植物内源茉莉酸类物质的生物合成途径及其生物学意义

茉莉酸类物质(JAs)是新确认的一类广泛存在于植物体内的内源激素, 在植物的生长发育、应激反应和次生代谢过程中起着重要的调控作用。该文主要概述了植物中茉莉酸类物质的生物合成途径、各关键酶的生理作用及其在植物次生代谢工程等方面的研究进展, 并探讨了茉莉酸类物质的潜在应用价值。     

植物的环境信号分子茉莉酸及其生物学功能

茉莉酸信号分子参与植物生长发育众多生理过程的调控,尤其是作为环境信号分子能有效地介导植物对生物及非生物胁迫的防御反应。迄今已知具有信号分子生理功能的至少包括茉莉酸(jasmonic acid,JA)以及茉莉酸甲酯(methyl jasmonate,Me JA)和茉莉酸-异亮氨酸复合物(jasmonoyl-isoleucine,JA-Ile)等茉莉酸衍生物,统称为茉莉酸类化合物(jasmonates,JAs)。从环境信号分子角度介绍了茉莉酸信号的启动(环境信号感知与转导、茉莉酸类化合物合成)、传递(局部传递、维管束传输、空气传播)和生物学功能(茉莉酸信号受体、调控的转录因子、参与的生物学过程)。     

植物内源茉莉酸类物质的生物合成途径及其生物学意义

茉莉酸类物质（JAs）是新确认的一类广泛存在于植物体内的内源激素,在植物的生长发育、应激反应和次生代谢过程中起着重要的调控作用。该文主要概述了植物中茉莉酸类物质的生物合成途径、各关键酶的生理作用及其在植物次生代谢工程等方面的研究进展,并探讨了茉莉酸类物质的潜在应用价值。     

茉莉酸甲酯抑制拟南芥根伸长生长电生理学机制

以外源茉莉酸甲酯(JA-Me)处理拟南芥,运用膜片钳技术研究JA-Me、过氧化氢(H2O2)和内向K+通道之间的关系,以探讨茉莉酸类物质(JAs)抑制根伸长生长分子机制。检测到10-4mol/L的JA-Me能抑制根细胞质膜内向K+电流,表明可能与根的伸长生长有关,并且发现H2O2可能作为第二信使参与了JAs抑制根伸长生长的过程,H2O2介导的JA-Me对根细胞内向K+通道的抑制是根生长受抑的可能电生理机制。     

质谱技术在植物内源激素检测中的应用(综述)

植物内源激素对植物的各种生理活动具有显著的调节作用,但含量极少,对其进行超微量定量检测具有重要意义。在各种检测方法中,质谱法因具有高效、快速、灵敏的优点而得以广泛应用。本文综述近年来质谱技术在植物内源激素检测中的应用,包括样品前处理方法、有机质谱联用技术(气相色谱-质谱、液相色谱-质谱)和生物质谱等,并探讨其未来研究方向。     

MeJA诱导的拟南芥保卫细胞H2O2积累与质膜H+-ATPase的关系

茉莉酸类物质(JAs)作为与昆虫啃噬及损伤相关的植物激素和信号分子在植物防御反应中起重要作用,但是茉莉酸引起的早期防御反应的机理仍不清楚。该研究以拟南芥叶片保卫细胞为材料,结合非损伤微测(NMT)及激光共聚焦技术探讨了茉莉酸诱导的保卫细胞中质膜H+-ATPase与H2O2积累的调控关系。结果表明:茉莉酸甲酯(MeJA)处理导致H+迅速跨膜外排和H2O2积累,H+外排和H2O2积累能够被钒酸钠抑制,而二苯基碘(DPI)处理则对MeJA诱导的H+跨膜外排无显著影响。研究结果证明,在MeJA诱导的早期信号事件中,质膜H+-ATPase的激活先于H2O2的产生。     

茉莉酸类化合物:从植物的诱导抗虫防御反应到生长-防御权衡

茉莉酸类化合物(jasmonates, JAs)可外源诱导植物产生抗虫防御反应.因此,JAs在植物生理及植物保护学领域具有十分重要的研究价值.本文归纳了近20年来在约40种植物上外源施用JAs对鳞翅目、半翅目等植食者及其天敌所产生的生态影响,并从JAs诱导植物产生的直接与间接抗虫反应、诱导系统抗性、诱导方法、田间诱导抗虫表现、应用现状等方面对JAs诱导植物抗虫的研究现状进行了系统的总结.同时,本文结合最新研究结果,从植物体内信号交流、JA信号途径节点调控等方面,对植物体内与JA途径相关的生长-防御“权衡”进行了综述.最后,本文对今后外源JAs诱导植物抗虫研究的发展方向与重点方面进行了分析和展望,以期促进相关研究及JAs田间应用的创新发展.     

茉莉酸类化合物及其信号通路研究进展

茉莉酸类化合物包括茉莉酸及其衍生物,是一类基本的植物激素,其结构上类似于后生动物的前列腺素,作为信号分子在植物的生长发育和胁迫信号响应过程中具有重要的作用.茉莉酸类化合物信号通路包括茉莉酸类化合物的生物合成以及茉莉酸信号的转导,JAZ蛋白是茉莉酸信号转导通路中的一个重要因子,JAZ蛋白的发现为茉莉酸信号转导分子机制的详细阐述铺平道路.简要介绍了茉莉酸类化合物在植物中的作用.重点介绍了其信号转导通路的研究进展.     

茉莉酸在植物诱导防御中的作用

茉莉酸(JA)和茉莉酸甲酯(MeJA)作为与损伤相关的植物激素和信号分子,广泛地存在于植物体中,外源应用能够激发防御植物基因的表达,诱导植物的化学防御,产生与机械损伤和昆虫取食相似的效果。大量研究表明,用茉莉酸类化合物处理植物可系统诱导蛋白酶抑制剂(PI)和多酚氧化酶(PPO),从而影响植食动物对营养物质的吸收,还能增加过氧化物酶、壳聚糖酶和脂氧合酶等防御蛋白的活性水平,导致生物碱和酚酸类次生物质的积累,增加并改变挥发性信号化合物的释放,甚至形成防御结构,如毛状体和树脂导管。经茉莉酸处理的植物提高了植食动物的死亡率,变得更加吸引捕食性和寄生性天敌。挥发性化合物——茉莉酸甲酯可以从植物的气孔进入植物体内,在细胞质中被酯酶水解为茉莉酸,实现长距离的信号传导和植物间的交流,诱导邻近植物产生诱导防御反应。茉莉酸和茉莉酸甲酯分别具有4种立体异构,其中具有活性的是顺式结构,但顺式结构不稳定,会差向异构化为反式结构。茉莉酸的代谢物(Z)-茉莉酮(cis-Jasmone)具电生理活性,在植物诱导防御中起作用,并且在防御信号的作用上不同于茉莉酸和茉莉酸甲酯。     

机械伤害诱导的植物防御机制和信号转导

茉莉酸是植物伤反应的特异激素, 在植物伤反应中具有核心作用, 其下游调控机制已经比较清晰。在番茄(Lycopersicon esculentum)伤反应中, 系统素和茉莉酸协同启动相关基因的表达, 行使系统性防御功能。拟南芥(Arabidopsis thaliana)信号肽是新发现的一类信号物质, 可以激活植物的初始免疫反应, 但其在伤反应中的作用机制有待进一步研究。脱落酸位于茉莉酸上游, 单独或者协同茉莉酸参与植物的防御反应。另外, 植物中还存在以核糖核酸酶为代表的且不依赖于茉莉酸的伤反应信号转导途径。该文对植物伤反应的防御机制和信号转导做了详细概述。     

Phytohormone responses in pepper (Capsicum annuum L.) leaves under a high density of aphid infestation

The time course response of selected phytohormones has been evaluated in sweet pepper plants (Capsicum annuum L.) submitted to a high density (200 aphids/plant) of aphid (Myzus persicae Sulzer) infestation. Abscisic acid (ABA), salicylic acid (SA), indole-3-acetic acid (IAA), and jasmonates (JAs), including jasmonic acid (JA), jasmonoyl-l -isoleucine (JA-Ile), and cis-OPDA have been simultaneously identified and quantitated by UHPLC–MS/MS in pepper leaf tissue harvested at 3, 8 hours post-infestation (hpi), 1, 2, 4 and 7 days post-infestation (dpi). Infested plants showed a reduction in stem length at 7 dpi and in the number of leaves and leaf width from 4 dpi onwards. JA and JA-Ile significantly increased very early (from 3 hpi) while SA only accumulated at 7 dpi. Despite the high density of infestation, the aphid-induced accumulation of JAs was much lower than the burst typically induced by chewing herbivores. On the other side, ABA peaked in aphid-infested plants at 2 and 4 dpi, while IAA content did not change significantly at any time point. Growth inhibition may be partially explained by the high levels of JAs found in aphid-infested plants. The possibility that the obtained results support the hypothesis of the aphid manipulation of plant metabolism is discussed.     

Light-dependent regulation of the jasmonate pathway

Jasmonates (JAs) are plant hormones which are crucial for the response of plants to several biotic and abiotic stresses. Beside this important function, they are involved in several developmental processes throughout plant life. In this short review, we would like to summarize the recent findings about the function of JAs in photomorphogenesis with a main focus on the model plant rice. Early plant development is determined to a large extent by light. Depending on whether seedlings are raised in darkness or in light, they show a completely different appearance which led to the terms skoto- and photomorphogenesis, respectively. The different appearance depending on the light conditions has been used to screen for mutants in photoperception and signalling. By this approach, mutants for several photoreceptors and in the downstream signalling pathways could be isolated. In rice, we and others isolated mutants with a very intriguing phenotype. The mutated genes have been cloned by map-based cloning, and all of them encode for JA biosynthesis genes. The most bioactive form of JAs identified so far is the amino acid conjugate jasmonoyl-isoleucin (JA-Ile). In order to conjugate JA to Ile, an enzyme of the GH3 family, JASMONATE RESISTANT 1, is required. We characterized mutants of OsJAR1 on a physiological and biochemical level and found evidence for redundantly active enzymes in rice.     

Light-dependent regulation of the jasmonate pathway

Jasmonates (JAs) are plant hormones which are crucial for the response of plants to several biotic and abiotic stresses. Beside this important function, they are involved in several developmental processes throughout plant life. In this short review, we would like to summarize the recent findings about the function of JAs in photomorphogenesis with a main focus on the model plant rice. Early plant development is determined to a large extent by light. Depending on whether seedlings are raised in darkness or in light, they show a completely different appearance which led to the terms skoto- and photomorphogenesis, respectively. The different appearance depending on the light conditions has been used to screen for mutants in photoperception and signalling. By this approach, mutants for several photoreceptors and in the downstream signalling pathways could be isolated. In rice, we and others isolated mutants with a very intriguing phenotype. The mutated genes have been cloned by map-based cloning, and all of them encode for JA biosynthesis genes. The most bioactive form of JAs identified so far is the amino acid conjugate jasmonoyl-isoleucin (JA-Ile). In order to conjugate JA to Ile, an enzyme of the GH3 family, JASMONATE RESISTANT 1, is required. We characterized mutants of OsJAR1 on a physiological and biochemical level and found evidence for redundantly active enzymes in rice.     

外用茉莉素诱导植物抗虫性研究进展

茉莉素是一类可以激活一系列植物抗虫防卫反应的重要内源信号分子。该文综述了茉莉素在植物体内的抗虫作用,外用茉莉素对植物诱导抗虫性的影响,及其化学和分子机制,茉莉素诱导抗虫反应的收益和成本,并展望了茉莉素可能的应用前景。     

Regulation of stress hormones jasmonates and ethylene by MAPK pathways in plants

Plant stress hormones, such as jasmonates (JAs) and ethylene (ET) are essential in plant defence against stress conditions. JAs are used in cosmetics and food flavouring, and the recently demonstrated anti-cancer activity of JAs highlights their potential in health protection. It reinforces the need for a better understanding of biosynthetic regulation of JAs. Which mechanisms are involved in the regulation of the biosynthesis of JAs and ET? Production of stress hormones is induced in plants after wounding or herbivore attack. ET is a gaseous compound and plant JAs are oxylipins structurally similar to prostaglandins that are induced upon inflammation or injury in mammals. Wounding activates protein phosphorylation cascades involving mitogen-activated protein kinases (MAPKs). MAPKs regulate ET production. The induction of JA biosynthesis was suggested to require MAPK activation; however the defined roles of MAPKs in JA production remain unclear. Here we will highlight the most recent findings suggesting the regulation of JA biosynthesis and ethylene production by stress activated MAPKs and phosphatases that inactivate these MAPKs.     

Role and activity of jasmonates in plants under in vitro conditions

Jasmonates (JAs), such as jasmonic acid and its methyl ester, are lipid-derived compounds with signal functions in plant growth and development, as well as in responses to stress. JAs are widely distributed in plants as natural plant growth regulators. JAs do not work independently but work as a part of a complex signaling network with other phytohormones. They are deployed to induce response during wounding and are often used for elicitation and stimulation of secondary metabolites production in different in vitro culture systems. Application of JAs seems to be promising during different steps of the micropropagation system for different species. JAs stimulate proliferation rate of shoots, roots, callus and induce microtubers and bulblets formation. However, negative effects of JAs on the condition of plant tissues are also reported, e.g. leaf senescence, reduced growth and inhibited somatic embryogenesis. This review summarizes the current knowledge of the application and properties of jasmonates under in vitro conditions in terms of cell division, explant growth, proliferation ability, storage organ formation and stress response.

     

Exploring the impact of wounding and jasmonates on ascorbate metabolism

Vitamin C (ascorbate, AsA) is the most abundant water-soluble antioxidant in plants. Ascorbate provides the first line of defense against damaging reactive oxygen species (ROS), and helps protect plant cells from many factors that induce oxidative stress, including wounding, ozone, high salinity, and pathogen attack. Plant defenses against these stresses are also dependent upon jasmonates (JAs), a class of plant hormones that promote ROS accumulation. Here, we review evidence showing that wounding and JAs influence AsA accumulation in various plant species, and we report new data from Arabidopsis and tomato testing the influence of JAs on AsA levels in wounded and unwounded plants. In both species, certain mutations that impair JA metabolism and signaling influence foliar AsA levels, suggesting that endogenous JAs may regulate steady-state AsA. However, the impact of wounding on AsA accumulation was similar in JA mutants and wild type controls, indicating that this wound response does not require JAs. Our findings also indicate that the effects of wounding and JAs on AsA accumulation differ between species; these factors both enhanced AsA accumulation in Arabidopsis, but depressed AsA levels in tomato. These results underscore the importance of obtaining data from more than one model species, and demonstrate the complexity of AsA regulation.     

Proteomic identification of differentially expressed proteins in Arabidopsis in response to methyl jasmonate

Jasmonates (JAs) are the well characterized fatty acid-derived cyclopentanone signals involved in the plant response to biotic and abiotic stresses. JAs have been shown to regulate many aspects of plant metabolism, including glucosinolate biosynthesis. Glucosinolates are natural plant products that function in defense against herbivores and pathogens. In this study, we applied a proteomic approach to gain insight into the physiological processes, including glucosinolate metabolism, in response to methyl jasmonate (MeJA). We identified 194 differentially expressed protein spots that contained proteins that participated in a wide range of physiological processes. Functional classification analysis showed that photosynthesis and carbohydrate anabolism were repressed after MeJA treatment, while carbohydrate catabolism was up-regulated. Additionally, proteins related to the JA biosynthesis pathway, stress and defense, and secondary metabolism were up-regulated. Among the differentially expressed proteins, many were involved in oxidative tolerance. The results indicate that MeJA elicited a defense response at the proteome level through a mechanism of redirecting growth-related metabolism to defense-related metabolism.