AtAGP30, an arabinogalactan-protein in the cell walls of the primary root, plays a role in root regeneration and seed germination

Arabinogalactan-proteins (AGPs) are extracellular proteoglycans that are implicated in many plant growth and developmental processes, but in no case has a biological function been assigned to a particular AGP. AtAGP30 is a non-classical AGP core protein from Arabidopsis that is expressed only in roots. Analysis of the corresponding mutant, agp30, has revealed that the wild-type gene product is required in vitro for root regeneration and in planta for the timing of seed germination. The mutant shows a suppression of the abscisic acid (ABA)-induced delay in germination and altered expression of some ABA-regulated genes. This suggests that AtAGP30 functions in the ABA response. By analogy to proteoglycan-mediated regulation of growth-factor-signalling pathways in animals, our data indicate that phytohormone activity in plants can be modulated by AGPs.     

Involvement of plasma-membrane NADPH oxidase in abscisic acid- and water stress-induced antioxidant defense in leaves of maize seedlings

The roles of the plasma-membrane (PM) NADPH oxidase in abscisic acid (ABA)- and water stress-induced antioxidant defense were investigated in leaves of maize ( Zea mays L.) seedlings. Treatment by exogenous ABA (100 micro M ABA) or osmotic stress (-0.7 MPa induced by polyethylene glycol) significantly increased the activity of the PM NADPH oxidase, the production of leaf O(2)(-), the activities of several antioxidant enzymes (superoxide dismutase, catalase, ascorbate peroxidase and glutathione reductase), and the contents of antioxidant metabolites (ascorbate and reduced glutathione). Pretreatment with three different inhibitors of NADPH oxidase (diphenylene iodonium, imidazole and pyridine) or an inhibitor of ABA biosynthesis (tungstate) reduced the increase in the activity of the PM NADPH oxidase and the production of leaf O(2)(-), and the capacity of antioxidant defense systems mediated by ABA. The inhibitory effects above caused by tungstate were reversed by exogenous ABA. These data indicate that NADPH oxidase is involved in the ABA-induced production of active oxygen species (AOS), and our results depict a minimal chain of events initiated by water stress-induced ABA accumulation, which then triggers the production of AOS by membrane-bound NADPH oxidase, resulting in the induction of antioxidant defense systems against oxidative damage in plants.     

ABA metabolites induce group 3 LEA mRNA and inhibit germination in wheat

In plants, metabolism of the plant hormone (+)- S -abscisic acid (ABA) occurs by oxidation at the 8'-carbon on the ABA ring, producing (+)-8'-hydroxy-ABA (8'OH-ABA), which undergoes ring closure to phaseic acid (PA), or at the 7'-carbon producing 7'-hydroxy-ABA (7'OH-ABA). New methods for synthesixing and stabilizing 8'OH-ABA have enabled us for the first time to compare the biological activities of the ABA metabolites. 8'OH-ABA. PA and 7'OH-ABA. Activities were determined in wheat ( Triticum aestivum , cvs Brevor and Clarks Cream) using optically pure natural enantiomers of ABA. 8'OH-ABA, PA, and 7'OH-ABA. Comparison of wheat embryo germination inhibitory activity showed that only the metabolite 7'OH-ABA had significant activity (10 to 40% of effective ABA activity) as a germination inhibitor of wheat embryos. The metabolites had differential effects on ABA-responsive gene expression. Both 8'OH-ABA and PA were effective inducers of an ABA-responsive LEA (late embryogenesis abundant) gene, wheat group 3 LEA , in seedling roots, suggesting that ABA metabolites can maintain and prolong LEA gene expression. The metabolites had only a slight effect on accumulation of an ABA-responsive protein kinase ( PKABA1 ) mRNA or pMA1951 . These results are consistent with the idea that there are several control points in the ABA metabolic pathway and indicate that assessment of ABA signalling responses should include consideration of the biological activities of ABA metabolites.     

8[prime]-Methylene Abscisic Acid (An Effective and Persistent Analog of Abscisic Acid)

We report here the synthesis and biological activity of a new persistent abscisic acid (ABA) analog, 8[prime]-methylene ABA. This ABA analog has one additional carbon atom attached through a double bond to the 8[prime]-carbon of the ABA molecule. (+)-8[prime]-Methylene ABA is more active than the natural hormone (+)-ABA in inhibiting germination of cress seed and excised wheat embryos, in reducing growth of suspension-cultured corn cells, and in reducing transpiration in wheat seedlings. The (+)-8[prime]-methylene analog is slightly weaker than (+)-ABA in increasing expression of ABA-inducible genes in transgenic tobacco, but is equally active in stimulating a transient elevation of the pH of the medium of corn cell cultures. In corn cells, both (+)-ABA and (+)-8[prime]-methylene ABA are oxidized at the 8[prime] position. ABA is oxidized to phaseic acid and (+)-8[prime]-methylene ABA is converted more slowly to two isomeric epoxides. The alteration in the ABA structure causes the analog to be metabolized more slowly than ABA, resulting in longer-lasting and more effective biological activity relative to ABA.     

Improved development of microspore-derived embryo cultures of Brassica napus cv Topaz following changes in glutathione metabolism

Glutathione has been shown to play an important role during embryo development in both plant and animal systems. The effects of altered glutathione metabolism during microspore-derived embryos (MDEs) of Brassica napus were investigated following exogenous application of reduced glutathione (GSH), its oxidized form (GSSG) and buthionine sulfoximine (BSO), an inhibitor of glutathione de novo synthesis. Applications of BSO which lowered the cellular glutathione redox status, i.e. GSH/(GSH + GSSG), enhanced significantly the quality of the embryos and their ability to convert into viable plants. Histological analyses revealed that inclusions of BSO in the culture medium altered the pattern of storage product accumulation in the embryos and improved the architecture of the shoot apical meristems (SAMs). Compared with their control counterparts which showed severe signs of SAM deterioration, such as the formation of intercellular spaces and differentiation of the meristematic cells, BSO-treated embryos had well-organized SAMs. The improved SAM organization observed in the presence of BSO also correlated with the proper localization pattern of WUSCHEL , a SAM molecular marker gene which was miss-expressed in control embryos. The beneficial effects of BSO on embryo development and conversion were ascribed to the increasing levels of ABA. The concentration of this growth regulator in BSO-treated embryos was always higher than that of control embryos during the second half of the maturation period. Furthermore, many structural alterations induced by BSO could be reproduced in embryos cultured in the presence of ABA. Taken together, these results suggest that a lowering of the glutathione redox status during embryo development may represent a metabolic switch needed for increasing the endogenous levels of ABA, which is required for successful completion of the developmental program.     

Use of the glucosyltransferase UGT71B6 to disturb abscisic acid homeostasis in Arabidopsis thaliana

A glucosyltransferase (GT) of Arabidopsis, UGT71B6, recognizing the naturally occurring enantiomer of abscisic acid (ABA) in vitro, has been used to disturb ABA homeostasis in planta. Transgenic plants constitutively overexpressing UGT71B6 (71B6-OE) have been analysed for changes in ABA and the related ABA metabolites abscisic acid glucose ester (ABA-GE), phaseic acid (PA), dihydrophaseic acid (DPA), 7'-hydroxyABA and neo-phaseic acid. Overexpression of the GT led to massive accumulation of ABA-GE and reduced levels of the oxidative metabolites PA and DPA, but had marginal effect on levels of free ABA. The control of ABA homeostasis, as reflected in levels of the different metabolites, differed in the 71B6-OEs whether the plants were grown under standard conditions or subjected to wilt stress. The impact of increased glucosylation of ABA on ABA-related phenotypes has also been assessed. Increased glucosylation of ABA led to phenotypic changes in post-germinative growth. The use of two structural analogues of ABA, known to have biological activity but to differ in their capacity to act as substrates for 71B6 in vitro, confirmed that the phenotypic changes arose specifically from the increased glucosylation caused by overexpression of 71B6. The phenotype and profile of ABA and related metabolites in a knockout line of 71B6, relative to wild type, has been assessed during Arabidopsis development and following stress treatments. The lack of major changes in these parameters is discussed in the context of functional redundancy of the multigene family of GTs in Arabidopsis.     

Biochemical characterization of the aba2 and aba3 mutants in Arabidopsis thaliana.

Abscisic acid (ABA)-deficient mutants in a variety of species have been identified by screening for precocious germination and a wilty phenotype. Mutants at two new loci, aba2 and aba3, have recently been isolated in Arabidopsis thaliana (L.) Hynh. (K.M. Léon-Kloosterziel, M. Alvarez-Gil, G.J. Ruijs, S.E. Jacobsen, N.E. Olszewski, S.H. Schwartz, J.A.D. Zeevaart, M. Koornneef [1996] Plant J 10: 655-661), and the biochemical characterization of these mutants is presented here. Protein extracts from aba2 and aba3 plants displayed a greatly reduced ability to convert xanthoxin to ABA relative to the wild type. The next putative intermediate in ABA synthesis, ABA-aldehyde, was efficiently converted to ABA by extracts from aba2 but not by extracts from aba3 plants. This indicates that the aba2 mutant is blocked in the conversion of xanthoxin to ABA-aldehyde and that aba3 is impaired in the conversion of ABA-aldehyde to ABA. Extracts from the aba3 mutant also lacked additional activities that require a molybdenum cofactor (Moco). Nitrate reductase utilizes a Moco but its activity was unaffected in extracts from aba3 plants. Moco hydroxylases in animals require a desulfo moiety of the cofactor. A sulfido ligand can be added to the Moco by treatment with Na2S and dithionite. Treatment of aba3 extracts with Na2S restored ABA-aldehyde oxidase activity. Therefore, the genetic lesion in aba3 appears to be in the introduction of S into the Moco.     

Competitive Inhibition of Abscisic Acid-Regulated Gene Expression by Stereoisomeric Acetylenic Analogs of Abscisic Acid

The properties of two enantiomeric synthetic acetylenic abscisic acid (ABA) analogs (PBI-51 and PBI-63) in relation to ABA-sensitive gene expression are reported. Using microspore-derived embryos of Brassica napus as the biological material and their responsiveness to ABA in the expression of genes encoding storage proteins as a quantitative bioassay, we measured the biological activity of PBI-51 and PBI-63. Assays to evaluate agonistic activity of either compound applied individually showed a dose-dependent increase in napin gene expression on application of PBI-63. Maximal activity of about 40 [mu]M indicated that PBI-63 was an agonist, although somewhat weaker than ABA. PBI-63 has a similar stereochemistry to natural ABA at the junction of the ring and side chain. In contrast, PBI-51 showed no agonistic effects until applied at 40 to 50 [mu]M. Even then, the response was fairly weak. PBI-51 has the opposite stereochemistry to natural ABA at the junction of the ring and side chain. When applied concurrently with ABA, PBI-63 and PBI-51 had distinctly different properties. PBI-63 (40 [mu]M) and ABA (5 [mu]M) combined gave results similar to the application of either compound separately with high levels of induction of napin expression. PBI-51 displayed a reversible antagonistic effect with ABA, shifting the typical ABA dose-response curve by a factor of 4 to 5. This antagonism was noted for the expression of two ABA-sensitive genes, napin and oleosin. To test whether this antagonism was at the level of ABA recognition or uptake, ABA uptake was monitored in the presence of PBI-51 or PBI-63. Neither compound decreased ABA uptake. Treatments with either PBI-51 or PBI-63 showed an effect on endogenous ABA pools by permitting increases of 5- to 7-fold. It is hypothesized that this increase occurs because of competition for ABA catabolic enzymes by both compounds. The fact that ABA pools did not decrease in the presence of PBI-51 suggests that PBI-51 must exert its antagonistic properties through direct competition with ABA at a hormone-recognition site.     

NADK3, a novel cytoplasmic source of NADPH, is required under conditions of oxidative stress and modulates abscisic acid responses in Arabidopsis

In plants, excess reactive oxygen species are toxic molecules induced under environmental stresses, including pathogen invasions and abiotic stresses. Many anti-oxidant defense systems have been reported to require NADPH as an important reducing energy equivalent. However, the sources of NADPH and the molecular mechanisms of maintaining cytoplasmic redox balance are unclear. Here, we report the biological function of a putative cytoplasmic NADH kinase (NADK3) in several abiotic stress responses in Arabidopsis. We found that cytoplasmic NADPH is provided mostly by the product of the NADK3 gene in Arabidopsis. Expression of he NADK3 gene is responsive to abscisic acid (ABA) and abiotic stress conditions, including methyl violgen (MV), high salinity and osmotic shock. An NADK3 null mutant showed hypersensitivity to oxidative stress in both seed germination and seedling growth. Seed germination of the mutant plants also showed increased sensitivity to ABA, salt and mannitol. Furthermore, stress-related target genes were identified as upregulated in the mutant by mannitol and MV. Our study indicates that this cytoplasmic NADH kinase, a key source of the cellular reductant NADPH, is required for various abiotic stress responses.     

Evalution of toxicity of abcisic acid and gibberellic acid in rats: 50 days drinking water study

In the present study, the influence of subchronic effects of two plant growth regulators (PGRs) [Abcisic acid (ABA) and Gibberellic acid (GA3)] on antioxidant defense systems [reduced glutathione (GSH), glutathione reductase (GR), superoxide dismutase (SOD), glutathione-S-transferase (GST) and catalase (CAT)] and lipid peroxidation level (malondialdehyde = MDA) in various tissues of the rat were investigated during treatment as a drinking water model. 75 ppm of ABA and GA3 in drinking water were continuously administered orally to rats (Sprague-Dawley albino) ad libitum for 50 days. The PGRs treatments caused different effects on the antioxidant defense systems and MDA content of dosed rats compared to controls. The lipid peroxidation end product MDA significantly increased in the lungs, heart and kidney of rats treated with GA3 without significant change in the spleen. ABA caused also a significant increase in MDA content in the spleen, lungs, heart and kidney. The GSH levels were significantly depleted in the spleen, lungs and stomach of rats treated with ABA without any change in the tissues of rats treated with GA3 except the kidney where it increased. Antioxidant enzyme activities such as SOD significantly increased in the lungs and stomach and decreased in the spleen and heart tissues of rats treated with GA3. Meanwhile, SOD significantly decreased in the spleen, heart and kidney and increased in the lungs of rats treated with ABA. While CAT activity significantly decreased in the lungs of rats treated with GA3, a significant increase occurred in the heart of rats treated with both PGRs. On the other hand, the ancillary enzyme GR activity in the tissues were either significantly depleted or not changed with PGRs treatment. The drug metabolizing enzyme GST activity significantly decreased in the lungs of rats treated with ABA but increased in the stomach of rats treated with both PGRs. As a conclusion, the rats resisted oxidative stress via the antioxidant mechanism. But the antioxidant mechanism could not prevent the increases in lipid peroxidation in rat's tissues. This data, along with changes, suggests that PGRs produced substantial systemic organ toxicity in the spleen, lungs, stomach, heart and kidney during a 50-day period of subchronic exposure.     

Electrolytic reduction of abscisic acid methyl ester and its free acid

Abscisic acid (ABA, 1), a plant hormone, has electrophilicity derived almost entirely from the side-chain, 3-methylpenta-2,4-dienoic acid. The electrochemical property of ABA was investigated by analysis of its cathodic reaction. ABA methyl ester (1-Me) was reduced at a peak potential of −1.6 V to give a unique and unstable bicyclic compound (5-Me) as a major product at pH 3 and 7. This finding showed that an electron was absorbed in the conjugated dienecarboxyl group, and that C-5 with a high electron density attacked C-2′ through an intramolecular nucleophilic addition. At pH 10, in addition to 5-Me, a compound 4-Me was formed by isomerization of 5-Me under alkaline conditions. For a cathodic reaction of ABA at pH 3 and 7, compound 5 was a major product as well as in the case of ABA methyl ester. However, at pH 10, a dimer (6) with an epoxy group, 1′-deoxy-ABA (7) and other compounds were formed instead of compounds 4 and 5. Compounds 4 and 5 were biologically inactive, suggesting the importance of the electrophilic side-chain of ABA for biological activity.     

Synthesis and biological activity of abscisic acid esters

16 ABA esters including 11 new compounds were prepared by two different esterification routes. All the structures of ABA esters were confirmed by ¹H NMR, ¹³C NMR and HRMS. Their biological activity and hydrolysis stability were investigated. Fortunately, there were 15 and 9 compounds which displayed much better or nearly the same inhibition activity for rice seedling growth and Arabidopsis thaliana seed germination compared to ABA, respectively. Especially, compounds 2d and 2g showed better biological activities than ABA in the three tests. Moreover, we found that chemical hydrolysis ability of the esters in vitro had little relationship to their biological activity.     

Effects of singlet oxygen on membrane sterols in the yeast Saccharomyces cerevisiae.

Photodynamic treatment of the yeast Saccharomyces cerevisiae with the singlet oxygen sensitizer toluidine blue and visible light leads to rapid oxidation of ergosterol and accumulation of oxidized ergosterol derivatives in the plasma membrane. The predominant oxidation product accumulated was identified as 5alpha, 6alpha-epoxy-(22E)-ergosta-8,22-dien-3beta,7a lpha-diol (8-DED). 9(11)-dehydroergosterol (DHE) was identified as a minor oxidation product. In heat inactivated cells ergosterol is photooxidized to ergosterol epidioxide (EEP) and DHE. Disrupted cell preparations of S. cerevisiae convert EEP to 8-DED, and this activity is abolished in a boiled control indicating the presence of a membrane associated enzyme with an EEP isomerase activity. Yeast selectively mobilizes ergosterol from the intracellular sterol ester pool to replenish the level of free ergosterol in the plasma membrane during singlet oxygen oxidation. The following reaction pathway is proposed: singlet oxygen-mediated oxidation of ergosterol leads to mainly the formation of EEP, which is enzymatically rearranged to 8-DED. Ergosterol 7-hydroperoxide, a known minor product of the reaction of singlet oxygen with ergosterol, is formed at a much lower rate and decomposes to give DHE. Changes of physical properties of the plasma membrane are induced by depletion of ergosterol and accumulation of polar derivatives. Subsequent permeation of photosensitizer through the plasma membrane into the cell leads to events including impairment of mitochondrial function and cell inactivation.     

Metabolism of oxidized linoleic acid: distribution of activity for the enzymatic oxidation of 13-hydroxyoctadecadienoic acid to 13-oxooctadecadienoic acid in rat tissues

Oxidation products of linoleic acid, including hydroperoxy- and hydroxyoctadecadienoic acids have been shown to possess biological activities in a number of different systems. In this work we describe an enzymatic activity which catalyzes the conversion of 13-hydroxyoctadecadienoic acid to a 2,4-dienone product, 13-oxooctadecadienoic acid. The enzyme activity is widely distributed, with the highest activity in the colon and the liver. The distribution of activity among various tissues is distinct from other dehydrogenases known to use oxygenated unsaturated fatty acids as substrates. This enzyme may play a key role in the metabolism of 13-hydroxyoctadecadienoic acid in epithelial tissues.     

Morphological and anatomical effects of abscisic acid (ABA) and fluridone (FLU) on the growth of rice mesocotyls

It has been reported that abscisic acid (ABA) promotes the growth ofrice mesocotyls. We investigated the effects of ABA and fluridone (FLU), aninhibitor of ABA biosynthesis, on the morphological and anatomicalcharacteristics of the mesocotyl of dark-grown rice seedlings. By 5 days aftersowing (DAS), the mesocotyl of control seedlings had reached their a maximumlength of 50.0 mm. In ABA treated seedlings, the mesocotylcontinued growing until 12 DAS, reaching a length of 152.6 mm.Mesocotyls treated with FLU elongated until 4DAS attaining a final length ofonly 10.5 mm. The data indicated that the greater length ofmesocotyls in seedlings treated with ABA was mainly due to their longer growingperiod. An anatomical study showed that the cell division activity of themesocotyl localised near the coleoptilar node and that ABA prolonged the celldivision activity of the meristem. The results suggested that ABA regulates thegrowth of rice mesocotyls by controlling the activity of the meristem localisednear the coleoptilar node.     

Regulation of abscisic acid metabolism: towards a metabolic basis for abscisic acid-cytokinin antagonism

The penultimate step in abscisic acid (ABA) biosynthesis involves oxidation of xanthoxal (XAN) catalysed by a molybdenum-cofactor (MoCo)-containing aldehyde oxidase (AO) and represents one potential site of regulation of ABA in plant tissues. In an attempt to understand the biochemical basis for cytokinin-abscisic acid (CK-ABA) antagonism the effect of several CKs, molybdate, tungstate and allopurinol (an inhibitor of xanthine oxidase activity and purine metabolism) on the formation of XAN, ABA and related catabolites in mesocarp of ripening avocado (Persea americana Mill. cv. Hass) was investigated. Treatment with either adenine (Ade), isopentenyladenine (2iP) or zeatin (Z) enhanced conversion of ABA to phaseic acid (PA) and caused a reduction in the amount of radioactivity incorporated from 3R-[2-¹⁴C] mevalonolactone (MVL) into ABA by stimulating overall ABA metabolism. Ancymidol and N-(2-chloro-4-pyridyl)-N-phenylur ea (CPPU), while not affecting formation of PA and DPA, appeared to retard ABA biosynthesis which resulted in the accumulation of XAN. Tungstate caused accumulation of XAN at the expense of ABA and related acidic metabolites while molybdate and allopurinol accelerated ABA metabolism, i.e. formation of XAN, ABA, PA, and DPA. These findings are discussed in terms of the regulation of the ABA biosynthetic pathway in avocado fruit by CK-induced suppression of xanthine dehydrogenase (XDH) activity and a model illustrating the proposed metabolic interrelationship is presented.     

Evalution of toxicity of abcisic acid and gibberellic acid in rats: 50 days drinking water study

In the present study, the influence of subchronic effects of two plant growth regulators (PGRs) [Abcisic acid (ABA) and Gibberellic acid (GA₃)] on antioxidant defense systems [reduced glutathione (GSH), glutathione reductase (GR), superoxide dismutase (SOD), glutathione-S-transferase (GST) and catalase (CAT)] and lipid peroxidation level (malondialdehyde = MDA) in various tissues of the rat were investigated during treatment as a drinking water model. 75 ppm of ABA and GA₃ in drinking water were continuously administered orally to rats (Sprague-Dawley albino) ad libitum for 50 days. The PGRs treatments caused different effects on the antioxidant defense systems and MDA content of dosed rats compared to controls. The lipid peroxidation end product MDA significantly increased in the lungs, heart and kidney of rats treated with GA₃ without significant change in the spleen. ABA caused also a significant increase in MDA content in the spleen, lungs, heart and kidney. The GSH levels were significantly depleted in the spleen, lungs and stomach of rats treated with ABA without any change in the tissues of rats treated with GA₃ except the kidney where it increased. Antioxidant enzyme activities such as SOD significantly increased in the lungs and stomach and decreased in the spleen and heart tissues of rats treated with GA₃. Meanwhile, SOD significantly decreased in the spleen, heart and kidney and increased in the lungs of rats treated with ABA. While CAT activity significantly decreased in the lungs of rats treated with GA₃, a significant increase occurred in the heart of rats treated with both PGRs. On the other hand, the ancillary enzyme GR activity in the tissues were either significantly depleted or not changed with PGRs treatment. The drug metabolizing enzyme GST activity significantly decreased in the lungs of rats treated with ABA but increased in the stomach of rats treated with both PGRs.

As a conclusion, the rats resisted oxidative stress via the antioxidant mechanism. But the antioxidant mechanism could not prevent the increases in lipid peroxidation in rat's tissues. This data, along with changes, suggests that PGRs produced substantial systemic organ toxicity in the spleen, lungs, stomach, heart and kidney during a 50-day period of subchronic exposure.