1795–1995: Milestones in ROS research

Summary

Oxygen (O₂)-dependent and O₂-independent antimicrobial mechanisms are used by alveolar macrophages (AM) to maintain lung sterility, but these mechanisms are underdeveloped in neonatal AM. Nitric oxide (NO^.), a more recently described antimicrobial and immunomodulating molecule, has not been studied in neonatal AM. Lavaged AM from 3-day-old, 10-day-old, maternal and adult rats were treated with or without lipopolysaccharide (LPS) and/or interferon-γ (IFN-γ) and NO^. synthase activity was measured as its L-arginine metabolites: NO₂^?, NO₃^?, and citrulline. Superoxide anion (O₂^.-) production by suspended macrophages, initiated by either opsonized zymosan or phorbol, was used as a marker of O₂-dependent antimicrobial activity. Lysozyme content of AM was measured as a component of O₂-independent antimicrobial activity. Unstimulated 3-day-old macrophages generated >10-fold more NO₂^? + NO₃^? than did 10-day-old, maternal or adult AM. Twenty hours after LPS and IFN-γ stimulation, 3-day-old AM produced > 2 times more NO₂^? and NO₃^? than did the more mature macrophages. Basal and stimulated O₂^.- release was similar among 3-day-old, 10-day-old and adult AM, while lysozyme concentrations were > 4-fold higher in adult macrophages compared to AM from 3-day-old pups. Rather than having a role in NO^.-dependent antimicrobial activity, we propose that newborn AM have amplified NO^. production to modulate their own differentiation and replication after birth. The age-dependent differences in NO^. synthase expression by AM may lend insight into the regulation of this important enzyme.     

Role of Nitrate in Photosynthetic Electron Transport of Chlorella Vulgaris

Addition of nitrate to a suspension of NO₃ ^--depleted Chlorella vulgaris cells raised the O₂-evolving capacity of the organism by 60%. The rate of O₂-evolution under flash irradiation of the depleted cells was drastically reduced, which could be restored by addition of NO₃ ^-. The 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB)-insensitive O₂-evolution, i.e., photosystem (PS) 2 activity of NO₃--depleted cells, showed a 75% stimulation by addition of NO₃ ^-. PS1-mediated electron transport was also stimulated (50%) by addition of NO₃ ^-. Fluorescence yields of the NO₃ ^--depleted cells were significantly reduced. A normal fluorescence response was restored by the addition of NO₃ ^-. The fluorescence yield of the NO₃ ^--depleted and DCMU-treated-cells increased significantly after addition of NO₃ ^- ions, indicating a further reduction of the primary acceptor of PS2 (Q). In addition, the low temperature fluorescence emission spectra showed that energy transfer to PS2 and PS1 was much higher when nitrate was present. Hence nitrate accelerates the light-induced charge transfer from the intact O₂-evolving system to the primary electron acceptor of PS2 and stimulates the PS1-mediated electron transport. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Characteristics and Regulatory Mechanisms of Superoxide Generation from eNOS Reductase Domain

In addition to superoxide (O₂ ^.-) generation from nitric oxide synthase (NOS) oxygenase domain, a new O₂ ^.- generation site has been identified in the reductase domain of inducible NOS (iNOS) and neuronal NOS (nNOS). Cysteine S-glutathionylation in eNOS reductase domain also induces O₂ ^.- generation from eNOS reductase domain. However, the characteristics and regulatory mechanism of the O₂ ^.- generation from NOS reductase domain remain unclear. We cloned and purified the wild type bovine eNOS (WT eNOS), a mutant of Serine 1179 replaced with aspartic acid eNOS (S1179D eNOS), which mimics the negative charge caused by phosphorylationand truncated eNOS reductase domain (eNOS RD). Both WT eNOS and S1179D eNOS generated significant amount of O₂ ^.- in the absence of BH4 and L-arginine. The capacity of O₂ ^.- generation from S1179D eNOS was significantly higher than that of WT eNOS (1.74:1). O₂ ^.- generation from both WT eNOS and S1179D eNOS were not completely inhibited by 100nM tetrahydrobiopterin(BH4). This BH4 un-inhibited O₂ ^.- generation from eNOS was blocked by 10mM flavoprotein inhibitor, diphenyleneiodonium (DPI). Purified eNOS reductase domain protein confirmed that this BH4 un-inhibited O₂ ^.- generation originates at the FMN or FAD/NADPH binding site of eNOS reductase domain. DEPMPO-OOH adduct EPR signals and NADPH consumptions analyses showed that O₂ ^.- generation from eNOS reductase domain was regulated by Serine 1179 phosphorylation and DPI, but not by L-arginine, BH4 or calmodulin (CaM). In addition to the heme center of eNOS oxygenase domain, we confirmed another O₂ ^.- generation site in the eNOS reductase domain and characterized its regulatory properties.     

Design and Synthesis of LNA-Based Mercaptoacetamido-Linked Nucleoside Dimers

Three LNA-based mercaptoacetamido-linked nonionic nucleoside dimers T^L-S-T, T-S-T^L , and T^L-S-T^L have been synthesized by HOBT and HBTU catalyzed condensation of silyl-protected 2-S-(thymidin-5?′-yl)mercaptoacetic acid or 2-S-(2?′-O,4?′-C-methylenethymidin-5?′-yl)mercaptoacetic acid with 3?′-amino-3?′-deoxy-5?′-O-DMT-2?′-O,4?′-C-methylenethymidine or with 3?′-amino-3?′-deoxy-5?′-O-DMT-β-thymidine followed by desilylation of the protected dimers. The 3?′-O-phosphoramidite derivative of one of the nucleoside dimers was successfully prepared by condensation with [P(-Cl)(-OCH₂CH₂CN)-N(iPr)₂}] in DCM in the presence of N,N-diisopropylethylamine (DIPEA), which is a building block for the preparation of mercaptoacetamido-linked oligonucleotides of therapeutic applications.     

Light dependent reduction of nitrate by pea chloroplasts in the presence of nitrate reductase and C4-dicarboxylic acids

In the presence of purified nitrate reductase (NR) and 1 mM NADH, illuminated pea chloroplasts catalysed reduction of NO₃^? to NH₃ with the concomitant evolution of O₂. The rates were slightly less than those for reduction of NO₂^? to NH₃ and O₂, evolution by chloroplasts in the absence of NR and NADH (ca 6 μg atoms N/mg Chl/hr). Illuminated chloroplasts quantitatively reduced 0.2 mM oxaloacetate (OAA) to malate. In the presence of an extrachloroplast malate-oxidizing system comprised of NAD-specific malate dehydrogenase (NAD-MDH), NAD, NR and NO₃^?, illuminated chloroplasts supported OAA-dependent reduction of NO₃^? to NH₃ with the evolution of O₂. The reaction did not proceed in the absence of any of these supplements or in the dark but malate could replace OAA. The results are consistent with the reduction of NO₃^?by reducing equivalents from H₂O involving a malate/OAA shuttle. The ratios for O₂, evolved: C₄-acid supplied and N reduced: C₄-acid supplied in certain experiments imply recycling of the C₄-acids.     

Microscale Distribution of Nitrification Activity in Sediment Determined with a Shielded Microsensor for Nitrate

Microprofiles of O₂ and NO₃^- were measured simultaneously in freshwater sediment with microsensors which were completely free from electrical interference because of coaxial designs. Depth profiles of nitrification (NO₃^- production) and denitrification (NO₃^- consumption) were subsequently determined by computer simulation of the measured microprofiles. The nitrifying bacterial community responded very quickly to changes in environmental conditions, and new steady-state microprofiles of O₂ and NO₃^- were usually approached within a few hours after perturbation. Nitrification started quickly after introduction of O₂ in previously anoxic layers, suggesting prolonged survival of the nitrifiers during anaerobiosis. Changes in the availability of O₂ and NH₄⁺ greatly affected the nitrification profile, and there was a high rate of coupled nitrification-denitrification under conditions in which nitrification occurred right above the oxic-anoxic interface. Addition of C₂H₂ rapidly removed the NO₃^- peaks, indicating that NO₃^- production was due mainly to autotrophic nitrification.     

The Novel Relationship between Urban Air Pollution and Epilepsy: A Time Series Study

MethodsA hospital record-based study was carried out in Xi’an, a heavily-polluted metropolis in China. Daily baseline data were obtained. Time-series Poisson regression models were applied to analyze the association between air pollution and epilepsy.ResultsA 10 μg/m³ increase of NO₂, SO₂, and O₃ concentrations corresponded to 3.17% (95%Cl: 1.41%, 4.93%), 3.55% (95%Cl: 1.93%, 5.18%), and -0.84% (95%Cl: -1.58%, 0.09%) increase in outpatient-visits for epilepsy on the concurrent days, which were significantly influenced by sex and age. The effects of NO₂ and SO₂ would be stronger when adjusted for PM_2.5. As for O₃, a -1.14% (95%Cl: -1.90%, -0.39%) decrease was evidenced when adjusted for NO₂. The lag models showed that the most significant effects were evidenced on concurrent days.ConclusionsWe discovered previously undocumented relationships between short-term air pollution exposure and epilepsy: while NO₂ and SO₂ were positively associated with outpatient-visits of epilepsy, O₃ might be associated with reduced risk.     

Superoxide dismutase enhances chain-breaking antioxidant capability of hydroquinones

2-tert-butyl-(1), 2,6-dimethyl-(2), 2,5-dimethyl-(3), trimethyl-(4), and 2,3-dimethoxy-5-methyl-(5) substituted p-hydroquinones (QH₂) were tested as a chainbreaking antioxidant during the oxidation of methyl linoleate (ML) in dodecyl sulfate micellar solution, pH 7.40, at 37°C. In the absence of superoxide dismutase (SOD), all the studied QH₂ displayed very moderate if any antioxidant capability. When 5–25 U/ml SOD was added, QH₂ showed a pronounced ability to inhibit ML oxidation. The stoichiometric factor of inhibition was found to be about one for all the tested QH₂ in the presence of SOD. The reactivities of QH₂ to the ML peroxy radical increase in the order QH₂5 < QH₂ 3 < QH₂1≈QH₂2 < QH₂4; reactivity of QH₂4 exceds that reported for the majority of phenolic antioxidants. The features of QH₂ as an antioxidant in aqueous environment is likely associated with the reactivity of semiquinone (O^·-) formed due to attack of the peroxy radical to QH₂. O^·- reacts readily with molecular oxygen with formation of superoxide (O^·-₂); in turn, O^·-₂ attacks both to QH₂ and ML (likely, as HO^·₂) that results in fast depleting QH₂ and chain propagation, respectively. The addition of SOD results in purging a reaction mixture from O^·-₂ and, as a corollary, in depressing undesirable reactions with the participation of O^·-₂. Under these conditions, QH₂ displays the theoretically highest inhibitory activity which is determined solely by the reactivity of QH₂ to the peroxy radical.     

Light-dependent incorporation of selenite and sulphite into selenocysteine and cysteine by isolated pea chloroplasts

Illuminated intact pea chloroplasts in the presence of O-acetylserine (OAS) catalysed incorporation of SeO₃^2- and SO₃^2- into selenocysteine and cysteine at rates of ca 0.36 and 6 μmol/mg Chl per hr respectively. Sonicated chloroplasts catalysed SeO₃^2- and SO₃^2- incorporation at ca 3.9 and 32% respectively of the rates of intact chloroplasts. Addition of GSH and NADPH increased the rates to ca 91 and 98% of the intact rates, but SeO₃^2- incorporation under these conditions was essentially light-independent. In the absence of OAS, intact chloroplasts catalysed reduction of SO₃^2- to S^2- at rates of ca 5.8 μmol/mg Chl per hr. In the presence of OAS, S^2- did not accumulate. Glutathione (GSH) reductase was purified from peas and was inhibited by ZnCl₂. This enzyme, in the presence of purified clover cysteine synthase, OAS, GSH and NADPH, catalysed incorporation of SeO₃^2- into selenocysteine (but not SO₃^2- into cysteine). The reaction was inhibited by ZnCl₂. Incorporation of SeO₃^2- into selenocysteine by illuminated intact chloroplasts and sonicated chloroplasts (with NADPH and GSH) was also inhibited by ZnCl₂ but not by KCN. Conversely, incorporation of SO₃^2- into cysteine was inhibited by KCN but not by ZnCl₂. It was concluded that SeO₃^2- and SO₃^2- are reduced in chloroplasts by independent light-requiring mechanisms. It is proposed that SeO₃^2- is reduced by light-coupled GSH reductase and that the Se^2- produced is incorporated into selenocysteine by cysteine synthase.     

Nitric oxide concentrations in gas emanating from the tails of obese rats

Abstract

This study was undertaken to investigate the effects of oral L-arginine administration and exercising training on the NO concentration emanating from rat tail and NO_x in plasma. Obese (fa/fa) Zucker rats (n = 22) were divided into four groups: (1) oral L-arginine administration (A) (n = 6), (2) exercise training (E), (3) exercise training + L-arginine administration (E + A) (n = 5), and (4) non-exercise training + non-L-arginine administration (N) (n = 6). The control (+/+) Zucker rats (n = 22) were also divided into the same four groups. The body weight of the E + A and the A groups was significantly lower than that of the N group. The NO concentration emitted from the tail was higher in the L-arginine (E + A and A) groups than in the non-L-arginine (E and N) groups in both obese and control rats. Exercise training did not affect the skin gas NO concentration in either obese or control rats. Plasma NO_x concentrations in four obese rats were significantly higher than those observed in control rats. Exercise training did not influence the level of plasma NO_x in obese or control rats. In conclusion, this study confirmed that L-arginine administration increases the skin gas NO concentration and obesity increases the plasma NO_x level. The plasma NO_x concentrations were not affected by L-arginine administration or exercise training in obese or control rats.     

Catalase catalyzes nitrotyrosine formation from sodium azide and hydrogen peroxide

Sodium azide (NaN₃) is known as an inhibitor of catalase, and a nitric oxide (NO) donor in the presence of catalase and H₂O₂. We showed here that catalase-catalyzed oxidation of NaN₃ can generate reactive nitrogen species which contribute to tyrosine nitration in the presence of H₂O₂. The formation of free-tyrosine nitration and protein-bound tyrosine nitration by the NaN₃/catalase/H₂O₂ system showed a maximum level at pH 6.0. Free-tyrosine nitration induced by peroxynitrite was inhibited by ethanol and dimethyl-sulfoxide (DMSO), and augmented by superoxide dismutase (SOD). However, free-tyrosine nitration induced by the NaN₃/catalase/H₂O₂ system was not affected by ethanol, DMSO and SOD. NO^-₂ and NO donating agents did not affect free-tyrosine nitration by the NaN₃/catalase/H₂O₂ system. The reaction of NaN₃ with hydroxyl radical generating system showed free-tyrosine nitration, but no formation of nitrite and nitrate. The generation of nitrite (NO^-₂) and nitrate (NO^-₃) by the NaN₃/catalase/H₂O₂ system was maximal at pH 5.0. These results suggested that the oxidation of NaN₃ by the catalase/H₂O₂ system generates unknown peroxynitrite-like reactive nitrogen intermediates, which contribute to tyrosine nitration.     

Nitrate and ammonium as nitrogen sources for lupins prior to nodulation

Two cultivars of Lupinus angustifolius L. were grown in a glasshouse in solutions containing NO₃ ^-, NH₄ ⁺ or NH₄NO₃ with a total nitrogen concentration of 2.8 M m^-3 in each treatment. One cultivar chosen (75A-258) was relatively tolerant to alkaline soils whereas the other (Yandee) was intolerant to alkalinity. Controlled experiments were used to assess the impact of cationic vs. anionic forms of nitrogen on the relative performance of these cultivars. Relative growth rates (dry weight basis) were not significantly different between the two cultivars when grown in the presence of NO₃ ^-, NH₄ ⁺ or NH₄NO₃. However, when NO₃ ^- was supplied, there was a modest decline in relative growth rates in both cultivars over time. When plants grown on the three sources of nitrogen for 9 days were subsequently supplied with ¹⁵NH₄NO₃ or NH₄ ¹⁵NO₃ for 30 h, NH₄ ⁺ uptake was generally twice as fast as NO₃ ^- uptake, even for plants grown in the presence of NO₃ ^-. Low rates of NO₃ ^- uptake accounted for the decrease in growth rates over time when plants were grown in the presence of NO₃ ^-. It is concluded that the more rapid growth of 75A-258 than Yandee in alkaline conditions was not due to preferential uptake of NH₄ ⁺ and acidification of the external medium. In support of this view, acidification of the root medium was not significantly different between cultivars when NH₄ ⁺ was the sole nitrogen source.     

STUDIES ON NITRIC OXIDE FREE RADICALS GENERATED FROM POLYMORPHONUCLEAR LEUKOCYTES (PMN) STIMULATED BY PHORBOL MYRISTATE ACETATE (PMA)

The interaction of NO and O^?₂free radicals generated from PMA (phorbol myristate acetate)-stimulated PMN (polymorphonuclear leukocytes) was studied by a nitroxide spin trap, DMPO (5,5-dimethyl-1-pyrroline-1-oxide). It was found that addition of L-arginine to the system would significantly decrease the trapped O^?₂by DMPO and addition of N^G-monomethyl-arginine (NGMA) would significantly increase the trapped O^?₂by DMPO. It was proved that the formation of ONOO^?by the reaction of NO and O^?₂was the main reason for the decrease of trapped O^?₂in the experiment with xanthine/xanthine oxidase and irradiation of riboflavin systems. The yield of NO during this process was calculated. The generation dynamic of NO was studied by a luminol-dependent chemiluminescence technique and it was found that after stimulation of PMN by PMA, there would be an immediate, significant chemi-luminescence, which came mainly from the active oxygen free radicals generated by PMN. If L-arginine was added to this system, the chemiluminescence would increase about 100-fold, but NGMA inhibited the increase of the chemiluminescence. Ten minutes after addition of L-arginine, this increase did not change, the chemiluminescence peak decreased gradually, but the half life increased. The ESR and chemiluminescence properties of NO and ONOO^?synthesized were also studied in model systems.     

The effect of the source of inorganic nitrogen on growth and enzymes of nitrogen assimilation in soybean and wheat cells in suspension cultures

Summary Soybean (Glycine max L. cv. Mandarin) and wheat (Triticum monococcum L.) cells were grown in media with NO₃ ^- plus NH₄ ⁺ (B₅) and NO₃ ^- without NH₄ ⁺ (B₅-NH₄) as nitrogen sources. Changes in pH, [NO₃ ^-] and [NH₄ ⁺] in media, and dry weight, protein content, nitrate reductase (NR) and glutamate dehydrogenase (GDH) in the cells were followed for about 170 h. With both NH₄ ⁺ and NO₃ ^- in the medium, NH₄ ⁺ was utilized very quickly. Soybean cells grew poorly in the absence of NH₄ ⁺ while wheat cells grew equally well on media with or without NH₄ ⁺. When soybean cells were grown in medium with NO₃ ^- plus NH₄ ⁺, dry weight and NR activity remained relatively low for several hours after which both increased rapidly. This coincided with the time NH₄ ⁺ was depleted from the medium. In the absence of NH₄ ⁺, soybean cell growth and NR activity remained low. NR activity in wheat cells, and GDH activity in soybean and wheat cells, did not vary significantly in the presence or absence of NH₄ ⁺.This work was supported by a grant in aid of research from the National Research Council of Canada to one of us (J. K.). NRCC No. 12521.     

Survival of Denitrifiers in Nitrate-Free, Anaerobic Environments

Experiments were undertaken to explain the occurrence of a high denitrification capacity in anaerobic, NO₃^--free habitats. Deep layers of freshwater sediments that were buried more than 40 years ago and digested sludge were the habitats studied. The denitrifier populations were 3.1 × 10³ and 3.1 × 10⁵ cells cm^-3 in deep sediments from a river and lake, respectively, and 5.3 × 10⁶ cells cm^-3 in digested sludge. The denitrification capacities of the samples reflected the population densities. Strict anaerobic procedures were used to obtain the predominant isolates that would grow on anaerobic medium with NO₃^-. All strict anaerobes isolated failed to denitrify. All isolates that denitrified were aerobic, gram-negative bacteria, particularly species of Pseudomonas and Alcaligenes. No detectable growth was observed when these strains were incubated with electron acceptors other than NO₃^- or O₂. When representative isolates were added to sterile, O₂- and NO₃^--free porewater from their original locations at their natural densities (10⁵ cells cm^-3), no change in viable population was noted over 3 months of incubation. Metabolic activity was demonstrated in these cells by slow formation of formazan granules when exposed to tetrazolium and by observation of motile cells. When [¹⁴C]glucose was added to cell suspensions of the pseudomonads that had been starved for 3 months without electron acceptors (O₂ or NO₃^-), ¹⁴C-labeled products, including cell biomass, ¹⁴CO₂, and fermentation products, were produced. The high denitrification capacity of these anaerobic environments appears to be due to conventional respiratory denitrifiers. These organisms have the capacity for long-term survival without O₂ or NO₃^- and appear to be capable of providing for their maintenance by carrying on a low level of fermentation.     

Nitric oxide and peroxynitrite. The ugly,the uglier and the not so good

Nitric oxide, a gaseous free radical, is poorly reactive with most biomolecules but highly reactive with other free radicals. Its ability to scavenge peroxyl and other damaging radicals may make it an important antioxidant in vivo, particular in the cardiovascular system, although this ability has been somewhat eclipsed in the literature by a focus on the toxicity of peroxynitrite, generated by reaction of O^·-₂ with NO^· (or of NO^- with O₂). On balance, experimental and theoretical data support the view that ONOO^- can lead to hydroxyl radical (OH^·) generation at pH 7.4, but it seems unlikely that OH^· contributes much to the cytotoxicity of ONOO^-. The cytotoxicity of ONOO^- may have been over-emphasized: its formation and rapid reaction with antioxidants may provide a mechanism of using NO^· to dispose of excess O^·-₂, or even of using O^·-₂ to dispose of excess NO^·, in order to maintain the correct balance between these radicals in vivo. Injection or instillation of “bolus” ONOO^- into animals has produced tissue injury, however, although more experiments generating ONOO^- at steady rates in vivo are required. The presence of 3-nitrotyrosine in tissues is still frequently taken as evidence of ONOO^- generation in vivo, but abundant evidence now exists to support the view that it is a biomarker of several “reactive nitrogen species”. Another under-addressed problem is the reliability of assays used to detect and measure 3-nitrotyrosine in tissues and body fluids: immunostaining results vary between laboratories and simple HPLC methods are susceptible to artefacts. Exposure of biological material to low pH (e.g. during acidic hydrolysis to liberate nitrotyrosine from proteins) or to H₂O₂ might cause artefactual generation of nitrotyrosine from NO^-₂ in the samples. This may be the origin of some of the very large values for tissue nitrotyrosine levels quoted in the literature. Nitrous acid causes not only tyrosine nitration but also DNA base deamination at low pH: these events are relevant to the human stomach since saliva and many foods are rich in nitrite. Several plant phenolics inhibit nitration and deamination in vitro, an effect that could conceivably contribute to their protective effects against gastric cancer development.     

Nitrate reductase and nitrate accumulation in relation to nitrate toxicity in Boronia megastigma

Moderate levels of N were toxic to the native Australian plant boronia (Boronia megastigma Nees). As NO^-₃ is the major N form available for plants under cultivated conditions, NO^-₃ reduction and accumulation patterns in boronia were examined following the supply of various levels of NO^-₃ to understand the physiological basis of this toxicity. At a low level of supplied NO^-₃ [15 mmol (plant)^-1], NO^-₃ was reduced without any detectable accumulation and without nitrate reductase activity (NRA) reaching its maximum capacity. When higher NO^-₃ levels [≥25 mmol (plant)^-1] were supplied, both NRA and NO^-₃ accumulation increased further. However, NRA increased to a maximum of ca 500 nmol NO^-₃ (g fresh weight)^-1 h^-1, both in the roots and leaves, irrespective of a 4-fold difference in the levels of supplied NO^-₃, whereas NO^-₃ continued to accumulate in proportion to the level of supplied NO^-₃. Chlorotic toxicity symptoms appeared on the leaves at an accumulation of ca 32 μmol NO^-₃ (g fresh weight)^-1. High endogenous NO^-₃ concentrations inhibited NRA. The low level of NRA in boronia was not limited by NO^-₃ or electron donor availability. It is concluded that the low NR enzyme activity is a genetic adaptation to the low NO^-₃ availability in the native soils of boronia. Thus, when NO^-₃ supply is high, the plat cannot reduce it at high rates, leading to large and toxic accumulations of the ion in the leaf tissues.     

New binary copper(II) complexes containing intercalating ligands: DNA interactions,an unusual static quenching mechanism of BSA and cytotoxic activities

New binary copper(II) complexes – [Cu(4-mphen)₂(NO₃)]NO₃·H₂O (1), [Cu(5-mphen)₂ (NO₃)]NO₃·H₂O (2), the known complex [Cu(dmphen)₂(NO₃)]NO₃ (3) and [Cu(tmphen)₂ (NO₃)]NO₃·H₂O (4) - (4-mphen: 4-methyl-1,10-phenanthroline, 5-mphen: 5-methyl-1,10-phenanthroline, dmphen: 4,7-dimethyl-1,10-phenanthroline, tmphen: 3,4,7,8-tetramethyl-1,10-phenanthroline), have been synthesized and characterized by CHN analysis, ESI-MS, FTIR and single-crystal X-ray diffraction techniques. Interaction of these complexes with calf thymus DNA (CT-DNA) has been investigated by absorption spectral titration, ethidium bromide (EB) and Hoechst 33,258 displacement assay and thermal denaturation measurement. These complexes cleaved pUC19 plasmid DNA in the absence and presence of an external agent. Notably, in the presence of H₂O₂ as an activator, the cleavage abilities of these complexes are obviously enhanced at low concentration. Addition of hydroxyl radical scavengers like DMSO shows significant inhibition of the DNA cleavage activity of these complexes. BSA quenching mechanism was investigated with regard to the type of quenching, binding constant, number of binding locations and the thermodynamic parameters. The experimental results suggested that the probable quenching mechanism was an unusual static process and hydrophobic forces play a dominant role. The CT-DNA and BSA binding efficiencies of these complexes follow the order: 4 > 3 > 1 > 2. Furthermore, in vitro cytotoxicities of these complexes on tumor cells lines (Caco-2, MCF-7 and A549) and healthy cell line (BEAS-2B) showed that these complexes exhibited anticancer activity with low IC₅₀ values. The effect of hydrophobicity of the methyl-substituted phenanthrolines on DNA and protein binding activities of these complexes is discussed.     

Salt-induced NO<Subscript>3</Subscript><Superscript>-</Superscript> uptake inhibition in cowpea roots is dependent on the ionic composition of the salt and its osmotic effect

Salinity remarkably inhibits NO₃ ^- uptake but the mechanisms are not well understood. This study was addressed to elucidate the role of ionic and osmotic components of salinity on NO₃ ^- influx and efflux employing classic kinetics involving a low affinity transport system (LATS) and a high affinity transport system (HATS). In the presence of KCl, NaCl, and Na₂SO₄ at 100 mM concentrations, in both LATS and HATS, Michaelis constant (K_m) was similar for the three salts and maximum rate (V_max) decreased as follows: KCl > NaCl > Na₂SO₄, compared to control indicating a non-competitive interaction with NO₃ ^-. Unexpectedly, iso-osmotic solutions (osmotic potential Ψ_π = -0.450) of polyethylene glycol (PEG, 17.84 %, v/v) and mannitol (100 mM) remarkably increased K_m in both the LATS and the HATS, but V_max did not change indicating a competitive inhibition. Under the PEG and mannitol treatments, K_m and V_max were higher than under the salt treatments. The salts increased slightly NO₃ ^- efflux in the following order KCl > NaCl > Na₂SO₄. In contrast, mannitol strongly stimulated and the PEG inhibited NO₃ ^- efflux. The obtained data reveal that salinity effects were not dependent on the anion type (Cl^- versus SO₄ ^2-) indicating a non-competitive inhibition mechanism between Cl^- and NO₃ ^-. In contrast, the cation types (K⁺ versus Na⁺) had a pronounced effect. The osmotic component is important to net NO₃ ^- uptake affecting remarkably the influx in both LATS and HATS components of cowpea roots.     

Effects of a localized supply of nitrate on NO3 - uptake rate and growth of roots in Lolium multiflorum Lam.

Roots of higher plants are usually exposed to varying spatial and temporal changes in concentrations of soil mineral nitrogen. A split root system was used to see how Lolium multiflorum Lam. roots adapt to such variations to cope with their N requirements. Plants were grown in hydroponic culture with their root system split in two spatially separated compartments allowing them to be fed with or without KNO₃. Net NO₃ ^- uptake, ¹⁵NO₃ ^- influx and root growth were studied in relation to time. Within less than 24 h following deprivation of KNO₃ to half the roots, the influx in NO₃ ^- fed roots was observed to increase (about 200% of the influx measured in plant uniformly NO₃ ^- supplied control plant) thereby compensating the whole plant for the lack of uptake by the N deprived roots. Due to the large NO₃ ^- concentrations in the roots, the NO₃ ^- efflux was also increased so that the net uptake rate increased only slightly (35% maximum) compared with the values obtained for control plants uniformly supplied with NO₃ ^-. This increase in net NO₃ ^- uptake rate was not sufficient to compensate the deficit in N uptake rate of the NO₃ ^- deprived split root in the short term. Over a longer period (>1 wk), root growth of the part of the root system locally supplied with NO₃ ^- was stimulated. An increase in root growth was mainly responsable for the greater uptake of nitrate in Lolium multiflorum so that it was able to fully compensate the deficit in N uptake rate of the NO₃ ^- deprived split root.