脱落酸信号转导研究进展

脱落酸(ABA)对植物生长发育和适应环境胁迫等多方面有重要的调节作用,其信号转导机制非常引人注目,近年来这方面研究进展很快。本文利用现有文献,对脱落酸不敏感和超敏感性突变体、脱落酸的结合位点与受体、ABA信号转导涉及的细胞第二信使（Ca2+、磷酸肌醇、cADPR、阴离子通道与H+）、蛋白质可逆磷酸化以及ABA诱导基因表达所必需的顺式作用元件(cis-acting element) 和反式作用因子trans-acting factor）等几方面的最新研究进展作了介绍。     

植物AREB／ABF转录因子及其参与的ABA信号转导

AREB（ABA responsive element binding protein）／ABF（ABRE binding factors）转录因子即ABA（脱落酸）应答元件结合蛋白,参与调控ABA相关基因的表达,提高植物对环境胁迫的适应能力。本文从AREBs的克隆与表达、在抗非生物胁迫中的作用以及参与的ABA信号转导等方面阐述现有的研究进展。     

脱落酸（ABA）诱导基因表达的调控元件

本文详细介绍了脱落酸（ABA）诱导诱导基因表达的各种调控元件及各调控元件间的相经作用和关系,综述了近年来对ABA诱导基因表达的调控元件的研究进展。     

脱落酸在植物花发育过程中的作用

植物激素脱落酸(ABA)对植物的生长发育具有多方面的调节作用,比如种子休眠、萌发,营养生长,环境胁迫反应等。大量研究显示,ABA也参与了植物的成花调控。影响植物成花调控的环境因子,包括光周期变化、春化作用、干旱等均会导致植物体内ABA代谢的变化。本文从调控植物开花的4条主要途径与植物体内ABA代谢变化之间的相互关系,花芽分化时期ABA在植物叶芽和花芽中的动态分布以及离体培养条件下ABA对花芽分化的影响等方面总结了ABA与植物花发育这一领域的最新研究进展。对ABA在植物成花诱导和花发育中的作用进行了综合分析。     

保卫细胞的ABA信号转导

植物激素脱落酸（ABA）调节植物体多种生理过程,尤其在一些逆境条件下,植物体中ABA大量合成,诱导气孔关闭,从而有效地调控植物体内的水分平衡,尽管人们对ABA诱导气孔关闭作用已得到共识,但有关信号转导的细节还很不清楚,该文简要介绍了研究气孔保卫细胞信号转导途径的相关技术以及与ABA信号转导直接相关的ABA受体,第二信使,蛋白质磷酸化和离子通道调节等方面的最新研究进展,并在前人研究工作的基础上,勾画出气孔保卫细胞ABA,H2O2的信号转导模式图。     

苔藓植物脱落酸研究进展

脱落酸(ABA)作为逆境信号,在植物抗逆特别是抗旱过程中起关键作用。苔藓植物是最早登陆的高等植物,探究其ABA的作用机理对于理解陆生植物的进化具有重要意义。本文主要描述ABA在苔藓植物中的功能和作用,并以小立碗藓(Physcomitrella patens)为例,总结了ABA合成和信号转导途径的研究进展,丰富了对ABA在早期陆生植物生存与进化过程中作用的认识。     

植物脱落酸PYR/PYL/RCAR受体

脱落酸(abscisic acid,ABA)对植物生长发育、生物与非生物胁迫的应答具有重要作用。近年研究发现ABA在植物体中引起的信号通路源于其受体的参与,以ABA受体及ABA信号通路为基础的研究成为新的研究热点。本文简略介绍了ABA受体的研究进展概况,重点介绍细胞内ABA受体PYR/PYL/RCAR蛋白对ABA信号感知和下游转导的研究进展,最后总结了PYR/PYL/RCAR介导的ABA信号通路。     

植物MAPK级联途径参与调控ABA信号转导

促分裂原活化蛋白激酶(MAPK)级联途径信号通路在真核生物细胞信号的转换和放大过程中起重要作用。MAPK级联途径由三个成员组成,分别是MAPK、MAPKK及MAPKKK,此三个信号组分按照MAPKKK-MAPKK-MAPK的方式依次磷酸化将外源信号级联放大向下传递。大量研究表明,植物MAPK级联途径参与调控脱落酸(ABA)信号转导。因此,该文就ABA和MAPK的生物学功能、ABA信号转导中的磷酸化与去磷酸化以及MAPK级联途径与ABA信号转导之间的关系等方面的研究进展进行综述,以便进一步认识MAPK和ABA信号转导的分子机制。     

脱落酸 (ABA)诱导基因表达的调控元件

本文详细介绍了脱落酸（ABA）诱导基因表达的各种调控元件及各调控元件间的相互作用和关系。综述了近年来对ABA诱导基因表达的调控元件的研究进展。     

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。     

Activity, but not Expression, of Soluble and Cell Wall-Bound Acid Invertases Is Induced by Abscisic Acid in Developing Apple Fruit

The present experiment, involving both the in vivo injection of abscislc acid （ABA） Into apple （Malus domestica Brohk.） fruits and the in vivo Incubation of fruit tissues in ABA-contalnlng medium, revealed that ABA activates both soluble and cell wall-bound acid invertases. Immunoblottlng and enzyme-linked Immunosorbent assays showed that this ABA-induced acid invertase activation is Independent of the amount of enzyme present. The acid Invertase activation induced by ABA is dependent on medium pH, time course, ABA dose, living tissue and developmental stage. Two isomers of cls-（＋）-ABA, （-）-ABA and trans- ABA, had no effect on acid invertases, showing that ABA-induced acid invertase activation is specific to physiologically active cis-（＋）ABA. Protein kinase inhlbltors K252a and H7 as well as acid phosphatase Increased the ABA-Induced effects. These data indicate that ABA specifically activates both soluble and cell wall-bound acid Invertases by a posttranslational mechanism probably Involving reversible protein phosphorylatlon, and this may be one of the mechanisms by which ABA Is Involved In regulating fruit development.     

Modulation of carrier-mediated uptake of abscisic acid by methyl jasmonate in Phaseolus coccineus L

The effects of methyl jasmonate and jasmonic acid on uptake of abscisic acid (ABA) by suspension-cultured runner-bean cells and subapical runner-bean root segments have been investigated. Increasing concentrations of methyl jasmonate inhibit ABA uptake by the cultured cells with a K _i of 22±3 M. This is not due to cytoplasmic acidification or to effects on metabolism of ABA, and is not additive with inhibition of radioactive ABA uptake by nonradioactive ABA. Uptake of indol-3-yl acetic acid (IAA) is unaffected by methyl jasmonate. The maximum effect of nonradioactive ABA in inhibiting uptake of radioactive ABA, previously shown to reflect saturation of an ABA carrier, is generally greater than the effect of maximally inhibitory concentrations of methyl jasmonate. Similar results were obtained with root segments, but longer incubation times were necessary to observe inhibitory effects of methyl jasmonate. Demethylation of methyl jasmonate to jasmonic acid does not appear to be required since similar concentrations of jasmonic acid had no observable direct effect on ABA uptake other than that attributable to cytoplasmic acidification. Histidine reagents, a proton ionophore and acidic external pH all affect in parallel the inhibition by methyl jasmonate and nonradioactive ABA of uptake of radioactive ABA by the cultured cells. There is no effect of ABA or nonradioactive methyl jasmonate on uptake of radioactive methyl jasmonate by the cultured cells. It is proposed that methyl jasmonate interacts with the ABA carrier. Various models for this interaction are discussed.Abbreviations ABA abscisic acid - DMO 5,5-dimethyloxazolidine-2,4-dione - IAA indol-3-yl acetic acid     

Changes of free and conjugated abscisic acid and phaseic acid in xylem sap of drought-stressed sunflower plants

Abscisic acid (ABA), conjugated abscisic acid, phaseic acid (PA), and conjugated phaseic acid were determined by enzyme-linked immunosorbent assay (ELISA) and gas chromatography (GC) in xylem sap of well-watered and drought-stressed sunflower plants. Conjugated ABA and conjugated PA were determined indirectly after chemical or enzymatic hydrolysis. Conjugated ABA was found to be the predominant ABA metabolite in xylem sap. In xylem sap from well-watered plants at least five, and in sap from drought-stressed plants at least six alkaline hydrolysable ABA conjugates were found. One of them corresponds chromatographically (HPLC) with abscisic acid glucose ester (ABAGE). Under drought conditions the concentrations of ABA, alkaline hydrolysable ABA conjugates, -glucosidase hydrolysable ABA conjugates, PA, and conjugated PA increased. After rewatering the drought-stressed plants, the ABA and the conjugated ABA content decreased. The possible function of the ABA conjugates in the xylem sap as a source of free ABA is discussed.     

Disrupting Abscisic Acid Homeostasis in Western White Pine (<Emphasis Type="Italic">Pinus monticola</Emphasis> Dougl. Ex D. Don) Seeds Induces Dormancy Termination and Changes in Abscisic Acid Catabolites

To investigate the role of abscisic acid (ABA) biosynthesis and catabolism in dormant imbibed seeds of western white pine (Pinus monticola), ABA and selected catabolites were measured during a combined treatment of the ABA biosynthesis inhibitor fluridone, and gibberellic acid (GA). Fluridone in combination with GA effectively disrupted ABA homeostasis and replaced the approximately 90-day moist chilling period normally required to break dormancy in this species. Individually, both fluridone and GA treatments decreased ABA levels in the embryos and megagametophytes of white pine seeds compared to a water control; however, combined fluridone/GA treatment, the only treatment to terminate dormancy effectively, led to the greatest decline in ABA content. Fluridone treatments revealed that a high degree of ABA turnover/transport occurred in western white pine seeds during the initial stages of dormancy maintenance; at this time, ABA levels decreased by approximately two-thirds in both embryo and megagametophyte tissues. Gibberellic acid treatments, both alone and in combination with fluridone, suggested that GA acted transiently to disrupt ABA homeostasis by shifting the ratio between biosynthesis and catabolism to favor ABA catabolism or transport. Increases in phaseic acid (PA) and dihydrophaseic acid (DPA) were observed during fluridone/GA treatments; however, increases in ABA metabolites did not account for the reduction in ABA observed; additional catabolism and/or transport of ABA and selected metabolites in all probability accounts for this discrepancy. Finally, levels of 7′ hydroxy-ABA (7′OH-ABA) were higher in dormant-imbibed seeds, suggesting that metabolism through this pathway is increased in seeds that maintain higher levels of ABA, perhaps as a means to further regulate ABA homeostasis.     

GA,ABA, phenol interaction in the control of growth: Phenolic compounds as effective modulators of GA-ABA interaction in radish seedlings

Abscisic acid, a potent growth inhibitor inhibits hypocotyl growth ofRaphanus sativus seedlings. Phenolic compounds,viz., trans-cinnamic acid, chlorogenic acid, ferulic acid, salicylic acid, tannic acid and quercetin when applied with ABA, antagonize ABA action and restore normal seedling growth. Gibberellic acid promotes hypocotyl growth and on combined application with ABA, the ratio of their concentrations determines the course of the resultant growth. This interaction can be modulated by phenolic compounds. Phenolic compounds in low concentrations when present together with GA and ABA, favour GA-induced growth by antagonizing the inhibitory influence of ABA. The inhibitory action of abscisic acid on a wide range of growth processes is so far known to be reversed only by growth promoting hormones,viz., IAA, GA and cytokinins. Antagonistic action of phenolic compounds towards ABA, and increasing the action of GA when present together with GA and ABA, establishes a dual role to this class of compounds; balancing the effect of both growth promoting and growth inhibiting hormones. Part I.     

Effect of water stress on transport of [2-14C]abscisic acid in intact plants ofPhaseolus coccineus L.

Summary Eight- to 10-day-old plants ofPhaseolus coccineus, which grow on vermiculite with a water content of 12–17% of the water-holding capacity, stop growing completely, whereas water potential and relative water content are almost unaffected. [2-¹⁴C]Abscisic acid, which is applied to the midrib of a primary leaf, is transported especially to the roots and the apical bud, but not to the second primary leaf and the cotyledons. Water-stressed plants, however, export only negligible amounts of ABA from the donor leaf to the plant. Thus an accumulation of ABA occurs in the donor leaf. Consequently water stress can increase ABA concentration in leaves not only by stimulating ABA synthesis but also by inhibiting ABA transport. Recovery of growth and ABA transport after reirrigation is very weak. Water stress has no effect on ABA metabolism in bean plants.Abbreviations ABA abscisic acid - GA gibberellic acid - IAA indoleacetic acid - RWC relative water content in plants - TLC thin-layer chromatography     

Abscisic acid activates acid invertases in developing grape berry

Acid invertases play a key role in sugar metabolism, and the plant hormone abscisic acid (ABA) enhances sugar accumulation in crop sink organs, but information about the relationship between ABA and acid invertases has been limited. The present experiments were done with both in vivo pre-incubation of the grape ( Vitis vinifera  ×  V . labrusca L.) berry tissues in ABA-containing medium and in vivo infiltration of ABA into the intact berries. The results show that ABA activates both the soluble and cell wall-bound acid invertases during fruit development by enhancing their activities and amounts as assessed by immunoblotting or enzyme-linked immunosorbent assay. This activation was pH, time course and ABA dose dependent. The serine/threonine protein kinase inhibitors K252a, staurosporine and H7 and acid phosphatase increased the activation of ABA-induced acid invertase, but the tyrosine protein kinase inhibitor quercetin strongly suppressed the ABA-induced effects, suggesting that a complex reversible protein phosphorylation is involved in the ABA-induced activation of acid invertases. The effects of the protein kinase inhibitors were dependent on the in vivo state of the tissues but independent of the expression of acid invertases. Two ABA analogues, (–)-ABA and trans-ABA, had no effect on acid invertases, showing that the ABA-induced activation of acid invertases is specific to the physiologically active form of ABA. These data suggest that ABA may be involved in fruit development by activating acid invertases.     

Signalling mechanisms involved in the response of two varieties of Humulus lupulus L. to soil drying: II. changes in the concentration of abscisic acid catabolites and stress-induced phytohormones

Abscisic acid (ABA) is one of the most common stress signals that appear in plant organs in response to soil drying. Equilibrium between ABA biosynthesis and catabolism regulates ABA accumulation in plants under water stress. The aim of our work was to explore the dynamics of changes in ABA metabolites as well as other stress-induced phytohormones such as jasmonic acid, indole-3-acetic acid, and their respective metabolites in hop [Humulus lupulus (L.)] plants during drying and to identify among them potential signals involved in drought signalling. We showed that the concentrations of all ABA metabolites (except the concentration of ABA glucosyl ester in leaves) increased in the same manner in leaves and xylem sap approximately at the same level of soil water content when the relative water content of leaves decreased. The predominant metabolites in leaves and xylem sap were phaseic acid and dihydroxyphaseic acid. ABA glucosyl ester was not a source of the increased concentration of ABA in leaves and xylem sap because of its considerably lower concentration compared to ABA. The concentration of jasmonates decreased in leaves of hop plants. Changes in auxin concentration suggest that this hormone is involved in the response of hop plants to soil drying.     

Transport and metabolism of [214-C]abscisic acid in maize root

The tips of intact maize (cv. LG 11) roots, maintained vertically, were pretreated with a droplet of buffer solution or a bead of anion exchange resin, both containing [2¹⁴-C]abscisic acid (ABA). A significant basipetal ABA movement was observed and two metabolites of ABA (possibly phaseic acid and dihydrophaseic acid) were found. ABA pretreatment enhanced the gravireaction of 10 mm apical root segments kept both in the dark and in the light. The possibility that ABA could be one of the endogenous growth inhibitors produced or released by the cap cells is discussed.Abbreviations ABA abscisic acid - 3,3-DGA 3,3-dimethyl-glutaric acid - DPA dihydrophaseic acid - PA phaseic acid - GCMS gas chromatography-mass spectrometry     

Isolation and Characterization of ABA-Insensitive Cell Lines of Carrot

While abscisic acid (ABA) exerts multiple effects on somatic embryogenesis, the most pronounced of these effects is the arrestment of torpedo-stage embryos, preventing them from developing into plantlets. In order to understand the mechanism of ABA inhibition of plantlet formation, we have isolated seven ABA-insensitive cell lines capable of developing into plantlets in the presence of ABA. These ABA-insensitive cell lines, whose frequency of appearance is 7 × 10⁻⁶, have been isolated from a haploid cell line of Daucus carota L. var Juwarot. Surprisingly, all seven cell lines exhibit auxin insensitivity as evidenced by their ability to produce heart-stage embryos in various auxins including 2,4-dichlorophenoxyacetic acid (2,4-D), naphthalene acetic acid, and indolacetic acid. Three of the cell lines, ABA 1, ABA 15, and ABA 17, have been further characterized. We found that all three showed lower levels of ABA uptake which may be the cause of ABA insensitivity. However, the uptake of 2,4-D is higher in the three cell lines than in the wild type. The basis of the interaction between ABA and 2,4-D responses is discussed.