Abstract
Pheromones are environmentally friendly alternatives to traditional pesticides for pest control. They are widely applied for insect monitoring, mating disruption and mass trapping. Nicotiana benthamiana and N. tabacum are potential green biomass production platforms of moth sex pheromones. Using these two Nicotiana species as plant factories, we expressed biosynthetic genes of plant and insect origin in leaf tissue. Moth sex pheromone precursors (E)-11-tetradecenoic acid, (Z)-11-tetradecenoic acid and (Z)-11-hexadecenoic acid were produced by introducing the acyl-ACP thioesterases CpuFatB1 from Cuphea pulcherrima or CpaFatB2 from C. palustris and the fatty acyl desaturases Ave∆11 from Argyrotaenia velutinana, CpaE11 from Choristoneura parallela or Atr∆11 from Amyelois transitella, under the control of CaMV-35S promoter. Among the Nicotiana spp. transformants, the best line produced (Z)-11-hexadecenoic acid at 17.6% of total fatty acids in leaves, during flowering stage, corresponding to 335 µg of (Z)-11-hexadecenoic acid per gram of fresh leaf. The (Z)-11-hexadecenoic acid production lines from N. benthamiana were selected for further propagation to obtain homozygous lines. In the N. benthamiana T2 generation, the production quantity of (Z)-11-hexadecenoic acid was stable. Our study demonstrates the feasibility of stable transformation of N. benthamiana for production of moth pheromone precursors in vegetative tissue.
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Key message
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Pheromones are environmentally friendly alternatives to traditional pesticides for pest control. We established a novel approach to produce moth pheromone precursors stably.
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This is the first report on production of insect pheromone precursors over generations in plants.
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We produced (E)-11-tetradecenoic acid, (Z)-11-tetradecenoic acid and (Z)-11-hexadecenoic acid, the fatty acid precursors of pheromones used by hundreds of moth pest species.
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Worthwhile amounts of (Z)-11-hexadecenoic acid may be produced by cultivating our most productive N. benthamiana line under field conditions.
Introduction
The insect order Lepidoptera contains more than 160,000 described moth and butterfly species (Nieukerken et al. 2011). Species of moths are among the most damaging pests of food and fiber crops. Moths also have the capability of adapting fast and evolving resistance to insecticides (Simmons et al. 2010). Female moths emit species-specific sex pheromone component blends that attract males of the same species over long distances for mating (Wyatt 2003). Due to the numerous problems associated with use of conventional pesticides (Brittain and Potts 2011; Bull 1982), synthetic pheromones have emerged as an alternative for insect control (Reddy and Guerrero 2000). Currently, tons of synthetic pheromones are produced for application in pest management (Weatherston and Stewart 2002). However, use of hazardous chemicals and generation of by-products during conventional chemical synthesis of pheromones (Mori 2007, 2010) may cause pollution problems. High costs for synthesis also limit the use of pheromones in many crops.
Since the techniques for genetically engineering of plants were developed in the early 1980s, numerous research projects have focused on utilizing transgenic plants to produce high-value recombinant proteins or compounds (Boehm 2007; Karg and Kallio 2009; Lienard et al. 2007; Ma et al. 2005; Mett et al. 2008). During the past 20 years, producing insect pheromones or their biosynthetic precursors in genetically modified plant factories has been attempted. A moth pheromone precursor was produced in Nicotiana tabacum by the introduction of a moth desaturase (Nešněrová et al. 2004), and an aphid alarm pheromone was produced from endogenous plant sesquiterpene by expression of a (E)-β-farnesene synthase in Arabidopsis (Beale et al. 2006). Moreover, Ding et al. (2014) proved that transient expression of genes coding for consecutive pheromone biosynthetic steps in N. benthamiana resulted in production of biologically active multi-component sex pheromones. The sex pheromone mixtures prepared from the acetylated fatty alcohol fractions produced by the genetically modified plants has the same activity for trapping of male small ermine moths Yponomeuta evonymella and Y. padella compared to conventionally produced synthetic pheromones (Ding et al. 2014). These studies have demonstrated that it is feasible to produce highly attractive and species-specific moth pheromones in genetically modified plants. However, the use of stably transformed N. benthamiana for semi-synthetic preparation of pheromones was so far never explored.
The majority of known moth pheromones are unsaturated C10–C18 straight chain primary alcohols, acetates or aldehydes (Ando et al. 2004; Löfstedt et al. 2016). The biosynthesis of these compounds starts from de novo synthesis of palmitic acid or stearic acid, followed by desaturation, chain elongation or shortening to produce specific chain lengths, double bond positions and stereochemistry and finally the formation of the terminal functional groups (Löfstedt et al. 2016). In plant leaf tissue, the fatty acid biosynthesis takes place primarily in the chloroplasts utilizing C3 products of photosynthesis as carbon source (Bao et al. 2000). The palmitic and oleic acids so produced are then released into the cytosol as precursors for extra-plastid lipid synthesis and provide a pool of substrates that pheromone biosynthetic enzymes might utilize for moth pheromone production. Furthermore, the enzymes deployed for the biosynthesis of extra-plastid lipids and the insect desaturases introduced for the biosynthesis of moth pheromones in this study are located in the endoplasmic reticulum (Heinemann and Ozols 2003; Li et al. 2013), which also offers advantages for producing moth pheromones in plant leaves.
Nicotiana spp. are suitable to use for lipid metabolic engineering as they can be transformed by Agrobacterium with relative ease and high efficiency as well as having a fairly large green biomass (Aslan et al. 2014; Naim et al. 2012; Reynolds et al. 2015). In the present study, we used genes for Nicotiana spp. transformation that have been functionally characterized in heterologous expression systems in previous studies. These genes include: two plastid acyl-ACP thioesterases, CpuFatB1 from Cuphea pulcherrima (Myrtales: Lythraceae) (Kim et al. 2015a) and CpaFatB2 from C. palustris (Dehesh et al. 1996a) that can increase the amount of palmitic acid and myristic acid, respectively, by hydrolyzing the thioester bond of acyl-chain-ACP synthesized by the fatty acid synthase complex; three ∆11 fatty acyl desaturases, i.e., Ave∆11 from Argyrotaenia velutinana (Lepidoptera: Tortricidae) and CpaE11 from Choristoneura parallela (Lepidoptera: Tortricidae) producing (Z)-11-tetradecenoic acid (Z11-14:acid) (Liu et al. 2002) and (E)-11-tetradecenoic acid (E11-14:acid) (Liu et al. 2004), and Atr∆11 from Amyelois transitella (Lepidoptera: Pyralidae) producing (Z)-11-hexadecenoic acid (Z11-16:acid) (Ding et al. 2014). We used Agrobacterium-mediated leaf-disc stable transformation (Clemente 2006) on N. tabacum to allow pheromone precursors Z11-14:acid, E11-14:acid and Z11-16:acid production. The three pheromone precursors were produced in all regenerated transformants. Subsequently, the same set of genes were introduced into N. benthamiana. We then propagated and selected N. benthamiana lines for the production of Z11-16:acid, an immediate pheromone precursor for many moth species (Ando et al. 1979; Kehat and Dunkelbum 1990; Lynch et al. 1984; Rothschild et al. 1982). Our study proves the feasibility to produce a high quantity of moth pheromone precursors in stably transformed plants.
Materials and methods
Construction of plant expression vectors for tobacco stable transformation
CpaFatB2 (GeneBank accession number: AAC49180), Atr∆11 (JX964774), Ave∆11 (AF416738), CpaE11 (AF518014) were amplified from entry clones (Ding et al. 2014). CpuFatB1 (AGG79283) was a gift from E. Cahoon (University of Nebraska, Lincoln). Cauliflower mosaic virus 35S promoter (35S) and Octopine Synthase gene terminator (OCS) were used to regulate gene expression. For assembling multiple genes into one expression cassette, each gene, including promoter and terminator, was first amplified by PCR, with primers (Table S1) spanning from the start codon to the stop codon of the opening reading frame (ORF), on a Veriti Thermo Cycler. The conditions used were: 95 °C for 5 min, 35 cycles of 95 °C for 30 s, 55 °C for 40 s, 72 °C for 1 min, followed by a final extension for 10 min at 72 °C. The reactions were performed in a total volume of 50 μL, containing 25 μL of Maxima polymerase master mix (Thermo Scientific™), 2.5 μL for each primer (10 µM) (Table S1), 1 μL of sample cDNA (15 ng/μL), 19 μL of sterilized H2O. The PCR products were analyzed by electrophoresis on 1.5% w/v agarose gel in TAE buffer (40 mM Tris–acetate, 2 mM Na2EDTA-H2O), and gel purified with a GeneJET Gel Extraction Kit (Thermo Scientific™). Subsequently, fusion PCR (phusion®Taq, Thermo Scientific) was used to perform truncation and gene fusion for gene assembly (Atanassov et al. 2009). All genes with promoters and terminators were cloned into plant expression vector pXZP393 by Gateway recombination cloning technology (Invitrogen).
Assembly of moth pheromone biosynthetic pathways
Three plant expression vectors (Fig. 1a) were constructed to produce different pheromone precursors by assembling various transgene combinations. The expression of the exogenous genes was controlled by the 35S promoter (Gatz et al. 1992) and OCS terminator (Schünmann et al. 2003). The engineered pathways for pheromone precursors production are shown in Fig. 1b. The thioesterases encoded by CpaFatB2 and CpuFatB1 take the myristate and palmitate plastid acyl carrier protein (ACP) from chain elongation, respectively, to form the corresponding myristic (14:0) (Dehesh et al. 1996) and palmitic (16:0) acid (Kim et al. 2015). The fatty acids are acylated to 14:CoA and 16:CoA when transported out of the plastid into the cytosol. The 14:CoA and 16:CoA are then subsequently converted into the corresponding pheromone precursors Z11-14:CoA, E11-14:CoA and Z11-16:CoA, by a desaturase encoded by Ave∆11, CpaE11 or Atr∆11 (Ding et al. 2014). The expression vector with the functional transgene combination of CpuFatB1-Atr∆11 was transformed both into N. tabacum and N. benthamiana, cultivating the line for production of Z11-16:CoA. The other expression vectors that contained CpaFatB2-Ave∆11 or CpaFatB2-CapE11 were only transformed into N. tabacum, cultivating two different lines for production of Z11-14:CoA and E11-14:CoA, or E11-14:CoA alone, respectively.
Plant material and growth condition
Wild-type N. benthamiana, wild-type N. tabacum (Wisconsin 38) and transgenic plants were grown either in the greenhouse under 16 h/8 h or in a climate chamber under 14 h/10 h light/dark conditions. Growth temperature and relative humidity in greenhouse were set at 24 °C/18 °C in day/night and 40%, respectively. In the climate chamber, the temperature was set at 22 °C.
Transformation of Agrobacterium
All the constructed expression clones in pXZP393 were confirmed by sequencing and then electroporated into A. tumefaciens GV3101 (MP90RK) with settings of 1700Vmm−1, 5 ms (Eppendorf 2510).
Agrobacterium-mediated leaf-disc transformation
For each construct, 30 ml of Agrobacterium solution was incubated at 30 °C in LB medium supplemented with 50 mg/L rifampicin, 50 mg/L gentamicin and 50 mg/L spectinomycin for 24 h (30 °C, 300 rpm (INNOVA®42, Incubator Shaker Series)). The bacteria were spun down at 3,300 g for 5 min at room temperature and resuspended in LB medium without any antibiotic. Optical density (A600nm) of each Agrobacterium culture was adjusted to 0.9–1 in a total volume of 30 ml with LB medium prior to tobacco leaf-disc transformation. Plant material was obtained from 4–5-week-old Nicotiana plants grown under sterile conditions on MS medium (Murashige and Skoog 1962) in a climate chamber.
Transgenic lines were obtained by Agrobacterium-mediated leaf-disc transformation. Leaf discs (20 mm × 20 mm) were cut out and incubated 5 min in an A. tumefaciens solution, dried with sterile napkin paper and transferred to Petri dishes with MS medium (Horsch el al. 1985). After 48 h incubation in darkness, leaf discs were transferred to selection medium (MS medium supplemented with 50 mg/L kanamycin, 250 mg/L cefotaxime, 1 mg/L 6-benzylaminopurine (BAP) and 0.1 mg/L naphthalene acetic acid (NAA)). After 2–3 weeks of incubation, the calli produced on the leaf edges were transferred to shoot-inducing medium (the selection medium supplemented with 100 mg/L kanamycin). After 2–3 weeks of incubation, the shoots were transferred to root-inducing medium (identical as shoot-inducing medium, but without hormones) with 100 mg/L kanamycin and 250 mg/L cefotaxime. The shoots were finally transferred into soil and grown in greenhouse until maturity.
Sampling for leaf lipids analysis
The T0 plants regenerated from calli were used for lipid analysis. From each T0 plant at the age of 1.5 months, three pieces of different mature leaves (size ca. 50 mm × 50 mm) were randomly taken. Samples from each T0 plant were analyzed in triplicate. Then, the T0 plants were kept growing in greenhouse until maturity of T1 seeds. Subsequently, T1 seeds collected from the best target compound-producing T0 plant were sown on MS medium supplemented with 100 mg/L kanamycin. For N. tabacum and N. benthamiana, eight and thirty T1 plants from each T0 plant were cultivated, respectively. Seedlings from each T1 plant surviving the selection were transferred to soil and grown to maturity for producing T2 seeds. Thirty N. benthamiana T2 seeds from each plant were collected and cultivated to T2 plants for analysis. For T1 and T2 plant analysis, at the same age to T0 plant, three pieces of mature leaves (size was same to T0 plant) were randomly taken from each plant and mixed as one sample.
Total fatty acids analysis
For fatty acid analysis, 100–300 mg fresh leaf tissue per sample was treated by 1 mL 2% sulfuric acid in methanol containing 3.12 µg methyl nonadecanoate (19:Me) as internal standard, incubated at 90ºC for 1 h. Subsequently, 1 mL water and 1 mL heptane were added and the mixture was vigorously vortexed and centrifuged at 2000 rpm (Heraeus™ Sepatech-3760) for 2 min. Finally, ca. 1 mL heptane phase containing the fatty acids in the form of corresponding methyl esters was transferred to a new glass vial for GC/MS analysis.
TLC separation of leaf neutral lipids
For neutral lipid analysis, total lipids from 1 g fresh leaf were extracted in 4 mL of methanol/chloroform (2:1, v/v) using a glass tissue grinder. The crude extract was transferred to a glass tube, and the grinder was washed with 1 mL of chloroform, which was then transferred to the extract. One milliliter of water was added to produce a biphasic mixture, which was then vortexed vigorously and centrifuged at 2000 rpm (Heraeus™ Sepatech-3760) for 2 min. Total leaf lipids extract was then present in ca. 2.3 mL chloroform phase. From this phase, 300 µL was taken and concentrated to ca. 40 µL under gentle nitrogen flow and then loaded at 20 mm from the bottom of a thin-layer chromatography (TLC) plate without fluorescent indicator (Silica gel 60, Merck, Germany), along with standard (TLC Mix 34, Larodan, Sweden). The plate was developed in a solvent system of heptane/diethyl ether/acetic acid (60:40:1, v/v/v). The obtained lipid bands were scraped off and extracted with 1.5 mL of methanol/chloroform (2:1, v/v) containing 3.12 µg 19:Me in a sonication bath until the gel bands were totally shattered. One mL of water was added to the tube to partition the lipids into the chloroform phase, which was then transferred to a new tube and evaporated to dryness, followed by acid methanolysis as described above.
Gas chromatography/mass spectrometry (GC/MS)
Plant leaf samples were analyzed by using an Agilent 5975 mass-selective detector, coupled to an Agilent 6890 series gas chromatograph either equipped with a polar column (HP-INNOWax, 30 m × 0.25 mm, 0.25 μm film thickness) or a nonpolar column (HP-5MS, 30 m × 0.25 mm, 0.25 μm film thickness), and helium was used as carrier gas. For analysis of fatty acid methyl esters (FAMEs), the oven temperature was set at 80 °C for 1 min, then increased to 230 °C at a rate of 10 °C/min and held for 10 min.
To determine the position of double bonds in target compounds, DMDS derivatization was performed according to Dunkelblum et al. (1985). The DMDS adducts were analyzed by GC/MS on a nonpolar column (HP-5MS) using the following oven temperature program: 80 °C for 2 min, then increased at a rate of 15 °C/min to 140 °C, then increased at a rate of 5 °C /min to 260 °C and held for 3 min.
Statistical analysis
Data were subjected to analysis of variance, and means were compared by unpaired t-test with two-tailed P value by using the Prism software program (Prism 8). P < 0.05 indicates a significant difference.
Results
Fatty acid composition in N. tabacum and N. benthamiana leaves
The GC/MS analysis showed that wild-type N. tabacum leaves contained 54 ± 5% linolenic acid (18:3), 12 ± 3% palmitic acid (16:0), 10 ± 3% linoleic acid (18:2), 8 ± 2% (Z,Z,Z)-7,10,13-hexadecatrienoic acid (16:3) and 2 ± 1% stearic acid (18:0) (Table 1 and Fig. 2a). In addition, oleic acid (18:1), (Z,Z)-7,10-hexadecadienoic acid (16:2) and (Z)-13-hexadecenoic acid (16:1(13)) and arachidic acid (20:0) were found in the leaf (Table 1 and Fig. 2a). Wild-type N. benthamiana leaves showed a similar fatty acid composition as in N. tabacum, the majority of the total fatty acids were 18:3, 18:2, 16:0 and 16:3, followed by 16:1(13), 18:0 and 18:1, and besides that 16:2 and 20:0 were also detected (Table 2 and Fig. 2b).
A large variation in the production of 14:0, 16:0 and unsaturated pheromone precursors was observed in both T0 and T1 N. tabacum lines (Table 1 and Fig. 3). For production of C14 pheromone precursor in N. tabacum, CpaFatB2-Ave∆11 and CpaFatB2-CpaE11 transformants contained 14:0 and 16:0 from 0.2 to 5.5% and 12.3 to 38.3%, respectively (Table 1), higher than the wild type which produced 0.1% of 14:0 and 12.2% of 16:0. CpaFatB2-Ave∆11 transformants produced Z11-14:acid and a smaller amount of E11-14:acid (Fig. 4a), and CpaFatB2-CpaE11 transformants produced E11-14:acid (Fig. 4b). For production of C16 pheromone precursors in N. tabacum, CpuFatB1-Atr∆11 transformants produced 0.2 to 1.6% of 14:0 and 13.0 to 30.0% of 16:0, higher than that from the wild-type plants (Table 1). Z11-16:acid was produced in the transformant lines up to 0.9% (Table 1 and Fig. 4c). Taking these transformant lines to a second generation did not improve the levels of pheromone precursor production (Fig. 3). Eight T1 plants from CpuFatB1-Atr∆11 #001 T0 parent produced 13.1 to 22.5% of 16:0 (Fig. 3a) and 0.1 to 1.0% of Z11-16:acid (Fig. 3b).
CpuFatB1-Atr∆11 transformants of N. benthamiana also showed a large variation in T0 and T1 lines. T0 N. benthamiana transformants contained 15.0 to 31.6% of 16:0 (with the exception that #027 plant produced 10.0%), higher than the wild-type plants that produced an average of 14.8% (Table 2). These transformants produced Z11-16:acid (Fig. 4d), ranging from 0.1 to 4.8% (Table 2). Among the twenty-eight T0 transformants, six plants accumulated more than 2.0% of Z11-16:acid (Table 2). The percentage of Z11-16:acid varied significantly (0.3 to 4.2%) among different leaves from same plant at the same stage, indicating presence of chimerism in the plant (Fig. S1). More than 150 T1 plants from five T0 parent plants (at least 30 T1 from each selected T0) were grown to the next generation, and the production of Z11-16:acid ranged from 0.1 to 10.1% (Fig. 5), thus in many cases reaching higher percentages as compared to the T0 plants. Besides this, the T1 plant #025-16 produced even higher proportion of Z11-16:acid in the mature leaves during plant flowering (Fig. 6). This line produced 17.6% Z11-16:acid, corresponding to 335 µg per gram fresh leaf and equaling ca. 50 mg Z11-16:acid in the entire plant. The highest 16:0 production recorded in T1 plants was 38.1% (Fig. 5), higher than the best T0 plant (Table 2). Five T1 plants from each line are propagated to next generation. Two T2 lines (#00621, #00830) still showed big variation in Z11-16:acid production (Fig. 5a–b). The other three T2 lines (#00925, #02516, #02615) showed smaller variation (Fig. 5c–e), and in the #02615 T2 line, we consider the Z11-16:acid production stable (Fig. 5e).
Fitness of transgenic N. tabacum and N. benthamiana
Compared to the wild-type N. tabacum, the transgenic tobacco was growing much slower, and the leaves were less green when the CpaFatB2 was introduced. There were also small tissue lesions on the surface of leaves (data not shown). In addition, such deleterious effect on the leaves as well as delayed growth rate and chlorosis were more often observed in the plants that produced higher amounts of Z/E11-14:acid, and more than one-fifth of T1 plants of CpaFatB2-CpaE11 transformants did not survive during development (Fig. 3). However, no developmental problem was observed in CpuFatB1-Atr∆11 transformed N. tabacum and N. benthamiana.
Lipid fractions in transgenic N. benthamiana leaves
In order to understand the distribution of pheromone precursors in transgenic N. benthamiana leaves, total lipids were separated by TLC into different molecular classes analysis (Fig. S2). The results showed that the wild-type leaves contain about 80% polar lipids (PL), 10% sterol esters (SE), 4% monoacylglycerols (MAG), 3% triacylglycerols (TAG) and diacylglycerols (DAG) plus 1% free fatty acids (FFA) (Fig. 7a). Compared to the wild type, the amount of TAG and SE in the transgenic plants was significantly increased.
In wild-type leaves, nearly 80% of 16:0 was present in PL, and small amount of 16:0 was found in SE, TAG, MAG and DAG, whereas the transformed leaves showed a significant enrichment of 16:0 in the TAG and SE, at about 20–40%. A small fraction of 16:0 was present in the MAG, DAG and FFA, at a similar level as in the wild type. The pheromone precursor Z11-16:acid shows a similar distribution to 16:0 (Fig. 7b).
Discussion
The successful production of several insect sex pheromone precursors in N. tabacum and N. benthamiana by stable transformation was demonstrated in this study. All of the transformed plastid thioesterases and fatty acyl desaturases were functionally active in producing pheromone precursor in both Nicotiana species. This is the first report of Z/E11-14:acid production in a plant by stable transformation and levels of up to 17.6% Z11-16:acid of the total fatty acids was achieved. The Z11-16:acid production in N. benthamiana was better than in N. tabacum (Tables 1 and 2). The average value of Z11-16:acid production in T0 N. tabacum was 0.2% (Table 1), whereas in T0 N. benthamiana, it was 1.8% (Table 2). The best N. benthamiana transgenic line #025 produced as high as 13.6% of Z11-16:acid of the total fatty acids in T2 plants (Fig. 5), which is much higher than the production reported by Nešnerová et al. (2004), who claimed that 6% of Z11-16:acid of total fatty acids was produced in their transgenic N. tabacum NtD15B line. The quantity of Z11-16:acid in N. benthamiana was calculated as 335 µg per gram fresh leaf, compared to 32 µg per gram of N. tabacum fresh leaf in Nešnerová et al. 2004. The results suggest that N. benthamiana has potential to be more efficient than N. tabacum as a plant factory for Z11-16:acid production. In the study of Ding et al. (2014), 381 µg per gram fresh leaf of Z11-16:acid was produced in N. benthamiana by transient expression, which is a massive overexpression of exogenous genes over a few days that ignores the health of the plant. Here, the production of 335 µg per gram leaf of Z11-16:acid by stable transformation shows the ability of vegetative material to function with the expression of CpuFatB1 and Atr∆11 and yield compounds over development, providing the potential for further commercial production.
Interestingly, although at low levels, we detected the elongation product (Z)-13-octadecenoic acid (Z13-18:acid) in both transformed N. benthamiana and N. tabacum lines when the Z11-16:acid was produced. This indicates that the novel fatty acids are accepted by an endogenous fatty acyl elongase in both species. Additionally, it is interesting that both wild-type N. tabacum and N. benthamiana produce more than 2% monounsaturated (Z)-13-hexadecenoic acid (Z13-16:acid) in their fatty acid profiles. Z13-16:acid is a pheromone precursor of the moth Herpetogramma submarginale (Yan et al. 2015b), which uses (Z)-13-hexadecenyl acetate (Z13-16:OAc) as its major sex pheromone component.
Moreover, it is observed that in transgenic N. benthamiana T1 plant #025–16, the amount of Z11-16:acid increased from 10.1% of total fatty acids in 6-week-old plants to 17.6% in 3-month-old flowering plants (Fig. 6). This may be due to some of the fatty acids being re-allocated from polar lipids to neutral lipids during the plant development. The fatty acids in the leaves reach a maximum at early flowering (Chu and Tso 1968; Leech et al. 1973), which provides an improvement of substrates to desaturase during leaf oil accumulation. The overexpression of acyl-ACP thioesterases has previously been reported to modify oil profile in transgenic plants (Mandal et al. 2000; Salas et al. 2002; Voelker et al. 1996). Overexpression of Arabidopsis thaliana thioesterases in transgenic N. benthamiana leaf was confirmed to increase the TAG as well (EI-Tahchy et al. 2017). Our results of lipid distribution in N. benthamiana leaves also indicate that the thioesterase gene CpuFatB1 elevated the TAG amount, leading to an increase in pheromone precursor levels (Fig. 7). Medium-chain fatty acids (MCFA) produced in leaves result in unbalanced membrane lipid profiles and undesirable chlorosis and cell death (Reynolds et al. 2017), which we think might be the reason for low productivity of pheromone precursors and insignificant increase of 14:0. Also, the deleterious effect on the CpaFatB2-CpaE11 N. tabacum transformants is likely caused by the E11-14:acid product rather than 14:0, because no deleterious effect was observed in CpuFatB1-Atr∆11 transformed Nicotiana spp., which also produced higher 14:0 than the wild-type plants. Reynolds et al. (2017) demonstrated that overexpression of the KENNEDY pathway genes can push the MCFA to the TAG pool to increase the MCFA production in leaf oils without disturbing membrane homoeostasis and cell death. Therefore, to improve TAG accumulation could be a means to increase the production of pheromone precursor by sequestering products into TAG instead of ending up in membranes with a negative influence on plant function and health.
Typically TAG accounts for less than 1.5% of the total leaf fatty acids and takes up less than 3% of de novo synthesized fatty acids (Fan et al. 2013a; Yang and Ohlrogge 2009). However, benefitting from the development of biotechnology and utilizing bioengineering approaches the levels of TAG in the leaves may increase up to 30–33% TAG (Vanhercke et al. 2017; Cernac and Benning 2004; Eastmond 2006; Kelly et al. 2011; Santos-Mendoza et al. 2008; Hu et al. 2017; Nguyen et al. 2015; Pidkowich et al. 2007). This may be implemented as existing possibilities in order to optimize the plant factory in future studies. Furthermore, increasing the exogenous gene activities by modification of promoters and enhancer (Kay et al. 1987; Minetoki et al. 1998), transformation of multiple transgene copies (Carrier et al. 1998; Mansur et al. 2005; Nguyen et al. 2015; Schultz et al. 1987; Fath et al. 2011) and transformation of virus silencing suppressor genes (Naim et al. 2016) might also contribute to higher quantity of pheromone precursor in plant factories.
In conclusion, in the present study we established a novel approach for stable production of moth sex pheromone precursors. Nicotiana spp. were genetically modified for production of pheromone precursors via integration of genes using Agrobacterium-mediated leaf-disc transformation. This is the first report on an extended production of insect pheromone precursors over generations in plants. Our best line of N. benthamiana produced 335 µg of the target compound per gram of fresh leaf, demonstrating it a good platform species for production of C16 pheromone precursors, which can be simply converted into pheromones by a semi-synthetic approach. Considering that the production of N. benthamiana green biomass is as high as 100–300 tons per hectare (Sheen, 1983; Werner et al. 2011), a worthwhile amount of pheromone precursors may be produced by cultivating our most productive N. benthamiana line under field conditions. Also, our study is a step forward toward our long-term vision of producing moth pheromones in stably transformed plants that can be used for direct emission of the pheromones for attraction or mating disruption.
Author contributions statement
YHX, BJD, HLW, CJS, PH and CL conceived and designed the study. YHX and BJD carried out vector design and sequencing; YHX performed leaf-disc transformation, plant cultivation and all the sample analysis; YHX drafted the manuscript, and all authors reviewed and edited the manuscript.
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Acknowledgement
Open access funding provided by Lund University. This work was supported by grants from the Carl Trygger Foundation for Scientific Research, Swedish Foundation for Strategic Research (Oil Crops for the Future), and FORMAS to Christer Löfstedt. The Chinese Scholarship Council supported Yihan Xia’s PhD scholarship. We would like to thank Prof. Edgar Cahoon for providing the CpuFatB1 gene plasmid and Erling Jirle for excellent technical support.
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Xia, YH., Ding, BJ., Wang, HL. et al. Production of moth sex pheromone precursors in Nicotiana spp.: a worthwhile new approach to pest control. J Pest Sci 93, 1333–1346 (2020). https://doi.org/10.1007/s10340-020-01250-6
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DOI: https://doi.org/10.1007/s10340-020-01250-6