McKersie,B.D., Leshem,Y.Y.: Stress and stress coping in cultivated plants

Biologia Plantarum -     

Nitric Oxide Production in Plants: Facts and Fictions

There is now general agreement that nitric oxide (NO) is an important and almost universal signal in plants. Nevertheless, there are still many controversial observations and opinions on the importance and function of NO in plants. Partly, this may be due to the difficulties in detecting and even more in quantifying NO. Here, we summarize major pathways of NO production in plants, and briefly discuss some methodical problems.Key Words: chemiluminescence, DAF-fluorescence, mitochondria, nitrate reductase, nitric oxide, nitric oxide synthase, NO detection, NO signaling     

Nitric Oxide Signalling In Plants

Nitric oxide (NO) is an important molecule that acts in many tissues to regulate a diverse range of physiological processes. It is becoming apparent that NO is a ubiquitous signal in plants. Since the discovery of NO emission by plants in the 1970s, this gaseous compound has emerged as a major signalling molecule involved in multiple physiological functions. Research on NO in plants has gained significant awareness in recent years and there is increasing indication on the role of this molecule as a key-signalling molecule in plants. The investigations about NO in plants have been concentrated on three main fields: The search of NO or any source of NO generation, effects of exogenous NO treatments, NO transduction pathways. However we have limited information about signal transduction procedures by which NO interaction with cells results in altered cellular activities. This article reviews recent advances in NO synthesis and its signalling functions in plants. First, different sources and biosynthesis of NO in plants, then biological processes involving NO signalling are reviewed. NO signalling relation with cGMP, protein kinases and programmed cell death are also discussed. Besides, NO signalling in plant defense response is also examined. Especially NO signalling between animal and plant systems is compared.     

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。     

一氧化氮在植物体内的信号分子作用

一氧化氮 (ｎｉｔｒｉｃｏｘｉｄｅ ,ＮＯ)是一种广泛分布于生物体的气体活性分子 ,它具有多种生理功能。动物体研究结果揭示 ,ＮＯ在血管松驰、神经转导及先天性免疫反应等一系列生理代谢过程均可作为一种关键的信号和效应分子。有关ＮＯ作为信使物质参与植物抗病及其他生理代谢调节的报道也日益增多。1 .植物内源ＮＯ的产生途径植物体内氮代谢的关键酶硝酸还原酶(ｎｉｔｒａｔｅｒｅｄｕｃｔａｓｅ,ＮＲ)也可以ＮＡＤＨ/ＮＡＤＰＨ作为电子供体 ,催化硝酸盐和亚硝酸盐的单电子还原反应来合成ＮＯ。如在含有ＮＯ-2 和ＮＡＤＨ的缓冲液 (ｐ…     

Nitric Oxide in Plants: The Roles of Ascorbate and Hemoglobin

Ascorbic acid and hemoglobins have been linked to nitric oxide metabolism in plants. It has been hypothesized that ascorbic acid directly reduces plant hemoglobin in support of NO scavenging, producing nitrate and monodehydroascorbate. In this scenario, monodehydroascorbate reductase uses NADH to reduce monodehydroascorbate back to ascorbate to sustain the cycle. To test this hypothesis, rates of rice nonsymbiotic hemoglobin reduction by ascorbate were measured directly, in the presence and absence of purified rice monodehydroascorbate reductase and NADH. Solution NO scavenging was also measured methodically in the presence and absence of rice nonsymbiotic hemoglobin and monodehydroascorbate reductase, under hypoxic and normoxic conditions, in an effort to gauge the likelihood of these proteins affecting NO metabolism in plant tissues. Our results indicate that ascorbic acid slowly reduces rice nonsymbiotic hemoglobin at a rate identical to myoglobin reduction. The product of the reaction is monodehydroascorbate, which can be efficiently reduced back to ascorbate in the presence of monodehydroascorbate reductase and NADH. However, our NO scavenging results suggest that the direct reduction of plant hemoglobin by ascorbic acid is unlikely to serve as a significant factor in NO metabolism, even in the presence of monodehydroascorbate reductase. Finally, the possibility that the direct reaction of nitrite/nitrous acid and ascorbic acid produces NO was measured at various pH values mimicking hypoxic plant cells. Our results suggest that this reaction is a likely source of NO as the plant cell pH drops below 7, and as nitrite concentrations rise to mM levels during hypoxia.     

一氧化氮（NO）对植物的生理和病理功能

介绍了NO在植物抑御病害及种子萌发、叶片生长、果实成熟、胁迫响应等过程中的作用及其机制。     

植物一氧化氮(NO)研究进展

一氧化氮（NO）是植物的重要生物活性分子,它参与植物生长发育的许多过程,如种子萌发、下胚轴伸长、叶扩展、根生长、侧根形成、细胞凋亡以及植物抗逆反应等。大量的证据表明,植物可以通过与动物NO合酶类似的酶产生NO。此外,植物还可通过硝酸还原酶产生NO。NO在植物中的信号传递途径仍不十分清楚,植物有可能采用与动物相类似的机制。由于植物的大多数生长发育现象都受到植物激素的调节和控制,NO与植物激素之间的关系也受到越来越多的关注。通过激素起作用可能是植物内源NO作用的机理之一。     

植物体中一氧化氮的检测方法及其应用

文章介绍植物体中NO的各种检测方法及其应用的研究进展。     

植物中一氧化氮与园艺产品的成熟和衰老

概述了一氧化氮(NO)的生物学特性、植物中NO的来源、NO对园艺产品成熟保鲜的作用及其生理机制研究的新进展.     

一氧化氮在植物中的生理功能

一氧化氮是植物体内一种重要的活性分子,它对植物的种子萌发、生长发育、气孔运动、呼吸作用以及抗逆反应等生理过程起重要的调节作用,与植物激素存在密切关系。现对一氧化氮在植物中的生理功能进行综述。     

Fibrinogen-Dependent Signaling in Microvascular Erythrocyte Function: Implications on Nitric Oxide Efflux

Experimental evidence has shown that plasma fibrinogen plays a key role as a major cardiovascular risk factor, acting directly to trigger erythrocyte aggregation in occlusive vascular disease. However, due to the complex and hitherto unclear interaction between fibrinogen and the erythrocyte membrane, no study has yet evaluated the effects of fibrinogen, under physiological range values, on the erythrocyte nitric oxide (NO) mobilization. Taking into consideration the potential NO-derived molecules, we have raised the hypothesis that fibrinogen, under physiological conditions, may act to influence blood flow via erythrocyte NO modulation. In this in vitro study whole-blood samples were harvested from healthy subjects, erythrocyte suspensions were incubated in the absence (control aliquots) and presence of different fibrinogen concentrations and levels of NO, nitrite, nitrate and S-nitroglutathione (GSNO) were determined. Our results showed, when compared with control aliquots, that the presence of fibrinogen modulates the NO mobilization in erythrocytes by (1) decreasing erythrocyte NO efflux levels (P < 0.001); (2) increasing levels of intraerythrocytic NO oxidative metabolites, namely, nitrite (P < 0.0001) and nitrate (P < 0.0001); and (3) enhancing the formation of GSNO (P < 0.001). In conclusion, this study provides new insights into an unknown mechanism by which fibrinogen modulates the erythrocyte capacity to supply NO, the effects of which on inflammation profiles (generally associated with blood hyperviscosity and hyperaggregation) still need to be elucidated. Also, increased erythrocyte GSNO levels may be associated with platelet NO metabolism, its activation status and hypotension, which may be extremely relevant in the clinical setting as biomarkers.     

Nitric Oxide Transport in Normal Human Thoracic Aorta: Effects of Hemodynamics and Nitric Oxide Scavengers

Despite the crucial role of nitric oxide (NO) in the homeostasis of the vasculature, little quantitative information exists concerning NO transport and distribution in medium and large-sized arteries where atherosclerosis and aneurysm occur and hemodynamics is complex. We hypothesized that local hemodynamics in arteries may govern NO transport and affect the distribution of NO in the arteries, hence playing an important role in the localization of vascular diseases. To substantiate this hypothesis, we presented a lumen/wall model of the human aorta based on its MRI images to simulate the production, transport and consumption of NO in the arterial lumen and within the aortic wall. The results demonstrated that the distribution of NO in the aorta was quite uneven with remarkably reduced NO bioavailability in regions of disturbed flow, and local hemodynamics could affect NO distribution mainly via flow dependent NO production rate of endothelium. In addition, erythrocytes in the blood could moderately modulate NO concentration in the aorta, especially at the endothelial surface. However, the reaction of NO within the wall could only slightly affect NO concentration on the luminal surface, but strongly reduce NO concentration within the aortic wall. A strong positive correlation was revealed between wall shear stress and NO concentration, which was affected by local hemodynamics and NO reaction rate. In conclusion, the distribution of NO in the aorta may be determined by local hemodynamics and modulated differently by NO scavengers in the lumen and within the wall.     

Cellular Responses,Osmotic Adjustments,and Role of Osmolytes in Providing Salt Stress Resilience in Higher Plants: Polyamines and Nitric Oxide Crosstalk

Journal of Plant Growth Regulation - Salinity stress is a chief abiotic hindrance affecting crop productivity and yield particularly in arid and semi-arid regions across the globe. Plants have...     

Nitric Oxide in Arthritis

Nitric oxide’s (NO) involvement in arthritis was first demonstrated when levels of nitrite, a stable endproduct of NO metabolism, were shown to be elevated in serum and synovial fluid samples of rheumatoid and osteoarthritis patients. NO production by chondrocytes, its involvement in various biochemical events of cartilage metabolism, and the in vivo suppression of experimental arthritis by NO synthase inhibitors further implicated NO in arthritis. However, a conclusive role for NO in the pathogenesis of arthritis remains to be defined, in contrast to the NO-cGMP signal transduction pathway of endothelium-mediated vasodilation. It appears that NO has limited modulating effects in cartilage metabolism, with evidence for both protective and deleterious effects. Recent developments that contribute to our understanding of NO’s role in arthritis are discussed.     

Iron, Nitric Oxide, and Myeloperoxidase in Asthmatic Patients

Plasma nitric oxide (NO), myeloperoxidase (MPO), and iron (Fe) levels were determined in bronchial asthma. The relations among these parameters in different stages of asthma were interpreted. Their association with airway inflammation observed in patients with bronchial asthma as well as the roles and the contributions to the pathological processes were evaluated. A total of 62 individuals, 32 asthmatics and 30 controls, were included into the scope of this study. Plasma nitric oxide metabolites (NOx) and MPO and Fe levels were determined by the Griess reaction, ELISA, and the automated TPTZ (2,4,6-tri[2-pyridyl]-5-triazine) method, respectively. In the asthmatic individuals, plasma NOx, MPO, and Fe concentrations were 133 +/- 13 microM, 95 +/- 20 ng/ml, and 159 +/- 20 microg/dl, respectively; in the control group these values were 82 +/- 11 microM, 62 +/- 11 ng/ml, and 96 +/- 9 microg/dl. Increased values were detected for plasma MPO (p > 0.05), NOx (p < 0.01), and Fe (p < 0.01) concentrations in asthmatic individuals. Considering the facts that NO modulates the catalytic activity of MPO and induces the expression of heme oxygenase as important contributors to the mechanisms causing free Fe release, it is concluded that elevated NOx, MPO, and Fe levels observed in the asthmatic group act in a concerted manner and appear to be involved in the pathogenesis of asthma.     

Role of Nitric Oxide in Methamphetamine Neurotoxicity: Protection by 7-Nitroindazole, an Inhibitor of Neuronal Nitric Oxide Synthase

Abstract: The role of nitric oxide (NO^•) in the neurotoxic effects of methamphetamine (METH) was evaluated using 7-nitroindazole (7-NI), a potent inhibitor of neuronal nitric oxide synthase. Treatment of mice with 7-NI (50 mg/kg) almost completely counteracted the loss of dopamine, 3,4-dihydroxyphenylacetic acid, and tyrosine hydroxylase immunoreactivity observed 5 days after four injections of 10 or 7.5 mg/kg METH. With the higher dose of METH, this protection at 5 days occurred despite the fact that combined administration of METH and 7-NI significantly increased lethality and exacerbated METH-induced dopamine release (as indicated by a greater dopamine depletion at 90 min and 1 day). Combined treatment with 4 × 10 mg/kg METH and 7-NI also slightly increased the body temperature of mice as compared with METH alone. Thus, the neuroprotective effects of 7-NI are independent from lethality, are not likely to be related to a reduction of METH-induced dopamine release, and are not due to a decrease in body temperature. These results indicate that NO^• formation is an important step leading to METH neurotoxicity, and suggest that the cytotoxic properties of NO^• may be directly involved in dopaminergic terminal damage.     

Plant Haemoglobins,Nitric Oxide and Hypoxic Stress

It is now known that there are several classes of haemoglobins in plants. A specialized class of haemoglobins, symbiotic haemoglobins, were discovered 62 years ago and are found only in nodules of plants capable of symbiotic nitrogen fixation. Plant haemoglobins, with properties distinct from symbiotic haemoglobins were discovered 18 years ago and are now believed to exist throughout the plant kingdom. They are expressed in different organs and tissues of both dicot and monocot plants. They are induced by hypoxic stress and by oversupply of certain nutrients. Most recently, truncated haemoglobins have been shown to also exist in plants. While hypoxic stress‐induced haemoglobins are widespread in the plant kingdom, their function has not been elucidated. This review discusses the recent findings regarding the function of these haemoglobins in relation to adaptation to hypoxia in plants. We propose that nitric oxide is an important metabolite in hypoxic plant cells and that at least one of the functions of hypoxic stress‐induced haemoglobins is to modulate nitric oxide levels in the cell.