植物系统获得性抗性的信号转导

坏死病原菌（necrotizingpathogen）的侵染或者一些化学因子的处理能诱导植物的非侵染或非处理部位产生对多种病原再侵染产生抗性,即系统获得性抗性（systemicacquiredresistance,SAR）。获得系统抗性的组织中SAR基因产物的累积和防卫反应的潜在诱导增强（potentiation）是其两类抗病机制。SAR至少有通过水杨酸（salicylicacid,SA）或茉莉酸（jasmonicacid,JA）、乙烯（ethylene）为系统信号分子的两类信号转导途径。遗传分析已用于SAR产生的信号转导过程的分析,一些与SAR信号转导相关的基因已经和正在克隆,这些基因具有明显提高植物广谱抗性的潜能。     

系统获得性抗性移动信号Pip/NHP研究进展

系统获得性抗性(SAR)是一种因病原微生物初次侵染植物局部叶片而被激活的整株水平上的持久广谱抗性。在初次侵染部位快速产生的抗性信号, 可通过韧皮部传输到植物其它部位, 从而激活SAR。哌啶酸/N-羟基哌啶酸(Pip/NHP)作为新发现的移动信号分子, 在SAR信号通路中具有重要作用。该文综述了Pip/NHP的合成、转运以及对SAR调控作用的最新研究进展。     

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。     

植物抗病反应的信号传导网络

植物由抗病基因介导的防卫过程存在一系列生理生化和分子生物学反应,这些反应从病原菌侵染点开始的超敏反应(HR)并延伸到远处组织的系统抗性或获得性抗性(SAR),受制于一种信号传导网络的调控。这个信号系统由抗病蛋白和病原菌非毒性蛋白在一种配体-受体的互作模式下激发,并由信号分子H2O2,NO和系统信号分子SA,JA和乙烯和通过关键调控基因传递和放大,最终诱导一系列防卫反应基因的表达和代谢的变化而产生抗性。植物防卫信号的产生有类似于动物免疫系统因子的介导,并可由非寄主病原菌或诱导子诱发。这些信号途径所产生的广谱抗性为植物抗病基因工程的应用奠定了基础。     

植物系统获得性抗生的信号转导

坏死病原菌（ｎｅｃｒｏｔｉｚｉｎｇ ｐａｔｈｏｇｅｎ）的侵染或者一些化学因子的处理能诱导植物的非侵染或非处理部位产生对多种病原再侵染产生抗性,即系统获得性抗性（ｓｙｓｔｅｍｉｃ ａｃｑｕｉｒｅｄ ｒｅｓｉｓｔａｎｃｅ,ＳＡＲ）。获得系统抗生的组织中ＳＡＲ基因产物的累积和防卫反应的潜在诱导增加（ｐｏｔｅｎｔｉａｔｉｉｏｎ）是其两类抗病机制。ＳＡＲ至少有通过水杨酸（ｓａｌｉｃｙｌｉｃ ａｃｉｄ,ＳＡ）     

植物抗病反应的信号传导网络

植物由抗病基因介导的防卫过程存在一系列生理生化和分子生物学反应,这些反应从病原菌侵染点开始的超敏反应（HR）并延伸到远处组织的系统抗性或获得性抗性（SAR）,受制于一种信号传导网络的调控,这个信号系统由抗病蛋白和病原菌非毒性蛋白在一种配体-受体的互作模式下激发,并由信号分子H2O2,NO和系统信号分子SA,JA和乙烯和通过关键调控基因传递和放大,最终诱导一系列防卫反应基因的表达和代谢的变化而产生抗性。植物防卫信号的产生有类似于动物免疫系统因子的介导,并可由非寄主病原菌或诱导子诱发,这些信号途径所产生的广谱抗性为植物抗病基因工程的应用奠定了基础。     

植物病程相关蛋白及其在烟草中的研究进展

植物在受到病原物侵染时,会产生一系列抗性反应,病程相关蛋白是其中参与抗病性的重要物质,能够被病原物诱导产生并在植物体内积累,对于诱导植物系统抗性,阻止病原物侵染具有重要作用。对植物病程相关蛋白的性质、诱导因素、分类和功能进行综述,并概述病程相关蛋白与烟草系统抗性的紧密联系以及烟草病程相关蛋白基因在增强系统抗性中的应用,为烟草抗病育种和病虫害防治提供了理论。     

硅在植物体内的分布和吸收及其在病害逆境胁迫中的抗性作用

硅在地壳中含量位居第二位,尽管还没有被列为植物生长的必需营养元素,但它在促进植物生长发育和营养吸收、提高植物对非生物逆境胁迫和生物逆境胁迫的抗性等方面都具有重要作用。综述了近些年来国内外关于硅在植物体内的分布、吸收及其生理效应,重点介绍了硅在病害逆境胁迫中的抗性作用机理。高等植物以单硅酸[Si(OH)4]的形式吸收硅,存在硅的主动吸收和被动吸收机制。硅主要沉积在叶片及叶鞘表皮细胞,形成硅化细胞和角质-硅双层结构,能增强寄主植物细胞壁的机械强度和稳固性,从而延缓和抵御病菌的侵入和扩展。更多的证据表明,硅处理能增加植物叶片保护酶(过氧化物酶、多酚氧化酶、苯丙氨酸解氨酶等)活性和诱导寄主产生次生代谢抗性物质(如植保素、多酚类化合物、木质素),从而激活植物的防御系统,增强对病原菌的抵抗能力。分子水平上的研究显示,硅能诱导与植物防御机制相关的基因表达,参与抗病信号分子(如水杨酸、茉莉酸和乙烯)在信号传导中的作用。     

一氧化氮对植物重金属胁迫抗性的影响研究进展

一氧化氮(NO)作为一种重要的信号分子,在调节植物重金属胁迫抗性方面上起着非常重要的作用。综述了NO在植物体内的产生途径,重金属胁迫下植物体内内源NO含量的变化以及外源NO与内源NO对植物重金属胁迫抗性的影响。大量研究表明外源NO能够增强植物对重金属胁迫的抗性,一方面是通过增强植物细胞的抗氧化系统或直接清除活性氧,另一方面是通过影响植物对重金属的吸收以及重金属在植物细胞内的分布。然而内源NO在调节植物重金属胁迫抗性上的功能角色仍存在争议。有些研究表明内源NO是有益的,能够缓解重金属胁迫诱导的毒性;但是也有证据表明内源NO是有害的,能够通过促进植物对重金属的吸收以及对植物螯合素进行S-亚硝基化弱化其解毒功能,从而参与重金属诱导的毒害反应和细胞凋亡过程。     

水杨酸诱导普通菜豆镰孢菌枯萎病抗病性的研究

普通菜豆是人类主要食用豆类之一,其营养价值高、栽培面积大。镰孢菌枯萎病是普通菜豆典型的土传病害,给普通菜豆生产带来严重损失。水杨酸(SA)被认为是诱导植物抗病反应的重要信号分子之一,参与植物的过敏反应(HR)和系统获得性抗性反应(SAR)。本研究通过不同植物激素处理普通菜豆BRB-130,结果表明,SA处理普通菜豆叶片使植株根中SA的含量升高,并显著提高植株对枯萎病原菌FOP-DM01菌株的抗性。SA诱导普通菜豆根组织中苯丙氨酸解氨酶、过氧化物酶活性及过氧化氢的含量显著升高,从而诱导普通菜豆产生HR和SAR。因此,SA作为普通菜豆抗病信号途径中重要的化学激活因子,能够显著提高普通菜豆对枯萎病原菌的抗病性,为发展环境友好型化学农药提供新的思路。     

Signalling in Rhizobacteria-Induced Systemic Resistance in Arabidopsis thaliana

Abstract: To protect themselves from disease, plants have evolved sophisticated defence mechanisms in which the signal molecules salicylic acid, jasmonic acid and ethylene often play crucial roles. Elucidation of signalling pathways controlling disease resistance is a major objective in research on plant-pathogen interactions. The capacity of a plant to develop a broad spectrum, systemic acquired resistance (SAR) after primary infection with a necrotizing pathogen is well-known and its signal transduction pathway extensively studied. Plants of which the roots have been colonized by specific strains of non-pathogenic fluorescent Pseudomonas spp. develop a phenotypically similar form of protection that is called rhizobacteria-mediated induced systemic resistance (ISR). In contrast to pathogen-induced SAR, which is regulated by salicylic acid, rhizobacteria-mediated ISR is controlled by a signalling pathway in which jasmonic acid and ethylene play key roles. In the past eight years, the model plant species Arabidopsis thaliana was explored to study the molecular basis of rhizobacteria-mediated ISR. Here we review current knowledge of the signal transduction steps involved in the ISR pathway that leads from recognition of the rhizobacteria in the roots to systemic expression of broad-spectrum disease resistance in aboveground foliar tissues.     

Induced systemic resistance (ISR) in plants: mechanism of action

Plants possess a range of active defense apparatuses that can be actively expressed in response to biotic stresses (pathogens and parasites) of various scales (ranging from microscopic viruses to phytophagous insect). The timing of this defense response is critical and reflects on the difference between coping and succumbing to such biotic challenge of necrotizing pathogens/parasites. If defense mechanisms are triggered by a stimulus prior to infection by a plant pathogen, disease can be reduced. Induced resistance is a state of enhanced defensive capacity developed by a plant when appropriately stimulated. Systemic acquired resistance (SAR) and induced systemic resistance (ISR) are two forms of induced resistance wherein plant defenses are preconditioned by prior infection or treatment that results in resistance against subsequent challenge by a pathogen or parasite. Selected strains of plant growth-promoting rhizobacteria (PGPR) suppress diseases by antagonism between the bacteria and soil-borne pathogens as well as by inducing a systemic resistance in plant against both root and foliar pathogens. Rhizobacteria mediated ISR resembles that of pathogen induced SAR in that both types of induced resistance render uninfected plant parts more resistant towards a broad spectrum of plant pathogens. Several rhizobacteria trigger the salicylic acid (SA)-dependent SAR pathway by producing SA at the root surface whereas other rhizobacteria trigger different signaling pathway independent of SA. The existence of SA-independent ISR pathway has been studied in Arabidopsis thaliana, which is dependent on jasmonic acid (JA) and ethylene signaling. Specific Pseudomonas strains induce systemic resistance in viz., carnation, cucumber, radish, tobacco, and Arabidopsis, as evidenced by an enhanced defensive capacity upon challenge inoculation. Combination of ISR and SAR can increase protection against pathogens that are resisted through both pathways besides extended protection to a broader spectrum of pathogens than ISR/SAR alone. Beside Pseudomonas strains, ISR is conducted by Bacillus spp. wherein published results show that several specific strains of species B. amyloliquifaciens, B. subtilis, B. pasteurii, B. cereus, B. pumilus, B. mycoides, and B.sphaericus elicit significant reduction in the incidence or severity of various diseases on a diversity of hosts.     

The Arabidopsis ISR1 Locus is Required for Rhizobacteria-Mediated Induced Systemic Resistance Against Different Pathogens

Abstract: In Arabidopsis thaliana, non-pathogenic, root-colonizing Pseudomonas fluorescens WCS417r bacteria trigger an induced systemic resistance (ISR) that is phenotypically similar to pathogen-induced systemic acquired resistance (SAR). In contrast to SAR, WCS417r-mediated ISR is controlled by a salicylic acid (SA)-independent signalling pathway that requires an intact response to the plant hormones jasmonic acid (JA) and ethylene (ET). Arabidopsis accessions RLD1 and Ws-0 fail to express ISR against Pseudomonas syringae pv. tomato and show enhanced disease susceptibility to this pathogen. Genetic analysis of progeny from crosses between WCS417r-responsive and non-responsive accessions demonstrated that ISR inducibility and basal resistance against P. syringae pv. tomato are controlled by a single dominant locus (ISR1) on chromosome III (Ton et al., 1999^[294]). Here, we investigated the role of the ISR1 locus in ISR, SAR and basal resistance against three additional pathogens: Xanthomonas campestris pv. armoraciae, Peronospora parasitica and turnip crinkle virus (TCV), using accessions Col-0 (ISR1), RLD1 (isr1) and Ws-0 (isr1) as host plants.     

生防菌诱导植物系统抗性及其生化和细胞学机制

生防菌通常可利用竞争、抗生、寄生和交叉保护等直接的拮抗机制抑制植物病害;同时某些生防菌还能促进植物生长,诱导植物对真菌、细菌和病毒引起的病害乃至对线虫和昆虫为害的抗性,称为诱导系统抗性(ISR).ISR具有非特异性、广谱性和系统性,其在表型上与病原菌侵染激发的系统获得抗性(SAR)相似,具有同样的效率;但在寄主植物上不发生过敏性坏死反应(HR),无可见症状,为发展和改善更加安全而环境友好的植物保护策略开辟了新的思路.本文总结了生防真菌和细菌诱导系统抗性及其激发子和信号转导途径等方面的研究进展,重点阐述了寄主防御反应的生化和细胞学机制,并对ISR在植物病害生物防治中的应用前景进行了展望.     

Effects of jasmonic acid, ethylene, and salicylic acid signaling on the rhizosphere bacterial community of Arabidopsis thaliana

Systemically induced resistance is a promising strategy to control plant diseases, as it affects numerous pathogens. However, since induced resistance reduces one or both growth and activity of plant pathogens, the indigenous microflora may also be affected by an enhanced defensive state of the plant. The aim of this study was to elucidate how much the bacterial rhizosphere microflora of Arabidopsis is affected by induced systemic resistance (ISR) or systemic acquired resistance (SAR). Therefore, the bacterial microflora of wild-type plants and plants affected in their defense signaling was compared. Additionally, ISR was induced by application of methyl jasmonate and SAR by treatment with salicylic acid or benzothiadiazole. As a comparative model, we also used wild type and ethylene-insensitive tobacco. Some of the Arabidopsis genotypes affected in defense signaling showed altered numbers of culturable bacteria in their rhizospheres; however, effects were dependent on soil type. Effects of plant genotype on rhizosphere bacterial community structure could not be related to plant defense because chemical activation of ISR or SAR had no significant effects on density and structure of the rhizosphere bacterial community. These findings support the notion that control of plant diseases by elicitation of systemic resistance will not significantly affect the resident soil bacterial microflora.     

病程相关基因非表达子1（NPR1）：植物抗病信号网络中的关键节点

最早从拟南芥（Arabidopsis thaliana）中克隆到的NPR1（nonexpressor of pathogenesis-related genes 1）基因是调控植物病害抗性的一个关键基因。它不仅对植物系统获得抗性（systemic acquired resistance,SAR）和诱导系统抗性（induced systemic resistance, ISR）起核心调控作用,而且是植物基础抗性（basic resistance）以及由抗病基因（resistance gene,R）决定的抗性的重要调控因子。氧化突发（oxidative burst）造成的强还原势导致NPR1蛋白还原成单体,以及NPR1单体在细胞核内的积累是诱导水杨酸（salicylic acid,SA）介导的PR（pathogenesis-related）基因表达和SAR产生的充分必要条件。NPR1通过与TGA转录因子的相互作用调控PR基因表达。NPR1作为多种信号途径的交叉点,与某些WRKY转录因子和NPR4一起,在调节和平衡SA和茉莉酸信号传导途径中起关键作用。NPR1的这种调控作用在细胞质内进行,通过遗传工程将其用于植物保护有很好的应用前景。     

Induction of resistance against pathogens by β-aminobutyric acid

Among the many types of plant stressors, pathogen attack, mainly fungi and bacteria can cause particularly severe damage both to individual plants and, on a wider scale, to agricultural productivity. The magnitude of these pathogen-induced problems has stimulated rapid progress in green biotechnology research into plant defense mechanisms. Plants can develop local and systemic wide-spectrum resistance induced by their exposure to virulent (systemic acquired resistance—SAR) or non-pathogenic microbes and various chemical elicitors (induced systemic resistance—ISR). β-Aminobutyric acid (BABA), non-protein amino acid, is though to be important component of the signaling pathway regulating ISR response in plants. After treatment with BABA or various chemicals, after infection by a necrotizing pathogen, colonization of the roots by beneficial microbes many plants establish a unique physiological state that is called the “primed” state of the plant. This review will focus on the recent knowledge about the role of BABA in the induction of ISR against pathogens mainly against fungi.     

Abscisic acid modulates salicylic acid biosynthesis for systemic acquired resistance in tomato

Among the regulatory mechanisms of systemic acquired resistance (SAR) in tomato, antagonistic interaction between salicylic acid (SA) and abscisic acid (ABA) signaling pathways was investigated. Treatment with 1,2-benzisothiazol-3(2H)-one1,1-dioxide (BIT) induced SAR in tomato thorough SA biosynthesis. Pretreatment of ABA suppressed BIT-induced SAR including SA accumulation, suggesting that ABA suppressed SAR by inhibiting SA biosynthesis.