The allene oxide cyclase of barley (Hordeum vulgare L.)--cloning and organ-specific expression

The naturally occurring enantiomer of the various octadecanoids and jasmonates is established in a biosynthetic step catalyzed by the allene oxide cyclase (AOC). The AOC converts an allene oxide formed by an allene oxide synthase (AOS). Here, we show cloning and characterization of cDNAs encoding the AOC and a third AOS, respectively, in addition to the two AOSs previously published (Plant J. 21, 199-213, 2000). The ORF of the AOC-cDNA of 717 bp codes for a protein of 238 amino acid residues carrying a putative chloroplast target sequence. Overexpression without chloroplast target sequence revealed AOC activity. The AOC was found to be a single copy gene which mapped on chromosome 6H. AOC mRNA accumulation appeared in leaf segments upon treatment with various jasmonates, octadecanoids and ABA or during stress such as treatment with sorbitol or glucose solutions. Infection with powdery mildew activated AOC expression in susceptible and resistant lines of barley which correlated with PR1b expression. Among different tissues of barley seedlings, the scutellar node and leaf base accumulated AOC mRNA preferentially which correlated with accumulation of mRNAs for other biosynthetic enzymes (lipoxygenases, AOSs). AOC mRNA accumulation appeared also abundantly in parts of the root containing the tip and correlated with elevated levels of jasmonates. The data suggest a link of AOC expression and JA formation and support role of JA in stress responses and development of barley.     

Molecular cloning and functional expression of soybean allene oxide synthases

A plant allene oxide synthase (AOS) reacting with 13S-hydroperoxy-9Z,11E,15Z-octadecatrienoic acid (13-HPOT), a lipoxygenase product of alpha-linolenic acid, provides an allene oxide which functions as an intermediate for jasmonic acid (JA) synthesis, making AOS a key enzyme regulating the JA level in plants. Although AOSs in various plants have been investigated, there is only limited information about AOSs in soybean (Glycine max). In this study, we cloned and characterized two soybean AOSs, GmAOS1 and GmAOS2, sharing 95% homology in the predicted amino acid sequences. GmAOS1 and GmAOS2 were composed of 564 and 559 amino acids respectively, with predicted N-terminal chloroplast-targeting signal peptides. Both AOSs expressed in Escherichia coli were selective for 13S-hydroperoxides of alpha-linolenic and linoleic acids, suggesting the potential of GmAOS1 and GmAOS2 to contribute to JA synthesis. GmAOS1 and GmAOS2 were expressed in leaves, stems, and roots, suggesting broad distribution in a soybean plant.     

长春花丙二烯氧化物合酶基因的克隆与表达

利用RT-PCR和RACE相结合的方法,从长春花中克隆了丙二烯氧化物合酶(AOS)基因。结果显示:长春花AOS基因(CrAOS)cDNA全长为2 118bp,包括5′和3′非翻译区,polyA尾和一个长1 638bp的开放阅读框,其基因组中不含内含子;CrAOS基因编码的蛋白含545个氨基酸。多重比对表明CrAOS蛋白与其他的AOS蛋白具有较高的相似性,CrAOS蛋白序列中含有AOS家族应有的保守氨基酸残基。Southern杂交表明:CrAOS基因在长春花中为低拷贝。qRT-PCR结果显示:CrAOS在各个组织均有表达但表达量存在差异,在老叶中最高,在幼花中表达最低。对长春花幼苗进行不同处理,结果表明:伤害、低温、甲基茉莉酸、乙烯利处理等可使CrAOS基因表达量显著提高,水杨酸处理对基因表达影响不大。     

冬小麦丙二烯氧化合酶基因(TaAOS)的克隆及其特性

丙二烯氧化合酶(allene oxide synthase,AOS)是茉莉酸脂加氧酶合成途径过程中的第一个酶.从冬小麦(Triticum aestivum L. cv.Jinghua No.3)克隆到了该酶的一个全长cDNA片段,其开放阅读框长约1 410 bp,编码一约含470个氨基酸残基的多肽,推测其分子量为51.9 kD.Southern分析显示其在基因组中以3个拷贝的形式存在.Northern杂交分析表明该基因表达可被外源的茉莉酸诱导,诱导10 h时达到高峰,进一步的RNA原位杂交表明该基因优先在幼叶中,尤其是在维管束附近的薄壁细胞中表达.同时,原位杂交还显示质膜钙通道的抑制剂La3 并不能抑制外源茉莉酸诱导该区域TaAOS的表达.     

Wound response in passion fruit (<Emphasis Type="Italic">Passiflora</Emphasis> f. <Emphasis Type="Italic">edulis flavicarpa</Emphasis>) plants: gene characterization of a novel chloroplast-targeted allene oxide synthase up-regulated by mechanical injury and methyl jasmonate

The induction of a chloroplast-localized 13-lipoxygenase (13-LOX) in passion fruit leaves in response to methyl jasmonate (MeJa) was previously reported. Since allene oxide synthase (AOS) is a key cytochrome P450 enzyme in the oxylipin pathway leading to AOS-derived jasmonates, the results above led in turn to an investigation of AOS in our model plant. Spectrophotometric assays showed that 24 h exposure of MeJa caused a high increase in 13-hydroperoxy linolenic acid (13-HPOT) metabolizing activity in leaf tissue. Western analysis using polyclonal antibodies against tomato AOS strongly indicate that, at least a part of the 13-HPOT metabolizing capacity can be attributed to AOS activity. We cloned the cDNA from a novel AOS encoding gene from passion fruit, named PfAOS. The 1,512 bp open reading frame of the AOS–cDNA codes a putative protein of 504 amino acid residues containing a chloroplast target sequence. Database comparisons of the deduced amino acid sequence showed highest similarity with dicot AOSs. Immunocytochemistry analysis showed the compartmentalization of AOS in chloroplasts of MeJa treated leaves, corroborating the predicted subcellular localization. Northern analysis showed that AOS gene expression is induced in leaf tissue in response to mechanical wounding and exposure to MeJa. In addition, such treatments caused an increase in papain inhibitor(s) in leaf tissue. Taken together, these results indicate that PfAOS may play an important role in systemic wound response against chewing insect attack. Furthermore, it can be useful as a tool for understanding the regulation of jasmonates biosynthesis in passion fruit.     

Allene oxide synthase: a major control point in Arabidopsis thaliana octadecanoid signalling

The analysis of allene oxide synthase (AOS) mRNA levels, of AOS polypeptide levels and specific enzymatic activities, as well as the quantitative determination of the levels of the octadecanoids cis-12-oxophytodienoic acid (cis-OPDA) and JA following a number of treatments, has shown that AOS is a regulatory site in octadecanoid biosynthesis in A. thaliana. AOS activity, mRNA and polypeptide levels are increased in wounded leaves locally and systemically. The methyl esters of OPDA or JA (OPDAME, JAME) and coronatine, are strong inducers of AOS mRNA, polypeptide and enzymatic activity. Ethephon also induces AOS activity. Salicylic acid (SA) was an inducer of AOS activity while abscisic acid (ABA) had no effect. At the level of the octadecanoids, the consequences of induction of AOS by the different inducers were distinctly different, depending on the nature of the inducer. Wounding led to a strong, bi-phasic accumulation of JA in wounded leaves and to a less pronounced increase in JA-levels in systemic leaves. Levels of OPDA changed very little in wounded leaves and remained constant or even declined in systemic leaves. Ethephon treatment resulted in a strong, transient increase in JA-levels kinetically coinciding with the second, more pronounced peak in wound-induced JA. In SA-treated leaves, the level of cis-OPDA increased throughout the experimental period while there was no effect on JA levels during the first 24 h following treatment and only a slight accumulation after 48 h. Clearly, mechanisms in addition to regulating substrate (LA) availability and the regulation of AOS accumulation control the output of the octadecanoid pathway.     

Expression of a Flax Allene Oxide Synthase cDNA Leads to Increased Endogenous Jasmonic Acid (JA) Levels in Transgenic Potato Plants but Not to a Corresponding Activation of JA-Responding Genes

Both jasmonic acid (JA) and its methyl ester, methyl jasmonate (MeJA), are thought to be significant components of the signaling pathway regulating the expression of plant defense genes in response to various stresses. JA and MeJA are plant lipid derivatives synthesized from [alpha]-linolenic acid by a lipoxygenase-mediated oxygenation leading to 13-hydroperoxylinolenic acid, which is subsequently transformed by the action of allene oxide synthase (AOS) and additional modification steps. AOS converts lipoxygenase-derived fatty acid hydroperoxide to allene epoxide, which is the precursor for JA formation. Overexpression of flax AOS cDNA under the regulation of the cauliflower mosaic virus 35S promoter in transgenic potato plants led to an increase in the endogenous level of JA. Transgenic plants had six- to 12-fold higher levels of JA than the nontransformed plants. Increased levels of JA have been observed when potato and tomato plants are mechanically wounded. Under these conditions, the proteinase inhibitor II (pin2) genes are expressed in the leaves. Despite the fact that the transgenic plants had levels of JA similar to those found in nontransgenic wounded plants, pin2 genes were not constitutively expressed in the leaves of these plants. Transgenic plants with increased levels of JA did not show changes in water state or in the expression of water stress-responsive genes. Furthermore, the transgenic plants overexpressing the flax AOS gene, and containing elevated levels of JA, responded to wounding or water stress by a further increase in JA and by activating the expression of either wound- or water stress-inducible genes. Protein gel blot analysis demonstrated that the flax-derived AOS protein accumulated in the chloroplasts of the transgenic plants.     

Tobacco mitotic cyclins: cloning, characterization, gene expression and functional assay

Barley leaves respond to application of (−)-jasmonic acid (JA), or its methylester (JM) with the synthesis of abundant proteins, so-called j asmonate i nduced p roteins (JIPs). Here Western blot analysis is used to show a remarkable increase upon JM treatment of a 100 kDa lipoxygenase (LOX), and the appearance of two new LOX forms of 98 and 92 kDa. The temporal increase of LOX-100 protein upon JM treatment was clearly distinguishable from the additionally detectable LOX forms. JM-induced LOX forms in barley leaves were compared with those of Arabidopsis and soybean leaves. Both dicot species showed a similar increase of one LOX upon JM induction, whereas, leaves from soybean responded with additional synthesis of a newly formed LOX of 94 kDa.
Using immunofluorescence analysis and isolation of intact chloroplasts, it is demonstrated that JM-induced LOX forms of barley leaves are exclusively located in the chloroplasts of all chloroplast-containing cells. Analogous experiments carried out with Arabidopsis and soybean revealed a similar plastidic location of JM-induced LOX forms in Arabidopsis but a different situation for soybean. In untreated soybean leaves the LOX protein was mainly restricted to vacuoles of paraveinal mesophyll cells. Additionally, LOX forms could be detected in cytoplasm and nuclei of bundle sheath cells. Upon JM treatment cytosolic LOX was detectable in spongy mesophyll cells, too. The intracellular location of JM-induced LOX is discussed in terms of stress-related phenomena mediated by JM.     

Jasmonate biosynthesis and the allene oxide cyclase family of Arabidopsis thaliana

In biosynthesis of octadecanoids and jasmonate (JA), the naturally occurring enantiomer is established in a step catalysed by the gene cloned recently from tomato as a single-copy gene (Ziegler et al., 2000). Based on sequence homology, four full-length cDNAs were isolated from Arabidopsis thaliana ecotype Columbia coding for proteins with AOC activity. The expression of AOCgenes was transiently and differentially up-regulated upon wounding both locally and systemically and was induced by JA treatment. In contrast, AOC protein appeared at constitutively high basal levels and was slightly increased by the treatments. Immunohistochemical analyses revealed abundant occurrence of AOC protein as well as of the preceding enzymes in octadecanoid biosynthesis, lipoxygenase (LOX) and allene oxide synthase (AOS), in fully developed tissues, but much less so in 7-day old leaf tissues. Metabolic profiling data of free and esterified polyunsaturated fatty acids and lipid peroxidation products including JA and octadecanoids in wild-type leaves and the jasmonate-deficient mutant OPDA reductase 3 (opr3) revealed preferential activity of the AOS branch within the LOX pathway. 13-LOX products occurred predominantly as esterified derivatives, and all 13-hydroperoxy derivatives were below the detection limits. There was a constitutive high level of free 12-oxo-phytodienoic acid (OPDA) in untreated wild-type and opr3 leaves, but an undetectable expression of AOC. Upon wounding opr3 leaves exhibited only low expression of AOC, wounded wild-type leaves, however, accumulated JA and AOC mRNA. These and further data suggest regulation of JA biosynthesis by OPDA compartmentalization and a positive feedback by JA during leaf development.     

The barley scutellar peptide transporter: biochemical characterization and localization to the plasma membrane

Thiol-affinity labelling was used to identify and characterize components of the peptide transport system in the barley (Hordeum vulgare) scutellar epithelium. SDS-PAGE and 2D-PAGE in conjunction with fluorography were used to study derivatized proteins. Membrane proteins of 42 kDa and 66 kDa were identified using a strategy devised to label substrate protectable protein with the thiol specific reagent [14C] N-ethylmaleimide (NEM). The scutellar plasma membrane is the anticipated site of transporters involved in the mobilization of endosperm storage reserves in the germinating barley grain. The subcellular localization of these proteins to the plasma membrane was demonstrated by thiol-affinity labelling of high purity plasma membrane vesicles isolated from barley scutellar tissue. A peptide transporter, HvPTR1, specific to the barley scutellum has recently been cloned in this laboratory. A 66 kDa protein, comparable to the predicted molecular mass of HvPTR1, was identified by [14C]NEM labelling studies of Xenopus laevis oocytes expressing HvPTR1 cRNA, but not water injected controls. Peptide antiserum raised to HvPTR1 also cross-reacted with a 66 kDa membrane protein in barley scutellar tissue. This confirms that the 66 kDa protein identified here by thiol-affinity labelling studies is the barley scutellum peptide transporter HvPTR1, and demonstrates that this protein is localized to the plasma membrane of scutellar epithelial cells during germination.