一氧化氮与激发子诱导的植物抗病防卫反应

来源于真菌或植物细胞壁的激发子可以诱导植物的抗性反应。一系列的信号分子,如一氧化氮、活性氧、茉莉酸、水杨酸、乙烯等都参与了激发子诱导的植物抗性反应。它们在介导激发子刺激诱发胞内抗性反应的过程中起着重要的作用。本文介绍了激发子的种类,并简述了激发了受体以及植物细胞对激发子刺激的感受与传递;重点介绍了一氧化氮在激发子诱导植物抗性反应过程中的作用,以及它与其他信号分子之间相互关系的研究进展。     

植物体内一氧化氮合成途径研究进展

一氧化氮(NO)作为一种气体信号分子,在植物生理过程中发挥重要作用,它参与调节植物的生长、发育及对外界环境的应激反应.植物体内主要通过酶催化途径和非酶催化途径合成NO.酶催化途径合成NO的主要酶包括一氧化氮合酶(nitric oxide synthase,NOS)和硝酸还原酶(nitrate reductase,NR),以及在某些植物的特定组织或器官或在特殊环境条件下存在的一氧化氮氧化还原酶(nitric oxide oxidoreductase,Ni-NOR)和黄嘌呤氧化还原酶(xanthine oxidoreductase,XOR).非酶催化合成途径主要是在酸性和还原剂存在条件下将亚硝酸盐还原成NO.该文主要结合研究方法,综述了植物体内NO合成途径的研究进展,为植物体内NO信号的作用机理的深入研究提供信息资料.     

一氧化氮在植物抗病反应中的信号作用

近年来的研究发现,一氧化氮(nitricoxide,NO)在植物抗病反应中具有重要作用,本文概述了植物中NO的来源、NO在植物抗病反应中的信号传导作用、NO与植物中其它信号分子之间的相互作用以及NO的研究进展。     

一氧化氮:植物体内一种新的生长调控因子

一氧化氮是具有生物活性,自然界存在的10种最小分子之一。越来越多的证据显示,一氧化氮是生物体内一种广泛分布的信号传导分子。一氧化氮参与植物生长发育调控和对生物与非生物环境胁迫的应答反应。该文重点讨论一氧化氮在植物体内的产生,基本功能以及在信号传导网络系统中与Ca^2 的相互作用。     

植物一氧化氮信号分子的研究进展

一氧化氮(NO)作为一种重要的信号分子,不仅参与植物的种子休眠和萌发以及根的形态建成等生长发育过程,还参与调节植物细胞的气孔运动以及植物抗逆应答反应。该文结合最新研究成果,总结了植物NO信号调控机理的研究进展,主要包括NO合成途径、信号转导途径及其与其它信号分子之间的交叉反应和对植物抗逆的调控作用等。     

植物体内一氧化氮的来源及其与其它信号分子之间的关系

介绍了植物体内一氧化氮的分布及形成途径(即一氧化氮合酶途径、硝酸还原酶/亚硝酸还原酶途径和非酶途径),一氧化氮与过氧化氢、水杨酸、脱落酸、生长素、细胞分裂素等信号分子的对话,特别是在植物抗病防御反应中的相互关系的研究进展.     

一氧化氮与植物成熟衰老的关系

植物体可以通过依赖于类似哺乳动物的一氧化氮合成酶或硝酸还原酶的酶促合成途径和非酶促合成途径产生一氧化氮。植物内源一氧化氮可以通过抑制乙烯的生物合成和调控环化核苷酸在植物组织中的水平,来延缓植物组织的成熟和衰老,延长果蔬等组织的货架期。     

一氧化氮调控植物缺铁响应的研究进展

一氧化氮(nitric oxide,NO)是植物体内一种重要的信号分子,不仅对植物的生长发育具有重要的调控作用,而且在植物应答缺铁胁迫中同样扮演着关键角色。近年来,有关NO介导的植物缺铁响应调控机制研究取得了一系列重要进展。本文重点针对植物体内NO的合成及其信号转导途径在缺铁胁迫应答中的作用和NO与其他信号分子互作介导植物缺铁响应调控研究进行系统综述与展望,以加深NO在植物缺铁响应调控功能的认识。     

DELLA蛋白参与拟南芥幼苗对一氧化氮逆境的抵抗

DELLA蛋白是赤霉素信号途径中的一类对植物生长起抑制作用的重要蛋白质,在拟南芥（Arabidopsis thaliana）基因组中已经鉴定出5个DELLA蛋白基因。目前研究发现,DELLA蛋白在抗逆中也起了重要的作用。近年来,一氧化氮（nitric oxide,NO）的研究工作取得重要进展,低浓度的NO能够促进植物的生长,但在高浓度下它对植物生长起抑制作用甚至导致细胞死亡。通过外施一氧化氮供体硝普钠（sodium nitro prusside,SNP）,研究高浓度NO对拟南芥幼苗生长的影响,发现植物体内H2O2积累,幼苗死亡。通过研究DELLA蛋白基因表达的变化及其相关突变体的表型,证明DELLA蛋白在抵抗NO逆境中起了重要作用。研究结果揭示了DELLA蛋白与NO逆境的关系,为今后科学指导农业生产提供了理论依据。     

一氧化氮在植物抗病反应中的信号作用

近年来的研究发现,一氧化氮（nitic oxide,NO)在植物抗病反应中具有重要作用,本文概述了植物中NO的来源,NO在植物抗病反应中的信号传导作用,NO与植物中其它信号分子之间的相互作用以及NO的研究进展。     

浮游植物中一氧化氮的生理作用研究进展

一氧化氮（NO）作为一种具有生物活性的气体自由基分子,它的功能代表了生物学系统中信号传递的新途径。大量证据表明,NO在浮游植物细胞中的功能和在高等动植物中类似,具有调节生长和参与抗逆性的作用,NO和ROS可能作为信号分子参与介导浮游植物程序性死亡（PCD）过程。文章较全面地介绍了NO在浮游植物中的产生途径、测定方法、生理功能和PCD的关系及作为信号分子的作用,并对该领域今后的研究进行了展望。     

Biochemical aspects of the reaction of hemoglobin and NO: implications for Hb-based blood substitutes

The role of Hemoglobin (Hb) on nitric oxide (NO) biology has received much attention. Until recently, the reaction between erythrocytic Hb and NO was generally considered in the context of mechanisms that safely detoxify NO. However, recent insights suggest that properties associated with the red blood cell limit NO-Hb interactions under physiological conditions, and provide some resolution to the question of how NO functions in the presence of blood. Furthermore, Hb-dependent mechanisms that preserve, not destroy NO bioactivity in vivo have also been proposed. The emerging picture suggests that the interplay between NO and erythrocytic Hb is important in regulating the functions of both these molecules in vivo. However, Hb-dependent scavenging and loss of NO function is significant when this heme protein is present outside the red blood cell. This can occur during hemolysis or administration of Hb-based blood substitutes. Scavenging of NO is a significant problem that limits the use of Hb-based blood substitutes in the clinic, and development of Hb molecules that do not efficiently react with NO remains an important area of investigation. In this article, the reactions between NO and erythrocytic Hb or cell-free Hb are described and the effects on NO and Hb function in vivo and development of blood substitutes discussed.     

A Novel Protein Protects Bacterial Iron-Dependent Metabolism from Nitric Oxide

Reactive nitrogen species (RNS), in particular nitric oxide (NO), are toxic to bacteria, and bacteria have mechanisms to allow growth despite this stress. Understanding how bacteria interact with NO is essential to understanding bacterial physiology in many habitats, including pathogenesis; however, many targets of NO and enzymes involved in NO resistance remain uncharacterized. We performed for the first time a metabolomic screen on NO-treated and -untreated bacteria to define broadly the effects of NO on bacterial physiology, as well as to identify the function of NnrS, a previously uncharacterized enzyme involved in defense against NO. We found many known and novel targets of NO. We also found that iron-sulfur cluster enzymes were preferentially inhibited in a strain lacking NnrS due to the formation of iron-NO complexes. We then demonstrated that NnrS is particularly important for resistance to nitrosative stress under anaerobic conditions. Our data thus reveal the breadth of the toxic effects of NO on metabolism and identify the function of an important enzyme in alleviating this stress.     

Skeletal muscle nitric oxide signaling and exercise: a focus on glucose metabolism

Nitric oxide (NO) is an important vasodilator and regulator in the cardiovascular system, and this link was the subject of a Nobel prize in 1998. However, NO also plays many other regulatory roles, including thrombosis, immune function, neural activity, and gastrointestinal function. Low concentrations of NO are thought to have important signaling effects. In contrast, high concentrations of NO can interact with reactive oxygen species, causing damage to cells and cellular components. A less-recognized site of NO production is within skeletal muscle, where small increases are thought to have beneficial effects such as regulating glucose uptake and possibly blood flow, but higher levels of production are thought to lead to deleterious effects such as an association with insulin resistance. This review will discuss the role of NO in skeletal muscle during and following exercise, including in mitochondrial biogenesis, muscle efficiency, and blood flow with a particular focus on its potential role in regulating skeletal muscle glucose uptake during exercise.     

一氧化氮的功能及其作用机制(Ⅰ)——性质与功能

一氧化氮(nitric oxide,NO)是第一个被发现的参与细胞信号转导的气体信号分子。NO参与的生命活动非常广泛,在神经、免疫、呼吸等系统中发挥着重要作用。很久以来,一氧化氮合酶(nitric oxide synthase,NOS)被认为是人体内合成NO的主要途径,其活性受到严格的调控。直到最近,人们才发现亚硝酸盐(nitrite,NO2-)也可以参与体内NO的合成。本综述总结NO的相关性质与功能,并简介亚硝酸盐的研究进展。     

一氧化氮在植物生长发育和抗逆过程中的作用研究进展

NO不仅在植物的抗病过程中发挥重要作用,同时也参与植物生长、发育和对干旱、高盐、高温、低温等非生物胁迫的响应等过程。该文对近年来国内外有关NO在植物生长、发育、非生物胁迫抗性过程中的作用及其与植物激素之间的互作关系等方面的研究进展进行综述,为相关研究提供信息和资料。     

Abnormal platelet aggregation in idiopathic pulmonary arterial hypertension: role of nitric oxide

Idiopathic pulmonary arterial hypertension (IPAH) is a rare and progressive disease. Several processes are believed to lead to the fatal progressive pulmonary arterial narrowing seen in IPAH including vasoconstriction, cellular proliferation inflammation, vascular remodeling, abnormalities in the lung matrix, and in situ thrombosis. Nitric oxide (NO) produced by NO synthases (NOS) is a potent vasodilator and plays important roles in many other processes including platelet function. Reduced NO levels in patients with IPAH are known to contribute to the development of pulmonary hypertension and its complications. Platelet defects have been implied in IPAH, but original research supporting this hypothesis has been limited. Normal platelets are known to have NOS activity, but little is known about NOS expression and NO production by platelets in patients with IPAH. Here we characterized the phenotype of the platelets in IPAH and show a defect in their ability to be activated in vitro by thrombin receptor activating protein but not adenosine diphosphate. We also show that endothelial NOS (eNOS) levels in these platelets are reduced and demonstrate that NO is an important regulator of platelet function. Thus reduced levels of eNOS in platelets could impact their ability to regulate their own function appropriately.     

The interaction between endothelin-1 and nitric oxide in the vasculature: new perspectives

Nitric oxide (NO) and endothelin-1 (ET-1) are natural counterparts in vascular function, and it is becoming increasingly clear that an imbalance between these two mediators is a characteristic of endothelial dysfunction and is important in the progression of vascular disease. Here, we review classical and more recent data that suggest that ET-1 should be regarded as an essential component of NO signaling. In particular, we review evidence of the role of ET-1 in models of acute and chronic NO synthase blockade. Furthermore, we discuss the possible mechanisms by which NO modulates ET-1 activity. On the basis of these studies, we suggest that NO tonically inhibits ET-1 function, and in conditions of diminished NO bioavailability, the deleterious effects of unmitigated ET-1 actions result in vasoconstriction and eventually lead to vascular remodeling and dysfunction.     

S-nitrosylation of Bcl-2 inhibits its ubiquitin-proteasomal degradation. A novel antiapoptotic mechanism that suppresses apoptosis

Bcl-2 is a key apoptosis regulatory protein of the mitochondrial death pathway whose function is dependent on its expression levels. Although Bcl-2 expression is controlled by various mechanisms, post-translational modifications, such as ubiquitination and proteasomal degradation, have emerged as important regulators of Bcl-2 function. However, the underlying mechanisms of this regulation are unclear. We report here that Bcl-2 undergoes S-nitrosylation by endogenous nitric oxide (NO) in response to multiple apoptotic mediators and that this modification inhibits ubiquitin-proteasomal degradation of Bcl-2. Inhibition of NO production by the NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide and by NO synthase inhibitor aminoguanidine effectively inhibited S-nitrosylation of Bcl-2, increased its ubiquitination, and promoted apoptotic cell death induced by chromium (VI). In contrast, the NO donors dipropylenetriamine NONOate and sodium nitroprusside showed opposite effects. The effect of NO on Bcl-2 stability was shown to be independent of its dephosphorylation. Mutational analysis of Bcl-2 further showed that the two cysteine residues of Bcl-2 (Cys158 and Cys229) are important in the S-nitrosylation process and that mutations of these cysteines completely inhibited Bcl-2 S-nitrosylation. Treatment of the cells with other stress inducers, including Fas ligand and buthionine sulfoxide, also induced Bcl-2 S-nitrosylation, suggesting that this is a general phenomenon that regulates Bcl-2 stability and function under various stress conditions. These findings indicate a novel function of NO and its regulation of Bcl-2, which provides a key mechanism for the control of apoptotic cell death and cancer development.     

Nitric oxide (NO) expression during annual reproductive activity in buffalo epididymis: a histochemical and immunocytochemical study

The buffalo is one of the few domestic animals that has a seasonal mating cycle, influenced by the photoperiod. It is known that the photoperiod regulates gonadal function probably via the pineal and/or hypothalamus-pituitary axis. Moreover, the hypothalamus (melatonin) and gonads influence the production of the signaling transmitter nitric oxide (NO), suggesting that the NO may have an important role in the regulation of gonadotropin-releasing hormone secretion. This further suggests the hypothesis that NO in the epididymis has an important role in the maturation of spermatozoa and their motility and posterior fertilization capacity. The aim of the present study is to investigate the seasonal variations in the morphology of the epididymis by means histochemical and immunocytochemical techniques. We used the NADPH-d, nitric oxide synthase (NOS) I and NOS III to clarify the relationship between epididymis function and NO signaling activity. The results of this work show that NO is present in the caput of epididymis during short photoperiods, i.e., periods of maximum gonadal activity (winter) and absent during long photoperiods, i.e., periods of gonadal regression according to the previously described role of NO in spermatozoa capacitation and motility in the caput epididymis.