活性氮、活性氧及植物激素在种子休眠解除中的作用及相互关系研究进展

休眠是植物种子对环境变化的适应机制,其机理至今未完全清楚阐明。前期对种子休眠机制的研究主要集中在激素调节上,近期的研究结果表明,一氧化氮（nitric oxide,NO）参与打破种子的休眠,并与其所引起的种子中活性氧的变化有关。本文简要综述活性氮（reactive nitrogen species,RNS）、活性氧（reactive oxygen species,R0s）和植物激素在种子休眠解除中的作用及相互关系研究进展。     

Influence of antioxidants on NO-dependent induction of heme oxygenase-1 in U937 monocytes

Thiol antioxidants are known to inhibit the nitric oxide-dependent induction of the hemoxygenase-1 gene (HOX-1). To estimate the degree to which the inhibitory effect of thiol antioxidants is accounted for by them scavenging oxidized NO derivatives or their precursors, the reactive oxygen and nitrogen species (ROS and RNS), we studied the inhibitory effect of nonthiol antioxidants: dimethyl sulfoxide, dimethylthiourea, sodium salicylate, sodium formate, uric acid, catalase, and superoxide dismutase. Partial inhibition of NO-dependent HOX-1 induction was observed in the presence of the nonpolar HO scavengers dimethyl sulfoxide and dimethylthiourea. The antioxidants which selectively bind other ROS had no effect on HOX-1 expression. To reveal the role of RNS in NO-dependent HOX-1 induction, cells were treated with the NO-generating compound DPTA-NO in the presence of 2-phenyl-4,4,5,5,-tetramethylimidazole-1-oxyl 3 oxide (PTIO), which oxidizes NO to NO₂. PTIO proved to significantly enhance NO-dependent HOX-1 induction. Thiol antioxidants completely inhibited the stimulating effect of PTIO, which is evidence that their inhibitory effect is explained by RNS scavenging. The results of this study indicate that antioxidants can be used to modulate the cell response to NO.Translated from Molekulyarnaya Biologiya, Vol. 39, No. 1, 2005, pp. 89–95.Original Russian Text Copyright © 2005 by Litvinov, Prasolov, Bouton, Drapier, Turpaev.     

H2O2-induced Leaf Cell Death and the Crosstalk of Reactive Nitric/Oxygen Species([F])

In plants, the chloroplast is the main reactive oxygen species (ROS) producing site under high light stress. Catalase (CAT), which decomposes hydrogen peroxide (H₂O₂), is one of the controlling enzymes that maintains leaf redox homeostasis. The catalase mutants with reduced leaf catalase activity from different plant species exhibit an H₂O₂‐induced leaf cell death phenotype. This phenotype was differently affected by light intensity or photoperiod, which may be caused by plant species, leaf redox status or growth conditions. In the rice CAT mutant nitric oxide excess 1 (noe1), higher H₂O₂ levels induced the generation of nitric oxide (NO) and higher S‐nitrosothiol (SNO) levels, suggesting that NO acts as an important endogenous mediator in H₂O₂‐induced leaf cell death. As a free radical, NO could also react with other intracellular and extracellular targets and form a series of related molecules, collectively called reactive nitrogen species (RNS). Recent studies have revealed that both RNS and ROS are important partners in plant leaf cell death. Here, we summarize the recent progress on H₂O₂‐induced leaf cell death and the crosstalk of RNS and ROS signals in the plant hypersensitive response (HR), leaf senescence, and other forms of leaf cell death triggered by diverse environmental conditions. [ Chengcai Chu (Corresponding author)]     

Redox signaling

Reactive oxygen species (ROS) and reactive nitrogen species (RNS) have recently been shown to be involved in a multiplicity of physiological responses through modulation of signaling pathways. Some of the specific signaling components altered by reactive oxygen and nitrogen species (RONS) have begun to be identified. We will discuss RONS signaling by detailing the chemistry of signaling, the roles of antioxidant enzymes as signaling components, thiol chemistry in the specificity of RONS signaling, NO-heme interactions, and some do's and don'ts of redox signal research. The principal points raised are that: (1) as with classic signaling pathways, signaling by RONS is regulated; (2) antioxidant enzymes are essential 'turn-off' components in signaling; (3) spatial relationships are probably more important in RONS signaling than the overall 'redox state' of the cell; (4) deprotonation of cysteines to form the thiolate, which can react with RONS, occurs in specific protein sites providing specificity in signaling; (5) although multiple chemical mechanisms exist for producing nitrosothiols, their formation in vivo remains unclear; and (6) caution should be taken in the use of 'antioxidants' in signal transduction.     

Unravelling how plants benefit from ROS and NO reactions,while resisting oxidative stress

Background and Aims Reactive oxygen species (ROS) and reactive nitrogen species (RNS), such as nitric oxide (NO), play crucial roles in the signal transduction pathways that regulate plant growth, development and defence responses, providing a nexus of reduction/oxidation (redox) control that impacts on nearly every aspect of plant biology. Here we summarize current knowledge and concepts that lay the foundations of a new vision for ROS/RNS functions – particularly through signalling hubs – for the next decade.Scope Plants have mastered the art of redox control using ROS and RNS as secondary messengers to regulate a diverse range of protein functions through redox-based, post-translational modifications that act as regulators of molecular master-switches. Much current focus concerns the impact of this regulation on local and systemic signalling pathways, as well as understanding how such reactive molecules can be effectively used in the control of plant growth and stress responses.Conclusions The spectre of oxidative stress still overshadows much of our current philosophy and understanding of ROS and RNS functions. While many questions remain to be addressed – for example regarding inter-organellar regulation and communication, the control of hypoxia and how ROS/RNS signalling is used in plant cells, not only to trigger acclimation responses but also to create molecular memories of stress – it is clear that ROS and RNS function as vital signals of living cells.     

Peroxisomes sense and respond to environmental cues by regulating ROS and RNS signalling networks

Background Peroxisomes are highly dynamic, metabolically active organelles that used to be regarded as a sink for H₂O₂ generated in different organelles. However, peroxisomes are now considered to have a more complex function, containing different metabolic pathways, and they are an important source of reactive oxygen species (ROS), nitric oxide (NO) and reactive nitrogen species (RNS). Over-accumulation of ROS and RNS can give rise oxidative and nitrosative stress, but when produced at low concentrations they can act as signalling molecules.Scope This review focuses on the production of ROS and RNS in peroxisomes and their regulation by antioxidants. ROS production is associated with metabolic pathways such as photorespiration and fatty acid β-oxidation, and disturbances in any of these processes can be perceived by the cell as an alarm that triggers defence responses. Genetic and pharmacological studies have shown that photorespiratory H₂O₂ can affect nuclear gene expression, regulating the response to pathogen infection and light intensity. Proteomic studies have shown that peroxisomal proteins are targets for oxidative modification, S-nitrosylation and nitration and have highlighted the importance of these modifications in regulating peroxisomal metabolism and signalling networks. The morphology, size, number and speed of movement of peroxisomes can also change in response to oxidative stress, meaning that an ROS/redox receptor is required. Information available on the production and detection of NO/RNS in peroxisomes is more limited. Peroxisomal homeostasis is critical for maintaining the cellular redox balance and is regulated by ROS, peroxisomal proteases and autophagic processes.Conclusions Peroxisomes play a key role in many aspects of plant development and acclimation to stress conditions. These organelles can sense ROS/redox changes in the cell and thus trigger rapid and specific responses to environmental cues involving changes in peroxisomal dynamics as well as ROS- and NO-dependent signalling networks, although the mechanisms involved have not yet been established. Peroxisomes can therefore be regarded as a highly important decision-making platform in the cell, where ROS and RNS play a determining role.     

Epithelial,dendritic, and CD4 T cell regulation of and by reactive oxygen and nitrogen species in allergic sensitization

Background

While many of the contributing cell types and mediators of allergic asthma are known, less well understood are the factors that induce allergy in the first place. Amongst the mediators speculated to affect initial allergen sensitization and the development of pathogenic allergic responses to innocuous inhaled antigens and allergens are exogenously or endogenously generated reactive oxygen species (ROS) and reactive nitrogen species (RNS).

Scope of review

The interactions between ROS/RNS, dendritic cells (DCs), and CD4⁺ T cells, as well as their modulation by lung epithelium, are of critical importance for the genesis of allergies that later manifest in allergic asthma. Therefore, this review will primarily focus on the initiation of pulmonary allergies and the role that ROS/RNS may play in the steps therein, using examples from our own work on the roles of NO₂ exposure and airway epithelial NF-κB activation.

Major conclusions

Endogenously generated ROS/RNS and those encountered from environmental sources interact with epithelium, DCs, and CD4⁺ T cells to orchestrate allergic sensitization through modulation of the activities of each of these cell types, which quantitiatively and qualitatively dictate the degree and type of the allergic asthma phenotype.

General significance

Knowledge of the effects of ROS/RNS at the molecular and cellular levels has the potential to provide powerful insight into the balance between inhalational tolerance (the typical immunologic response to an innocuous inhaled antigen) and allergy, as well as to potentially provide mechanistic targets for the prevention and treatment of asthma.     

Determination of reactive oxygen and nitrogen species in rat aorta using the dichlorofluorescein assay

A method for the determination of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in macroscopic sections of vessels has been developed on the basis of the dichlorofluorescein (DCF) assay. DCF was measured by fluorescence in extracts of vessels. The main artifact of the method is the oxidation of dichlorodihydrofluorescein (DCFH₂) which is released from vessels together with DCF during the extraction procedure. This problem was resolved by decreasing pH during the extraction. The optimal conditions and the time for aorta incubation with DCFH₂-DA and for the extraction of DCF from aorta have been determined. The ROS/RNS production in different aorta segments and the dependence of ROS/RNS production on rat age have been studied. It was shown that thoracic aorta sections produced the same amounts of ROS/RNS and the intermediate between the thoracic and the abdominal aorta part produced ROS and RNS by 14% more than the thoracic aorta. It was found that ROS/RNS production in aorta increases with rat age: the doubling time of ROS/RNS production rate is 113 days from birth.     

Oxidative pathways in response to polyunsaturated aldehydes in the marine diatom Skeletonema marinoi (Bacillariophyceae)

Polyunsaturated aldehydes (PUA) have recently been shown to induce reactive oxygen species (ROS) and possibly reactive nitrogen species (RNS, e.g., peroxynitrite) in the diatom Skeletonema marinoi (S. marinoi), which produces high amounts of PUA. We now are attempting to acquire better understanding of which reactive molecular species are involved in the oxidative response of S. marinoi to PUA. We used flow cytometry, the dye dihydrorhodamine 123 (DHR) as the main indicator of ROS (but which is also known to partially detect RNS), and different scavengers and inhibitors of both nitric oxide (NO) synthesis and superoxide dismutase activity (SOD). Both the scavengers Tempol (for ROS) and uric acid (UA, for peroxynitrite) induced a lower DHR‐derived green fluorescence in S. marinoi cells exposed to the PUA, suggesting that both reactive species were produced. When PUA‐exposed S. marinoi cells were treated with the NO scavenger 2‐4‐carboxyphenyl‐4,4,5,5‐tetramethylimidazoline‐1‐oxyl‐3‐oxide (cPTIO), an opposite response was observed, with an increase in DHR‐derived green fluorescence. A higher DHR‐derived green fluorescence was also observed in the presence of sodium tungstate (ST), an inhibitor of NO production via nitrate reductase. In addition, two different SOD inhibitors, 2‐methoxyestradiol (2ME) and sodium diethyldithiocarbamate trihydrate (DETC), had an effect, with DETC inducing the strongest inhibition after 20 min. These results indicate the involvement of O₂^? generation and SOD activity in H₂O₂ formation (with downstream ROS generation dependent from H₂O₂) in response to PUA exposure. This is relevant as it refines the biological impact of PUA and identifies the specific molecules involved in the response. It is speculated that in PUA‐exposed S. marinoi cells, beyond a certain threshold of PUA, the intracellular antioxidant system is no longer able to cope with the excess of ROS, thus resulting in the observed accumulation of both O₂^?? and H₂O₂. This might be particularly relevant for population dynamics at sea, during blooms, when cell lysis increases and PUA are released. It can be envisioned that in the final stages of blooms, higher local PUA concentrations accumulate, which in turn induces intracellular ROS generation that ultimately leads to cell death and bloom decay.     

Molecular mechanisms of survival and apoptosis in RAW 264.7 macrophages under oxidative stress

Organisms living in an aerobic environment are continuously exposed to reactive oxygen species (ROS). Apoptosis of cells can be induced by ROS and cells also develop negative feedback mechanisms to limit ROS induced cell death. In this study, RAW264.7 murine macrophage cells were treated with H₂O₂ and cDNA microarray technique was used to produce gene expression profiles. We found that H₂O₂ treatment caused up-regulation of stress, survival and apoptosis related genes, and down-regulation of growth and cell cycle promoting genes. Numerous genes of metabolism pathways showed special expression patterns under oxidative stress: glycolysis and lipid synthesis related genes were down-regulated whereas the genes of lipid catabolism and protein synthesis were up-regulated. We also identified several signaling molecules as ROS-responsive, including p53, Akt, NF- B, ERK, JNK, p38, PKC and INF- . They played important roles in the process of apoptosis or cell survival. Finally, an interactive pathway involved in cellular response to oxidative stress was proposed to provide some insight into the molecular events of apoptosis induced by ROS and the feedback mechanisms involved in cell survival.Y. Zhang and C.C. Fong contributed equally to this work.     

Redox signalling: from nitric oxide to oxidized lipids

Cellular redox signalling is mediated by the post-translational modification of proteins in signal-transduction pathways by ROS/RNS (reactive oxygen species/reactive nitrogen species) or the products derived from their reactions. NO is perhaps the best understood in this regard with two important modifications of proteins known to induce conformational changes leading to modulation of function. The first is the addition of NO to haem groups as shown for soluble guanylate cyclase and the newly discovered NO/cytochrome c oxidase signalling pathway in mitochondria. The second mechanism is through the modification of thiols by NO to form an S-nitrosated species. Other ROS/RNS can also modify signalling proteins although the mechanisms are not as clearly defined. For example, electrophilic lipids, formed as the reaction products of oxidation reactions, orchestrate adaptive responses in the vasculature by reacting with nucleophilic cysteine residues. In modifying signalling proteins ROS/RNS appear to change the overall activity of signalling pathways in a process that we have termed 'redox tone'. In this review, we discuss these different mechanisms of redox cell signalling, and give specific examples of ROS/RNS participation in signal transduction.     

The effects of reactive nitrogen and oxygen species on the regeneration and growth of cucumber cells from isolated protoplasts

The present study investigated changes in the production of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in isolated mesophyll protoplasts and cell cultures of the cucumber Cucumis sativus cv. Marketer. Although only a minor increase in the level of nitrogen oxide (NO) was observed during the first 7 days of culture following protoplast isolation, a substantial accumulation of ROS was detected. Compounds known to modulate endogenous ROS and RNS levels were employed to study their role in cucumber protoplast regeneration and growth. Supplementing the culture medium with the NO donors S-nitrosoglutathione and sodium nitroprusside and the ROS scavenger ascorbate significantly increased protoplast viability and cell density. In contrast, cell density was significantly decreased following the addition of catalase to the medium. Scavenging of ROS and RNS induced the formation of cucumber microcalli, thus suggesting a differential role of NO in the maintenance of cell viability and in the control of cell division. Our findings confirm the crucial role of controlled ROS and RNS production in both protoplast regeneration and cellular growth and differentiation.     

Reactive nitrogen and oxygen species activate different sphingomyelinases to induce apoptosis in airway epithelial cells

Airway epithelial cells are constantly exposed to environmental insults such as air pollution or tobacco smoke that may contain high levels of reactive nitrogen and reactive oxygen species. Previous work from our laboratory demonstrated that the reactive oxygen species (ROS), hydrogen peroxide (H(2)O(2)), specifically activates neutral sphingomyelinase 2 (nSMase2) to generate ceramide and induce apoptosis in airway epithelial cells. In the current study we examine the biological consequence of exposure of human airway epithelial (HAE) cells to reactive nitrogen species (RNS). Similar to ROS, we hypothesized that RNS may modulate ceramide levels in HAE cells and induce apoptosis. We found that nitric oxide (NO) exposure via the NO donor papa-NONOate, failed to induce apoptosis in HAE cells. However, when papa-NONOate was combined with a superoxide anion donor (DMNQ) to generate peroxynitrite (ONOO(-)), apoptosis was observed. Similarly pure ONOO(-)-induced apoptosis, and ONOO(-)-induced apoptosis was associated with an increase in cellular ceramide levels. Pretreatment with the antioxidant glutathione did not prevent ONOO(-)-induced apoptosis, but did prevent H(2)O(2)-induced apoptosis. Analysis of the ceramide generating enzymes revealed a differential response by the oxidants. We confirmed our findings that H(2)O(2) specifically activated a neutral sphingomyelinase (nSMase2). However, ONOO(-) exposure did not affect neutral sphingomyelinase activity; rather, ONOO(-) specifically activated an acidic sphingomyelinase (aSMase). The specificity of each enzyme was confirmed using siRNA to knockdown both nSMase2 and aSMase. Silencing nSMase2 prevented H(2)O(2)-induced apoptosis, but had no effect on ONOO(-)-induced apoptosis. On the other hand, silencing of aSMase markedly impaired ONOO(-)-induced apoptosis, but did not affect H(2)O(2)-induced apoptosis. These findings support our hypothesis that ROS and RNS modulate ceramide levels to induce apoptosis in HAE cells. However, we found that different oxidants modulate different enzymes of the ceramide generating machinery to induce apoptosis in airway epithelial cells. These findings add to the complexity of how oxidative stress promotes lung cell injury.     

Bordetella bronchiseptica responses to physiological reactive nitrogen and oxygen stresses

Bordetella bronchiseptica can establish prolonged airway infection consistent with a highly developed ability to evade mammalian host immune responses. Upon initial interaction with the host upper respiratory tract mucosa, B. bronchiseptica are subjected to antimicrobial reactive nitrogen species (RNS) and reactive oxygen species (ROS), effector molecules of the innate immune system. However, the responses of B. bronchiseptica to redox species at physiologically relevant concentrations (nM-microM) have not been investigated. Using predicted physiological concentrations of nitric oxide (NO), superoxide and hydrogen peroxide (H2O2) on low numbers of CFU of B. bronchiseptica, all redox active species displayed dose-dependent antimicrobial activity. Susceptibility to individual redox active species was significantly increased upon introduction of a second species at subantimicrobial concentrations. An increased bacteriostatic activity of NO was observed relative to H2O2. The understanding of Bordetella responses to physiologically relevant levels of exogenous RNS and ROS will aid in defining the role of endogenous production of these molecules in host innate immunity against Bordetella and other respiratory pathogens.     

Zinc induces distinct changes in the metabolism of reactive oxygen and nitrogen species (ROS and RNS) in the roots of two Brassica species with different sensitivity to zinc stress

Background and Aims Zinc (Zn) is an essential micronutrient naturally present in soils, but anthropogenic activities can lead to accumulation in the environment and resulting damage to plants. Heavy metals such as Zn can induce oxidative stress and the generation of reactive oxygen and nitrogen species (ROS and RNS), which can reduce growth and yield in crop plants. This study assesses the interplay of these two families of molecules in order to evaluate the responses in roots of two Brassica species under high concentrations of Zn.Methods Nine-day-old hydroponically grown Brassica juncea (Indian mustard) and B. napus (oilseed rape) seedlings were treated with ZnSO₄ (0, 50, 150 and 300 µm) for 7 d. Stress intensity was assessed through analyses of cell wall damage and cell viability. Biochemical and cellular techniques were used to measure key components of the metabolism of ROS and RNS including lipid peroxidation, enzymatic antioxidants, protein nitration and content of superoxide radical (O2·−), nitric oxide (NO) and peroxynitrite (ONOO⁻).Key Results Analysis of morphological root damage and alterations of microelement homeostasis indicate that B. juncea is more tolerant to Zn stress than B. napus. ROS and RNS parameters suggest that the oxidative components are predominant compared with the nitrosative components in the root system of both species.Conclusions The results indicate a clear relationship between ROS and RNS metabolism as a mechanism of response against stress caused by an excess of Zn. The oxidative stress components seem to be more dominant than the elements of the nitrosative stress in the root system of these two Brassica species.     

活性氧在气孔运动中的作用

水分代谢是植物基础代谢的重要组成部分,气孔开关精细地调节着植物水分散失和光合作用。气孔运动受到多种因子的调控,保卫细胞内大量的第二信使分子是响应外界刺激、调节保卫细胞代谢方式、改变保卫细胞水势进而引起气孔开关的重要功能组分。细胞内的活性氧就是其中重要的成员之一。保卫细胞中的活性氧包括过氧化氢、超氧阴离子自由基和羟自由基等,这些活性氧可以通过光合作用、呼吸作用产生或通过专门的酶催化合成,在触发下游生理反应、完成信号转导后由专门的酶将其清除。在植物激素(脱落酸、水杨酸)、一氧化氮、质外体钙调素、细胞外ATP等因子调节气孔运动的过程中,活性氧都发挥了介导作用。该文对于近年来活性氧在气孔运动过程中发挥的作用方面的研究进展进行了综述。     

Oxidative and nitrosative signaling in plants: Two branches in the same tree?

Reactive oxygen species (ROS) and reactive nitrogen species (RNS) constitute key features underpinning the dynamic nature of cell signaling systems in plants. Despite their importance in many aspects of cell biology, our understanding of oxidative and especially of nitrosative signaling and their regulation remains poorly understood. Early reports have established that ROS and RNS coordinately regulate plant defense responses to biotic stress. In addition, evidence has accumulated demonstrating that there is a strong cross-talk between oxidative and nitrosative signaling upon abiotic stress conditions. The goal of this mini-review is to provide latest findings showing how both ROS and RNS comprise a coordinated oxidative and nitrosative signaling network that modulates cellular responses in response to environmental stimuli.Key words: abiotic stress, nitrosative stress, oxidative stress, reactive nitrogen species, reactive oxygen species, signaling     

PFG acted as an inducer of premature senescence in TIG-1 normal diploid fibroblast and an inhibitor of mitosis in the HeLa cells

Our previous work has reported an anti-proliferative compound from moutan cortex, paeoniflorigenone which can induce cancer-selective apoptosis. However, its anti-proliferative mechanism is still unknown. According to morphology changes (hypertrophy and flattening), we hypothesized that PFG can induce senescence or inhibit cell mitosis. Here we show that PFG can induce cellular senescence, evidenced by the expression of senescence-associated β-galactosidase, G0/G1 cell cycle arrest and permanent loss of proliferative ability, in normal TIG-1 diploid fibroblast but not cancerous HeLa cells. In cancerous HeLa cells, PFG inhibited proliferation by inducing S and G2/M cell cycle arrest and mitosis inhibition. DNA damage response was activated by PFG, interestingly the reactive oxygen species level was suppressed instead of escalated. To sum up, we report 3 new roles of PFG as, 1. inducer of premature senescence in normal TIG-1 cells, 2. inhibitor of mitosis in cancerous HeLa cells, 3. ROS scavenger.

Abbreviations: PFG: Paeoniflorigenone; ROS: reactive oxygen species; ATM: ataxia telangiectasia mutated; t-BHP: tert-butyl hydroperoxide; SA-β-gal: senescence-associatedβ-galactosidase; DNA-PK_cs: DNA-dependent protein kinase; γ-H2AX: H2AX phosphoryla-tion at Ser-139