Abstract
In plants, cis-jasmone (CJ) is synthesized from α-linolenic acid (LA) via two biosynthetic pathways using jasmonic acid (JA) and iso-12-oxo-phytodienoic acid (iso-OPDA) as key intermediates. However, there have been no reports documenting CJ production by microorganisms. In the present study, the production of fungal-derived CJ by Lasiodiplodia theobromae was observed for the first time, although this production was not observed for Botrytis cinerea, Verticillium longisporum, Fusarium oxysporum, Gibberella fujikuroi, and Cochliobolus heterostrophus. To investigate the biosynthetic pathway of CJ in L. theobromae, administration experiments using [18,18,18-2H3, 17,17-2H2]LA (LA-d5), [18,18,18-2H3, 17,17-2H2]12-oxo-phytodienoic acid (cis-OPDA-d5), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 8:0 (OPC8-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 6:0 (OPC6-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 4:0 (OPC4-d6), and [11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl iso-12-oxo-phytodienoate (iso-MeOPDA-d8) were carried out, revealing that the fungus produced CJ through a single biosynthetic pathway via iso-OPDA. Interestingly, it was suggested that the previously predicted decarboxylation step of 3,7-didehydroJA to afford CJ might not be involved in CJ biosynthesis in L. theobromae.
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Introduction
Jasmonic acid (JA) is a phytohormone and key mediator in plant wound responses to insects, necrotrophic pathogens1,2,3 and other environmental stresses. The biosynthesis of JA begins with the oxygenation of α-linolenic acid (LA) in the chloroplast to give (+)-7-iso-JA in the peroxisome4 via 12-oxo-phytodienoic acid (cis-OPDA), 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-octanoic acid (OPC 8:0), 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-hexanoic acid (OPC 6:0), and 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-butanoic acid (OPC 4:0). (+)-7-iso-JA is readily epimerized to afford JA, which has an absolute configuration of (3R, 7R) (Fig. 1). The synthesized (+)-7-iso-JA is metabolized to afford other jasmonates, including MeJA, 12-hydroxy-JA (12-OH-JA), and JA-amino acid conjugates. It has been generally accepted that the compounds derived from oxygenated polyunsaturated fatty acids are categorized as oxylipins, and thus, JA and its derivatives are members of this family. JA-related compounds are well known, and their biological functions have been reported5, 6. Among of them, jasmonoyl isoleucine (JA-Ile) is an important player due to its curtail biological roles to interact with its receptor, COI17,8,9,10, which needs to induce JA dependent biological phenomena. However, Yan et al.11 reported that JA-Ile and other four JA conjugates are the ligand of the JA receptor. Methyl jasmonate (MeJA) is a volatile compound involved in the response to wound stress, and volatized MeJA is thought to induce defensive proteins in plants12.
Biosynthetic pathway to give CJ and JA. LA: α-linolenic acid, OPDA: 12-oxo-phytodienoic acid, OPC 8:0: 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-octanoic acid, OPC 6:0: 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-hexanoic acid, OPC 4:0: 3-oxo-2-(2′-[Z]-pentenyl)-cyclopentane-1-butanoic acid (OPC 4:0). 13-LOX: 13-lipoxygenase, AOS: alene oxide synthase, AOC: alene oxide cyclase, OPR3: 12-oxophytodienoate reductase 3.
cis-Jasmone (CJ) is one of oxylipins, and it was reported that the biosynthetic pathway of CJ in plant was proceeded using JA as a biosynthetic intermediate (pathway A, Fig. 1)13. In this report, [7-2H1, 5,5-2H2, 2,2-2H2]JA and [9-2H1, 8-2H1]methyl 3,7-didehydrojasmonate were converted into deuterium-labeled CJs in jasmine flowers and the leaves of six higher plants, including lima beans (Phaseolus lunatus) and willow (Salix alba). It was proposed that the conversion of 3,7-didehydroJA to CJ is achieved by decarboxylation13. Moreover, a recent study has shown that iso-12-oxo-phytodienoic acid (iso-OPDA) is an early precursor of CJ14, suggesting biosynthesis via pathway B (Fig. 1). iso-OPDA is an isomer of cis-OPDA, an important intermediate in the JA biosynthetic pathway (Fig. 1). Interestingly, the successful conversion of labelled iso-OPDA into CJ by the yeast Saccharomyces cerevisiae has also been reported, although the yeast had no operative pathway for CJ. Several reports have demonstrated the biological activities of cis-OPDA15, 16. The existence of OPDA-Ile in Arabidopsis thaliana was proven17, the related biological activity was evaluated by Arnold et al.18. However, no similar reports exist for iso-OPDA. There is an interesting report about iso-OPDA as a metabolite, which revealed that cis-OPDA isomerase is involved in phytohormone detoxification in the insect gut, a process by which cis-OPDA is converted to iso-OPDA19,20,21,22,23. It has been generally accepted that CJ is involved in plant defense systems, similar to JA. For example, CJ is released from wounded leaves, attracts aphid parasitoids and acts as a repellent of the pest24, 25. CJ is also released from the flowers of many plants, such as jasmine, neroli (Citrus bigaradia), jonquil (Narcissus jonquilla L.), bergamot (Citrus bergamia), and the Pittosporum family. On the other hand, some insects such as butterflies26 and silk worms27 use CJ as a sex pheromone. Therefore, potential agricultural use of CJ in applications such as aphid control has been studied28.
Plant pathogens produce various secondary metabolites, and some fungi produce phytohormones, such as JA, auxin, and abscisic acid29. It was initially thought that fungi produce phytohormones to disturb signaling systems of plants and enable facile invasion of plants. The fungus, Verticillium longisporum uses CORONATINE INSENSITIVE1 (COI1), which is an essential protein for establishing the JA-dependent wound response, to invade plants, and thus, it was hypothesized that the fungus might synthesize JA-related compounds. Fusarium oxysporum causes vascular wilt disease in more than 100 plant species and reportedly produces 22 kinds of JA analogues30. Furthermore, Thatcher and coworkers discovered that F. oxysporum also hijacks COI1-mediated jasmonate signaling to promote disease development in Arabidopsis 31. The fungus Botrytis cinerea, Gibberella fujikuroi and Lasiodiplodia theobromae also synthesize JA, and the JA biosynthetic pathway in L. theobromae has been reported by Tsukada et al.32. Cochliobolus heterostrophus can cause corn leaf blight in maize and produces a death acid that is an analogue of JA33. The biosynthetic pathway of this death acid is similar to that of JA, and the fungus reportedly uses the plant’s JA biosynthetic pathway to synthesize the death acid. However, fungal production of CJ has not been reported. In this study, we discovered that L. theobromae produces CJ. Furthermore, we used a combined approach involving feeding the fungus deuterium-labeled compounds and gas chromatography–mass spectrometry (GC-MS) analysis to elucidate the CJ biosynthetic pathway in L. theobromae.
Results and Discussion
Screening of fungal producers of CJ
The similarities in the chemical structures of CJ and JA suggest that some species of plant pathogens that synthesize JA or its related compounds could produce CJ. Thus, the ability of six species of plant pathogens, L. theobromae, B. cinerea, V. longisporum, F. oxysporum, G. fujikuroi, and C. heterostrophus, to synthesize CJ was evaluated using GC-MS. To ensure accuracy in the experiment, [4,4-2H2, 3,3-2H2, 1,1,1-2H3]CJ (CJ-d7, m/z 171) was synthesized according to a reported method34, except that commercially available CJ was used as the starting material. The isotopic purity was established by comparing the data of GC-MS for CJ and CJ-d7. The incorporation of 2H2 was found to be 94% for CJ-d7. Representative GC-MS/MS chromatograms for authentic CJ are shown in Supplementary Fig. 1, and the results of screening experiment are given in Fig. 2. Peaks corresponding to CJ-d7 (m/z 171), an internal standard, in selected ion monitoring mode were detected in the extracts of all the six species of fungi (Fig. 2A–F, upper panels). However, a peak corresponding to CJ (m/z 164) was only detected in the culture filtrate derived from L. theobromae (Fig. 2A, lower panel), and the corresponding MS pattern agreed with that of the authentic standard shown in Supplementary Fig. S1. However, the peak corresponding to CJ was not detected in the filtrates derived from the other five pathogens (Fig. 2B–F, lower panels). A concentration of CJ, calculated based on the peak area ratio between CJ-d7 and fungal-derived CJ, was determined to be 8.7 μg/mL in the culture filtrate of L. theobromae.
Representative GC MS chromatograms analyzing fungal derived cis-jasmone. (A, B, C, D, E and F) measuring fungal derived cis-jasmone using selected ion monitoring at m/z 164 (lower) and 171 (upper, internal standard) for L. theobromae, B. cinerea, V. longisporum, F. oxysporum, G. fujikuroi, and C. heterostrophus, respectively.
Metabolism of deuterium-labeled LA-d5 and cis-OPDA-d5 to MeJA-d5 and CJ-d5 in feeding experiments
CJ in plants is reportedly synthesized using JA and iso-OPDA as synthetic intermediates via independent pathways (pathways A and B, respectively, in Fig. 1) that utilize LA and cis-OPDA as common intermediates in an early biosynthetic step (Fig. 1)13, 14. Based on these reports, we hypothesized that L. theobromae also uses these pathways to produce CJ. To determine the biosynthetic pathway affording CJ, L. theobromae was administered deuterium-labeled intermediates, including [18,18,18-2H3, 17,17-2H2]LA (LA-d5), [18,18,18-2H3, 17,17-2H2]cis-OPDA (cis-OPDA-d5), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 8:0 (OPC8-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 6:0 (OPC6-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 4:0 (OPC4-d6), and [11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl iso-12-oxo-phytodienoate (iso-MeOPDA-d8) (Fig. 3). A schematic illustration of the experimental procedure is shown in Supplementary Fig. 2. cis-OPDA-d5 was synthesized using commercially available LA-d5 according to the method reported by Kajiwara et al.35, while OPC8-d6, OPC6-d6, and OPC4-d6 were synthesized according to Matsuura et al.36. CJ was detected in the extract without modification, although a portion of the EtOAc extract was treated with a CH2N2 solution to convert endogenous JA into MeJA to increase its volatility. Representative GC-MS chromatograms of authentic MeJA are shown in Supplementary Fig. 3. In the feeding experiment using LA-d5 as a substrate, the GC-MS chromatograms obtained in selected ion monitoring mode contained ion peaks at m/z 224 and 229 for MeJA and [12,12,12-2H3, 11,11-2H2]MeJA (MeJA-d5), respectively, at Rt. 7.5 min (Fig. 4). The mass fragmentation patterns for the m/z 224 and 229 ion peaks are shown in Supplementary Fig. 4 and substantiated the presence of MeJA and MeJA-d5 in the fungal culture filtrate. The GC-MS chromatograms for the analysis of CJ and [11,11,11-2H3, 10,10-2H2]CJ (CJ-d5) when using LA-d5 as a feeding substrate are shown in Fig. 5. These chromatograms contained ion peaks of m/z 164 and 169 for CJ and CJ-d5, respectively, which were detected at Rt. 15.7 min in selected ion monitoring mode. The mass fragmentation patterns of the m/z 164 and 169 ion peaks are shown in Supplementary Fig. 5 and confirmed the presence of CJ and CJ-d5 in the fungal culture filtrate. The results of the feeding experiment using cis-OPDA-d5 were identical to those of the LA-d5 experiment (data not shown).
Representative GC-MS chromatograms for measuring MeJA in feeding experimet using LA-d5. (A) Representative GC-MS chromatogram monitoring total ion. (B) Representative GC-MS chromatogram for measuring fungal derived MeJA using selected ion monitoring at m/z 224. (C) Representative GC-MS chromatogram for measuring fungal derived MeJA-d5 using selected ion monitoring at m/z 229. Representative MS chart of the peak indicated by arrow is given in Supplementary Figure S4.
Representative GC-MS chromatograms for measuring CJ in feeding experiment using LA-d5. (A) Representative GC-MS chromatogram monitoring total ion. (B) Representative GC-MS chromatogram for measuring fungal derived CJ using selected ion monitoring at m/z 164. (C) Representative GC-MS chromatogram for measuring fungal derived CJ-d5 using selected ion monitoring at m/z 169. Representative MS chart of the peak indicated by arrow is given in Supplementary Figure S5.
Deuterium-labeled OPC 8:0, OPC 6:0, and OPC 4:0 are metabolized to MeJA but not CJ
In the feeding experiment using OPC8-d6 as a substrate, the GC-MS chromatograms obtained in selected ion monitoring mode contained ion peaks at m/z 224 and 230 for MeJA and [12,12,12-2H3, 11,11-2H2, 10-2H1]MeJA (MeJA-d6), respectively, at Rt. 7.5 min (Fig. 6). The mass fragmentation patterns for the m/z 224 and 230 ion peaks are shown in Supplementary Fig. 6 and confirmed the presence of MeJA and MeJA-d6 in the fungal culture filtrate. The GC-MS chromatograms for the analysis of CJ and [11,11,11-2H3, 10,10-2H2, 6-2H1]CJ (CJ-d6) when using OPC8-d6 as a feeding substrate are shown in Fig. 7. The m/z 164 ion peak was detected at Rt. 15.7 min in the selected ion monitoring chromatogram (Fig. 7B), although the identical ion peak was not detected in the chromatogram obtained from selected ion monitoring at m/z 170 (Fig. 7C). The mass fragmentation pattern of the ion peak at m/z 164 is shown in Supplementary Fig. 7 and confirmed the presence of CJ in the fungal culture filtrate. Because the m/z 170 ion peak could not be detected in a GC-MS chromatogram of acceptable quality (Fig. 7C), it was concluded that OPC8-d6 was not used as a building block to synthesize CJ-d6. The results of the feeding experiments using OPC6-d6 and OPC4-d6 were identical to those obtained using OPC8-d6 (data not shown). The results of the deuterium-labeled OPC 8:0, OPC 6:0, and OPC 4:0 feeding experiments thus suggested that biosynthetic pathway A was not involved in CJ production in L. theobromae (Fig. 1).
Representative GC-MS chromatograms for measuring MeJA in feeding experiment using OPC 8:0-d6. (A) Representative GC-MS chromatogram monitoring total ion. (B) Representative GC-MS chromatogram for measuring fungal derived MeJA using selected ion monitoring at m/z 224. (C) Representative GC-MS chromatogram for measuring fungal derived MeJA-d6 using selected ion monitoring at m/z 230. Representative MS chart of the peak indicated by arrow is given in Supplementary Figure S6.
Representative GC-MS chromatograms for measuring CJ in feeding experiment using OPC8-d6. (A) Representative GC-MS chromatogram monitoring total ion. (B) Representative GC-MS chromatogram for measuring fungal derived CJ using selected ion monitoring at m/z 164. (C) Representative GC-MS chromatogram for measuring fungal derived CJ-d5 using selected ion monitoring at m/z 170. Representative MS chart of the peak indicated by arrow is given in Supplementary Figure S7.
Feeding deuterium-labeled iso-MeOPDA to growing fungal cultures produces labeled CJ as a metabolite but not labeled MeJA
Plants also use iso-OPDA as a key intermediate in biosynthetic pathway B to synthesize CJ14. Furthermore, it has been proposed that the final step in establishing the chemical backbone of CJ is a decarboxylation reaction in which a carboxyl group is eliminated from 3,7-didehydroJA. In a previous report demonstrating biosynthetic pathway B in plants, [16-2H1, 15-2H1]iso-OPDA (iso-OPDA-d2) was synthesized and administered to the plants to demonstrate CJ metabolism. However, the final decarboxylation step was not fully proven. To examine biosynthetic pathway B in L. theobromae as well as the decarboxylation step, an experiment to administer [11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl iso-12-oxo-phytodienoate (iso-MeOPDA-d8) was carried out. The carbon backbone of iso-MeOPDA-d8 was synthesized according to a reported method37, and deuterium labels were added to the product according to the reported method34 with some modifications, as described in the experimental section. The isotopic purity was established by comparing the data of GC-MS for iso-MeOPDA and iso-MeOPDA-d8. The incorporation of 2H2 was found to be 72% for iso-MeOPDA-d8. The synthesized compound was fed to L. theobromae, and the culture filtrate was analyzed by GC-MS. A representative GC-MS chromatogram is shown in Fig. 8. The m/z 164 and 168 ion peaks were detected at Rt. 15.7 min in selected ion monitoring mode (Fig. 8A and B, respectively). However, the predicted ion peak for m/z 170 was not detected (Fig. 8C). The mass fragmentation patterns of the m/z 164 and 168 ion peaks are shown in Supplementary Fig. 8 and confirmed the presence of CJ and [4,4-2H2, 3,3-2H2]CJ (CJ-d4) in the fungal culture filtrate. The labeled CJ-d4 pattern was determined and had specific characteristics. Ion peaks for a [M-CH3]+ fragment were observed in the CJ and CJ-d4 MS chromatograms (Supplementary Fig. 8), and a [M-CD3]+ fragment was detected in CJ-d7 (m/z 171, Supplementary Fig. 9), indicating that deletion of the methyl group at the C-1 position had occurred during MS fragmentation. This type of deletion was also observed as [M-CH3]+ from CJ and [9-2H1, 8-2H1]CJ and [M-CD2H]+ from [4,4-2H2, 1,1-2H2]CJ in the previous report9. These results supported the detection of CJ-d4 as [4,4-2H2, 3,3-2H2]CJ. Based on the abovementioned results, it appeared reasonable to suppose that CJ was synthesized via biosynthetic pathway B, and the predicted decarboxylation reaction might not be involved in the final biosynthetic step to afford CJ in L. theobromae. Interestingly, [5,5-2H2, 4,4-2H2, 2,2-2H2]MeJA (m/z 230) was not detected in the GC-MS data (Supplementary Fig. 10).
Representative GC MS/MS chromatograms analyzing fungal derived. CJ, CJ-d4, and CJ-d6 using iso-OPDA-d8 as a substrate for a feeding experiment. (A) Representative GC-MS chromatogram for measuring fungal derived CJ using selected ion monitoring at m/z 164. (B) Representative GC-MS chromatogram for measuring fungal derived CJ-d4 using selected ion monitoring at m/z 168. (C) Representative GC-MS chromatogram for measuring fungal derived CJ-d6 using selected ion monitoring at m/z 170. Representative MS chart of the peak indicated by arrow is given in Figure S8.
In this paper, it was found that L. theobromae produced CJ, although B. cinerea, V. longisporum, F. oxysporum, G. fujikuroi, and C. heterostrophus did not (Fig. 2). It appears that the ability to produce CJ is a unique feature of L. theobromae. In addition, it was suggested that the fungus used biosynthetic pathway B (Fig. 1) to produce CJ, and the predicted decarboxylation reaction might not be involved in the final biosynthesis step to produce fungal-derived CJ, suggesting the involvement of an unknown step. However, it has been generally accepted that the deuterium atoms at the α-position tend to be removed by enolization, and the α-methylene group at the C-2 position in 3,7-didehydroJA, which is strongly acidic due to the carboxyl groups, is a typical example of where this type of enolization can occur. However, Koch et al.13 have proven that deuterium-labeled atoms at the α-positions in [7-2H1, 5,5-2H2, 2,2-2H2] JA remain throughout the biosynthetic steps to give [4,4-2H2, 1,1-2H2]CJ in lima bean (Phaseolus lunatus cv. Sieva). Based on this report, it was presumed that the loss of deuterium atoms detected in the present study might not be due to enolization. To draw a more reliable conclusion, further research, such as feeding experiments applying [2-13C] and [1-13C, 2-13C]sodium acetate to fungal cultures of L. theobromae, is needed.
During our research, it was revealed that the fungus, L. theobromae, produced CJ. Since CJ has similar chemical structure with that of JA, it was assumed that CJ could mimic the biological activity of JA such as antagonistic effect upon salicylic acid signaling pathway38 that induces plant defense system. Given that CJ had JA like biological activity, L. theobromae might produce CJ to inhibit salicylic acid signaling pathway to facilitate invasion into the plants. However, this consideration was just hypothesis, and further research on the production of CJ in the fungus is needed to evaluate why the fungus synthesized CJ.
Experimental Section
General experimental procedures
NMR spectra were recorded in CDCl3 using a JNM-EX 270 FT-NMR spectrometer (JEOL) for 1H NMR experiments at 270 MHz and an AMX 500 (Bruker) for 1H NMR experiments at 500 MHz. FD-MS and FI-MS analyses were performed on a JMS-T100GCV (JEOL) instrument. GC-MS analyses were performed using a Varian instrument. Authentic CJ was purchased from Sigma-Aldrich. LA-d5 (98%) was purchased from Cambridge Isotope Laboratories, Inc.
GC-MS conditions
GC-MS analysis of CJ and MeJA was completed on a Varian CP-3800 gas chromatograph with a Varian 1200 L quadrupole MS/MS in electron ionization mode. For the analysis of CJ, the injection temperature was 150 °C, and a fused-silica capillary column (TC-5; 30 m × 0.25 mm i.d., 0.25 μm film thickness; GL Sciences) was used. The temperature program started at 40 °C for 1 min and subsequently increased at 22 °C/min to 290 °C, which was maintained for 20 min. Helium was used as the carrier gas at a linear velocity of 1.2 mL/min, and all spectra were scanned within the range m/z 10–520. For the analysis of MeJA, the injection temperature was 250 °C, and a fused-silica capillary column (TC-5) was used. The temperature program started at 80 °C for 1 min and subsequently increased at 22 °C/min to 290 °C, which was maintained for 20 min.
Identity of fungal sources
B. cinerea (MAFF No. 237695), V. longisporum (MAFF No. 243295), G. fujikuroi (MAFF No. 241712), L. theobromae (MAFF No. 306027), and C. heterostrophus (MAFF No. 243065) fungal cultures were obtained from The Genetic Resources Center, National Agriculture and Food Research Organization (NARO). The F. oxysporum culture (KF192-2) was a culture stock from the Laboratory of Plant Pathology, Research Faculty of Agriculture, Hokkaido University.
Feeding experiments
The fungi were grown in 50 mL flasks containing 20 mL of 2% potato-sucrose stationary medium at 25 °C in the dark for 14 days. Deuterium-labeled compounds were dissolved in 1 mM aq. NH4OH (500 μL) and added to the medium at a final concentration of 1 mM. For extraction, 10 mL of EtOAc was added to the culture together with addition of 1M aq. HCL (0.1 mL), and for the addition of internal standard, CJ-d7 (1 μg) was added to the separated EtOAc extract. The organic solvent in the extract were removed by a stream of N2. The resulting residues were dissolved in EtOAc. A portion of the EtOAc solution was subjected to GC-MS analysis to detect CJ, and another portion was treated with CH2N2 and subjected to GC-MS analysis to detect MeJA.
[11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl 12-oxophytodienoate (iso-MeOPDA-d8)
iso-MeOPDA (9 mg), which was synthesized according to a reported method33, was dissolved in CH3OD (1.0 mL) in an ampule; CH3ONa (4 mg) was then added to this solution. The ampule was sealed and heated at 65 °C for 5 days. The reaction mixture was quenched with 10% aq. NH4Cl and a small volume of water, and the solvent was removed under low pressure. Then, the residue was extracted with diethyl ether (10 mL × 3), and the solvent was removed under low pressure. The residue was purified by chromatography on silica gel (2 g) using ethyl acetate/n-hexane (1:4, v/v) to afford the product in a yield of 3.7 mg (35%). 1H NMR (500 MHz, CDCl3): δ 0.97 (t, J = 7.6 Hz, 3H), 1.31 (m, 6H), 1.49 (m, 2H), 1.58 (m, 2H), 2.13 (q, J = 7.4 Hz, 2H), 2.90 (d, J = 7.2 Hz, 2H), 3.64 (s, 3H), 5.19 (m, 1H), and 5.34 (m, 1H). FD-MS (m/z); 314 ([M]+ (100), 313 (31), 312 (6.3), 311 (2.1), which revealed the labeling ration of iso-MeOPDA-d8 was to be 72%.
[4,4-2H2, 3,3-2H2, 1,1,1-2H3]CJ (CJ-d7)
A solution of CJ (51.6 mg) in CH3OD (1 mL) was added dropwise to a solution of CH3ONa (40 mg) in 2 mL of CH3OD. The mixture was refluxed for 5 days. NH4Cl was added, and the organic solvent was evaporated. The residue was dissolved in water (1 mL). After the product was extracted with Et2O (50 mL × 3), the organic layer was dried over Mg2SO4 and concentrated in vacuo after filtration. The residue was purified by flash column chromatography with silica gel (40 g) using ethyl acetate/n-hexane (1:9, v/v) to give [4,4-2H2, 3,3-2H2, 1,1,1-2H3]CJ in a yield of 53.7 mg (99%). GC-MS (m/z); 171 [M]+ (100), 170 (4.3), 169 (1.7), which revealed the labeling ration of CJ-d7 was to be 94%. 1H NMR (270 MHz, CDCl3): δ 0.96 (t, J = 7.0 Hz, 3H), 2.13 (m, 2H), 2.91 (d, J = 7.1 Hz, 2H), 5.24 (m, 1H), and 5.34 (m, 1H). FI-MS (m/z); [M+] 171.
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Acknowledgements
The MeJA used as the starting material for the synthesis of deuterium-labeled compounds was kindly provided by the ZEON Corporation (Tokyo, Japan). We acknowledge the assistance of Dr. Eri Fukushi and Mr. Yusuke Takata (Research Faculty of Agriculture, Hokkaido University) in obtaining the spectroscopic data.
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R.M., N.A., K.T., Y.T., and W.S. performed the biochemical experiments. H.M., N.K., and K.M. supported the experiments, and R.M. and H.M. wrote the manuscript.
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Matsui, R., Amano, N., Takahashi, K. et al. Elucidation of the biosynthetic pathway of cis-jasmone in Lasiodiplodia theobromae . Sci Rep 7, 6688 (2017). https://doi.org/10.1038/s41598-017-05851-7
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DOI: https://doi.org/10.1038/s41598-017-05851-7
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