Traumatin- and Dinortraumatin-containing Galactolipids in Arabidopsis

Background: The pathway to form green leaf volatiles is important for plant defense against pathogens and herbivores. Results: Galactolipids with truncated oxoacids are formed as counterparts of green leaf volatiles. Conclusion: Galactolipid-hydroperoxides are substrates for hydroperoxide lyase. Significance: The biosynthetic pathway partly proceeds directly with galactolipids, without the involvement of lipases, to form free fatty acids. Green leaf volatiles (GLVs) consisting of six-carbon aldehydes, alcohols, and their esters, are biosynthesized through the action of fatty acid hydroperoxide lyase (HPL), which uses fatty acid hydroperoxides as substrates. GLVs form immediately after disruption of plant leaf tissues by herbivore attacks and mechanical wounding and play a role in defense against attackers that attempt to invade through the wounds. The fates and the physiological significance of the counterparts of the HPL reaction, the 12/10-carbon oxoacids that are formed from 18/16-carbon fatty acid 13-/11-hydroperoxides, respectively, are largely unknown. In this study, we detected monogalactosyl diacylglycerols (MGDGs) containing the 12/10-carbon HPL products in disrupted leaf tissues of Arabidopsis, cabbage, tobacco, tomato, and common bean. They were identified as an MGDG containing 12-oxo-9-hydroxy-(E)-10-dodecenoic acid and 10-oxo-7-hydroxy-(E)-8-decenoic acid and an MGDG containing two 12-oxo-9-hydroxy-(E)-10-dodecenoic acids as their acyl groups. Analyses of Arabidopsis mutants lacking HPL indicated that these MGDGs were formed enzymatically through an active HPL reaction. Thus, our results suggested that in disrupted leaf tissues, MGDG-hydroperoxides were cleaved by HPL to form volatile six-carbon aldehydes and non-volatile 12/10-carbon aldehyde-containing galactolipids. Based on these results, we propose a novel oxylipin pathway that does not require the lipase reaction to form GLVs.

Green leaf volatiles (GLVs), 2 which consist of six-carbon (C6) aldehydes, alcohols, and their esters, are ubiquitous in the leaves of most plants (1). GLVs form rapidly after the disruption of plant tissues (2,3). Insecticidal, fungicidal, and bactericidal activities have been reported for (Z)-3-hexenal and its related aldehydes (4 -7). A portion of the C6 aldehydes that form in disrupted tissues diffuses into adjacent intact tissues, where they are reduced to C6 alcohols and further acetylated to C6 acetates (8). They function as airborne infochemicals in specific plant-herbivore, plant-carnivore, and plant-plant relationships (9).
In general, GLVs and the corresponding traumatins, as well as JAs, are thought to be formed from free fatty acids that are released from glycerolipids by lipases; however, there are only a few reports on the identification of lipases involved in JA synthesis (11). Mono-and digalactosyldiacylglycerols (MGDGs and DGDGs) that contain 12-oxophytodienoic acid and/or 12-oxodinorphytodienoic acid (collectively known as arabidopsides) have been identified in Arabidopsis (Col-0) (12,13). The oxidative modification of MGDG to yield arabidopsides occurs on esterified fatty acids (14). Thus, the first enzyme acting on the lipid may be LOX, especially AtLOX2 in Arabidopsis, because this LOX is known to contribute the major portion of arabidopsides formed after leaf wounding (15). The oxylipin galactolipids containing divinyl ether residues (linolipins) that are present in flax were thought to be biosynthesized without free fatty acid intermediates derived from the lipase reaction (16). Therefore, in some plant species, lipases are not essential to form oxylipins.
Nonenzymatic oxidation of lipids can also occur, especially in chloroplasts, because reactive oxygen species such as 1 O 2 are inevitably formed as by-products of photosynthesis (17). The chloroplast-abundant lipids, such as MGDGs and DGDGs, are prone to conversion into their peroxides, a portion of which are modified by radical-catalyzed fragmentation reactions to yield a wide variety of compounds (e.g. malondialdehyde (18), trioxygenated products, phytoprostanes, or even MGDGs harboring C12 or C9 oxoacids) (19 -20).

EXPERIMENTAL PROCEDURES
Plant Materials-Seeds of Arabidopsis (Arabidopsis thaliana (L.) Heynh.) wild-type ecotypes Col-0, Ler-0, No-0, and WS and the transfer DNA-inserted line aos::Col-6 (gl1) (25) were obtained from ABRC (Columbus, OH). aos::Col-6 (gl1) was crossed with Ler-0, and a line showing the aos (male-sterile) and HPL (ability to form GLVs) phenotypes was selected from the resultant F2 progenies. The line was denoted as aos::Ler-0. hpl1 has a Col-0-derived deletion of the HPL gene in the Ler-0 background; thus, it has no HPL activity (26). The seeds were germinated in soil (Metro-Mix, Sun Gro Horticulture Distribution Inc., Bellevue, WA) in plastic pots (6-cm inner diameter). Plants were cultivated in a growth chamber at 22°C under fluorescent lights (60 mol m Ϫ2 s Ϫ1 ) with a 14-h light/10-h dark photoperiod for 30 days until they reached the stage just before bolting. Seeds of Brassica oleracea, Nicotiana tabacum, Solanum lycopersicum, and Phaseolus vulgaris were purchased from a local market and were cultivated in a growth chamber at 25°C under fluorescent lights (60 mol m Ϫ2 s Ϫ1 ) with a 14-h light/10-h dark photoperiod for 30 days. Clover (Trifolium repens L.) . Then the free fatty acid is oxygenated by lipoxygenase, and resulting hydroperoxides are cleaved to form (Z)-3-hexenal and free traumatin or dinortraumatin derivatives. In disrupted leaves of Arabidopsis and some other plant species, galactolipids are directly oxygenated by lipoxygenase to form galactolipid-hydroperoxides which are subsequently cleaved by hydroperoxide lyase to form (Z)-3-hexenal and traumatinand dinortraumatin-containing galactolipids. leaves were harvested from the experimental farm at the Faculty of Agriculture, Yamaguchi University, in June 2009. Spinach (Spinacia oleracea L.) was purchased from a local market.
Chemicals-(9Z)-Traumatin was purchased from Larodan (Malmö, Sweden). 9-OH-traumatin was generated by nonenzymatic oxidation of (9Z)-traumatin at 60°C for 80 min (22,27). (7Z,10Z,13Z)-7,10,13-Hexadecatrienoic acid (16:3) was purified from MGDGs isolated from spinach leaves. Crude lipids were extracted from 1 kg of spinach leaves using the Bligh-Dyer method (28) and fractionated by column chromatography on silica gel (Wakogel C-300, Wako Pure Chemicals, Osaka, Japan) with a solvent system consisting of chloroform and acetone. The fractions eluted with chloroform/acetone (3:2, v/v) were collected. A portion (100 mg) of the purified MGDGs was submitted to alkaline hydrolysis with 50% ethanolic 3.5 M KOH in boiling water for 2 h. Then, after acidification of the reaction mixture, the fatty acids were extracted with diethyl ether. The fatty acid mixture was fractionated by preparative HPLC using a Mightysil RP-18 column (250 mm ϫ 4.6-mm inner diameter, Kanto Chemicals, Tokyo, Japan) with acetonitrile as the elution solvent at a flow rate of 1 ml min Ϫ1 . Compounds were detected by monitoring absorbance at 220 nm. Purified 16:3 eluting at ϳ4 min was collected, and its identity was confirmed by GC-MS analysis after methyl esterification with 2.0 M trimethylsilyldiazomethane in hexane (Sigma-Aldrich).
Extraction and Analysis of Free Traumatin Derivatives-Arabidopsis (No-0) leaves (2.5 g FW) were homogenized in 5 ml of 20 mM sodium phosphate buffer (pH 6.3) containing 0.1 mM DETAPAC. The homogenate was incubated for 5 min at 25°C. Then the homogenate was acidified to pH 4.0 by adding HClO 4 , and 10 nmol each of 15-hydroxy-(11Z,13E)-11,13-icosadecadienoic acid (prepared from (11Z,14Z)-11,14-icosadienoic acid (Sigma-Aldrich) with soybean LOX-1) and 10-hydroxy-(E)-2decenoic acid (Wako Pure Chemicals) were added as internal standards. Then 25 ml of methanol (containing 0.0025% butylated hydroxytoluene), 12.5 ml of chloroform, and 12.5 ml of 1% KCl solution were added to the mixture, and the aqueous and organic phases were allowed to separate. The aqueous phase was extracted again with chloroform (12.5 ml), and the combined organic phase was washed with 1% KCl solution. The solvent was removed under vacuum, and the remaining residue was dissolved in 0.7 ml of chloroform. To isolate lipids from intact leaves, the leaves (2.5 g FW) were homogenized with 10 ml of methanol containing 0.0025% butylated hydroxytoluene to avoid any enzymatic modifications of the lipid composition, and then extraction was conducted as described above.
A portion (ϳ1 mg) of the crude lipids was dried in a stream of N 2 gas and suspended in 1 ml of 0.1 M Tris-HCl (pH 8.0) containing 0.01% sodium deoxycholate with the aid of an ultrasonic bath (US Cleaner, AS ONE Co., Osaka, Japan) under an N 2 atmosphere. To the suspension 0.1 ml of 2.2% CaCl 2 solution and 0.5 ml of 20 mg ml Ϫ1 pancreatin (Wako Pure Chemicals) were added. The mixture was incubated at 37°C for 30 min. After hydrolysis, the mixture was acidified to pH 4.0 with HClO 4 and applied to a Bond Elut C18 cartridge (200 mg, Agilent Technologies Inc., Santa Clara, CA) equilibrated with water. The hydrolyzed compounds were eluted with methanol.
Free forms of traumatin derivatives were analyzed by LC-MS/MS (3200 Q-TRAP LC/MS/MS System (AB Sciex, Framingham, MA) equipped with a Prominence UFLC (Shimadzu, Kyoto, Japan)). Products were separated on a Mightysil RP18 column (150 mm ϫ 2-mm inner diameter) with a binary gradient consisting of water/formic acid (100:0.1, v/v, solvent A) and acetonitrile/formic acid (100:0.1, v/v, solvent B). The run consisted of a linear increase from 20% B to 90% B over 25 min (flow rate, 0.2 ml min Ϫ1 ). Compounds were detected with a photodiode array detector (SPD-M20A, Shimadzu) and by MS/MS using ESI in the negative ion mode (ion spray voltage, Ϫ4500 V; nitrogen as both the curtain gas (set to 40 arbitrary units) and collision gas (set to "high"); collision energy, Ϫ10 V; scan range, m/z 100 -1200; scan speed, 4,000 Da s Ϫ1 ; declustering potential, Ϫ10 V) and multiple reaction monitoring ( Table 1). The response curves of the traumatin derivatives versus the IS were determined and used to calculate the response factors (Table 1). To quantify traumatin derivatives, the areas of corresponding peaks in the chromatogram were integrated and divided by the peak area of the IS, and the values were corrected by the respective response factor. The peak with a signal/noise ratio of more than 10 (0.6 pmol for traumatin and dinortraumatin and 0.4 pmol for their hydroxylated derivatives; roughly corresponding to 0.15 and 0.10 nmol g FW Ϫ1 , respectively) was used for calculation.
Six-carbon aldehydes formed after complete disruption of Arabidopsis leaves were quantified by HPLC after derivatization of the aldehydes with 2,4-dinitrophenylhydrazine, as described previously (32). Under these experimental conditions, (Z)-3-hexenal was the main product, accounting for ϳ85% of the GLVs formed (8).
Extraction and Analysis of Galactolipid Oxylipins-Plant leaves were thoroughly ground using a mortar and pestle, and a portion (0.1 g FW) of the slurry was mixed with 1 ml of acetone containing 0.1% butylated hydroxytoluene and 10 ng ml Ϫ1 formononetin (IS). The suspension was mixed vigorously for 10 min and then centrifuged at 17,000 ϫ g for 10 min. The resultant green supernatant was analyzed by LC-MS/MS (see below). To determine the amounts in intact leaves, the leaves were frozen in liquid nitrogen immediately after harvest. The extraction was conducted as described above after powdering the frozen tissues.
MGDGs containing traumatin derivatives were qualitatively analyzed using the LC-PDA-MS/MS system described above. Multiple reaction monitoring analysis was conducted to quantify the compounds (Table 1). When the partially purified MGDG-9-OH-traumatin/7-OH-dinortraumatin and MGDGbis-9-OH-traumatin were analyzed by LC-PDA-MS/MS, we found that there was no other compound with absorbance around 220 nm. Therefore, these compounds were tentatively quantified using the molar absorption coefficient (⑀) reported for 4-hydroxy-(E)-2-nonenal (13,750) (33), which has the same chromophore. The response curves of MGDG 7-OH-dinortraumatin/9-OH-traumatin and MGDG bis-9-OH-traumatin versus those of IS (formononetin) were determined and used to calculate the response factors (Table 1). For quantification, the corresponding peak areas obtained by integration of the ion chromatograms were divided by that of the IS, and the values were corrected by the respective response factor. The detection limit for MGDG 7-OH-dinortraumatin/9-OH-traumatin and MGDG bis-9-OH-traumatin was 0.2 nmol g FW Ϫ1 with a signal/noise ratio on the multiple reaction monitoring chromatogram of more than 10. Arabidopsides A and B were identified from their MS and MS/MS spectra according to parameters reported by Buseman et al. (13). Because standard arabidopsides were unavailable, the ratios of their areas to that of the IS were calculated.
Purification of MDGD Bis-9-OH-traumatin and MGDG 9-OH-traumatin/7-OH-dinortraumatin-Arabidopsis (No-0) leaves (437 g) were completely disrupted with a Polytron homogenizer (PT-20sk, Kinematica AG, Luzern, Switzerland), and the homogenate was stirred vigorously for 5 min to facilitate the enzyme reaction. Crude lipids were extracted with the Bligh-Dyer method as described above. Total lipids were subjected to column chromatography on silica gel (Wakogel C-300, 220 ϫ 20 mm inner diameter). The column was washed with chloroform/acetone (4:6, v/v), and the glycolipids were eluted with acetone/methanol (9:1, v/v). For further purification, the fraction was concentrated and subjected to preparative TLC (20 ϫ 20 cm, silica gel 60 F 254 , Merck) using ethyl acetate/acetone/acetic acid (10:10:1, v/v/v) as the developing solvent. The zones containing the galactolipids of traumatin derivatives were visible under UV light and were scraped off the plates. The lipids were eluted in ethyl acetate. The fraction containing MGDGs with traumatin and its derivatives was further separated by RP-HPLC with a Mightysil RP18 column (250 ϫ 4.6 mm) using a binary gradient consisting of acetonitrile/water/formic acid (20:80:0.1, v/v/v, solvent A) and acetonitrile/ water/formic acid (50:50:0.1, v/v/v, solvent B). The run consisted of a linear increase from 100% A to 100% B over 40 min at a flow rate of 1 ml min Ϫ1 . The MGDGs containing oxygenated traumatin derivatives were detected by monitoring UV absorbance at 220 nm and collected. NMR Analysis of MDGD 9-OH-traumatin/7-OH-dinortraumatin-Fractions enriched in MDGD 9-OH-traumatin/7-OH-dinortraumatin were concentrated under vacuum. The residue was dissolved in 70 l of CD 3 OD and transferred into a 2-mm NMR tube. NMR spectra were recorded using a Bruker Avance 500 NMR instrument (Bruker Biospin, Karlsruhe, Germany) operating at 500.13 MHz and equipped with a 5-mm TCI cryoprobe. The spectra were acquired at 300 K and a total of 5,000 -7,000 transient signals were recorded as 32,000 data points with a spectral width of 20 ppm using a pulse sequence with water suppression (zgpurge). Selective COSY (SELCOSY) (selcogp) and selective TOCSY (SELTOCSY) (selmlgp.2) spectra were recorded using standard Bruker pulse sequences with a 10-ms excitation range and 200-ms mixing time. Data analysis was conducted using Topspin version 3.1 software (Bruker Biospin, Karlsruhe, Germany). HPLC
To quantify the esterified forms of oxoacids, the crude lipid extract prepared from homogenized Arabidopsis (No-0) leaves was hydrolyzed with pancreatin, which has strong galactolipase activity and triacylglycerol lipase activity (34). The pancreatin treatment increased the amounts of 9-OH-traumatin, 7-OHdinortraumatin, and (7Z)-dinortraumatin (Fig. 2). The amount of (9Z)-traumatin hardly increased after hydrolysis. This result indicated that the oxoacids were present as their esterified forms, probably as the acyl groups of lipids.
Detection of MGDGs Containing Traumatin Derivatives-Esterified oxylipins have been found predominantly in galactolipids (12,13). The most abundant C6 compounds produced after wounding of Arabidopsis leaves are formed from octadecatrienoic acid (18:3) and hexadecatrienoic acid (16:3). Most 18:3 (ϳ65%) and 16:3 (ϳ96%) are found in MGDGs (24). We found that MGDGs were substrates for LOX to yield MGDG HPOs, which could be the substrates for HPL (29). Together, these findings led us to assume that a portion of esterified traumatin and its derivatives was present as the acyl moieties of MGDG. To explore this idea, we attempted to develop a method to analyze MGDGs containing oxoacids.
A crude lipid extract prepared from intact Arabidopsis (No-0) leaves was analyzed by LC-MS/MS to detect MGDGs containing C12 or C10 oxoacids. In intact leaf extracts, peaks corresponding to MGDGs containing C12/C10 acyl moieties were not detected. However, when the leaves were disrupted and incubated for 5 min to allow formation of GLVs, peaks corresponding to MGDG-9-OH-traumatin/7-OH-dinortraumatin and MGDG-bis-9-OH-traumatin were detected (Fig. 4).    Neither MGDGs containing C12/C10 oxoacids without hydroxylation nor those with only one hydroxylation were detected under these experimental conditions. Arabidopsides A and B were present in very low quantities in intact leaves, but their quantities increased markedly after disruption of the leaves as reported previously (13) (Fig. 4).
Arabidopsides are MGDGs containing 12-oxophytodienoic acid and/or 12-oxodinorphytodienoic acid formed via the AOS reaction (12,13). It is assumed that arabidopsides are formed from HPOs of MGDGs; therefore, AOS and HPL may compete for the same substrates in disrupted leaf tissues. Massive formation of arabidopsides A and B was detected in the various Arabidopsis ecotypes/genotypes, whereas they were undetectable in the   transfer DNA knock-out mutants, aos::Ler and aos::Col-gl1. The amounts of MGDG-9-OH-traumatin/7-OH-dinortraumatin and MGDG-bis-9-OH-traumatin formed after disruption of leaves were markedly lower in Ler leaves than in aos::Ler leaves (Fig. 7). This suggested that HPL and AOS compete at least in part for the same substrate (MGDG HPOs) to form oxylipin-containing MGDGs.

MGDG-oxoacids in Other Plant
Species-It has been reported that arabidopsides occur only in A. thaliana and Arabidopsis arenosa but not in any other plant species examined so far (38). We examined whether MGDG-oxoacids were present in cabbage (B. oleracea, Brassicaceae), tobacco (N. tabacum, Solanaceae), tomato (S. lycopersicum, Solanaceae), and common bean (P. vulgaris, Fabaceae) ( Table 3). As expected, arabidopsides were not detected in the disrupted leaf tissues of these four plant species. However, significant amounts of MGDG-9-OH-traumatin/7-OH-dinortraumatin and/or MGDG-bis-9-OH-traumatin were detected in all four species. The amounts varied, with lower amounts detected in tobacco than in Arabidopsis (No-0). Higher quantities formed in cabbage, tomato, and common bean leaves. The highest concentration detected was that of MGDG-bis-9-OH-traumatin (51 nmol g FW Ϫ1 ) in common bean leaves. Plants belonging to the Fabaceae have no 16:3, and accordingly, MGDG-9-OH-traumatin/7-OH-dinortraumatin was not detected.

DISCUSSION
It has been believed that HPLs show higher affinities for free fatty acid-HPOs as substrates; thus, the C12/C10 counterparts of HPL products were assumed to be free oxoacids. In this study, we detected less than 10 nmol g FW Ϫ1 of (9Z)-traumatin and 9-OH-traumatin in their free forms, compared with ϳ300 nmol g FW Ϫ1 of (Z)-3-hexenal in completely disrupted Arabidopsis (No-0) leaves. From this result, we propose that the C12/ C10 counterparts are formed via a different mechanism from the canonical HPL pathway, in which free fatty acid HPOs are the substrates. It was reported that esterified (10E)-traumatin is present in runner bean (21); thus, we tried to identify esterified C12/C10 oxoacid derivatives.
Accordingly, we analyzed MGDGs containing 9-OH-traumatin and/or 7-OH-dinortraumatin not only in disrupted leaves of Arabidopsis but also those of cabbage, tobacco, tomato, and common bean. This is the first report of endogenous MGDGs containing traumatin and its derivatives in disrupted plant leaves. Previous reports have described MGDGs with 12-oxodinorphytodienoic acid and divinylether, which were thought to be formed by AOS and divinylether synthase, both of which are CYP74 enzymes closely related to HPL. How-ever, these compounds were detected only in Arabidopsis sp. and flax plants (Linum usitatissimum), respectively (12)(13)16).
In Arabidopsis (No-0) leaves, MGDG-9-OH-traumatin/7-OH-dinortraumatin and/or MGDG-bis-9-OH-traumatin were formed quickly after disruption. This rapid formation coincided with the release of C6 aldehydes. The structures of their acyl moieties are those expected for the counterparts of canonical products of HPL activity toward free 13-HPOT and 11-HPHT, possibly followed by enzymatic or nonenzymatic peroxidation and subsequent reduction to yield hydroxylated oxo compounds (22,27). The requirement for active HPL was confirmed by comparing formation of MGDGs containing traumatin derivatives between Arabidopsis ecotypes and mutants with/without an active HPL. We also found that recombinant CaHPL showed catalytic activity toward pure MGDG HPOs. These lines of evidence indicated that MGDG HPOs are substrates of HPL and that volatile C6 aldehydes and nonvolatile MGDG containing C12/C10 oxoacids are the products of HPL in disrupted Arabidopsis leaf tissues.
It has been widely believed that the most suitable substrates for HPL are free fatty acid HPOs. However, it was reported that the Arabidopsis HPL showed significant activity (80% of that toward the free fatty acid derivative) toward the methyl ester of 13-HPOT (39). Hughes et al. (40) reported that detergent micelles massively affect HPL and AOS activities. In leaf tissues disrupted by mechanical wounding or herbivore attack, the enzymes in the oxylipin pathway show catalytic activity toward substrates that co-exist with a wide array of biological molecules, including lipids. Thus, the reaction conditions of these enzymes in situ differ greatly from those in vitro. This study demonstrated that at least the HPLs examined here were able to utilize lipid HPOs as substrates. The substrate preferences of HPLs and related enzymes involved in oxylipin formation in disrupted leaf tissues should be reevaluated, taking these results into account.
The total amounts of C10/C12 compounds (the sum of their free and MGDG forms) detected in disrupted Arabidopsis (No-0) leaves were still substantially lower than those expected from the amounts of C6 aldehydes. It is possible that traumatin and its derivatives were esterified to other lipids. Greater amounts of traumatin derivatives than MGDG-containing traumatin derivatives were detected after pancreatin treatment of crude lipids extracted from disrupted Arabidopsis (No-0) leaves. Zoeller et al. (20) reported that in Arabidopsis (Col-0), in addition to MGDGs, also DGDGs, phosphatidylglycerols, and triacylglycerols contained significant amounts of 18:3 and 16:3 that were partially oxygenated or even fragmented under biotic stress conditions. In addition, it is likely that MGDG-hydroxylated oxoacids are further converted because 9-OH-traumatin and 7-OH-traumatin should be very reactive with various kinds of nucleophiles present in cells, such as glutathione, because such compounds contain a highly electrophilic ␥-hydroxy-␣,␤unsaturated aldehyde moiety (41)(42). In the present study, the amounts of analytes detected may have been underestimated because of the spontaneous degradation of these reactive compounds, especially the hydroperoxides that may have formed as intermediates, during analysis. To match the reactions that occur in disrupted leaf tissues with the predicted stoichiometry between C6 and C12 products of HPL, an accurate system to quantify the possible metabolites must be established. A comparison of the amounts of arabidopsides and MGDG with traumatin derivatives between aos::Ler and Ler suggested that AOS and HPL competed for the same substrates, MGDG-HPOs, in disrupted Arabidopsis leaf tissues. AtLOX2 is involved in supplying the substrate, at least for AOS (15). Because significant amounts of these lipid oxylipins formed rapidly, it was assumed that substantial amounts of both AOS and HPL were present in intact leaf cells in their latent forms or were located in different cellular compartments, separated from their substrates. Arabidopsides were not formed in leaves of cabbage, tobacco, tomato, and common bean, although these species formed significant amounts of MGDG containing traumatin derivatives as well as GLVs after disruption of leaf tissues. These findings suggested that the nature of the Arabidopsis AOS differed from that of AOSs in these plants. AOSs in leaves of cabbage, tobacco, tomato, and common bean may not be able to utilize MDGD-HPOs, or the amount of AOS in intact leaf cells might be too low to compete with HPL.
These findings do not exclude the possibility that GLVs can be formed via the lipase reaction with lipids to form 18:3 and 16:3. It is still possible that the free C12/C10 compounds are re-esterified; however, this possibility is unlikely because arabidopsides form on lipids without hydrolysis, as shown in a series of excellent experiments using isotopes (18). The formation of esterified and free oxylipins is regulated differently between natural and stress-induced senescence (43). The biosynthesis of free oxylipins definitely requires lipases, such as AtDAD1 (44) or NaGPA1 (45). GLV formation occurs even in intact plant tissues distant from the site of herbivore damage (46), after pathogen infection (47), under heat stress, after sudden darkness (48), or even after treating the tissues with pathogen-induced plant volatiles (49). In an analogous situation to the formation of free JAs, hydrolysis of free fatty acids may be required for the formation of GLVs in intact tissues under stress. This idea is partly supported by the fact that free JA production was enhanced in transgenic rice suppressing HPL (50).