Induction of female sex pheromone production in male houseflies by ovary implants or 20-hydroxyecdysone

Implanting ovaries or injecting 20-hydroxyecdysone into male houseflies induced sex pheromone production, including (Z)-9-tricosene (muscalure), 9,10-epoxytricosane and (Z)-14-tricosen-10-one, which normally occurs only in vitellogenic females. Control males did not produce detectable amounts of these compounds. Injection of 20-hydroxyecdysone (5 μg/insect per day) for 3 days resulted in the accumulation of 1.81 μg/insect of (Z)-9-tricosene, 0.97 μg/insect of 9,10-epoxytricosane and 0.12 μg/insect (Z)-14-tricosen-10-one. Multiple injections of 20-hydroxyecdysone at doses as low as 50 ng resulted in the accumulation of 23:1, C₂₃ epoxide and C₂₃ ketone; shifted the distribution of label within the alkenes from 27:1 to 23:1 and decreased the amount of label in the hydrocarbon fractions as alkenes. Structures of the C₂₃ alkene and epoxide produced by the males were verified by gas chromatography-mass spectrometry. Radioactivity from [1-¹⁴C] acetate was incorporated into the C₂₃ alkene, epoxide and ketone in male insects after ovaries were implanted or they were injected with 20-hydroxyecdysone. Synthesis of the C₂₃ pheromone components decreased rapidly within several days after the administration of 20-hydroxyecdysone ceased, indicating that the enzymes involved in sex pheromone production were not permanently induced by hormone treatment. Ecdysone was also effective in initianing pheromone production in males, whereas inokosterone and cholesterol were not effective. Data presented demonstrate that male houseflies possess the metabolic capability to produce the sex pheromone components, and this suggests that 20-hydroxyecdysone alters the production of cuticular hydrocarbons such that the C₂₃ sex pheromone components become major products.     

Correlation of housefly sex pheromone production with ovarian development

Pheromone production in the housefly was monitored during oögenesis and in ovariectomized insects by gas-liquid chromatography (GLC) and radio-GLC. The presence of vitellogenic ovaries was required for the initiation of (Z)-9-tricosene (muscalure), (Z)-9,10-epoxytricosane and (Z)-14-tricosen-10-one synthesis. Methylalkane synthesis was enhanced by developing ovaries. Insects ovariectomized within 12 hr after emergence produced no detectable amounts of (Z)-9-tricosene, C₂₃ epoxide nor C₂₃ ketone and synthesized less methylalkanes than the controls. This effect was reversed by ovary implants. When flies were ovariectomized after oviposition, synthesis of (Z)-9-tricosene, C₂₃ epoxide and C₂₃ ketone continued. Thus, initiation of the synthesis of these C₂₃ pheromone compounds required a vitellogenic ovary, but the ovary was not required to maintain synthesis.     

Haemolymph ecdysteroid in the housefly,Musca domestica,during oögenesis and its relationship with vitellogenin levels

Ecdysteroid titre in the haemolymph of the housefly, Musca domestica, cycled during oögenesis and peaked at ～50 pg/μl during stages 5, 6 and 7. Levels of 10–20 pg/μl were found in houseflies with pre- and post-vitellogenic ovaries. Removal of the corpus allatum and corpus cardiacum complex resulted in low ecdysteroid levels (10 pg/μl). Ovariectomized flies also had lower ecdysteroid levels than the controls at 2 days (5 pg/μl) after emergence but not at 6 days (22 pg/μl). It is possible that the ecdysteroid peak that occurred during stages 5, 6 and 7 was produced by the ovaries because ovaries secreted and synthesized ecdysteroid in vitro. Endogenous haemolymph ecdysteroid levels had a linear correlation with the amount of vitellogenin that held for hormone concentrations of 5–43 pg/μl. Furthermore, the injection of 20-hydroxyecdysone at doses of 10 ng?1.0 μg/fly increased the amount of vitellogenin from 6 h to 12 h after injection; by 24 h, the vitellogenin returned to control levels. When 20-hydroxyecdysone was injected into ovariectomized flies, it was rapidly degraded and 96% was cleared from the haemolymph within 1 h.     

Semiochemicals from ovaries of gravid females attract ovipositing female houseflies,Musca domestica

Chemical signals originating from the ovaries of gravid females of Musca domestica (Diptera: Cyclorrhapha: Muscidae) attract ovipositing females to common egg-laying sites. Behavioral experiments indicated that females preferred to oviposit in fermented wheat bran containing ovaries from reproductively mature houseflies. Females preferred to oviposit in fermented wheat bran than wet wheat bran. This effect was additive with the attraction to housefly ovaries. Solvent extracts from housefly ovaries were attractive to gravid females. Extracts obtained with hexane were most attractive to gravid females for egg laying, and extracts obtained with ethyl acetate attracted more egg laying than extracts obtained by dichloromethane. Gas chromatography (GC) and gas chromatography coupled with mass spectrometry (GC-MS) analysis showed that tricosane and (Z)-9-tricosene were the main components of the hexane extracts. Both tricosane and (Z)-9-tricosene were shown to elicit dose-dependent aggregation of gravid females in oviposition bioassays, but high doses of either chemical were not attractive.     

Does ovarian ecdysone stimulate mosquitoes to synthesize vitellogenin?

Physiological amounts of 20-hydroxyecdysone do not initiate vitellogenin synthesis in unfed, non-vitellogenic mosquitoes. Injecting more than 10,000 times the physiological amount induced synthesis, but considerably less than was induced by a blood meal. A dose of 20-hydroxyecdysone which exceeded the physiological level only several hundred times, did not sustain vitellogenin synthesis, when blood-fed mosquitoes were ovariectomized just prior to injection. Transplanting ovaries from vitellogenic to non-vitellogenic females did not initiate synthesis of vitellogenin in the recipient. In vitro, neither 20-hydroxyecdysone nor the ovaries of vitellogenic females were able to induce synthesis of vitellogenin in non-vitellogenic fat bodies. These experiments suggest that ecdysteroid, released by the ovaries, does not initiate ovarian development in mosquitoes.     

Juvenile hormone and ovarian maturation in the diptera: A review of recent results

The roles of the JHs and ecdysteroids in ovarian maturation of adult Aedes aegypti, A. atropalpus, Musca domestica and Drosophila melanogaster have been characterized by comparing the effects of surgical (allatectomy, ovariectomy, decapitation, abdominal ligation), genetic, and nutritional (sugar feeding) manipulations. The results show that in all species JHs, or their mimics, and 20-hydroxyecdysone act in combination to stimulate ovarian maturation and vitellogenin (Vg) synthesis and that high doses of exogenous JHs, or their mimics, stimulate ovarian ecdysteroid synthesis, at least in A. aegypti, A. atropalpus, and D. melanogaster. Thus the gonadotropic regulatory mechanisms that exist in various dipteran species are more similar than originally suspected. In M. domestica, and possibly D. melanogaster, 20-hydroxyecdysone is present in the hemolymph at vitellogenic levels in newly emerged females and may persist in ovariectomized adults. If true for D. melanogaster, this could explain why topical application of JH, or its mimics, to ovariectomized, isolated abdomens is effective in stimulating Vg synthesis in the absence of the ovaries.     

Ovarian ecdysteroids and their secretion in late-pharate adults of Galleria mellonella

Approximately two-thirds of the total amount of ecdysteroids in late—pharate adults of the wax moth, Galleria mellonella, were found in the ovaries and one-third in the ovariectomized body. Chemical analysis of these ecdysteroids by thin-layer and high-pressure liquid chromatography, coupled with an ecdysteroid radioimmunoassay, revealed the presence of 2-deoxyecdysone, ecdysone and 20-hydroxyecdysone, as well as high and low polarity unknowns. The predominant identifiable ecdysteroid in both the ovaries and ovariectomized body was 2-deoxyecdysone, followed by lesser amounts of ecdysone and 20-hydroxyecdysone, respectively. Incubation of late-pharate adult ovaries in culture medium revealed that they synthesize and secrete ecdysteroids in vitro. The in vitro distribution of ecdysteroids between ovaries and incubation medium was similar to that observed between ovaries and ovariectomized bodies in situ and the predominant identifiable moiety both retained and released by the ovaries in vitro was 2-deoxyecdysone, followed by lesser amounts of ecdysone and 20-hydroxyecdysone. Collectively, these results support the idea that the ecdysteroids synthesized by the ovaries of late-pharate adult Galleria are both stored and secreted and that the quantity of a specifically secreted ecdysteroid is precisely controlled. This apparent regulation of the distribution of ovarian ecdysteroids raises the possibility that the stored and secreted forms have distinct functions in the reproductive physiology of this insect.     

Male-specific (Z)-9-tricosene stimulates female mating behaviour in the spider Pholcus beijingensis

Chemical signals play an important role in spider sexual communication, yet the chemistry of spider sex pheromones remains poorly understood. Chemical identification of male-produced pheromone-mediating sexual behaviour in spiders has also, to our knowledge, not been reported before. This study aimed to examine whether chemically mediated strategies are used by males of the spider Pholcus beijingensis for increasing the probability of copulation. Based on data from gas chromatography–mass spectrometry analysis, electroantennography assay and a series of behavioural tests, we verified that (Z)-9-tricosene is a male-specific compound in the spider P. beijingensis. This compound acts as an aphrodisiac: it increases the likelihood that a female will mate. Mate-searching males release (Z)-9-tricosene to stimulate sexual behaviour of conspecific females. In the two-choice assay, however, sexually receptive females show no preference to the chambers containing (Z)-9-tricosene. This indicates that the male pheromone of P. beijingensis is not an attractant per se to the conspecific females. This is, to our knowledge, the first identification of a male-produced aphrodisiac pheromone in spiders.     

Monoenyl hydrocarbons in female body wax of the yellow peach moth as synergists of aldehyde pheromone components

The non-polar components of female body wax and pheromone gland extracts of the yellow peach moth synergistically enhanced male behavioral responses from close to pheromone sources in wind tunnel tests when mixed with an aldehyde pheromone blend. When the non-polar fractions (NPFs) of female body wax were further separated by column chromatography, synergistic activities were found in the 3 and 50% ether in hexane fractions, and they additively increased male responses. The main components of the first fraction were (Z)-9-tricosene, (Z)-9-pentacosene, (Z)-9-heptacosene, (Z)-9-nonacosene and (Z)-9-hentriacontene. Only (Z)-9-heptacosene showed a significant synergistic effect in enhancing male responses, but the other components had no effect. A mixture of the five monoenyl hydrocarbons lost activity at lower doses than 5 ng. Natural ratios of these hydrocarbons in the female body wax and pheromone gland extracts were similar, but the amount of (Z)-9-heptacosene in the female body wax was significantly higher than in the pheromone gland extracts. We conclude that (Z)-9-heptacosene increases male responses to aldehyde pheromones, and unknown component(s) in the 50% ether in the hexane fraction are required for full synergistic enhancement by the NPFs of the female body wax and the pheromone gland extracts.     

Artifactual stimulation of vitellogenesis in Aedes aegypti by 20-hydroxyecdysone

Single or repeated, non-physiological, high doses (0.5–5.0 μg/female) of 20-hydroxyecdysone or ecdysone injected into sugar-fed female Aedes aegypti stimulated follicular growth and deposition of yolk, but suppressed accumulation of protein yolk to approximately one-third, and lipid yolk to one-half that in an equal number of follicles with equivalent yolk length taken from blood-fed controls. Physiological doses (500 pg/female) of ecdysone or 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries (verified by bioassay), into sugar-fed females failed to induce any yolk deposition. In these experiments, yolk precursors were not the limiting factor, because in decapitated females, digesting a blood meal, the injection of a physiological dose of 20-hydroxyecdysone or the implantation of ecdysone-secreting ovaries still did not stimulate vitellogenesis. Finally, continuous infusion of 500 pg or even 50 ng 20-hydroxyecdysone/hr for 22 hr was as ineffective as single or multiple injections of equivalent doses of hormone. Consequently, rapid excretion or catabolism of 20-hydroxyecdysone by the sugar-fed female does not explain the need for high doses to induce vitellogenesis, or the failure of oöcytes to mature with normal protein and lipid content. Apparently, ovarian ecdysone is not the factor by which normal vitellogenesis is initiated and maintained in this mosquito.     

The evolution of tachinid pollination in Neotinea ustulata is related to floral cuticular composition and the combined high relative production of (Z)-11-C23/C25enes

Among terrestrial orchids, and particularly among the subtribe Orchidinae, flies are underrepresented as pollinators. The European Neotinea ustulata, which developed specialized pollination by tachinid flies, is known to produce high relative concentrations of the floral cuticular alkenes (Z)-11-tricosene and (Z)-11-pentacosene (referred to as (Z)-11-C23/C25enes), which seem to be uncommon among orchid flowers. If the evolution of tachinid pollination is related to that of (Z)-11-C23/C25enes, we can expect that closely related species have a different floral chemical pattern and significantly small or no production of (Z)-11-C23/C25enes, independently of their pollinator guild identity (e.g., bees, flies, moths). We chemically compared the floral cuticular composition among Neotinea species, performed electrophysiological analyses, reconstructed the phylogenetic Orchidinae tree, and identified the evolutionary history of pollinator guild and (Z)-11-C23/C25enes production within the Orchidinae. Neotinea ustulata has evolved a markedly different floral cuticular composition compared to other Neotinea and produces both compounds ((Z)-11-C23/C25enes) in high relative quantities (i.e., above 8% in combination), which are detectable by tachinid antennae. Moreover, most Orchidinae taxa have minimal or no production of these alkenes, independently of the identity of their pollinator guild. Our ancestral reconstruction suggested that (Z)-11-C23/C25enes production was an evolutionary exaptation in Neotinea, whereas tachinid pollination was a unique evolutionary innovation for N. ustulata. Floral cuticular composition and, in particular, the combined production of (Z)-11-C23/C25enes at relatively high concentrations is intimately linked to the evolution of tachinid pollination within the Orchidinae.     

Adult house fly (Diptera: Muscidae) activity and age of females near varying levels of (Z)-9-tricosene on a southern California dairy

The number of adult male and female house flies, Musca domestica L. (Diptera: Muscidae), near varying levels of (Z)-9-tricosene alone (5, 50, or 100 micdrol) or combined (50 microl) with sugar was determined using conical screened traps on a dairy in southern California. Overall, significantly more males than females were collected in the traps. Significantly more flies (male and female) were collected in traps with (Z)-9-tricosene. There were no significant differences among doses of (Z)-9-tricosene alone, but numbers of both sexes were significantly higher in traps baited with (Z)-9-tricosene and sugar compared with the 5- and 50-microl doses without sugar. The age of female flies collected in traps was determined by pterin analysis. Mean female ages ranged from 94.7 to 99.6 degree-days (6.3-6.8 d of age) and did not differ significantly among treatments. Dissections of a subset of females from each treatment determined that collected females were primarily nongravid (86.3%). Proportions of gravid females that were collected did not differ among treatments.     

Cuticular hydrocarbons of Drosophila virilis: Comparison by age and sex

The cuticular hydrocarbons of Drosophila virilis were isolated and identified by TLC, GC, HPLC, GC-MS and ozonolysis-GC techniques. The major classes of hydrocarbons in both sexes were 2-methylalkanes, (Z)-11- and (Z)-13-alkenes, and a mixture of n-(Z,Z)-alkadienes. The key isolation step for the alkadienes was high pressure liquid chromatography on a silver nitrate impregnated silica column. The silver nitrate-silica column afforded separation of the alkadienes based primarily on number of carbons between the double bonds. The most abundant alkadienes had double bonds separated by six methylene units, but alkadienes with 2, 8, 10 and 12 methylenes between double bonds were also present.The cuticular hydrocarbons of adult D. virilis changed dramatically in quantity and composition between eclosion and 8 days of age:

• 1.1. The quantity of total hydrocarbons of flies of both sexes increased by 3-fold between the ages of 0 and 4 days. Between 4 and 8 days of age, the quantity on females remained unchanged, but on males there was an additional 2-fold increase in quantity of total hydrocarbons.
• 2.2. With increased age the average chain length of the hydrocarbons decreased.
• 3.3. (Z)-10-Heneicosene, exclusively from male flies, was absent at eclosion, started to appear at about 4 days of age, and amounted to over half of the total hydrocarbons on 8-day-old male flies.
• 4.4. Although no differences in (Z)-11-pentacosene between sexes were observed at 4 days old, (Z)-11-pentacosene on 8-day-old females was nearly 3 times more abundant than on 8-day-old males.

     

Sexual phenotype and vitellogenin synthesis in Drosophila melanogaster

An ovary transplanted from a Drosophila melanogaster female into a male will mature and form morphologically normal yolk-filled oocytes. Since it has been supposed that the yolk polypeptides come only from the female fat body, it was hypothesized that the implanted ovary induces the fat body of the male host to synthesize and secrete yolk polypeptides (YPs). To test this hypothesis, fat body preparations from females, untreated males, and males containing transplanted ovaries were cultured in vitro with ³⁵S-methionine and the medium was examined for the presence of newly labeled YPs. Female fat body secreted newly labeled YPs, but no freshly synthesized YPs were secreted by fat bodies from untreated males or from males containing transplanted ovaries. In vitro cultured ovaries, however, both from females and from male hosts did secrete newly synthesized YPs. Therefore, the YPs in an ovary that matured in a male come mainly from endogenous synthesis by the implanted ovary. To find whether males were responsive to the hormones that stimulate YP production in isolated female abdomens, we treated males with the juvenile hormone analogue ZR-515 and with 20-hydroxyecdysone. The latter, but not the former, was able to cause synthesis and secretion of three bands migrating precisely as YPs in SDS gels. Partial peptide digests of the 20-hydroxyecdysone-stimulated polypeptides in males showed them to be identical with those stimulated by 20-hydroxyecdysone or ZR-515 in isolated female abdomens and with the three YPs found in normal female hemolymph. Finally, YP synthesis was assayed in mutants that affect the phenotypic sex of a fly. It was found that flies bearing two X chromosomes and the mutations dsx, dsx^D, ix or three sets of autosomes continued to make YPs, but tra-3-pseudomales did not. These results suggest that the process of sex determination involves steps leading to synthesis of an ecdysteroid in females, which then activates synthesis of the YPs by the fat body. A hypothesis is suggested to explain the fact that two different hormones can stimulate YP synthesis and two different organs can synthesize YPs.     

Induction of malate dehydrogenase and acetylcholinesterase by 20-hydroxyecdysone and heat shock in Drosophila ovaries

The molting hormone 20-hydroxyecdysone induces de novo synthesis of cytoplasmic malate dehydrogenase (cMDH) in Drosophila ovaries, but not mitochondrial MDH (mMDH). A second enzyme, acetylcholinesterase (AChE), was found to be heat shock inducible. It is known that MDH and AChE are, respectively, heat shock and 20-hydroxyecdysone inducible (see Introduction). Now it is also known that these enzymes are under dual regulation, with 20-hydroxyecdysone and heat shock being two stimuli which act either separately or in combination, to increase the specific activity of these enzymes. The response to 20-hydroxyecdysone and/or heat shock was found to occur in seven additional D. melanogaster sibling species. In this case, hormone and heat shock maximize the interspecific variability, something which could be acted by natural selection to establish physiological adaptations.     

Ecdysteroids in adult males and females of Drosophila melanogaster

Ecdysteroid titres in whole flies and different tissues of adult male and female Drosophila were determined at various times after eclosion using a radioimmunoassay. The ecdysteroid titre decreased as the flies matured after eclosion. The differences in titre between males and females can be accounted for by their difference in body weight. The ecdysteroids were found to be distributed throughout several tissues. At eclosion not all of the ecdysteroid complement present could be accounted for by that found localised in tissues. After maturation of the flies the ecdysteroids in various tissues can account for the majority of that detected in whole-fly extracts. Ecdysteroids were produced during in vitro culture of various tissues, but the quantities detected were low by comparison with ring glands of wandering 3rd-instar larvae. Neither the ovaries nor the abdominal body walls (fat body) seem to be a major source of hormone, and they are only able to convert minute quantities of ecdysone to the biologically active form, 20-hydroxyecdysone, in vitro. The amounts of 20-hydroxyecdysone present were measured using high performance liquid chromatography and radioimmunoassay. We tentatively suggest that the differential experession of the yolk-protein-genes in the fat bodies of males and females does not result from differences in hormone titres between them.     

The effects of laboratory culturing on (Z)-9-tricosene (muscalure) quantities on female houseflies

Using gas chromatography the relative amounts of (Z)-9-tricosene (muscalure) and some other hydrocarbons on the cuticle of 1- to 20-day-old houseflies (Musca domestica L.) from different strains were determined. Flies from a WHO strain, in culture since 1961, and first-generation laboratory-cultured flies from two wild-type strains from a poultry breeding and a cow-house with pigsty, respectively, were compared. On WHO females hydrocarbons with 23–25 C atoms constituted about 65% of the total hydrocarbons, whereas on wild-type females less than 2% of these compounds was present. (Z)-9-tricosene comprised up to 20–30% of the total hydrocarbons on 5- to 20-day-old WHO females, whereas less than 0.5% (Z)-9-tricosene was present on the wild-type females. We also compared the amounts of (Z)-9-tricosene and some other hydrocarbons on female houseflies, kept in culture in the laboratory for several generations. It appeared that whereas on first-generation wild-type females hardly or no (Z)-9-tricosene could be detected, the amounts of this substance had increased considerably after some tens of generations in the laboratory. It is suggested that this was due to selection in subsequent generations of high-density populations. Production of (Z)-9-tricosene and of tricosane was shown to be closely linked. Selection did not affect the production of other cuticular hydrocarbons by the females. It is suggested that in mixed populations (both sexes together in a cage) in the course of time (Z)-9-tricosene is transferred from females to males and (Z)-9-heptacosene from males to females. It is concluded that reproductive ability of houseflies does not primarily depend on the amounts of (Z)-9-tricosene on females, although higher amounts of this substance may increase contacts between males and females.     

Hormonal control of ovarian development in the silkworm,Bombyx mori

Hormonal control of ovarian development was examined in Bombyx mori. The weight of the ovary increased suddenly by 3 days after pupal ecdysis, and vitellogenin could be immunologically detected in the ovary at that time. The ecdysteroid titers during pupal-adult development, quantified by radioimmunoassay, increased from day 0 to day 2. Ovarian development was arrested for a long period in brainless pupae and isolated pupal abdomens. Injection of 20-hydroxyecdysone into such preparations stimulated development of the ovaries, and vitellogenin could be detected in ovaries 2 days after injection. The results suggest that 20-hydroxyecdysone acts by stimulating the growth of ovary.     

A concise synthesis of β-sitosterol and other phytosterols

A convenient synthesis of sidechain-modified phytosterols is achieved via a temporary masking of the stigmasterol 5,6-alkene as an epoxide. Following performance of the desired modification, the alkene is regenerated through a mild deoxygenation. The approach is applied to the syntheses of β-sitosterol and campesterol acetate, and suggests a facile route to the (Z)-isomers of Δ^22-23 phytosterols.