植物抗脱水胁迫的分子机制

主要介绍植物在脱水胁迫下,逆激基因产物的功能和胁迫信号的转导过程.逆激基因产物的功能可分为两类：一类起“保护”作用,另一类起“调节”作用.在脱水胁迫起始信号和基因表达之间至少存在四条信号转导通路,两条依赖脱落酸(ABA),两条不依赖ABA,依赖ABA的途径中有1条必须有蛋白质合成.不依赖ABA的途径中有1条与低温胁迫应答有共同的信号转导通路.     

植物体内干旱信号的传递与基因表达

干旱是严重影响植物生长发育的重要环境胁迫因子之一。干旱能影响植物的水分状态,使植物缺水遭受伤害。近年来,相继从拟南芥等植物中克隆出了一些受干旱诱导的基因,如蛋白激酶基因、光合基因、渗透调节基因、功能蛋白基因（如LEA基因）等。干旱等胁迫信号经历一系列的传递过程,最后诱导这些特定基因的表达。在植物体中,可能存在依赖ABA型和不依赖ABA型两条干旱信号的传递途径。近年来从高等植物中分离出一系列调控干旱相关基因表达的转录因子,通过转录因子之间以及与其它相关蛋白之间的相互作用,激活或抑制干旱等胁迫因子诱导的基因表达。     

提高作物耐旱性的DREB转录因子研究进展

当植物受到干旱胁迫时就会感受到水分的变化,表达产生各种耐旱蛋白包括耐旱功能蛋白、转录因子和激酶,从而抵御干旱胁迫。目前已经明确的耐旱信号途径主要有4条：其中2条是ABA依赖的信号途径,另外2条是不依赖于ABA的信号途径。DREB转录因子是不依赖于ABA的信号途径中的一个重要的转录因子。由于DREB转录因子以及这一信号途径在各种植物中具有很高的保守性,研究这一信号途径对于改良作物的耐旱性以及了解植物抵御干旱的信号交叉联系具有重要意义。综述了近几年来在DREB基因的克隆、表达调控以及遗传转化方面的研究进展,并对未来的发展进行了展望。     

植物干旱胁迫信号转导及其调控机制研究进展

干旱是严重限制作物生长及产量的环境因子之一。经过长期的进化,植物形成了一套响应干旱胁迫的信号转导机制,包括对干旱胁迫信号的感知,第二信使的产生,信号转导和信号网络的形成。信号转导的结果是导致相关基因的表达和蛋白的合成,进而引起植物体渗透调节及抗氧化系统的改变,最终使植物适应干旱逆境或增强植物抗旱能力。干旱胁迫通常会促进ROS的积累及其他次级信号分子的产生。MAPK级联途径是真核生物信号转导最为保守的途径,在植物的生长发育及各种胁迫信号的传导中均起着较重要的作用。综述干旱胁迫信号及ROS→MAPK和ROS→Ca2+介导的信号途径,以及信号转导途径的调控机制。     

植物PP2C蛋白磷酸酶ABA信号转导及逆境胁迫调控机制研究进展

蛋白磷酸酶(protein phosphatase,PP)是蛋白质可逆磷酸化调节机制中的关键酶,而PP2C磷酸酶是一类丝氨酸/苏氨酸残基蛋白磷酸酶,是高等植物中最大的蛋白磷酸酶家族,包含76个家族成员,广泛存在于生物体中。迄今为止,在植物体内已经发现了4种PP2C蛋白磷酸酶。蛋白激酶和蛋白磷酸酶协同催化蛋白质可逆磷酸化,在植物体内信号转导和生理代谢中起着重要的调节作用,蛋白质的磷酸化几乎存在于所有的信号转导途径中。大量研究表明,PP2Cs参与多条信号转导途径,包括PP2C参与ABA调控,对干旱、低温、高盐等逆境胁迫的响应,参与植物创伤和种子休眠或萌发等信号途径,其调控机制不同,但酶催化活性都依赖于Mg2+或Mn2+的浓度。植物PP2C蛋白的C端催化结构域高度保守,而N端功能各异。文中还综述了高等植物PP2C的分类、结构、ABA受体与PP2Cs蛋白互作、PP2C基因参与ABA信号途径以及其他逆境信号转导途径的研究进展。     

水分胁迫的基因表达和信号转导(综述)

植物在水分胁迫条件下的依赖ABA和不依赖ABA的基因表达途径来调节对逆境的适应。植物通过渗透感受器感知胁迫信号,以MAPK和CDPK等途径传递信号,最终引起基因表达。     

高温胁迫及其信号转导

高温是影响当前农业生产重要的不利环境因素之一。本文综述了4种信号分子脱落酸(ABA),Ca2+,水杨酸(SA),茉莉酸(JA)对高温胁迫的响应以及它们的相互关系,高温胁迫能够诱导ABA,Ca2+,SA的含量升高,并且通过外施ABA,Ca2+,SA,JA都能提高植物的抗热性。作为胞内第二信使,外源Ca2+能够提高植物超氧化物歧化酶(SOD),过氧化氢酶(CAT)以及抗坏血酸氧化酶(APX)的活性,且能提高钙调蛋白水平。ABA诱导的抗热性受胞质游离的Ca2+介导。SA被认为是对胁迫反应所必需的信号分子,H2O2很可能是信号转导链的一部分。JA和ABA在生理功能上有很多相似之处,JA独自或通过提高ABA含量来起作用,JA和SA有不同的生理功能,也有相同的(不过它们的信号转导途径可能不同),最后,提出了今后高温胁迫信号转导研究的一些思路。     

干旱胁迫与ABA 的信号转导

植物经历干旱胁迫时,ABA被普遍认为是一种干旱信号而传递干旱信息。在干旱信号ABA的转导过程中,从ABA的被感知到保卫细胞发生变化引起气孔关闭以及ABA诱导的基因表达都经历了复杂的变化。本文对ABA的信号转导过程进行了综述。     

ABA信号转导途径中的MAPKs

脱落酸（ABA）是植物体内一种重要的激素分子,在调节植物生长发育和对环境适应的过程中发挥重要的信号作用。促分裂原活化蛋白激酶（MAPK）是一种广泛存在于真核生物中的信号转导途径,由环境胁迫、细胞因子、植物激素、生长因子等诱导,是植物细胞信号转导过程中的主要级联途径之一。已知许多蛋白激酶和蛋白磷酸酶参与了ABA信号途径,MAPKs作为ABA信号转导的下游组分发挥着重要的调节作用。本文就MAPK级联参与ABA信号转导途径的相关研究进展进行叙述,以便对MAPKs和ABA信号之间的交互作用（cross-talk）机制有更深入了解。     

逆境胁迫下ABA与钙信号转导途径之间的相互调控机制

Ca2+信号是植物应答各种逆境胁迫响应的一个重要组分,它在植物抗病、抗虫及适应非生物胁迫反应中起着重要的作用.Caz+信号作为第二信使在激素信号转导尤其是ABA信号转导过程中发挥着重要作用.研究表明,当植物受到如干旱、低温、盐害等环境胁迫时,细胞迅速积累ABA,胞内钙离子浓度瞬间升高,然后钙离子浓度呈现忽高忽低的震荡现象.在植物细胞中发现Caz+/CDPK、Caz+/CaM和Caz+/CBL三类钙信号系统,它们与逆境胁迫信号转导密切相关.本文通过综述植物在逆境条件下,ABA与钙信号的产生、转导及产生适应性和抗性等方面,介绍了ABA与钙信号之间的相互调节机制.     

Plant stress surveillance monitored by ABA and disease signaling interactions

Abiotic and biotic stresses are the major factors that negatively impact plant growth. In response to abiotic environmental stresses such as drought, plants generate resistance responses through abscisic acid (ABA) signal transduction. In addition to the major role of ABA in abiotic stress signaling, ABA signaling was reported to downregulate biotic stress signaling. Conversely recent findings provide evidence that initial activation of plant immune signaling inhibits subsequent ABA signal transduction. Stimulation of effector-triggered disease response can interfere with ABA signal transduction via modulation of internal calcium-dependent signaling pathways. This review overviews the interactions of abiotic and biotic stress signal transduction and the mechanism through which stress surveillance system operates to generate the most efficient resistant traits against various stress condition.     

SDIR1 is a RING finger E3 ligase that positively regulates stress-responsive abscisic acid signaling in Arabidopsis

Ubiquitination plays important roles in plant hormone signal transduction. We show that the RING finger E3 ligase, Arabidopsis thaliana SALT- AND DROUGHT-INDUCED RING FINGER1 (SDIR1), is involved in abscisic acid (ABA)-related stress signal transduction. SDIR1 is expressed in all tissues of Arabidopsis and is upregulated by drought and salt stress, but not by ABA. Plants expressing the ProSDIR1-beta-glucuronidase (GUS) reporter construct confirmed strong induction of GUS expression in stomatal guard cells and leaf mesophyll cells under drought stress. The green fluorescent protein-SDIR1 fusion protein is colocalized with intracellular membranes. We demonstrate that SDIR1 is an E3 ubiquitin ligase and that the RING finger conservation region is required for its activity. Overexpression of SDIR1 leads to ABA hypersensitivity and ABA-associated phenotypes, such as salt hypersensitivity in germination, enhanced ABA-induced stomatal closing, and enhanced drought tolerance. The expression levels of a number of key ABA and stress marker genes are altered both in SDIR1 overexpression and sdir1-1 mutant plants. Cross-complementation experiments showed that the ABA-INSENSITIVE5 (ABI5), ABRE BINDING FACTOR3 (ABF3), and ABF4 genes can rescue the ABA-insensitive phenotype of the sdir1-1 mutant, whereas SDIR1 could not rescue the abi5-1 mutant. This suggests that SDIR1 acts upstream of those basic leucine zipper family genes. Our results indicate that SDIR1 is a positive regulator of ABA signaling.     

ABA signal transduction at the crossroad of biotic and abiotic stress responses

Abscisic acid (ABA) regulates key processes relevant to seed germination, plant development, and biotic and abiotic stress responses. Abiotic stress conditions such as drought induce ABA biosynthesis initiating the signalling pathways that lead to a number of molecular and cellular responses, among which the best known are the expression of stress-related genes and stomatal closure. Stomatal closure also serves as a mechanism for pathogen defence, thereby acting as a platform for crosstalk between biotic and abiotic stress responses involving ABA action. Significant advances in our understanding of ABA signal transduction have been made with combination of approaches including genetics, biochemistry, electrophysiology and chemical genetics. Molecular components associated with the ABA signalling have been identified, and their relationship in the complex network of interactions is being dissected. We focused on the recent progress in ABA signal transduction, especially those studies related to identification of ABA receptors and downstream components that lead ABA signal to cellular response. In particular, we will describe a pathway model that starts with ABA binding to the PYR/PYL/RCAR family of receptors, followed by inactivation of 2C-type protein phosphatases and activation of SnRK2-type kinases, and eventually lead to activation of ion channels in guard cells and stomatal closure.     

The stomata frontline of plant interaction with the environment-perspectives from hormone regulation

Plants have evolved elaborate mechanisms to perceive and integrate signals from various environmental conditions.On leaf surface,stomata formed by pairs of guard cells mediate gas exchange,water transp...