ABA and IAA in rice seedlings under anaerobic conditions

The rice is important in plant science for its ability to germinate and grow with restricted or without oxygen availability. In this work we have investigated the variation of growth substances when anoxia was imposed to rice seedlings previously grown in air. An increase, in all the organs of a seedling and in particular in the fraction released in the medium, was observed for ABA (abscisic acid), PA (phaseic acid) and DPA (dihydrophaseic acid) quantities.Vice versa a reduction of total IAA (indol-3-ylacetic acid) was observed in seedlings. This was accompanied by its accumulation in roots. IAA was poorly released in aerobic conditions and anoxia has not changed this pattern.     

Comparison of effects of ABA and IAA on phospholipid bilayers

The plant hormones indole-3-acetic acid (IAA) and abscisic acid (ABA) affect the properties of phospholipid bilayers differently. IAA enhances permeability of bilayers composed of phosphatidylcholine to the non-electrolyte erythritol while ABA requires an additional phospholipid in the membrane to produce substantial enhancement. Similar conclusions are obtained by measuring hormone-induced permeability to chloride ions; IAA is effective with single component phosphatidylcholine membranes while ABA requires a second phospholipid. Erythritol permeability is shown to be pH dependent for both hormones. Although IAA is more effective at increasing erythritol permeability at pH 4 than at pH 7, both dissociated and undissociated IAA affect the process. In comparison ABA is almost totally ineffective in the dissociated form (at pH 7). Spin label electron spin resonance measurements demonstrated that neither hormone substantially disrupts acyl chain mobility within the membrane, indicating that the mechanism of permeability enhancement is not a general non-specific pertubation of membrane ordering and fluidity. Both hormones can also effect the stability of small unilamellar (sonicated) vesicles. Phosphatidylcholine vesicles are relatively stable and do not rapidly aggregate with either ABA or IAA. However, when phosphatidylethanolamine is incorporated as a minor component (10 mol%) into phosphatidylcholine vesicles ABA causes rapid aggregation while IAA has no effect. These experiments indicate that the two hormones may exhibit completely different behaviour on membranes without the requirement for specific proteinaceous receptors.     

Determination of IAA and ABA in the same plant sample by a widely applicable method using GC-MS with selected ion monitoring

A method for the purification and subsequent quantification of indole-3-acetic acid (IAA) and abscisic acid (ABA) from the same sample of highly pigmented green tissue has been developed and tested in several species. Solvent partitioning and high-performance liquid chromatography (HPLC) were used for purification. Separate fractions from HPLC-containing IAA and ABA were analyzed by gas chromatography-mass spectrometry (GC-MS) using selected-ion monitoring (SIM). Isotope dilution was used to correct for incomplete recovery. Results are presented for tissue samples from 11 different species and five different plant organs. The method can be completed, for both IAA and ABA, for two samples in 8 h by an experienced technician. IAA and ABA were the dominant peaks in the gas chromatograms from HPLC-purified samples, and amounts of about 1 ng can be detected. The extract was partitioned into an aqueous solution of pH 9.5, a step suspected of ester hydrolysis. By analyzing samples known to contain esters of IAA and ABA and comparing the results with methods which excluded this step, we have shown that this partitioning does not result in erroneously high values due to ester hydrolysis. A direct comparison of the method with one in which HPLC was not employed indicates that our method measures IAA and ABA in samples in which these compounds are not detectable when HPLC is omitted. Thus, HPLC is an essential purification step for samples where contaminating compounds co-purify with IAA and ABA through the solvent-partitioning steps.     

Changes in the Levels of IAA and ABA in Cucumber Leaves under Progressive Soil Drought

Changes in the IAA and ABA contents in cucumber (Cucumis sativus L.) leaves during adaptation to drought were studied. An increase in the water-retaining capacity and heat resistance of leaves indicating the onset of adaptation occurred when the leaf growth has been already suppressed. There was a transient increase in the ABA content during the initial stage of adaptation. An increased IAA content was maintained for a longer period, throughout about two-third of the adaptation period. A second increase in the ABA content was observed before the onset of leaf permanent wilting, when IAA content already decreased. Our data suggest that not only ABA, but also IAA are involved in the development of defense responses during the adaptation to drought.     

紫外光B辐射增强对水稻叶片内IAA和ABA含量的影响

 两个水稻品种CK46和Dular生长在人工气候箱的条件下,在0.0和13.0kJm-2 day-1(模拟臭氧浓度下降20％的UVB强度)的紫外光B(UV-B 280 nm-320 nm)下进行4周的照射处理,研究UV-B对水稻体内内源IAA和ABA含量的影响。结果表明：随着UV—B处理时间的延长,CK46和Dular叶片内的IAA含量下降。相反,UV-B辐射增强使两个品种叶片内的ABA含量上升。     

ABA 与植物胁迫抗性

ABA是一种重要的植物激素, 受到生物胁迫和非生物胁迫的调控, 在植物对胁迫耐受性和抗性中发挥着重要作用。本文着重阐述了植物胁迫对ABA的生物合成和代谢的调控、ABA在调控气孔关闭和调控基因表达从而调控植物耐逆性方面的作用, 以及植物胁迫信号转导途径间的联系和交叉。     

ABA与植物胁迫抗性

ABA是一种重要的植物激素,受到生物胁迫和非生物胁迫的调控,在植物对胁迫耐受性和抗性中发挥着重要作用。本文着重阐述了植物胁迫对ABA的生物合成和代谢的调控、ABA在调控气孔关闭和调控基因表达从而调控植物耐逆性方面的作用,以及植物胁迫信号转导途径间的联系和交叉。     

ABA与植物的耐盐性

文章介绍近年来ABA与植物耐盐性的研究进展。     

Evidence That IAA Conjugates Are Slow-Release Sources of Free IAA in Plant Tissues

Evidence that indoleacetic acid (IAA) conjugates are metabolized via enzyme-catalyzed hydrolysis to free IAA and that their biological activities are related to the rates at which they are hydrolyzed by the tissue is presented. These conclusions are based on the following observations. Slow but continuous decarboxylation of the IAA moiety of IAA-l-alanine and IAA-glycine occurs when these conjugates are applied to pea (Pisum sativum L. cv. Alaska) stem segments. Inasmuch as IAA conjugates are protected from peroxidase-catalyzed oxidative decarboxylation, the conjugates are probably hydrolyzed and the freed IAA then further metabolized. Free IAA and IAA-l-alanine are converted, by pea stem tissue, into the same metabolites. The metabolism is enzymic, since conjugates of IAA with the d-isomers of the amino acids are inactive. Ethylene production induced by IAA-l-alanine and by IAA-glycine is correlated with their hydrolysis, as indicated by their decarboxylation and with the appearance or nonappearance of IAA metabolites in the tissues.     

Distribution of IAA and ABA in gravistimulated primary roots ofZea mays. L.

The transport of¹⁴C-IAA and¹⁴C-ABA applied exogenously to root cap toward the elongation zone was investigated in gravi- and light-stimulated primary roots ofZea mays L. cv. Golden Cross Bantam 70. No significant difference of either IAA or ABA in radioactivities was observed between upper and lower halves of elongation zones during the latent period (0–60 min after the stimulation) of gravitropic response. When quantitative analysis of endogenous IAA and ABA by an internal standard method was carried out 60 min after gravi- and/or light-stimulation, no asymmetric redistribution of either IAA or ABA was observed between upper and lower halves of elongation zones. Light irradiation increased by 20% the contents of ABA in elongation zones. These results suggest that although both IAA and ABA are basipetally transportable and can transmit their information to the elongation zone during a latent period we cannot explain the gravitropic curvature by their redistributions between the two (upper and lower) halves of primary roots ofZea. On the basis of results from the present work and previous papers, the distribution of IAA and ABA in gravistimulatedZea roots is discussed. A part of this study was reported at the Eighth Annual Meeting of the IUPS Commission on Gravitational Physiology at Tokyo 1986.     

参与ABA诱导的水稻OsCaMs基因鉴定及其功能分析

以‘徐稻4号’为材料,构建OsCaMs的瞬时表达载体,利用生物信息学和RT-PCR方法设计OsCaMs定量引物5个,鉴定参与ABA诱导的OsCaMs基因并分析其生理功能,为进一步揭示ABA信号转导核心组分的研究奠定基础。结果显示:(1)水稻OsCaMs的5个家族基因的CDS等长,均为450bp,ABA(100μmol·L~(-1))处理能够明显诱导OsCaM1-1和OsCaM1-2的表达。(2)利用瞬时表达载体将表达荧光蛋白的OsCaM1-1-YFP和OsCaM1-2-YFP通过PEG方法转化到原生质体中,激光共聚焦分析显示,这2个基因均定位于细胞核、细胞质和细胞膜中;并构建了OsCaM1-1和OsCaM1-2的干扰载体dsOsCaM1-1和dsOsCaM1-2。(3)经ABA诱导的水稻原生质体抗氧化保护酶APX和SOD活性分别显著提高35%和31%;原生质体瞬时表达和瞬时沉默体系分析表明,OsCaM1-1和OsCaM1-2均能够影响抗氧化保护酶APX和SOD的活性,其中原生质体中瞬时过表达这2个基因对APX和SOD活性上调达到1.15~1.45倍,瞬时干扰这2个基因对APX和SOD活性下调达到25%~30%。(4)外源H_2O_2(10mmol·L~(-1))预处理水稻幼苗可诱导OsCaM1-1和OsCaM1-2基因表达量上调,并且OsCaM1-2能够诱导水稻原生质体中H_2O_2的积累。(5)原生质体瞬时表达分析发现,在水稻原生质体中瞬时表达OsCaM1-1和OsCaM1-2可分别诱导OsrbohB和OsrbohE的表达;而且在水稻原生质体中瞬时表达OsrbohB和OsrbohE可分别诱导OsCaM1-1和OsCaM1-2的表达,表明OsCaMs与Osrbohs之间存在正反馈调节机制。研究表明,OsCaM1-1和OsCaM1-2为水稻参与ABA信号转导中具有调控抗氧化保护作用的同源基因;OsCaM1-1和OsCaM1-2不仅受ABA诱导,也受H_2O_2诱导,而且ABA是通过H_2O_2进行调控。     

Stomatal responses to ABA and IAA in isolated epidermal strips ofVicia faba L.

Epidermal strips from well-watered faba-bean plants were subjected to a range of abscisic acid (ABA) and indolyl-3-acetic acid (IAA) concentrations (10^-5 to 1 mM) in the presence or absence of CO₂ in light or dark. ABA had inhibitory effect on abaxial stomatal apertures in all the concentrations studied and retained them closed even after addition of KCl (SO and 100 mM) to the incubation medium. It also influenced stomatal responses to CO₂. In the presence of CO₂ apertures were greater than in its absence in light as well as in darkness. This relationship remained unchanged also after addition of KCl. The action of ABA inhibited accumulation of potassium in the guard cells. IAA stimulated stomatal opening and its effect was quite opposite to ABA; in the presence of CO₂ the apertures were smaller than in its absence. IAA, however, was able to inhibit the closing effect of darkness, CO₂, and ABA, and stimulated potassium accumulation in the guard cells. Simultaneous action of ABA+IAA manifested effects of both substances.     

几种木本植物插穗生根与内源IAA,ABA的关系

迄今为止,传统的插条繁殖仍是林业和园林工作者获得良种无性系和培育苗木的重要途径。在影响插穗不定根形成内外因素中,植物内源激素水平和生长调节剂应用占有重要地位。已知第一个根原基细胞的分裂依赖于内源生长素或外源的生长调节剂(Hartmann 1983,Haissig 1974),低浓度的ABA(1.26～20μg/ml)能促进     

Changes in the Levels of IAA,ABA, and Cytokinins in Wheat Seedlings Infected with Tilletia caries

The seedling growth and the content of endogenous phytohormones in wheat seedlings were estimated 3, 6, and 9 days after infection with the bunt pathogen (Tilletia caries) (DC.)TUL. The infection of a pathogen-susceptible species Triticum aestivum L. and a resistant species T. timopheevii Zhuk. resulted, respectively, in an increase and a decrease in the seedling growth and the IAA content as compared to the control. The cytokinin content increased in both species, and the increase in T. timopheevii was more rapid. The pathogen-induced increase in auxin content is suggested to enhance fungal invasion of plants. In the susceptible species, a high ABA concentration was retained for a longer period of time and could act as a factor of virulence. At the same time, in the resistant species, an increase in ABA content was transient and seems to trigger plant defense mechanisms.     

The effect of decapitation on the levels of IAA and ABA in the lateral buds of Betula pendula roth

The level of IAA and ABA in lateral buds of birch shoots 24 h and 5 days after the decapitation of the apical bud was determined. Twenty four hours after decapitation, when visible signs of outgrowth of lateral buds were not observed yet, an increase in the level of IAA and a decrease of ABA, as compared with the buds of non-decapitated shoots, was found. Five days later, when lateral buds were in the period of intensive outgrowth, a decrease in the levels of IAA and ABA was observed. It has been suggested that removing the source of auxin, by the decapitation of the apical bud makes possible the lateral buds to undertake the synthesis of their own auxin. It could lead to the decrease in the content of ABA. These all events could create suitable conditions for the outgrowth of lateral shoots.     

Carotenoid deficiency impairs ABA and IAA biosynthesis and differentially affects drought and cold tolerance in rice

Plant responses to abiotic stresses are coordinated by arrays of growth and developmental programs. Phytohormones such as abscisic acid (ABA) and indole-3-acetic acid (IAA) play critical roles in developmental progresses and environmental responses through complex signalling networks. However, crosstalk between the two hormones at the biosynthesis level remains largely unknown. Here, we report that carotenoid-deficient mutants (phs1, phs2, phs3-1, phs4, and PDS-RNAi transgenic rice) were impaired in the biosynthesis of ABA and IAA. Under drought conditions, phs3-1 and PDS-RNAi transgenic rice showed larger stomata aperture and earlier wilting compared to the wild type at both seedling and panicle developmental stage. Interestingly, these carotenoid-deficient lines showed increased cold resistance, which was likely due to the combined effects of reduced IAA content, alleviated oxidative damage and decreased membrane penetrability. Furthermore, we found that IAA content was significantly declined in rice treated with fluridone (a carotenoid and ABA biosynthesis inhibitor), and expression of auxin synthesis and metabolism-related genes were altered in the fluridone-treated rice similar to that in the carotenoid-deficient mutants. In addition, exogenous IAA, but not ABA, could restore the dwarf phenotype of phs3-1 and PDS-RNAi transgenic rice. These results support a crosstalk between ABA and IAA at the biosynthesis level, and this crosstalk is involved in development and differentially affects drought and cold tolerance in rice.     

The effect of 4-chlororesorcinol on the endogenous levels of IAA,ABA and oxidative enzymes in cuttings

Treatment of bean cuttings with 4-chlororesorcinol (4-CR), known to increase the number of roots and extend their distribution, prevented the accumulation of free indol-3-yl-acetic acid (IAA) in the hypocotyls within 24 h after cutting preparation. In mung bean there was no change in the distribution (upper half vs. 1 ower half of the hypocotyl) of IAA within the hypocotyl as a result of the treatment. In bean cuttings the treatment with 4-CR prevented the accumulation of IAA in the bottom of the cutting. Oxidation of IAA as a measure of IAA oxidase activity in bean was enhanced appreciably by 4-chlororesorcinol. The level of abscisic acid in mung bean, on the other hand, remained 3–4 fold higher than in the control, yet still about 50% lower than the zero time level. In untreated mung bean cuttings the activity of peroxidase increased after cutting preparation. In contrast, the activity of peroxidase in 4-Cr-treated cuttings was consistently lower. In order to relate to the effect of exogenously applied auxin the level of peroxidase was measured also in indol-3-yl-butyric acid-treated cuttings. The overall peroxidase activity in IBA-treated cuttings was not affected. However, when assaying for the different isozymes the drop in peroxidase activity was most evident in the inducible basic isoperoxidases both in 4-CR and IBA treatments. It appears that the exposure to 4-CR exerts an effect that is similar to that of exogenously applied auxin, affecting the activity of basic peroxidases and enhancing the oxidation of endogenous IAA, thus allowing the organization of the primordia.Abbreviations ABA - abscisic acid - 4-CR - 4-chlororesorcinol - IAA - indol-3-yl-acetic acid - IBA - indol-3-yl-butyric acid