Detection of pheromone biosynthetic and degradative enzymes in vitro

Terminal steps in pheromone biosynthesis byHeliothis virescens andH. zea

In vivo application to the sex pheromone gland ofHeliothis Virescens andH. Zea of large quantities of alcohols normally present in small amounts resulted in the preferential conversion of the alcohols to the corresponding pheromonal aldehydes. Amounts of the minor component aldehydes were increased up to 15-fold by selectively applying large quantities of the alcohol precursors. Using this technique, we have inducedH. virescens to convert "bombykol," the sex pheromone of the silkworm, to the corresponding aldehyde, "bombykal," and have induced femaleH. zea to produce the same sex pheromone components used byH. virescens by applying tetradecanol and (Z)-9-tetradecenol to the surface of the gland. Further, treatedH. zea females were attractive toH. virescens males and caused males to attempt interspecific copulation repeatedly. We have also found that the enyzme involved in this conversion is dependent on the presence of molecular oxygen, indicating that a nonspecific alcohol oxidase is responsible for the terminal biosynthetic step in pheromone production by bothH. virescens andH. zea.

Metabolism of pheromone components and analogs by cuticular enzymes ofChoristoneura fumiferana

In vivo incubation ofChoristoneura fumiferana with (E)-11-tetradecenal, the major pheromone component, resulted in adsorption followed by transformation to (E)-11-tetradecenoic acid, the only observed metabolite. Antennae, legs, and wings from both sexes were investigated for enzyme activity. Specificity studies with the aldehyde dehydrogenase system showed that the enzyme prefers aldehydes of 14-carbon chain length or shorter.

Aldehydic contact poisons and alarm pheromone of the antCrematogaster scutellaris (Hymenoptera: Myrmicinae) : Enzyme-Mediated Production from acetate precursors

The Dufour gland ofCrematogaster scutellaris stores a mixture of long-chain primary acetates bearing a cross-conjugated dienone (Scheme 1, la-c). The poison gland contains two highly active enzymes: an acetate esterase and an alcohol oxidase. During venom emission, the constituents of both glands mix and accumulate on the sting, where the formation of the highly electrophilic aldehydes (Scheme 1, 2a-c) from their acetate precursors is initiated. Acetic acid, produced during the reaction, acts as alarm pheromone. The toxicity of the acetates (Scheme 1, la-c) and of the crude secretion has been assessed by topical application onMyrmica rubra. The acetatecontaining secretion from the Dufour gland was less toxic than the enzymatically altered secretion that was rich in aldehydes. The production of acids (Scheme 1, 3a-c) was an artifact resulting from the nonenzymatic oxidation of the unstable aldehydes.

Differential gene expression in the mandibular glands of queen and worker honeybees, Apis mellifera L.: implications for caste-selective aldehyde and fatty acid metabolism

In honeybees, queens synthesize the "queen pheromone," whereas workers synthesize fatty acid components of "royal jelly" in their mandibular glands (MGs). To identify candidate proteins involved in the caste-selective MG function, we performed a proteomic analysis and identified three proteins that were expressed selectively in queen MGs (aldehyde dehydrogenase 1 [ALDH1], medium-chain acyl-CoA dehydrogenase [MCAD], and electron transfer flavoprotein alpha [ETFalpha)]), and a protein that was expressed selectively in worker MGs (fatty acid synthase [FAS)]). The quantitative reversed transcription-polymerase chain reaction demonstrated that the level of aldh1 transcription in MGs was significantly higher, whereas that of fas transcription was lower in queens than in workers. Among the eight genes encoding proteins similar to ALDH1 that are registered in the honeybee genome database, aldh6, aldh7, and aldh1 were expressed at significantly higher levels in queen MGs than in worker MGs. In situ hybridization showed that in the queen head, aldh1 was expressed in MG cells, whereas aldh6 and aldh7 were expressed in fat cells attached to the MGs. These results suggest caste- and cell type-selective aldehyde/fatty acid metabolism in honeybee MGs.

Identification of candidate aldehyde oxidases from the silkworm Bombyx mori potentially involved in antennal pheromone degradation

Signal inactivation is a crucial step in the dynamic of olfactory process and involves various Odorant-Degrading Enzymes. In the silkworm Bombyx mori, one of the best models for studying olfaction in insects, the involvement of an antennal-specific aldehyde oxidase in the degradation of the sex pheromone component bombykal has been demonstrated over the three past decades by biochemical studies. However, the corresponding enzyme has never been characterized at the molecular level. Bioinformatic screening of B. mori genome and molecular approaches have been used to isolate several candidate sequences of aldehyde oxidases. Two interesting antennal-expressed genes have been further characterized and their putative functions are discussed in regard to their respective expression pattern and to our knowledge on aldehyde oxidase properties. Interestingly, one gene appeared as specifically expressed in the antennae of B. mori and associated in males with the bombykal-sensitive sensilla, strongly suggesting that it could encode for the previously biochemically characterized enzyme.

Functional specialization of maize mitochondrial aldehyde dehydrogenases

The maize (Zea mays) rf2a and rf2b genes both encode homotetrameric aldehyde dehydrogenases (ALDHs). The RF2A protein was shown previously to accumulate in the mitochondria. In vitro import experiments and ALDH assays on mitochondrial extracts from rf2a mutant plants established that the RF2B protein also accumulates in the mitochondria. RNA gel-blot analyses and immunohistolocation experiments revealed that these two proteins have only partially redundant expression patterns in organs and cell types. For example, RF2A, but not RF2B, accumulates to high levels in the tapetal cells of anthers. Kinetic analyses established that RF2A and RF2B have quite different substrate specificities; although RF2A can oxidize a broad range of aldehydes, including aliphatic aldehydes and aromatic aldehydes, RF2B can oxidize only short-chain aliphatic aldehydes. These two enzymes also have different pH optima and responses to changes in substrate concentration. In addition, RF2A, but not RF2B or any other natural ALDHs, exhibits positive cooperativity. These functional specializations may explain why many species have two mitochondrial ALDHs. This study provides data that serve as a basis for identifying the physiological pathway by which the rf2a gene participates in normal anther development and the restoration of Texas cytoplasm-based male sterility. For example, the observations that Texas cytoplasm anthers do not accumulate elevated levels of reactive oxygen species or lipid peroxidation and the kinetic features of RF2A make it unlikely that rf2a restores fertility by preventing premature programmed cell death.

Insect pheromones--an overview of biosynthesis and endocrine regulation

This overview describes, compares, and attempts to unify major themes related to the biosynthetic pathways and endocrine regulation of insect pheromone production. Rather than developing and dedicating an entirely unique set of enzymes for pheromone biosynthesis, insects appear to have evolved to add one or a few tissue-specific auxiliary or modified enzymes that transform the products of "normal" metabolism to pheromone compounds of high stereochemical and quantitative specificity. This general understanding is derived from research on model species from one exopterygote insect order (Blattodea) and three endopterygote insect orders (Coleoptera, Diptera, and Lepidoptera). For instance, the ketone hydrocarbon contact sex pheromone of the female German cockroach, Blattella germanica, derives its origins from fatty acid biosynthesis, arising from elongation of a methyl-branched fatty acyl-CoA moiety followed by decarboxylation, hydroxylation, and oxidation. Coleopteran sex and aggregation pheromones also arise from modifications of fatty acid biosynthesis or other biosynthetic pathways, such as the isoprenoid pathway (e.g. Cucujidae, Curculionidae, and Scolytidae), or from simple transformations of amino acids or other highly elaborated host precursors (e.g. Scarabaeidae and Scolytidae). Like the sex pheromone of B. germanica, female-produced dipteran (e.g. Drosophilidae and Muscidae) sex pheromone components originate from elongation of fatty acyl-CoA moieties followed by loss of the carbonyl carbon and the formation of the corresponding hydrocarbon. Female-produced lepidopteran sex pheromones are also derived from fatty acids, but many moths utilize a species-specific combination of desaturation and chain-shortening reactions followed by reductive modification of the carbonyl carbon. Carbon skeletons derived from amino acids can also be used as chain initiating units and elongated to lepidopteran pheromones by this pathway (e.g. Arctiidae and Noctuidae). Insects utilize at least three hormonal messengers to regulate pheromone biosynthesis. Blattodean and coleopteran pheromone production is induced by juvenile hormone III (JH III). In the female common house fly, Musca domestica, and possibly other species of Diptera, it appears that during hydrocarbon sex pheromone biosynthesis, ovarian-produced ecdysteroids regulate synthesis by affecting the activities of one or more fatty acyl-CoA elongation enzyme(s) (elongases). Lepidopteran sex pheromone biosynthesis is often mediated by a 33 or 34 amino acid pheromone biosynthesis activating neuropeptide (PBAN) through alteration of enzyme activities at one or more steps prior to or during fatty acid synthesis or during modification of the carbonyl group. Although a molecular level understanding of the regulation of insect pheromone biosynthesis is in its infancy, in the male California fivespined ips, Ips paraconfusus (Coleoptera: Scolytidae), JH III acts at the transcriptional level by increasing the abundance of mRNA for 3-hydroxy-3-methylglutaryl-CoA reductase, a key enzyme in de novo isoprenoid aggregation pheromone biosynthesis.

Aldehyde-oxidizing enzymes in an adult moth: in vitro study of aldehyde metabolism in Heliothis virescens

The conversion of pheromonal aldehydes to carboxylic acids in vitro in tissue extracts of Heliothis virescens is catalyzed by both aldehyde dehydrogenase and aldehyde oxidase enzymes. The aldehyde-oxidizing activity in antennae, heads, legs, and hemolymph from male and female moths was examined by radiochromatographic and spectroscopic assays. First, the enzymatic activity was measured in the presence or absence of added NAD+ using either (Z)-9-tetradecenal or (Z)-11-hexadecenal as tritiated substrate. Second, substrate specificity was determined spectroscopically by (i) indirect measurement of the AO-released hydrogen peroxide through the coupled AO-horseradish peroxidase reaction and by (ii) direct measurement of the ALDH-produced NADH. Both aldehyde-oxidizing activities were associated with soluble enzymes in the antennal extracts, and these enzymes degraded pheromone and nonpheromonal aldehydes. Both AO and ALDH activities were present in male and female tissues. AO activity was exhibited primarily in the antennal extracts and to a lesser degree in the leg extracts. Moreover, ALDH activity was distributed in the antenna, head, and leg extracts. A vinyl ketone analog of (Z)-11-hexadecenal preferentially inhibited the ALDH activity over the AO activity.

Aldehyde Pheromones in Lepidoptera: Evidence for an Acetate Ester Precursor in Choristoneura fumiferana

Labeling studies of the eastern spruce budworm in vivo indicate that trans-11-tetradecenyl acetate is synthesized specifically in the pheromone-producing gland and is degraded in concert with pheromone release; hence it may be a precursor to the trans-11-tetradecenal pheromone. Radioactivity from exogenously added labeled fatty acids did not appear to be directly incorporated into the ester, suggesting that de novo biosynthesis from acetate is the major route of ester biosynthesis. Conversion of the acetate ester to alcohol and aldehyde functional groups may be the principal method of regulating pheromone specificity between species of Choristoneura.