Jasmonate-induced gene expression of barley (Hordeum vulgare) leaves -- the link between jasmonate and abscisic acid

In barley leaves a group of genes is expressed in response to treatment with jasmonates and abscisic acid (ABA) [21]. One of these genes coding for a jasmonate-induced protein of 23 kDa (JIP-23) was analyzed to find out the link between ABA and jasmonates by recording its expression upon modulating independently, the endogenous level of both of them. By use of inhibitors of JA synthesis and ABA degradation, and the ABA-deficient mutant Az34, as well as of cultivar-specific differences, it was shown that endogenous jasmonate increases are necessary and sufficient for expression of this gene. The endogenous rise of ABA did not induce synthesis of JIP-23, whereas exogenous ABA did not act via jasmonates. Different signalling pathways are suggested and discussed.     

Isolation, characterization and expression of a cDNA coding for a jasmonate-inducible protein of 37 kDa in barley leaves

In barley leaves, there is a dramatic alteration of gene expression upon treatment with jasmonates leading to the accumulation of newly formed proteins, designated as jasmonate-inducible proteins (JIPs). In the present study, a new jasmonate-inducible cDNA, designated pHvJS37, has been isolated by differential screening of a γgt10 cDNA library constructed from mRNA of jasmonate-treated barley leaf segments. The open reading frame (ORF) encodes a 39-9 kDa polypeptide which cross-reacts with antibodies raised against the in vivo JIP-37. The hydropathic plot suggests that the protein is mainly hydrophilic, containing two hydrophilic domains near the C-terminus. Database searches did not show any sequence homology of pHv.JS37 to known sequences. Southern analysis revealed at least two genes coding for JIP-37 which map to the distal portion of the long arm of chromosome 3 and are closely related to genes coding for JIP-23. The expression pattern of the JIP-37 genes over time shows differential responses to jasmonate, abscisic acid (ABA), osmotic stress (such as sorbitol treatment) and desiccation stress. No expression was found under salt stress. From experiments using an inhibitor and intermediates of jasmonate synthesis such as α-linolenic acid and 12-oxophytodienoic acid, we hypothesize that there is a stress-induced lipid-based signalling pathway in which an endogenous rise of jasmonate switches on JIP-37 gene expression. Using immunocytochemical techniques, JIP-37 was found to be simultaneously located in the nucleus, the cytoplasm and the vacuoles.     

Endogenous abscisic acid levels are not linked to methyl jasmonate-promoted senescence of detached rice leaves

Both abscisic acid (ABA) and jasmonates are known to promote leaf senescence. Since ABA and jasmonates have both chemical and physiological similarities, we are interested to know whether senescence of detached rice leaves induced by methyl jasmonate (MJ) is mediated through an increase in endogenous ABA levels. In darkness, the endogenous level of ABA in detached rice leaves remained unchanged in the first day of incubation in water and increased about 5 times its initial value in the second day. However, the pattern of senescence, as judged by protein loss, was rapid during the first day. MJ significantly promoted senescence of detached rice leaves. Contrary to our expectation, endogenous ABA levels decreased in MJ-treated detached rice leaves. Similar to the effect of MJ, endogenous ABA levels decreased in detached rice leaves which were induced to senesce by treatment with NH₄Cl. These results suggest that endogenous ABA levels are not linked to MJ-induced senescence of detached rice leaves.     

Promotive effect of jasmonates on the senescence of detached maize leaves

Promotion of senescence of detached maize leaves by jasmonates was investigated. Senescence of detached maize leaves was promoted by linolenic acid, the precursor of biosynthesis of jasmonic acid, and retarded by inhibitors of lipoxygenase, the first enzyme in the biosynthetic pathway of jasmonic acid. Results support a role of endogenous jasmonates in the regulation of senescence of detached maize leaves. Silver thiosulfate, an inhibitor of ethylene action, was found to inhibit methyl jasmonate, linolenic acid- and abscisic acid-promoted senescence of detached maize leaves. It seems that jasmonate-promoted senescence is mediated through an increase in ethylene sensitivity in detached maize leaves.Abbreviations ABA abscisic acid - MJ methyl jasmonate - STS silver thiosulfate     

Occurrence and identification of jasmonic acid and its amino acid conjugates induced by osmotic stress in barley leaf tissue

The effect of osmotically active substances on the alteration of endogenous jasmonates was studied in barley (Hordeum vulgare L. cv. Salome) leaf tissue. Leaf segments were subjected to solutions of d-sorbitol, d-mannitol, polyethylene glycol 6000, sodium chloride, or water as a control. Alterations of endogenous jasmonates were monitored qualitatively and quantitatively using immunoassays. The structures of jasmonates isolated were determined on the basis of authentic substances by capillary gas chromatography-mass spectrometry. The stereochemistry of the conjugates was confirmed by high performance liquid chromatography with diastereoisomeric references. In barley leaves, jasmonic acid and its amino acid conjugates, for example, with valine, leucine, and isoleucine, are naturally occurring jasmonates. In untreated leaf segments, only low levels of these native jasmonates were found. After treatment of the leaf tissues with sorbitol, mannitol, as well as with polyethylene glycol, an increase of both jasmonic acid and its conjugates could be observed, depending on the stress conditions used. In contrast, salt stress was without any stimulating effect on the levels of endogenous jasmonates. From barley leaf segments exposed to sorbitol (1m) for 24 h, jasmonic acid was identified as the major accumulating compound. Jasmonic acid-amino acid conjugates increased likewise upon stress treatment.Abbreviations JM methyl jasmonate - JA jasmonic acid - JIP(s) jasmonate-induced protein(s) - PEG polyethylene glycol - RIA radioimmunoassay - ELISA enzyme-linked immunosorbent assay - HPLC high performance liquid chromatography - GC-MS gas chromatography-mass spectrometry - R _t retention time - IAA indole-3-acetic acid     

Jasmonic acid,polyamine, and antioxidant levels in apple seedlings as affected by Ultraviolet-C irradiation

The effect of UV-C irradiation on jasmonates, abscisic acid (ABA), polyamines and antioxidant activities was investigated in apple plants (Malus domestica Borkh.). The EC₅₀ values of O₂ ^–-scavenging activity in the UV-C treated leaves were lower than those in the untreated control. In addition, total ascorbic acid and polyphenolic concentrations in the UV-C treated leaves were generally higher than those in the untreated control. Although the endogenous ABA concentrations were not significantly different between the untreated control and UV-C treatment, the endogenous jasmonic acid, putrescine, and spermine concentrations in the UV-C treated plants were higher than those in the untreated control. However, the application of PDJ before UV treatment inhibited the rise of endogenous jasmonate and putrescine concentrations. The increase of ascorbic acid was also inhibited by PDJ application before UV treatment. These facts suggest that the increase of jasmonates and polyamines may be associated with UV-C stimulation, and UV-C irradiation may be effective for increasing antioxidant activity in apple leaves.     

Interaction of c-Jun amino-terminal kinase interacting protein-1 with p190 rhoGEF and its localization in differentiated neurons

c-Jun amino-terminal kinase (JNK) interacting protein-1 (JIP-1) was originally identified as a cytoplasmic inhibitor of JNK. More recently, JIP-1 was proposed to function as a scaffold protein by complexing specific components of the JNK signaling pathway, namely JNK, mitogen-activated protein kinase kinase 7, and mixed lineage kinase 3. We have identified the human homologue of JIP-1 that contains a phosphotyrosine binding (PTB) domain in addition to a JNK binding domain and an Src homology 3 domain. To identify binding targets for the hJIP-1 PTB domain, a mouse embryo cDNA library was screened using the yeast two-hybrid system. One clone encoded a 191-amino acid region of the neuronal protein rhoGEF, an exchange factor for rhoA. Overexpression of rhoGEF promotes cytoskeletal rearrangement and cell rounding in NIE-115 neuronal cells. The interaction of JIP-1 with rhoGEF was confirmed by coimmunoprecipitation of these proteins from lysates of transiently transfected HEK 293 cells. Using glutathione S-transferase rhoGEF fusion proteins containing deletion or point mutations, we identified a putative PTB binding site within rhoGEF. This binding site does not contain tyrosine, indicating that the JIP PTB domain, like that of Xll alpha and Numb, binds independently of phosphotyrosine. Several forms of endogenous JIP-1 protein can be detected in neuronal cell lines. Indirect immunofluorescence analysis localized endogenous JIP-1 to the tip of the neurites in differentiated NIE-115 and PC12 cells. The interaction of JIP-1 with rhoGEF and its subcellular localization suggests that JIP-1 may function to specifically localize a signaling complex in neuronal cells.     

Regulation of tobacco lipoxygenase by methyl jasmonate and fatty acids

Lipoxygenase (LOX) activity and gene expression have been described previously to be induced in tobacco by fungal infection and elicitor treatment. We now report that LOX activity is induced in tobacco cell suspensions by treatment with methyl jasmonate (MeJa). This compound had no effect on the in vitro activity of tobacco LOX. Induction of LOX activity is a dose-dependent response with a maximum around 890 μM MeJa. Linolenic acid, the precursor for jasmonate synthesis, also induces LOX activity. When applied together with fungal elicitor, linolenic acid drastically increases and prolongs the induction of LOX activity. LOX activity and gene expression in elicited tobacco cells are partially inhibited by pretreatment with eicosatetraynoic acid (ETYA), a potent inhibitor of tobacco LOX in vitro. The induction by methyl jasmonate, in contrast, was not inhibited by ETYA pretreatment. These data suggest that induction of LOX gene expression and activity upon elicitation are regulated at least partially by LOX products. © Académie des Sciences/ Elsevier, Paris     

Lipoxygenase6-Dependent Oxylipin Synthesis in Roots Is Required for Abiotic and Biotic Stress Resistance of Arabidopsis

Jasmonates are oxylipin signals that play important roles in the development of fertile flowers and in defense against pathogens and herbivores in leaves. The aim of this work was to understand the synthesis and function of jasmonates in roots. Grafting experiments with a jasmonate-deficient mutant demonstrated that roots produce jasmonates independently of leaves, despite low expression of biosynthetic enzymes. Levels of 12-oxo-phytodienoic acid, jasmonic acid, and its isoleucine derivative increased in roots upon osmotic and drought stress. Wounding resulted in a decrease of preformed 12-oxo-phytodienoic acid concomitant with an increase of jasmonic acid and jasmonoyl-isoleucine. 13-Lipoxygenases catalyze the first step of lipid oxidation leading to jasmonate production. Analysis of 13-lipoxygenase-deficient mutant lines showed that only one of the four 13-lipoxygenases, LOX6, is responsible and essential for stress-induced jasmonate accumulation in roots. In addition, LOX6 was required for production of basal 12-oxo-phytodienoic acid in leaves and roots. Loss-of-function mutants of LOX6 were more attractive to a detritivorous crustacean and more sensitive to drought, indicating that LOX6-derived oxylipins are important for the responses to abiotic and biotic factors.Oxylipins are ubiquitous signaling molecules that are derived from polyunsaturated fatty acids by enzymatic and nonenzymatic processes. In plants, the biosynthesis and function of oxylipins of the jasmonate family in aboveground tissues has been investigated in detail. Jasmonates comprise 12-oxo-phytodienoic acid (OPDA), jasmonic acid (JA), and derivatives of JA. In leaves, jasmonates accumulate in response to abiotic factors such as wounding, drought, osmotic stress, darkness, and ozone and during interactions with organisms such as herbivores, pathogens, and mutualistic organisms (Wasternack, 2007). The relevance of jasmonates in wound response, ozone tolerance, and the defense against herbivores and necrotrophic pathogens in leaves has been well investigated using mutants in JA biosynthesis and signaling (Browse, 2009a). In addition, jasmonates play an important role in flower development, and Arabidopsis (Arabidopsis thaliana) mutants in the JA pathway are male sterile (Browse, 2009b). The first step in jasmonate biosynthesis is catalyzed by 13-lipoxygenases (LOXs). The resulting 13(S)-hydroperoxyoctadecatrienoic acid (13-HPOTE) is converted by allene oxide synthase (AOS) and allene oxide cyclase to OPDA (Wasternack, 2007). These enzymatic steps are located in plastids. OPDA is transported to peroxisomes and converted to JA. JA can be further metabolized to different derivatives that take place mainly in the cytosol. The conjugation of JA with Ile is an important step because jasmonoyl-Ile (JA-Ile) has been identified as a biologically active jasmonate (Staswick and Tiryaki, 2004). OPDA is also biologically active without conversion to JA derivatives. In contrast to all other jasmonates, the OPDA structure contains an electrophilic α,β-unsaturated carbonyl group that renders OPDA more reactive than JA. Therefore, OPDA is classified as a reactive electrophile species with unique signaling properties different from other jasmonates (Farmer and Davoine, 2007).Of the six lipoxygenase genes present in Arabidopsis, four genes encode 13-LOX. For the respective enzymes LOX2, LOX3, LOX4, and LOX6, it was shown that linolenic acid is the preferred substrate and that 13-HPOTE is formed in vitro (Bannenberg et al., 2009). All four enzymes are proposed to be located in plastids. LOX2 is highly expressed in leaves; expression is up-regulated by jasmonates and stress treatments such as wounding and osmotic stress (Bell and Mullet, 1993; Seltmann et al., 2010a). LOX2 was shown to contribute the majority of jasmonate synthesis upon wounding and osmotic stress and during senescence in leaves (Bell et al., 1995; Glauser et al., 2009). LOX2 is also responsible for the accumulation of arabidopsides (Glauser et al., 2009), which are galactolipids containing esterified OPDA in plastids by direct oxidation of galactolipids (Zoeller et al., 2012). LOX3 and LOX4 are required for the development of fertile flowers (Caldelari et al., 2011). LOX6 shows overall low expression (Bannenberg et al., 2009). Recently, it was reported that LOX6 contributes to the fast accumulation of JA and JA-Ile in wounded leaves and is required for the fast increase of JA and JA-Ile in distal leaves after wounding (Chauvin et al., 2013).In contrast to leaves and flowers, little is known on jasmonate biosynthesis and function in roots. Expression of the plastid-localized enzymes of jasmonate synthesis LOX2, AOS, and allene oxide cyclase2 is very low in roots (Zimmermann et al., 2004). By contrast, enzymes such as 9-LOX and α-dioxygenase1 are strongly expressed in roots. These enzymes are involved in the biosynthesis of oxylipins different from jasmonates, and 9-LOX products have been shown to regulate lateral root development because mutants in LOX1 and LOX5 produce more lateral roots (Vellosillo et al., 2007). However, jasmonate function in roots is still obscure. Here, we analyzed jasmonate accumulation in roots upon different stress treatments and show that mutants defective in LOX6 are impaired in stress-induced jasmonate synthesis and are more susceptible to drought and detritivore feeding.     

Metabolic profiling of oxylipins upon sorbitol treatment in barley leaves

In barley leaves 13-lipoxygenases (LOXs) are induced by salicylate and jasmonate. Here, we analyse by metabolic profiling the accumulation of oxylipins upon sorbitol treatment. Although 13-LOX-derived products are formed and specifically directed into the reductase branch of the LOX pathway, accumulation is much later than in the cases of salicylate and jasmonate treatment. In addition, under these conditions only the accumulation of jasmonates as additional products of the LOX pathway has been found.     

Coordinated activation of metabolic pathways for antioxidants and defence compounds by jasmonates and their roles in stress tolerance in Arabidopsis

Jasmonic acid (JA) and methyl jasmonate (MeJA), collectively termed jasmonates, are ubiquitous plant signalling compounds. Several types of stress conditions, such as wounding and pathogen infection, cause endogenous JA accumulation and the expression of jasmonate-responsive genes. Although jasmonates are important signalling components for the stress response in plants, the mechanism by which jasmonate signalling contributes to stress tolerance has not been clearly defined. A comprehensive analysis of jasmonate-regulated metabolic pathways in Arabidopsis was performed using cDNA macroarrays containing 13516 expressed sequence tags (ESTs) covering 8384 loci. The results showed that jasmonates activate the coordinated gene expression of factors involved in nine metabolic pathways belonging to two functionally related groups: (i) ascorbate and glutathione metabolic pathways, which are important in defence responses to oxidative stress, and (ii) biosynthesis of indole glucosinolate, which is a defence compound occurring in the Brassicaceae family. We confirmed that JA induces the accumulation of ascorbate, glutathione and cysteine and increases the activity of dehydroascorbate reductase, an enzyme in the ascorbate recycling pathway. These antioxidant metabolic pathways are known to be activated under oxidative stress conditions. Ozone (O3) exposure, a representative oxidative stress, is known to cause activation of antioxidant metabolism. We showed that O3 exposure caused the induction of several genes involved in antioxidant metabolism in the wild type. However, in jasmonate-deficient Arabidopsis 12-oxophytodienoate reductase 3 (opr3) mutants, the induction of antioxidant genes was abolished. Compared with the wild type, opr3 mutants were more sensitive to O3 exposure. These results suggest that the coordinated activation of the metabolic pathways mediated by jasmonates provides resistance to environmental stresses.     

Jasmonoyl isoleucine accumulation is needed for abscisic acid build‐up in roots of Arabidopsis under water stress conditions

Phytohormones are central players in sensing and signalling numerous environmental conditions like drought. In this work, hormone profiling together with gene expression of key enzymes involved in abscisic acid (ABA) and jasmonate biosynthesis were studied in desiccating Arabidopsis roots. Jasmonic acid (JA) content transiently increased after stress imposition whereas progressive and concomitant ABA and Jasmonoyl Isoleucine (JA‐Ile) accumulations were detected. Molecular data suggest that, at least, part of the hormonal regulation takes place at the biosynthetic level. These observations also point to a possible involvement of jasmonates on ABA biosynthesis under stress. To test this hypothesis, mutants impaired in jasmonate biosynthesis (opr3, lox6 and jar1‐1) and in JA‐dependent signalling (coi1) were employed. Results showed that the early JA accumulation leading to JA‐Ile build up was necessary for an ABA increase in roots under two different water stress conditions. Signal transduction between water stress‐induced JA‐Ile accumulation and COI1 is necessary for a full induction of the ABA biosynthesis pathway and subsequent hormone accumulation in roots of Arabidopsis plants. The present work adds a level of interaction between jasmonates and ABA at the biosynthetic level.     

Changes in membrane permeability and mineral,phytohormone and polypeptide composition in rice suspension cells during growth and under the influence of the growth retardant tetcyclacis

The plant growth retardant tetcyclacis inhibits cell division growth in rice suspension cultures at concentrations above 10^–6 M. Tracer experiments with rice cells revealed that tetcyclacis reduced the incorporation of mevalonic acid into terpenoids after 30 min, the uptake of leucine, uridine and thymidine after 2 h and their incorporation into the corresponding macromolecules after 3–7 h. The changes in membrane permeability concluded to have been caused by an influence on phytosterol biosynthesis are probably also the explanation for alterations of tetcyclacis-treated cells in the content of macro- and microelements.As shown by immunoassay, tetcyclacis did not modify the levels of endogenous gibberellins (Grossmann et al. 1985), cytokinins and indole acetic acid during a growth cycle of 15 d. However, a clear rise in the abscisic acid (ABA) level occurred during the first 5 d of treatment. In untreated cells such a rise coincided only with the aging of the cell culture in the stationary growth phase. Investigations of the cell polypeptide pattern using sodium dodecyl sulphate-polyacrylamide gel electrophoresis showed that the ABA increase following tetcyclacis treatment seems not to be a consequence of advanced cell aging.Abbreviations IAA indole-3-acetic acid - IP isopentenyladenine - ABA abscisic acid     

Tendril Coiling in Grapevine: Jasmonates and a New Role for GABA?

Grapevine (Vitis vinifera L., Vitaceae) belongs to the genus Vitis, and is characterized as a vine due to the presence of tendrils, which are located opposite to leaves. Tendrils are thigmo-responsive organs, able to carry out delicate mechanosensory responses upon touch and related stimuli. These organs are an adaptation of the plant to climb with the help of support to higher places and finally remain at a position with favorable light quality. In previous studies on Bryonia dioica (Cucurbitaceae), phytohormones of the jasmonate class were identified as the endogenous hormone signals to initiate coiling of the tendrils. Strikingly, this is still the only example for jasmonate-induced tendril coiling. In grapevine, three compounds (12-oxo-phytodienoic acid, jasmonic acid (JA), and JA isoleucine conjugate) of the jasmonate class were found at higher concentrations in non-coiled tendrils when compared with coiled ones. Upon treatment with phytohormones, we could confirm the activity of jasmonates on tendril coiling in grapevine. However, not jasmonates but a non-proteinogenic amino acid, γ-aminobutyric acid (GABA), was detected to accumulate in grapevine tendrils at significantly higher levels than in all other tissues, independent of their coiling status. For GABA we detected a significant, transient positive effect on tendril coiling. Use of a GABA synthesis blocker, 3-mercaptopropionic acid, caused reduced GABA- but not JA-induced coiling scores. No additive effect of JA plus GABA was detectable on the tendrils’ coiling score. Thus, for grapevine, our data demonstrate a strong activity of jasmonates in tendril coiling induction even without mechanical stimuli and, furthermore, the data also suggest that GABA can independently promote tendril coiling.

     

A role for jasmonates in climacteric fruit ripening

Jasmonates are a class of oxylipins that induce a wide variety of higher-plant responses. To determine if jasmonates play a role in the regulation of climacteric fruit ripening, the effects of exogenous jasmonates on ethylene biosynthesis and color, as well as the endogenous concentrations of jasmonates were determined during the onset of ripening of apple (Malus domestica Borkh. cv. Golden Delicious) and tomato (Lycopersicon esculentum Mill. cv. Cobra) fruit. Transient (12 h) treatment of pre-climacteric fruit discs with exogenous jasmonates at low concentration (1 or 10 μM) promoted ethylene biosynthesis and color change in a concentration-dependent fashion. Activities of both 1-aminocyclopropane-1-carboxylic acid (ACC) oxidase and ACC synthase were stimulated by jasmonate treatments in this concentration range. The endogenous concentration of jasmonates increased transiently prior to the climacteric increase in ethylene biosynthesis during the onset of ripening of both apple and tomato fruit. The onset of tomato fruit ripening was also preceded by an increase in the percentage of the cis-isomer of jasmonic acid. Inhibition of ethylene action by diazocyclopentadiene negated the jasmonate-induced stimulation of ethylene biosynthesis, indicating jasmonates act at least in part via ethylene action. These results suggest jasmonates may play a role together with ethylene in regulating the early steps of climacteric fruit ripening. Received: 14 August 1997 / Accepted: 4 October 1997     

Identification of jasmonic acid and its methyl ester as gum-inducing factors in tulips

The purpose of this study was to identify endogenous factors that induce gummosis and to show their role in gummosis in tulip (Tulipa gesneriana L. cv. Apeldoorn) stems. Using procedures to detect endogenous factors that induce gum in the stem of tulips, jasmonic acid (JA) and methyl jasmonate (JA-Me) were successfully identified using gas–liquid chromatography–mass spectrometry. Total amounts of JA and JA-Me designated as jasmonates in tulip stems were also estimated at about 70–80 ng/g fresh weight, using deuterium-labeled jasmonates as internal standards. The application of JA and JA-Me as lanolin pastes substantially induced gums in tulip stems with ethylene production. The application of ethephon, an ethylene-generating compound, however, induced no gummosis although it slightly affected jasmonate content in tulip stems. These results strongly suggest that JA and JA-Me are endogenous factors that induce gummosis in tulip stems.     

Abscisic acid biosynthesis during corn embryo development

In this study we examined the biosynthesis of abscisic acid (ABA) by developing corn (Zea mays L.) embryos. Three comparisons were made: ABA biosynthesis in embryos isolated from kernels grown in vitro with those grown in the field; the developmental profile of ABA content with that of biosynthesis; and ABA biosynthesis in corn embryos lacking carotenoid precursors with ABA biosynthesis in normal embryos. Embryos were harvested at various times during seed development and divided into two groups. Endogenous levels of ABA were measured in one group of embryos and ABA biosynthetic capacity was measured in the other group. The ABA biosynthetic capacity was measured with and without tetcyclacis (an inhibitor of ABA degradation) in embryos from both field-grown and in-vitro-grown corn kernels. Reduced-carotenoid (either fluridone-treated or genetically viviparous) embryos were also included in the study. Corn kernels developing under field and in-vitro conditions differed from each other in their responses to tetcyclacis and in their profiles of ABA biosynthesis during development. Therefore, in-vitro kernel culture may not be an appropriate substitute for field conditions for studies of embryo development. The developmental profiles of endogenous ABA content differed from those of ABA biosynthesis in isolated embryos of both in-vitro-and field-grown kernels. This indicated that ABA levels in the developing embryos were determined by import from the maternal tissues available to the embryos rather than by in-situ biosynthesis. In embryos with reduced levels of carotenoids, either fluridone-treated or genetically viviparous embryos, ABA biosynthesis was low or nonexistent. This result is expected for the presence of an indirect pathway of ABA biosynthesis and in the absence of ABA precursors.Abbreviations ABA abscisic acid - DAP days after pollination