Yeast engineering to express sex pheromone gland genes of the oriental fruit moth,Grapholita molesta

Mating disruption by using sex pheromone is an ecofriendly alternative way to control insect pests. To be effective, large amounts of sex pheromone are needed, leading to a relatively high production cost. To reduce the cost for chemical synthesis of sex pheromone, yeast engineering technology has been devised. This study used a baker's yeast, Saccharomyces cerevisiae, to express genes associated with sex pheromone biosynthesis of the Oriental fruit moth, Grapholita molesta. Compared to other fatty acid biosynthetic pathways, two steps that are unique to pheromone gland of G. molesta are proposed: desaturation at even number catalyzed by desaturase (Gm-DES) and terminal reduction catalyzed by fatty acyl reductase (Gm-FAR). Gm-DES and Gm-FAR were cloned into a yeast expression vector, pYES2.1. They were used to transform S. cerevisiae by a double transfection method. The transformed yeast was induced with 2% galactose to over-express these two exogenous genes. Their expression was confirmed by RT-PCR and western blotting. To facilitate pheromone production, transformed yeasts were supplied with myristic acid during over-expression. Resulting fatty acid composition was analyzed by GC-MS after fatty acid methyl ester derivatization. Control yeast produced mostly saturated fatty acids. However, a single gene (Gm-DES)-transformed yeast produced unsaturated fatty acids at ∆9 such as Z9-tetradecenoic acid (Z9-14:1), palmitoleic acid (Z9-16:1), and oleic acid (Z9-18:1) in addition to saturated fatty acids. The double-transformed yeast produced an additional component, alcohol form of oleic acid (Z9-18:OH). These results suggest that Gm-DES can catalyze desaturation of fatty acids at ∆9 and Gm-FAR can reduce terminal carboxylic acid into alcohol.     

Discovery of a disused desaturase gene from the pheromone gland of the moth Ascotis selenaria, which secretes an epoxyalkenyl sex pheromone

Female Ascotis selenaria (Geometridae) moths use 3,4-epoxy-(Z,Z)-6,9-nonadecadiene, which is synthesized from linolenic acid, as the main component of their sex pheromone. While the use of dietary linolenic or linoleic fatty acid derivatives as sex pheromone components has been observed in moth species belonging to a few families including Geometridae, the majority of moths use derivatives of a common saturated fatty acid, palmitic acid, as their sex pheromone components. We attempted to gain insight into the differentiation of pheromone biosynthetic pathways in geometrids by analyzing the desaturase genes expressed in the pheromone gland of A. selenaria. We demonstrated that a Δ11-desaturase-like gene (Asdesat1) was specifically expressed in the pheromone gland of A. selenaria in spite of the absence of a desaturation step in the pheromone biosynthetic pathway in this species. Further analysis revealed that the presumed transmembrane domains were degenerated in Asdesat1. Phylogenetic analysis demonstrated that Asdesat1 anciently diverged from the lineage of Δ11-desaturases, which are currently widely used in the biosynthesis of sex pheromones by moths. These results suggest that an ancestral Δ11-desaturase became dysfunctional in A. selenaria after a shift in pheromone biosynthetic pathways.     

Neofunctionalization in an ancestral insect desaturase lineage led to rare Δ6 pheromone signals in the Chinese tussah silkworm

The Chinese tussah silkworm, Antheraea pernyi (Lepidoptera: Saturniidae) produces a rare dienoic sex pheromone composed of (E,Z)-6,11-hexadecadienal, (E,Z)-6,11-hexadecadienyl acetate and (E,Z)-4,9-tetradecadienyl acetate, and for which the biosynthetic routes are yet unresolved. By means of gland composition analyses and in vivo labeling we evidenced that pheromone biosynthesis towards the immediate dienoic gland precursor, the (E,Z)-6,11-hexadecadienoic acid, involves desaturation steps with Δ⁶ and Δ¹¹ regioselectivity. cDNA cloning of pheromone gland desaturases and heterologous expression in yeast demonstrated that the 6,11-dienoic pheromone is generated from two biosynthetic routes implicating a Δ⁶ and Δ¹¹ desaturase duo albeit with an inverted reaction order. The two desaturases first catalyze the formation of the (E)-6-hexadecenoic acid or (Z)-11-hexadecenoic acid, key mono-unsaturated biosynthetic intermediates. Subsequently, each enzyme is able to produce the (E,Z)-6,11-hexadecadienoic acid by accommodating its non-respective mono-unsaturated product. Besides elucidating an unusually flexible pheromone biosynthetic pathway, our data provide the first identification of a biosynthetic Δ⁶ desaturase involved in insect mate communication. The occurrence of this novel Δ⁶ desaturase function is consistent with an evolutionary scenario involving neo-functionalization of an ancestral desaturase belonging to a gene lineage different from the Δ¹¹ desaturases commonly involved in moth pheromone biosynthesis.     

Pheromone biosynthetic pathways in the moths Heliothis subflexa and Heliothis virescens

Sex pheromones of many moth species have relatively simple structures consisting of a hydrocarbon chain with a functional group and one to several double bonds. These sex pheromones are derived from fatty acids through specific biosynthetic pathways. We investigated the incorporation of deuterium-labeled tetradecanoic, hexadecanoic, and octadecanoic acid precursors into pheromone components of Heliothis subflexa and Heliothis virescens. The two species utilize (Z)11-hexadecenal as the major pheromone component, which is produced by Delta11 desaturation of hexadecanoic acid. H. subflexa also produced (Z)11-hexadecanol and (Z)-11-hexadecenyl acetate via Delta11 desaturation. In H. subflexa, octadecanoic acid was used to biosynthesize the minor pheromone components (Z)9-hexadecenal, (Z)9-hexadecenol, and (Z)9-hexadecenyl acetate. These minor components are produced by Delta11 desaturation of octadecanoic acid followed by one round of chain-shortening. In contrast, H. virescens used hexadecanoic acid as a substrate to form (Z)11-hexadecenal and (Z)11-hexadecenol and hexadecenal. H. virescens also produced (Z)9-tetradecenal by Delta11 desaturation of the hexadecanoic acid followed by one round of chain-shortening and reduction. Tetradecanoic acid was not utilized as a precursor to form Z9-14:Ald in H. virescens. This labeling pattern indicates that the Delta11 desaturase is the only active desaturase present in the pheromone gland cells of both species.     

Inhibitory effect of 10,11-methyl-enetetradec-10-enoic acid on a Z9-desaturase in the sex pheromone biosynthesis of Spodoptera littoralis

The effect of 10,11-methylenetetradec-10-enoic acid on the sex pheromone biosynthetic pathway of Spodoptera littoralis is reported. This new cyclopropene fatty acid inhibited the biosynthesis of the main pheromone component from labeled myristicacid. The study of each Z desaturation step revealed that the Z9-desaturase of E11–14:Acid was inhibited, whereas the Z11-desaturase of 16:Acid was not affected. The results presented in this article agree with our hypothesis that the methylenehexadecenoic acids are beta-oxidized in the pheromone gland to the corresponding methylenetetradecenoic acids. © 1994 Wiley-Liss, Inc.     

Sex pheromone biosynthesis in the processionary moth Thaumetopoea pityocampa by delta-13 desaturation

In vivo treatments of female sex pheromone glands of the processionary moth, Thaumetopoea pityocampa, with mass-labeled fatty acids showed that (Z)-13-hexadecen-11-ynyl acetate, the main sex pheromone component, is biosynthesized from palmitic acid by the combined action of delta-11 and delta-13 desaturases. The involvement of this unusual delta-13 has been proven by application of [16,16,16-2H3] [1,2-13C2]-hexadecanoic acid to the glands with a resultant incorporation of all labeled atoms into the pheromone and each one of the corresponding intermediates. These results seem to exclude alternative biosynthetic pathways, such as chain shortening and elongation combined with delta-11 desaturation. The delta-11 desaturase responsible for the formation of the triple bond in both the 11-hexadecynoyl and (Z)-13-hexadecen-11-ynoyl intermediates is also an unusual enzyme not previously reported in lepidopteran sex pheromone biosynthesis.     

cDNA cloning and in situ hybridization of Delta11-desaturase, a key enzyme of pheromone biosynthesis in Ostrinia scapulalis (Lepidoptera: Crambidae)

Female sex pheromones are considered to be produced in a "pheromone gland" located in the terminal abdominal segments (8th-10th, TAS) of a moth; however, in many moth species, the cells that produce pheromones have not actually been specified. We investigated cells in the TAS that synthesize pheromones in the adzuki bean borer Ostrinia scapulalis, by locating pheromones and their precursors, and mRNA for Delta11-desaturase, a key enzyme in pheromone biosynthesis. We demonstrated that the pheromone components, (E)-11- and (Z)-11-tetradecenyl acetates, and their fatty acyl precursors were specifically contained in the dorsal part of the TAS. A cDNA (OscaZ/E11) that encodes a Delta11-desaturase was cloned from the TAS. RT-PCR and in situ hybridization unequivocally showed that OscaZ/E11 is specifically expressed in the modified epidermal cells located at the dorsal end of the 8th-9th intersegmental membrane.     

Thiafatty acids as tracers to investigate biosynthetic pathways of lepidopteran sex pheromones

In order to investigate the potential utility of thiafatty acids as tracers for biosynthetic studies of moth sex pheromones, a series of thiatetradecanoic acids, namely 8-, 9-, 10-, 11-, 12- and 13-thiatetradecanoic, were prepared and their metabolism was investigated in pheromone glands of Spodoptera littoralis. Analysis by gas chromatography coupled to mass spectrometry of extracts from pheromone glands treated with the above acids showed that only 8-thiatetradecanoic acid and 13-thiatetradecanoic acid were metabolized by desaturation and were incorporated into the sex pheromone biosynthetic pathway. 13-Thiatetradecanoic acid was converted into (E)- and (Z)-13-thiatetradec-11-enoic acids, (Z,E)-13-thiatetradeca-9,11-dienoic acid, 11-thiadodecanoic acid, (E)- and (Z)-11-thiadodec-9-enoic acids and 15-thiahexadecanoic acid. 8-Thiatetradecanoic acid gave rise to two monoenoic thiafatty acids and two dienoic thiafatty acids, which were assigned to (Z)- and (E)-8-thiatetradec-11-enoic acids, (Z,E)-8-thiatetradeca-9,11-dienoic acid and (E,E)-8-thiatetradeca-10,12-dienoic acid. The other thiafatty acids tested, 9-, 10-, 11- and 12-thiatetradecanoic acids, were not metabolized by desaturation, although the corresponding products of beta-oxidation and chain elongation were detected. The occurrence of sulfoxides was not detected in this case, in disagreement with results on the metabolism of some thiaacids previously reported by other authors in yeast, Saccharomyces cerevisiae.     

Key biosynthetic gene subfamily recruited for pheromone production prior to the extensive radiation of Lepidoptera

Background  

Moths have evolved highly successful mating systems, relying on species-specific mixtures of sex pheromone components for long-distance mate communication. Acyl-CoA desaturases are key enzymes in the biosynthesis of these compounds and to a large extent they account for the great diversity of pheromone structures in Lepidoptera. A novel desaturase gene subfamily that displays Δ11 catalytic activities has been highlighted to account for most of the unique pheromone signatures of the taxonomically advanced ditrysian species. To assess the mechanisms driving pheromone evolution, information is needed about the signalling machinery of primitive moths. The currant shoot borer, Lampronia capitella, is the sole reported primitive non-ditrysian moth known to use unsaturated fatty-acid derivatives as sex-pheromone. By combining biochemical and molecular approaches we elucidated the biosynthesis paths of its main pheromone component, the (Z,Z)-9,11-tetradecadien-1-ol and bring new insights into the time point of the recruitment of the key Δ11-desaturase gene subfamily in moth pheromone biosynthesis.     

Effect of a neuroendocrine factor on sex pheromone biosynthesis in the tomato looper,Chrysodeixis chalcites (Lepidoptera: Noctuidae)

The presence of a pheromone biosynthesis activating neurohormone in the head gandlia, and its effect on the sex phermone biosynthetic pathway, were investigated in the tomato looper, Chrysodeixis chalcites (Esper). Comparison of pheromone components and precursor levels in the presence and absence of the factor was performed using untreated, ligated and ligated and injected virgin females. Pheromone glands of treated and untreated moths were extracted and analyzed by capillary gas chromatography for their most abundant pheromone components, (Z)-7-dodecenyl acetate and (Z)-9-tetradecenyl acetate, and the putative biosynthetic precursors hexadecanoate, (Z)-11-hexadecenoate, (Z)-9-tetradecenoate and (Z)-7-dodecenoate. Comparison of the amounts of the pheromone and precursor components in the three groups of females indicated that a neuroendocrine factor is involved in the regulation of the pheromone biosynthesis in C. chalcites. Lack of such a factor resulted in a marked decrease of the sex pheromone components as well as the three unsaturated putative biosynthetic precursors. However, no decrease was observed in the content of palmitoate, suggesting that the Δ11 desaturation step is affected by the neuroendocrine factor. Injection of head ganglia extracts into ligated females resulted in a recovery of unsaturated precursor and phermone content. Both male and female head ganglia were found to contain a sex pheromone biosynthesis regulatory factor. However, the stimulatory pattern of the factor from the two sexes was different, suggesting that the two factors are quantitatively and/or qualitatively distinct.     

Comparative study of sex pheromone composition and biosynthesis in Helicoverpa armigera, H. assulta and their hybrid

Two Helicoverpa species, H. armigera and H. assulta use (Z)-11-hexadecenal and (Z)-9-hexadecenal as their sex attractant pheromone components but in opposite ratios. Since both female and male interspecific hybrids produced by female H. assulta and male H. armigera have been obtained in our laboratory, we can make a comparative study of sex pheromone composition and biosynthesis in the two species and their hybrid. With GC and GC-MS analyses using single gland extracts, the ratio of (Z)-9-hexadecenal to (Z)-11-hexadecenal was determined as 2.1:100 in H. armigera, and 1739:100 in H. assulta. The hybrid has a ratio of 4.0: 100, which is closer to that of H. armigera, but significantly different from H. armigera. We investigated pheromone biosynthesis with labeling experiments, using various fatty acid precursors in H. armigera, H. assulta and the hybrid. In H. armigera, (Z)-11-hexadecenal is produced by delta11 desaturation of palmitic acid, followed by reduction and terminal oxidation; (Z)-9-hexadecenal results from delta11 desaturation of stearic acid, followed by one cycle of chain shortening, reduction and terminal oxidation. delta11 desaturase is the unique desaturase for the production of the two pheromone components. In our Chinese strain of H. assulta, palmitic acid is used as the substrate to form both the major pheromone component, (Z)-9-hexadecenal and the minor one, (Z)-11-hexadecenal. Our data suggest that delta9 desaturase is the major desaturase, and delta11 desaturase is responsible for the minor component in H. assulta, which is consistent with previous work. However, the weak chain shortening acting on (Z)-9 and (Z)-11-octadecenoic acid, which is present in the pheromone glands, does occur in this species to produce (Z)-7 and (Z)-9-hexadecenoic acid. In the hybrid, the major pheromone component, (Z)-11-hexadecenal is produced by delta11 desaturation of palmitic acid, followed by reduction and terminal oxidation. The direct fatty acid precursor of the minor component, (Z)-9-hexadecenoic acid is mainly produced by delta9 desaturation of palmitic acid, but also by delta11 desaturation of stearic acid and one cycle of chain shortening. The greater relative amounts of (Z)-9-hexadecenal in the hybrid are due to the fact that both palmitic and stearic acids are used as substrates, whereas only stearic acid is used as substrate in H. armigera. The evolutionary relationships between the desaturases in several Helicoverpa species are also discussed in this paper.     

Sex pheromone biosynthesis in the tortricid moth Planotortrix excessana (Walker) involves chain-shortening of palmitoleate and oleate

Biosynthesis of the sex pheromone components, (Z)-5-tetradecenyl acetate (Z5-14:OAc) and (Z)-7-tetradecenyl acetate (Z7-14:OAc), was investigated in the New Zealand tortricid moth Planotortrix excessana (Walker) by fatty acid methyl ester (FAME) analysis of base-methanolyzed extracts of lipids in the sex pheromone gland and through application of various labelled fatty acids. Analysis of the base-methanolyzed gland extracts revealed common FAMEs, including methyl oleate and methyl palmitoleate, as well as the FAMEs of the putative precursors, methyl (Z)-5-tetradecenoate and methyl (Z)-7-tetradecenoate. Application of labelled, saturated fatty acids, myristic, palmitic, and stearic did not result in any significant incorporation of label into either of the unsaturated pheromone components, although label was incorporated into tetradecyl acetate (14:OAc). In contrast, application of labelled oleic acid resulted in incorporation of label into Z5-14:OAc but not into Z7-14:OAc or into 14:OAc, whereas application of labelled palmitoleic acid resulted in incorporation of label into Z7-14:OAc but not into Z5-14:OAc or 14:OAc. These data support a route for biosynthesis of Z5-14:OAc and Z7-14:OAc in this species by limited β-oxidation of the common fatty acyl moieties, respectively, oleate (involving two cycles of 2-carbon chain-shortening) and palmitoleate (involving only one cycle of 2-carbon chain-shortening), and apparently involving no desaturase (other than the common Δ9) specific to sex pheromone biosynthesis. Interestingly, P. excessana females biosynthesize the same component (Z5-14:OAc) from an entirely different route from that of the related species Ctenopseustis obliquana (which biosynthesizes Z5-14:OAc by Δ5-desaturation of myristate). Additionally, the pheromone biosynthesis activating neuropeptide (PBAN) stimulates pheromone biosynthesis in this species. Arch. Insect Biochem. Physiol. 37:158–167, 1998. © 1998 Wiley-Liss, Inc.     

Acetylation of alcohols in the pheromone biosynthesis of the tomato looper,Chrysodeixis chalcites (Lepidoptera: Noctuidae)

A series of C11–C14 alcohols, varying in the number, position and geometry of double bonds, was applied topically to the sex pheromone glands of the tomato looper, Chrysodeixis chalcites, in order to study the acetylation step in the pheromone biosynthesis of this moth. Each application contained one of the alcohols and (Z)-11-tetradecenol, in equimolar amounts, as a metabolic standard for comparison of the relative conversion of the alcohols to acetates in the terminal biosynthetic step. One secondary and one tertiary alcohol were also included in the study. All alcohols were converted to the corresponding acetates at similar relative rates indicating that this step has a very low substrate specificity. One alcohol, (Z)-9-dodecenol was applied to the glands of head ligated females, which produces very small amounts of pheromone, in order to investigate the relation between the total biosynthesis of the pheromone and the acetylation step. The decrease in pheromone biosynthesis due to ligation of the head did not affect the acetylation step.     

CONTROL OF SEX PHEROMONE BIOSYNTHETIC PATHWAY BY PBAN IN ASIAN CORN BORER OSTRINIA FURNACALlS*

Abstract Sex pheromone titer in Ostrinia furnacalis was significantly decreased to a very low level by decapitation, but it could be restored by injection of head extract prepared from both male and female moths or synthetic pheromone biosynthesis activating neuropepide (PBAN). This fact indicates that pheromone production is under the control of a PBAN-like factor. The sex pheromone biosynthetic pathway of O. furnacalis originates with the biosynthesis of palmitic acid and followed by A14 desaturation, chain shortening, reduction and acetylation to form the pheromone components, (Z) and (E)-12-tetradecenyl acetate. In order to determine which step in the pathway is controlled by PBAN, the incorporation of different labeled precursors into the pheromone and its intermediate were studied. Our results suggest that PBAN controls pheromone biosynthesis in O. furnacalis by mainly regulating an early step from acetate to palmitic acid.     

Cloning and functional characterization of a fatty acid transport protein (FATP) from the pheromone gland of a lichen moth, Eilema japonica, which secretes an alkenyl sex pheromone

Sex pheromones of moths are largely classified into two types based on the presence (Type I) or absence (Type II) of a terminal functional group. While Type-I sex pheromones are synthesized from common fatty acids in the pheromone gland (PG), Type-II sex pheromones are derived from hydrocarbons produced presumably in the oenocytes and transported to the PG via the hemolymph. Recently, a fatty acid transport protein (BmFATP) was identified from the PG of the silkworm Bombyx mori, which produces a Type-I sex pheromone (bombykol). BmFATP was shown to facilitate the uptake of extracellular fatty acids into PG cells for the synthesis of bombykol. To elucidate the presence and function of FATP in the PG of moths that produce Type-II sex pheromones, we explored fatp homologues expressed in the PG of a lichen moth, Eilema japonica, which secretes an alkenyl sex pheromone (Type II). A fatp homologue cloned from E. japonica (Ejfatp) was predominantly expressed in the PG, and its expression is upregulated shortly after eclosion. Functional expression of EjFATP in Escherichia coli enhanced the uptake of long chain fatty acids (C₁₈ and C₂₀), but not pheromone precursor hydrocarbons. To the best of our knowledge, this is the first report of the cloning and functional characterization of a FATP in the PG of a moth producing a Type-II sex pheromone. Although EjFATP is not likely to be involved in the uptake of pheromone precursors in E. japonica, the expression pattern of Ejfatp suggests a role for EjFATP in the PG not directly linked to pheromone biosynthesis.     

Biosynthesis of 10,12-dienoic fatty acids by a bifunctional Delta11 desaturase in Spodoptera littoralis

In the biosynthetic pathway of Spodoptera littoralis sex pheromone, (E,E)-10,12-tetradecadienoic acid is produced from (Z)-11-tetradecenoic acid by desaturation and concomitant migration of the precursor double bond. With the aim of identifying the enzyme involved in this biotransformation, yeast Deltaelo1/Deltaole mutants, which are both elongase 1 and Delta9 desaturase-deficient, were transformed with the S. littoralis Delta11 desaturase gene using a Cu+2 inducible expression vector. The transformants produced a recombinant polyhistidine-tagged Delta11 desaturase that could be detected by immunoblotting from cell lysates. Lipid analysis revealed that besides producing large quantities of C11-monounsaturated fatty acids, mainly (Z)-11-hexadecenoic acid, (E,E)-10,12-tetradecadienoic acid and minor amounts of (E,Z)-10,12-hexadecadienoic acid were also produced, as well as very low quantities of another tetradecadienoate, which was tentatively identified as the (E,Z)-10,12-tetradecadienoic isomer. None of these dienes was detected with the Delta11 desaturase gene of Trichoplusia ni, which does not produce conjugated dienes as pheromone components. We conclude that the Delta11 desaturase of S. littoralis is a bifunctional enzyme with both Delta11 and Delta10,12 desaturation activities. The relationship between the substrate structure and the stereochemical outcome of the reaction is discussed.