2+ channels blocker that reduced the level of NO by 35-70% (P < or = 0.05), depending on the substances concentration and time of incubation. At that time proliferation potential of cells increased by 10-35% (P < or = 0.05). NO production in MCF-7 cells under the influence of Cl-lanthan in concentration of 0.01 and 0.1 mM is reduced by 50-60%, as compared with the control. But it had no influence on the number of live cells. On 2-D and 3-D models of tumor growth it was demonstrated that extracellular NO production in monolayer of MCF-7 was 3.2 pmol for 10(6) cells and for spheroids it was 8.5 pmol.     

Bronchial responsiveness is related to increased exhaled NO (FE(NO)) in non-smokers and decreased FE(NO) in smokers

Rationale

Both atopy and smoking are known to be associated with increased bronchial responsiveness. Fraction of nitric oxide (NO) in the exhaled air (FE_NO), a marker of airways inflammation, is decreased by smoking and increased by atopy. NO has also a physiological bronchodilating and bronchoprotective role.

Objectives

To investigate how the relation between FE_NO and bronchial responsiveness is modulated by atopy and smoking habits.

Methods

Exhaled NO measurements and methacholine challenge were performed in 468 subjects from the random sample of three European Community Respiratory Health Survey II centers: Turin (Italy), Gothenburg and Uppsala (both Sweden). Atopy status was defined by using specific IgE measurements while smoking status was questionnaire-assessed.

Main Results

Increased bronchial responsiveness was associated with increased FE_NO levels in non-smokers (p = 0.02) and decreased FE_NO levels in current smokers (p = 0.03). The negative association between bronchial responsiveness and FE_NO was seen only in the group smoking less <10 cigarettes/day (p = 0.008). Increased bronchial responsiveness was associated with increased FE_NO in atopic subjects (p = 0.04) while no significant association was found in non-atopic participants. The reported interaction between FE_NO and smoking and atopy, respectively were maintained after adjusting for possible confounders (p-values<0.05).

Conclusions

The present study highlights the interactions of the relationship between FE_NO and bronchial responsiveness with smoking and atopy, suggesting different mechanisms behind atopy- and smoking-related increases of bronchial responsiveness.