Preharvest application of exogenous abscisic acid (ABA) or an ABA analogue does not affect endogenous ABA concentration of onion bulbs

Bulb abscisic acid (ABA) concentration has been shown to decrease in stored onions, and onset of sprouting to occur at minimal ABA concentration. It was postulated that increasing prestorage bulb ABA concentration could increase storage life. Analogues of ABA that enhance biological activity and resist degradation are available and are becoming commercially viable. Exogenous ABA and an ABA analogue (8′-methylene ABA methyl ester; PBI-365) were applied separately as preharvest foliar sprays to six onion cultivars with varying storage potential. Quality indicators including pyruvate, total soluble solids and firmness were determined at regular intervals during storage. Neither ABA treatment increased endogenous bulb ABA concentration. Bulb ABA concentration decreased during storage and the onset of sprouting occurred at a minimal ABA concentration (ca. 50–120 ng g⁻¹ DW). This was followed by an increase in ABA concentration as sprout growth continued. No straightforward relationship between ABA and carbohydrate metabolism could be determined.     

荔枝和龙眼种子发育过程中ABA含量及对外源ABA敏感性的变化

在荔枝和龙眼种子发育过程中,内源ＡＢＡ水平先是上升,至大约７８～８０ＤＰＡ时出现高峰,之后两者ＡＢＡ含量均不断下降。果实成熟时采收的种子,ＡＢＡ含量比高峰时分别下降近６倍。另外,随着种子的发育,种子及其胚轴对外源ＡＢＡ的敏感性（ＳＡＢＡ）亦持续下降。１０－４ｍｏｌ／ＬＡＢＡ可以完全抑制９０ＤＰＡ前的荔枝和龙眼种子的萌发,但对成熟种子１０－２ｍｏｌ／ＬＡＢＡ亦不能抑制其萌发。龙眼种子离体胚轴的ＳＡＢＡ高于荔枝。ＡＢＡ含量与敏感性的这种变化可能是两种顽拗性种子成熟时萌动,进而不耐脱水贮藏的重要原因之一。     

Long-distance signalling of abscisic acid (ABA): the factors regulating the intensity of the ABA signal

Abscisic acid (ABA) is a stress signal, which moves in the xylem from the roots to the aerial parts of the plant, where it regulates stomatal movement and the activity of shoot meristems. Root growth-promoting microorganisms in the rhizosphere, lateral ABA flows in the root cortex across apoplastic barriers, ABA redistribution in the stem, leaf apoplastic pH values, and the action of beta-glucosidases, both in the apoplast and the cytosol of the mesophyll, play an important role in the regulation of signal intensity. The significance of abscisic acid glucose ester as a long-distance stress signal is discussed.     

Carotenoids and abscisic acid (ABA) biosynthesis in higher plants

Recent research has revealed that abscisic acid (ABA), synthesised in response to water stress, is an apo-carotenoid. Two potential carotenoid precursors, 9'- cis -neoxanthin and 9- cis -violaxanthin, have been identified in light-grown and etiolated leaves, and in roots of a variety of species. Experiments utilizing etiolated Phaseolus vulgaris leaves and deuterium oxide strongly suggest that 9'- cis -neoxanthin, synthesised from all- trans -violaxanthin, is the immediate pre-cleavage precursor of ABA. The cleavage of 9'- cis -neoxanthin, performed by an inducible and specific dioxygenase, is likely to be the rate-limiting step in ABA biosynthesis. Any apocarotenoids formed as by-products of cleavage are probably rapidly degraded by lipoxygenase or related enzymes. After cleavage xanthoxin is converted via ABA-aldehyde to ABA by constitutive enzymes in the cytosol.     

Abscisic acid (ABA) inhibition of lateral root formation involves endogenous ABA biosynthesis in Arachis hypogaea L.

ABA has been found to play a significant role in post-embryonic developmental in peanut seedlings. The results from the current study indicate that in the presence of exogenous 10 μmol l⁻¹ ABA, lateral roots (LRs) number decreased and seedling development was delayed. This effect was eliminated by 25 μmol l⁻¹ naproxen, an inhibitor of ABA biosynthesis. The Arabidopsis mutant deficient in ABA biosynthesis, nced3, displays a phenotype with more and longer LRs. We found that ABA decreased root-branching in peanut in a dose-dependent way. ABA-treated seedlings showed higher endogenous ABA levels than the control and naproxen-treated seedlings. RT-PCR results indicated that the expression of AhNCED1, a key gene in the ABA biosynthetic pathway, was significantly up-regulated by exogenous ABA in peanut. The mRNA levels of AhNCED1 began to increase 2 days after ABA treatment. The results from the current study show that ABA inhibits peanut LR development by increasing endogenous ABA contents.     

Role of abscisic acid (ABA) and Arabidopsis thaliana ABA-insensitive loci in low water potential-induced ABA and proline accumulation

The mechanisms by which plants respond to reduced water availability (low water potential) include both ABA-dependent and ABA-independent processes. Pro accumulation and osmotic adjustment are two important traits for which the mechanisms of regulation by low water potential, and the involvement of ABA, is not well understood. The ABA-deficient mutant, aba2-1, was used to investigate the regulatory role of ABA in low water potential-induced Pro accumulation and osmotic adjustment in seedlings of Arabidopsis thaliana. Low water potential-induced Pro accumulation required wild-type levels of ABA, as well as a change in ABA sensitivity or ABA-independent events. Osmotic adjustment, in contrast, occurred independently of ABA accumulation in aba2-1. Quantification of low water potential-induced ABA and Pro accumulation in five ABA-insensitive mutants, abi1-1, abi2-1, abi3, abi4, and abi5, revealed that abi4 had increased Pro accumulation at low water potential, but a reduced response to exogenous ABA. Both of these responses were modified by sucrose treatment, indicating that ABI4 has a role in connecting ABA and sugar in regulating Pro accumulation. Of the other abi mutants, only abi1 had reduced Pro accumulation in response to low water potential and ABA application. It was also observed that abi1-1 and abi2-1 had increased ABA accumulation. The involvement of these loci in feedback regulation of ABA accumulation may occur through an effect on ABA catabolism or conjugation. These data provide new information on the function of ABA in seedlings exposed to low water potential and define new roles for three of the well-studied abi loci.     

ABA对黑黄檀种子萌发的抑制作用以及其他植物激素对ABA的拮抗作用

以云南特有濒危树种黑黄檀(Dalbergia fusca)的种子为材料,研究了脱落酸(ABA)对种子萌发的抑制作用,以及种子萌发过程中吲哚乙酸(IAA)、赤霉酸(GA_3)、6-苄基腺嘌呤(6-BA)和乙烯利对ABA的拮抗作用.黑黄檀种子萌发的适宜温度为30℃.交替光照(14 h光照和10 h黑暗)以及黑暗对种子萌发没有明显的影响.0.001～0.1 mmol/L ABA不影响种子的萌发率,但降低种子的萌发进程;1 mmol/L和2.5mmol/L ABA显著地抑制种子的萌发率和萌发进程.种子的萌发率不被0.0001～1 mmol/L IAA和GA3、0.0001～0.1 mmol/L 6-BA、以及0.001～10 mmol/L 乙烯利(乙烯供体)的影响,但被1 mmol/L 6-BA抑制.1mmol/L ABA对种子萌发的抑制作用能被0.01～1 mmol/L IAA、0.01～1 mmol/L GA3、0.001～0.1 mmol/L 6-BA和0.1～10 mmol/L乙烯利所拮抗,而且这种拈扰作用与植物激素的类型和浓度有关.0.01 mmol/L 6-BA和0.1 mmol/L乙烯利对l mmol/L ABA抑制作用的拈抗不能被添加0.001 mmol/L IAA或者O.001 mmol/L GA3加成.但0.1 mmol/L 乙烯利对1 mmol/L ABA抑制作用的拮抗能够被添加O.01 mmol/L 6-BA或者0.1 mmol/L 6-BA加成,导致更高的萌发率和幼苗生长.     

ABA 对黑黄檀种子萌发的抑制作用以及其他植物激素对ABA 的拮抗作用

以云南特有濒危树种黑黄檀( Dalbergia fusca) 的种子为材料, 研究了脱落酸(ABA) 对种子萌发的抑制作用, 以及种子萌发过程中吲哚乙酸( IAA) 、赤霉酸(GA3 )、6-苄基腺嘌呤(6-BA) 和乙烯利对ABA的拮抗作用。黑黄檀种子萌发的适宜温度为30℃。交替光照(14 h 光照和10 h 黑暗) 以及黑暗对种子萌发没有明显的影响。0 . 001～0 . 1 mmol/L ABA 不影响种子的萌发率, 但降低种子的萌发进程; 1 mmol􊄯L 和2 . 5mmo􊄯l L ABA 显著地抑制种子的萌发率和萌发进程。种子的萌发率不被0 . 0001 ～ 1 mmo􊄯l L IAA 和GA3 、0 . 0001～0 . 1 mmol/L 6-BA、以及0 . 001～10 mmol/L 乙烯利( 乙烯供体) 的影响,但被1 mmol􊄯L 6-BA 抑制。1mmol/L ABA 对种子萌发的抑制作用能被0 . 01～1 mmol/L IAA、0 . 01～1 mmol/L GA3 、0 . 001～0 .1 mmol/L 6-BA 和0 . 1～10 mmol􊄯L 乙烯利所拮抗, 而且这种拮抗作用与植物激素的类型和浓度有关。0. 01 mmol/L 6-BA 和0 . 1 mmol/L 乙烯利对1mmol/L ABA 抑制作用的拮抗不能被添加0 . 001 mmol/L IAA 或者0 .001 mmol/L GA3 加成。但0 . 1mmol/L 乙烯利对1 mmol/L ABA 抑制作用的拮抗能够被添加0 . 01 mmol/L 6-BA 或者0 .1 mmol/L 6-BA 加成, 导致更高的萌发率和幼苗生长。     

Induction of a wheat Em promoter by ABA and optically pure ABA analogs in white spruce (Picea glauca) protoplasts

In white spruce ( Picea glauca ) protoplasts, abscisic acid (ABA) and optically pure ABA analogs induced expression of a reporter gene under regulation of a wheat ABA-responsive promoter. A fusion of a 650 bp promoter fragment from the wheat Em gene promoter and the Escherichia coli uidA sequence encoding β -glucuronidase (GUS) was linked in the plasmid pBM 113Kp. Expression of the Em-uidA fusion varied among 6 white spruce genotypes. Protoplasts from 4-day-old embryogenic suspension cultures gave the highest GUS activity relative 10 other stages in the 7-day growth cycle of suspension cultures. Racemic ABA [R.S-(±)-ABA] induced a significant increase of protoplast GUS activity over background at a concentration of 1 × 10⁻⁵ M , but maximum GUS activity was found at 1 × 10⁻³ M , ABA stereochemistry had a significant effect on gene expression. The natural isomer of ABA [S-(+)-ABA] was an effective inducer at a concentration as low as 1 × 10⁻⁷ M , but a concentration of greater than 1 × 10⁻⁴ M was required for induction by [R-(—)-ABA]. Moreover, analogs with the same configuration at C-l¹ as that of natural ABA were more effective for induction of expression from the Em-uidA . insert at 1 × 10⁻⁴ M than were their enamiomers. Plasnud pBI511. carrying the chloramphenicol acety] transferase (CAT) gene driven by the constitutively expressed, tandemly duplicated cauliflower mosaic virus 35S promoter, was co-electroporated with pBM113Kp for monitoring Ihe influence of addition of exogenous ABA or ABA analogs on heterologous gene expression in protoplasts. CAT activity was not significantly affected by the presence or absence of ABA or the analogs used.     

葡萄贮期脱落酸（ABA）变化的研究

试验研究了葡萄贮期脱落酸 ( ABA)的变化 ,结果表明 :葡萄贮期 ABA含量呈抛物线形变化 ,有明显的高峰出现 ,低温 ( 0± 0 .5℃ )贮藏具有推迟 ABA峰期和降低峰值的作用 ,经用 9种植物生长调节剂和 2种化学药品对葡萄果穗处理试验 ,三碘苯甲酸 ( TIBA)对 ABA的形成有极强的抑制作用 ,吲哚 - 3-乙酸 ( IAA)、赤霉素 ( GA3)、萘乙酸 ( NAA)和 6-苄基氨基嘌呤 ( 6- BA)对 ABA的形成也具有拮抗作用 ,矮壮素 ( CCC)、比久 ( B9)、乙烯利 ( CEPA)和外源脱落酸对 ABA的形成有促进作用。     

Initiation of the synthesis of 'stress' ABA by (+)-[(2) H(6) ]ABA infiltrated into leaves of Commelina communis

The 'fettered' fraction of abscisic acid (ABA) that is held within the chloroplasts of unwilted bean and Commelina communis leaves is released when the leaves wilt and it is this 'free' ABA that is now proposed to cause the stomata to close within 2 or 3 min, well before the rise in total ABA can be detected. The large increase in 'stress' ABA begins 2-3 h later. The fettered ABA in a centrifuged homogenate is released by hyperosmotic solutions of mannitol (0.8 M) and NaCl (0.4 M). Dilute solution of halothane (10 mM) and colchicine (1 mM), the detergent sodium dodecyl sulphate (1 mM) the herbicide 2,4-d (0.1 mM) and dithiothreitol (0.01 mM) also caused ABA to be released. Zeatin (0.01 mM), cumene hydroperoxide (0.01 mM) and CaCl(2) (1 mM) had negligible effects. It was postulated that the ABA released from the chloroplasts by wilting could be the signal that initiates the synthesis of the dioxygenase and other enzymes necessary to produce the rise (up to 40-fold) in the amount of stress ABA that is seen 2-3 h later. To test this hypothesis, a solution of (+)-[(2) H(6) ]ABA was vacuum infiltrated into unwilted Commelina leaves to mimic the rise in ABA caused by wilting and gas chromatography/mass spectrometry of the ABA in the extract after 3 h showed that concentrations of (+)-[(2) H(6) ]ABA of up to 0.3 μM stimulated synthesis of endogenous [(1) H]ABA by 15-fold in the unwilted leaves. A 0.5 μM solution blocked the increase in the amount of ABA formed and also reduced the amount of ABA formed in response to a 0.8 M mannitol solution.     

Three Classes of Abscisic Acid (ABA)-Insensitive Mutations of Arabidopsis Define Genes that Control Overlapping Subsets of ABA Responses

Wild type and three abscisic acid (ABA)-insensitive mutants of Arabidopsis (ABI1, ABI2, and ABI3) were compared for their ability to respond to ABA for a variety of ABA-inducible responses throughout the life cycle of the plants. The responses tested included effects on seedling growth, proline accumulation in seedlings, ABA-regulated protein synthesis in plantlets, and seed storage protein and lipid synthesis and accumulation. The abi1 and abi2 mutants showed reduced sensitivity to ABA for inhibition of seedling growth, induction of proline accumulation, and alterations in protein synthesis patterns during vegetative growth, but had wild type levels of storage reserves. In contrast, the abi3 mutant had wild type sensitivity for induction of proline accumulation and was only slightly less responsive to ABA with respect to effects on seedling growth and changes in patterns of protein synthesis. The major effects of this mutation were on seed development. Seeds of the abi3 mutant had two-thirds of the wild type level of storage protein and one-third the wild type level of eicosenoic acid, the major fatty acid component of storage lipids in wild type seeds. These results show that none of the abi mutants is insensitive for all ABA-inducible responses and that the abi3 effects are not seed-specific. Comparison of the degree of ABA sensitivity of monogenic mutant lines with that of digenic mutant lines carrying pairwise combinations of the abi mutations suggests that ABA responses in mature seeds are controlled by at least two parallel pathways.     

Effects of abscisic acid (ABA) and ABA analogs on freezing tolerance,low-temperature growth,and flowering in rapeseed

Brassica napus and B. campestris are grown in Western Canada in areas subject to unseasonable frosts. At the seedling stage, cultivars of Brassica are very sensitive to frosts of -2° to-5°C, which are either lethal or delay the development of the plant. Seedlings of B. napus and B. campestris, germinated and grown at 10°C (16-h photoperiod), were treated with a foliar spray of either 100 M racemic abscisic acid (ABA), 100 M of various ABA analogs, 0.1% acetone, or were untreated. Freeze tests indicated 2°C of frost tolerance could be gained in B. napus following an application of three ABA analogs. In B. campestris, three analogs also increased freezing tolerance approximately 1.5°C. The analogs 2,3 dihydro ABA and acetylenic divinyl methyl-ABA were effective in both species. Plant fresh weight and dry weight increased in treated plants relative to control or acetone-treated plants after 3 weeks at 10°C. The effect of frost and/or analog treatment on flowering was determined in both species. In B. campestris and B. napus, a mild frost advanced flowering by approximately 2 days compared with nonfrozen control plants. The promotive effect of frost on flowering decreased with increasing severity of the frost. Several of the analog treatments, particularly 2,3 dihydro ABA and acetylenic divinyl ABA, advanced flowering by 2–3 days in both species. The benefit of these ABA analog treatments on flowering was enhanced additionally by a mild frost. Plants treated with either ABA, 2,3 dihydro ABA, 2,3 acetylenic dihydro ABA, or acetylenic divinyl ABA flowered up to 5 days earlier than control plants.     

Effects of abscisic acid (ABA) on grain filling processes in wheat

The effect of in situ water stress on the endogenous abscisic acid (ABA) content of the endosperm and the in vitro application of ABA on some important yield regulating processes in wheat have been studied. Water stress resulted in a marked increase in the ABA content of the endosperm at the time close to cessation of growth. Application of ABA to the culture medium of detached ears reduced grain weight. Exogenously applied ABA, at the highest concentration (0.1 mM) reduced transport of sucrose into the grains and lowered the starch synthesis ability of intact grains. In vitro sucrose uptake and conversion by isolated grains was stimulated by low ABA concentrations (0.001 mM) in the medium but was inhibited by higher concentrations. ABA application had no effect on sucrose synthase (SS) and uridine diphosphate glucose pyrophosphorylase (UDP-Gppase) activities, whereas adenosine diphosphate glucose pyrophosphorylase (ADP-Gppase), soluble starch synthase (SSS), and granule-bound starch synthase (GBSS) activities were reduced. These results raise the possibility that water stress-induced elevated levels of endogenous ABA contribute to reduced grain growth.     

ABA consumption in norway spruce (Picea abies) and white spruce (Picea glauca) somatic embryo cultures

Summary We investigated abscisic acid (ABA) metabolism among Norway and white spruce somatic embryo cultures which exhibited differences in maturation response when placed on racemic abscisic acid [(±)-ABA]. Differences in metabolic rate among the spruce genotypes could affect the ABA pool available for the maturation process, and might therefore be responsible for the differences in maturation response. The production of cotyledonary (stage 3) somatic embryos in cultures (genotypes) of Norway spruce (PA86:26A and PA88:25B) and of white spruce (WS1F cryoD and WS46) was compared. In each species pair one of the two genotypes failed to show stage 3 embryo development (respectively, PA88:25B and WS46). The investigation of ABA metabolism of each species pair showed that no substantial differences in ABA consumption or in the production of metabolites occurred. In each case ABA was metabolized to phaseic acid and dihydrophaseic acid over the 42-day culture period, metabolites were recoverable from the agar-solidified medium, and the sum of residual ABA and metabolites were equivalent to the ABA initially supplied. The results indicate that the process of ABA metabolism occurs essentially independently of somatic embryo maturation. NRCC no. 37345.     

Structural Requirements of Abscisic Acid (ABA) and its Impact on Water Flow During Radial Transport of ABA Analogues Through Maize Roots

The effect of (+) (ABA) and (?)-abscisic acid and nine ABA metabolites, precursors or derivatives on radial water movement through maize roots, was investigated using a suction technique (Freundl and others 1998). (+)-ABA, (+)- and (?)-abscisyl aldehyde, (+)-8?-hydroxymethyl ABA, (+)-8?-methylene, and (+)-8?-acetylene ABA stimulated radial water transport. (?)-ABA, phaseic acid, and (+)-8?-acetylene methyl ABA were ineffective. ELISA analysis for ABA detected and apparent increase of free ABAxyl in xylem sap of excised root systems that were perfused with either (+)-abscisyl aldehyde, (+)-8?-methylene, (+)8?-acetylene-ABA, or ABA-glucose ester. The analogues (+)-8?-hydroxymethyl ABA and (?)-abscisyl aldehyde passed the cortex of maize roots without changing the ABAxyl. The data from this study permit conclusions about the structural requirements for hormonal regulation of hydraulic conductivity.     

Abscisic (ABA)-Aldehyde Is a Precursor to, and 1',4'-trans-ABA-Diol a Catabolite of, ABA in Apple

Previous ¹⁸O labeling studies of abscisic acid (ABA) have shown that apple (Malus domestica Borkh. cv Granny Smith) fruits synthesize a majority of [¹⁸O]ABA with the label incorporated in the 1′-hydroxyl position and unlabeled in the carboxyl group (JAD Zeevaart, TG Heath, DA Gage [1989] Plant Physiol 91: 1594-1601). It was proposed that exchange of ¹⁸O in the side chain with the medium occurred at an aldehyde intermediate stage of ABA biosynthesis. We have isolated ABA-aldehyde and 1′-4′-trans-ABA-diol (ABA-trans-diol) from ¹⁸O-labeled apple fruit tissue and measured the extent and position of ¹⁸O incorporation by tandem mass spectrometry. ¹⁸O-Labeling patterns of ABA-aldehyde, ABA-trans-diol, and ABA indicate that ABA-aldehyde is a precursor to, and ABA-trans-diol a catabolite of, ABA. Exchange of ¹⁸O in the carbonyl of ABA-aldehyde can be the cause of loss of ¹⁸O from the side chain of [¹⁸O]ABA. Results of feeding experiments with deuterated substrates provide further support for the precursor-product relationship of ABA-aldehyde → ABA → ABA-trans-diol. The ABA-aldehyde and ABA-trans-diol contents of fruits and leaves were low, approximately 1 and 0.02 nanograms per gram fresh weight for ABA-aldehyde and ABA-trans-diol, respectively, while ABA levels in fruits ranged from 10 to 200 nanograms per gram fresh weight. ABA biosynthesis was about 10-fold lower in fruits than in leaves. In fruits, the majority of ABA was conjugated to β-d-glucopyranosyl abscisate, whereas in leaves ABA was mainly hydroxylated to phaseic acid. Parallel pathways for ABA and trans-ABA biosynthesis and conjugation in fruits and leaves are proposed.     

Lateral ABA transport in maize roots (Zea mays): visualization by immunolocalization

The intensity of an ABA (abscisic acid) signal as a root-to-shoot signal, as well as its action on root hydraulic conductivity, strongly depends on the distribution of ABA during its radial transport across roots. Therefore ABA was visualized by immunolocalization with monoclonal ABA antibodies under conditions of lateral water flow induced by the application of a pressure gradient to the cut surface of the mesocotyl of maize seedlings. From the labelling of rhizodermis, hypodermis, cortical cells, and endodermis of roots of hydroponically (no exodermis) and aeroponically (with exodermis) grown seedlings it is concluded that the exodermis acts as a barrier to apoplastic transport that controls ABA uptake and efflux, but that the endodermis can easily be overcome via an apoplastic bypass. In longitudinal sections the strongest ABA signals originated from the root cap and the meristematic root tip, which is in agreement with the non-vacuolated cells of these tissues being an effective anion trap for ABA.