水杨酸诱导植物抗性的研究进展

水杨酸是一种重要的内源信号分子,能够激活一系列植物抗性防卫反应.为了研究这种抗性反应,对水杨酸诱导植物抗病性、抗旱性、抗盐性及与乙烯作用的新进展作了概述,并从水杨酸与过氧化氢及其代谢酶类相互作用的角度探讨了水杨酸诱导植物抗性生理的分子机理.     

水杨酸在植物抗病中的作用

水杨酸是一种重要的能激活植物抗病防卫反应的内源信号分子。本文首先介绍了水杨酸的基本性质及水杨酸在植物抗病中的作用,然后从水杨酸与水杨酸结合蛋白的相互作用以及水杨酸介导的信号传导途径与非水杨酸介导的信号途径等方面初步探讨了水杨酸诱导植物抗病性的作用机制,最后总结了研究水杨酸作用机制对植物抗性生理和抗性分子生物学发展的意义。     

水杨酸在植物抗病中的作用

水杨酸是一种重要的能激活植物抗病防卫反应的内源信号分子,本文首先介绍了水杨酸的基本性质及水杨酸在植物抗病中的作用,然后从水杨酸与水杨酸结合蛋白的相互作用以及水杨酸介导的信号传导途径与非水杨酸介导的信号途径等方面初步探讨了水杨酸诱导植物抗病性的作用机制,最后总结了研究水杨酸作用机制对植物抗性生理和抗性分子生物学发展的意义。     

反相高效液相色谱测定番茄组织中的水杨酸

DetendnationofSalicylicAcidinTOmatObyReve~Phaseaam--PerforrmceliqUidChro~twyXUYOu-Ping,MAZhi~Chao(~~,~~~dy,~310029)CAJXin-Zhong(~ofAn~,~~-d~ity,~310029)水杨酸是一种酚类物质,广泛存在于自然界。它与植物的开花、气孔关闭、种子发芽、产热、膜通透性以及离子吸收等许多生理生化过程有关[1]。有人认为水杨酸是一种新的植物激素[2],最近几年研究结果认为它与植物抗病性也有关系,是植物的系统性诱导抗病性（systemacqui。dr。sta。e,SAN）信号传递系统中的重要组成部分［’j。番茄组织中水杨酸含量的高效液相色谱…     

水杨酸与植物抗逆性

综述了植物体内水杨酸对不同逆境的响应与信号转导、基因表达和蛋白质合成过程 ;对外施水杨酸的效应和与活性氧、抗氧化系统、脱落酸的关系 ,以及水杨酸作为系统信号分子的可能性作了讨论     

水杨酸在AM真菌侵染和诱导植物抗病性中的作用

水杨酸（SA）是一种广泛存在于高等植物体内的酚类物质,是肉桂酸的衍生物,在植物许多生理过程中发挥重要作用（原永兵和曹宗巽,1994）,如诱导某些植物开花和气孔关闭;导致天南星科植物的佛焰花序产热;促进侧芽萌发;抑制乙烯的生物合成;调节某些植物的光周期;影响黄瓜的性别分化等（Wang＆Tsao,1979）;因而Raskin提出SA是一种新的植物激素（Raskin,1992）.许多试验证明SA是重要的能够激活植物过敏反应（HR）和系统获得抗性（SAR）的内源信号分子（Malamy et a1.,1990）,能诱导烟草和黄瓜等植物对细菌、真菌、病毒等多种病害的抗病性（原永兵等,1997）.     

1995年离体生物学会议摘要

利用新抗病性分子的遗传工程 美国Demeter Biotechnologies, Ltd.的J.M. Jaynes报告,他们发现了一种新的、在对植物组织无毒性的浓度下可直接摧毁多种不同类型的细菌和真菌植物病原体的分子。这些以肽为基础的膜相互作用分子(肽基MIMs)在与水解酶结合使用时可协同杀死微生物。当将一些有效的MIMs导入一些植物品种     

水杨酸对植物光合作用影响的研究进展

水杨酸作为一种信号分子,对植物呼吸代谢、种子萌发、成花诱导、衰老及抗逆等生理过程都有调节作用,近年来有关水杨酸对植物光合作用影响的研究取得了很大进展。水杨酸能够调节植物叶片气孔运动、光合色素含量、光合机构性能、光合碳同化酶活性等各方面,其效果因浓度、植物种类、环境条件等不同而表现出差异。该文就近年来国内外有关水杨酸对植物光合作用的影响(主要从植物叶片气孔运动、光合色素含量、光合机构性能和光合碳同化酶活性等方面)研究进展进行综述。     

水杨酸与植物抗非生物胁迫

本文综述了水杨酸在诱导植物抗（耐）非生物胁迫如重金属、臭氧、紫外辐射、过冷、热激、水分亏缺和盐胁迫等方面的进展,并探讨了水杨酸作用的分子、生理机制。     

PCR-RAPD分子生物学技术及其在植物抗病性研究中的应用

PCR—RAPD技术是一种高效的基因组DNA多态性分析技术,能够在对生物细胞或组织中DNA遗传多样性、亲缘关系及系统进化分子标记检测的同时进行基因定位与遗传作图。本综述了PCR—RAPD技术的基本原理和应用范围,以及近年来在植物抗感病品种(品系)间亲缘远近关系分析、植物抗病性遗传基因的DNA分子标记与检测、植物抗病基因的标记和定位、植物抗病基因的分离与克隆、植物抗病育种的分子标记辅助选择与检测等植物抗病性分子机制研究方面的应用,并对该技术所存在的问题及应用前景进行了探讨。     

Salicylic acid-independent plant defence pathways

Salicylic acid is an important signalling molecule involved in both locally and systemically induced disease resistance responses. Recent advances in our understanding of plant defence signalling have revealed that plants employ a network of signal transduction pathways, some of which are independent of salicylic acid. Evidence is emerging that jasmonic acid and ethylene play key roles in these salicylic acid-independent pathways. Cross-talk between the salicylic acid-dependent and the salicylic acid-independent pathways provides great regulatory potential for activating multiple resistance mechanisms in varying combinations.     

Riboflavin-induced Priming for Pathogen Defense in Arabidopsis thaliana

Riboflavin (vitamin B2) participates in a variety of redox processes that affect plant defense responses. Previously we have shown that riboflavin induces pathogen resistance in the absence of hypersensitive cell death (HCD) in plants. Herein, we report that riboflavin induces priming of defense responses in Arabidopsis thaliana toward infection by virulent Pseudomonas syringae pv. Tomato DC3000 (Pst). Induced resistance was mechanistically connected with the expression of defense response genes and cellular defense events, including H2O2 burst, HCD, and callose deposition in the plant. Riboflavin treatment and inoculation of plants with Pst were neither active but both synergized to induce defense responses. The priming process needed NPR1 (essential regulator of systemic acquired resistance) and maintenance of H2O2 burst but was independent of salicylic acid, jasmonic acid, ethylene, and abscisic acid. Our results suggest that the role of riboflavin in priming defenses is subject to a signaling process distinct from the known pathways of hormone signal transduction.     

SA, JA, ethylene, and disease resistance in plants

Exciting advances have been made during the past year: isolating mutants affecting plant disease resistance, cloning genes involved in the regulation of various defense responses, and characterizing novel defense signaling pathways. Recent studies have demonstrated that jasmonic acid and ethylene are important for the induction of nonspecific disease resistance through signaling pathways that are distinct from the classical systemic acquired resistance response pathway regulated by salicylic acid.     

Activation of the indole-3-acetic acid-amido synthetase GH3-8 suppresses expansin expression and promotes salicylate- and jasmonate-independent basal immunity in rice

New evidence suggests a role for the plant growth hormone auxin in pathogenesis and disease resistance. Bacterial infection induces the accumulation of indole-3-acetic acid (IAA), the major type of auxin, in rice (Oryza sativa). IAA induces the expression of expansins, proteins that loosen the cell wall. Loosening the cell wall is key for plant growth but may also make the plant vulnerable to biotic intruders. Here, we report that rice GH3-8, an auxin-responsive gene functioning in auxin-dependent development, activates disease resistance in a salicylic acid signaling- and jasmonic acid signaling-independent pathway. GH3-8 encodes an IAA-amino synthetase that prevents free IAA accumulation. Overexpression of GH3-8 results in enhanced disease resistance to the rice pathogen Xanthomonas oryzae pv oryzae. This resistance is independent of jasmonic acid and salicylic acid signaling. Overexpression of GH3-8 also causes abnormal plant morphology and retarded growth and development. Both enhanced resistance and abnormal development may be caused by inhibition of the expression of expansins via suppressed auxin signaling.     

植物抗病的分子生物学基础

随着分子生物学的不断发展，人们已逐步了解植物寄主与病原之间的相互作用及植物抗病的分子机理。植物受病原侵染后出现两种类型的卫反应：局部防卫反应（过敏反应）和系统获得性防卫反应。本质素、植保素、活性氧、水杨酸等物质已被证明了在植物抗病中起了重要作用。抗病基因和防卫基因的诱导表达构成了防卫反应的遗传基础。本文综述了近年来抗病的分子生物学研究进展，并对其发展和应用前景作了展望。     

Recent breakthroughs in the study of salicylic acid biosynthesis

Salicylic acid is an important regulator of induced plant resistance to pathogens. Consequently, the biosynthesis of salicylic acid and its regulation has received a lot of attention. Salicylic acid can be made from phenylalanine via cinnamic and benzoic acid. Recently, genetic studies in Arabidopsis have shown that salicylic acid is made in the chloroplast from isochorismate, a pathway that is known to operate in prokaryotes.