Communication via sex pheromones within and among Arrenurus spp. mites (Acari: Hydrachnida; Arrenuridae)

We present direct experimental evidence of pheromone use in six species of Arrenurus and indirect evidence for four species, including members of the subgenera Megaluracarus, Truncaturus, and Arrenurus. Water in which females were housed elicited arrestant behaviour in males, males oriented to the source, and at least some individuals in each species assumed the male readiness posture, a precursor to coupling. Most species responded to water treated with conspecific females, but there was also interspecific sex pheromone responsiveness. Arrenurus manubriator and A. megalurus demonstrated reciprocal pheromone cross-attractancy. Males of A. major, A. marshallae, and A. birgei responded to water from females of related species from within their subgenera. Arrenurus apetiolatus males failed to respond to conspecific female-treated water, but the same water elicited arrestant behaviour and orientation in A. manubriator. Heterospecific reactions to female-conditioned water were limited to cases involving members of the same species group and were not seen between species representing different species groups or different subgenera. The species for which cross-attractancy has been demonstrated commonly co-occur in nature, so apparently these pheromones are of limited value for species recognition. Shared reaction to sex pheromones provides additional evidence for inferring close phylogenetic relationship among species, and thus far, corresponds with morphological evidence based on adult males and larvae.     

Experimental evidence for a female sex pheromone in Arrenurus manubriator (Acari: Hydrachnida; Arrenuridae)

We present experimental evidence for a water-borne female-produced sex pheromone in aquatic parasitengonine mites. Water that has contained adult female Arrenurus manubriator Marshall will elicit arrestant behaviour in conspecific adult males, and if the cue is sufficiently strong, the males will assume a readiness posture (with 4th pair of legs held over the back, bent anteromedially at the genuotibial joint) that is typically a precursor to coupling. Water that has not been exposed to female mites does not induce any behavioural response from male mites. Female-conditioned water that has been passed through a C-18 column does not elicit any response from male A. manubriator, while the rehydrated residue from the column does induce arrestant behaviour and may result in the readiness posture. The results from the C-18 extraction indicate that the pheromone is nonpolar in nature. This revised version was published online in July 2006 with corrections to the Cover Date.     

Specificity of contact sex pheromones in tsetse flies, Glossina spp.

ABSTRACT. Interspecific mating tests among seven tsetse species covering the 'morsitans' and 'palpalis' groups showed a degree of reaction that extends beyond the traditional taxonomic groupings. Tests with either live or dead females as targets produced essentially similar results which shows that differing responses of males are largely the consequence of differences in composition of the female surface cuticular paraffins and not of female behaviour. Gas chromatographic (GLC) analysis of cuticular paraffins tends to confirm this view. Responses of males of different species to dead conspecific males baited with the most active synthetic G.morsitans pheromone were variable. Comparison of behavioural responses and of GLC profiles of cuticular paraffins suggest that the species tested do not share a pheromone structure in common with G.morsitans. Mating tests with G.morsitans males using dead conspecific males baited with a variety of synthetic compounds provided evidence of the molecular configuration required to elicit a mating response. Synthetic 15,19-dimethyltritriacontane induced a suboptimal response in male G.morsitans but is a likely candidate for a sex pheromone in G.austeni. Although not conclusive, a comparison of behavioural evidence and GLC data has permitted speculation on the nature of sex pheromones in tsetse of the 'palpalis' group.     

Evidence of female-produced sex pheromone of Adelphocoris suturalis (Hemiptera: Miridae): effect of age and time of day

After the reduction in the use of broad-spectrum insecticides, Adelphocoris suturalis (Hemiptera: Miridae) has become an important pest of transgenic cotton, Gossypium hirsutum L., in China. A. suturalis is a highly mobile insect, moving rapidly in and out of crop fields, and traps baited with sex pheromones may be useful in monitoring and controlling its numbers. However, little is currently known regarding the chemical communication based on sex pheromones by this species. To use the synthesized sex pheromone effectively as part of the integrated pest management, some fundamental biological parameters under which the pheromone is produced must be understood. In this study, attractiveness of adult females or males of A. suturalis to conspecific individuals was examined by Y-tube bioassay; we also investigated the female sexually mature age and circadian rhythm of male attraction to females of A. suturalis in the field in 2008 and 2010. Y-tube bioassay results indicated that only males were attracted to odors from sexually mature virgin females. Two-year field trapping experiments showed that 4-18-d-old virgin females effectively attracted males, and males were attracted to virgin females during the scotophase, with a peak between 1900 and 2300 hours. These results improve our understanding of the sexual communication behavior of A. suturalis and provide evidence of female-produced sex pheromone in this species.     

Conspecific and heterospecific pheromone effects on female receptivity

Courtship pheromones play an important role in salamander reproductive behaviour. In salamanders of the family Plethodontidae, males deliver specialized pheromones to females during courtship interactions. These courtship pheromones increase female receptivity and may be involved in mate discrimination. In order to test hypotheses related to mate discrimination, we staged courtship encounters between male-female Plethodon shermani pairs in which the female received pheromones obtained from either conspecific (P. shermani) or heterospecific (P. yonahlossee orP. montanus ) males. Both conspecific and heterospecific pheromones increased female receptivity. Moreover, pheromones from both heterospecific species were as effective as the conspecific pheromone in increasing female receptivity inP. shermani females. Our results suggest that the courtship pheromone signal and function may be conserved across related species, with mate discrimination occurring before pheromone delivery. Copyright 2003 The Association for the Study of Animal Behaviour. Published by Elsevier Ltd. All rights reserved.     

Role of genital sex pheromones inAmblyomma americanum andA. maculatum (Acari: Ixodidae)

Amblyomma americanum andA. maculatum were studied to determine if genital sex pheromones were present, as reported inDermacentor species. Chemical analysis of methanol extracts of the anterior reproductive tracts (source of the genital sex pheromone) ofA. americanum andA. maculatum confirmed the presence of the same fatty acids that act as components of the genital sex pheromone inDermacentor variabilis andD. andersoni. In bothAmblyomma species, removal of the anterior reproductive-tract of fed females eliminated the male copulatory response. ForA. americanum, use of anterior reproductive tract extracts made with water, methanol, ether and hexane elicited significant probing and copulatory responses by conspecific males. However, inA. maculatum, use of anterior reproductive-tract extracts made with water, methanol, ether, chloroform: methanol (41), hexane and pentane did not restore mating response by males. Treatment with known components ofDermacentor genital sex pheromones elicited weak but significant responses inA. americanum, but did not restore male mating responses inA. maculatum. These results indicate that genital sex pheromones exist inA. americanum and are not restricted to the genusDermacentor. Characteristics of theAmblyomma genital sex pheromone, however, do differ considerably from those inDermacentor. No genital sex pheromone was present inA. maculatum.     

Sex pheromones in the cereal aphid parasitoidsPraon volucre andAphidius rhopalosiphi

Laboratory and field experiments provided evidence for the release of sex pheromones by virgin femalePraon volucre Haliday andAphidius rhopalosiphi De Stefani-Perez (Hymenoptera: Braconidae, Aphidiinae). In Petri dish biosassays, rubber or vermiculite models treated with crude virgin female extracts were frequently approached by males and elicited rapid wing-fanning behaviour and copulation attempts. Delta-shaped water traps containing live virgin females caught large numbers of conspecific males when placed in winter wheat crops. Trapping slightly below crop height resulted in higher catches than trapping above the crop canopy.     

Dermacentor variabilis and Dermacentor andersoni: Genital sex pheromones

There is evidence for the existence of a previously undescribed sex pheromone (or pheromones) in the ticks Dermacentor variabilis and D. andersoni. In addition to 2,6-dichlorophenol, which attracts mate-seeking males, a pheromone released on the cuticle of the female genital area enables the sexually excited male to locate the gonopore. The compound (or compounds) appears to act as a contact pheromone; male copulation responses are greatly reduced when the female genital surface is washed with solvents, especially hexane. It is also a potent excitant; males will puncture or dislodge barriers placed over the gonopore to copulate. However, the response is eliminated if the genital area is washed (hexane or acetone) prior to sealing the gonopore, suggesting the reproductive system as the source of the pheromone. A species specific copulation-eliciting pheromone appears necessary to excite the male to form and implant its spermatophore in the vulva of a conspecific female. Males encountering trans-specific females probe their gonopores, but mating attempts are almost always aborted within 5–10 min. The copulation-eliciting pheromone may be the same, or similar, to that used to locate the gonopore. Physical differences in the shape of the female gonopore in the two species, although slight, may contribute to the male's ability to identify conspecific females. Using this pheromone-guided process of attraction and identification, females present in mixed species populations will almost always be distinguished and inseminated by conspecific mate-seeking males.     

Cereal aphid responses to sex pheromones and host-plant odours in the laboratory

Abstract. The movement of Sitobion fragariae (Wlk.) (Homoptera: Aphididae) males towards odours from conspecific sexual females (oviparae) and the aphid sex pheromone component (4a S ,7 S ,7a R )-nepetalactone were demonstrated in a linear-track olfactometer. Males of the closely related Sitobion avenae (Fab.) were attracted to odours from conspecific oviparae and also oviparae of S. fragariae. These results were consistent with the recent identification of this nepetalactone isomer as the major component of the sex pheromone in these species. Males of S.fragariae were not significantly attracted to oviparae of S.avenae. indicating some qualitative or quantitative difference in the pheromones of the two species. Males did not respond to the related (1R,4aS,7S,7aR)-nepetalactol or to host-plant odours. Gynoparae of these species moved towards the nepetalactone and also to host-plant odours. A combination of both stimuli was more attractive than plant odour alone. Gynoparae of S.fragariae also responded significantly to the combined treatment when this was tested against the nepetalactone.     

Mate Finding Via a Trail Sex Pheromone by <Emphasis Type="Italic">Aphytis melinus</Emphasis> DeBach (Hymenoptera: Aphelinidae) Males

Finding mates is frequently problematic for parasitoid wasps. In some parasitoid species, males rely on volatile, airborne sex pheromones for locating mates, while in others they rely on contact, trail sex pheromones. This study sought to shed light on the mate finding mechanism of males of Aphytis melinus. Specifically, the goal was to determine whether A. melinus males use airborne or contact pheromones, or both, for locating mates. The study showed that A. melinus males rely on a contact, trail sex pheromone for locating mates: A. melinus males responded to substrate-borne cues left by virgin females, while they did not respond to airborne cues from virgin females. Specifically, males more frequently encountered virgin females when the females walked across an arena to a fixed encounter point compared to when they were manually placed at the encounter point, and spent greater than expected time on surfaces previously visited by virgin females compared to control surfaces not visited by females. In contrast, males did not respond to airborne cues from virgin females in an airflow olfactometer nor to traps baited with virgin females in the field, and spent similar lengths of time on surfaces visited by newly-mated or 24-h mated females versus control surfaces not visited by females. The main effect of the trail sex pheromone on the behavior of A. melinus males was to direct their search and, so, increase the likelihood of encountering mates. This effect apparently is not preceded by longer-range attraction of males via an airborne female sex pheromone. Overall, the results of this study support a hypothesis in which A. melinus males searching on substrates on which females may be present rely exclusively on a trail sex pheromone to locate mates.     

CHEMICAL COMMUNICATION IN HAWAIIAN DROSOPHILA

We are interested in elucidating the extent to which lekking Hawaiian Drosophila species have diverged from their continental counterparts, which engage in sexual behavior at communal food sources, with regard to the chemical communication systems that the flies employ. Accordingly, we have analyzed flies from three closely related Hawaiian Drosophila species in the adiastola subgroup. These species are of interest because the males engage in a unique behavior: while courting, they raise their abdomens over their heads and emit anal droplets. Analysis of the flies' behavior, the hydrocarbons in males' anal droplets, and males' cuticular hydrocarbons suggest that females' responses to males may be mediated by cuticular pheromones and/or pheromones in males' extruded droplets that enable the females to distinguish conspecific from heterospeciflc males. Conversely, perception of cuticular hydrocarbons from conspecific females enables D. adiastola males to distinguish females from a closely related species from conspecific females. On the basis of these observations, we suggest that the adiastola subgroup species are unique among drosophilids in that they utilize an anal droplet-mediated pheromone communication system, some or all components of which are species specific. However, the lekking Hawaiian Drosophila species are similar to D. melanogaster and related continental species in that the Hawaiian flies employ a cuticular pheromone communication system, some components of which are sex and species-specific.     

Widespread reliance on olfactory sex and species identification by lyssomanine and spartaeine jumping spiders

Jumping spiders (Salticidae) are renowned for their exceptional vision, but this does not preclude use of other senses. Here we provide evidence that olfactory pheromones are widespread in the Spartaeinae and Lyssomaninae, two subfamilies regarded as basal clades within the Salticidae. Pheromone use by salticids was tested in a series of experiments: males were tested with the odour of conspecific females, heterospecific females, and conspecific males, and females were tested with the odour of conspecific males. With seven of the 29 species tested, we also tested males using the draglines of conspecific females (spider absent) as the odour source. Males of all species tested were attracted to the odour of conspecific females and to the odour of the draglines of conspecific females. There was no evidence of males responding to the odour of heterospecific females or conspecific males, or of females responding to the odour of conspecific males. These findings suggest that it is primarily males that respond to olfactory sex pheromones, consistent with the apparent trend within spiders of males more actively searching for females and females placing greater emphasis on mate‐choice decisions. Compared with most salticid groups, lyssomanines and spartaeines are unusually sedentary and this lifestyle may favour olfactory mate searching. © 2012 The Linnean Society of London, Biological Journal of the Linnean Society, 2012, 107 , 664–677.     

Sex pheromones in three Bradysia species (Dipt., Sciaridae): novel bioassays with female body extracts and fractions

Females of the fungus gnat species Bradysia difformis , Bradysia optata and Bradysia tilicola are able to produce sexual attractants. In males, the female extracts elicit species-specific courtship behaviour and attraction in an olfactometer bioassay. Attractiveness of the sex pheromone extracts seems to differ in the investigated species, being highly attractive for males in B. difformis and only moderately attractive in B. tilicola . Female B. difformis are attractive from late pupal stages until death of the imago. In contrast, female B. optata and B. tilicola are not attractive to males before emergence from the pupa and attractiveness decreases in older females. The pheromones seem to be located on the surface of several body compartments of freshly emerged females. Sexual pheromones of all three species represent multicomponent blends and can be separated in several fractions via thin layer chromatography (TLC). Males of all species show courtship behaviour when placed on developed TLC sheets, indicating the position of the biologically active compounds. In B. difformis and B. optata , the most non-polar TLC fraction is attractive to males, whereas the single fractions of B. tilicola -pheromone elicited almost no attraction of males.     

Pheromones and body coloration affect mate recognition in the Japanese nine-spotted moth Amata fortunei (Lepidoptera: Arctiidae)

Adults of the Japanese nine-spotted moth, Amata fortunei, are diurnal and have white-spotted black wings and a black-and-yellow striped body pattern. We evaluated whether this species uses sex pheromones and whether visual cues from the female body are used in mate recognition. We introduced extracts of potentially scent-bearing abdominal tips of females to males. Males responded more to the extracts than to dried female specimens, suggesting the presence of sex pheromones in the extracts. Indeed, no males responded to the dried female specimens. To evaluate the importance of visual cues, we conducted the experiments with crude extract and an additional model stimulant. Males responded more to model females with the same number and similar area of yellow bands to the original conspecific females than to those with more bands and greater total band area, suggesting that dissimilarity in band number and area to conspecific females could interrupt male mating behavior. Males of A. fortunei likely find mating partners using olfactory cues over relatively long distances, while using both olfactory and visual cues over short distances. These results suggest that olfactory cues play a major role in mate recognition, whereas visual cues play a supplementary role.     

Molecular mechanisms underlying sex pheromone production in the silkmoth, Bombyx mori: characterization of the molecular components involved in bombykol biosynthesis

Many species of female moths produce sex pheromones to attract conspecific males. To date, sex pheromones from more than 570 moth species have been chemically identified. Most moth species utilize Type I pheromones that consist of straight-chain compounds 10-18 carbons in length with a functional group of a primary alcohol, aldehyde, or acetate ester and usually with several double bonds. In contrast, some moth species use unsaturated hydrocarbons or hydrocarbon epoxides, classified as Type II lepidopteran pheromones, as sex pheromones. Studies over the past three decades have demonstrated that female moths usually produce sex pheromones as multi-component blends where the ratio of the individual components is precisely controlled, thus making it possible to generate species-specific pheromone blends. As for the biosynthesis of Type I pheromones, it is well established that they are de novo synthesized in the pheromone gland (PG) through modifications of fatty acid biosynthetic pathways. However, as many of the molecular components within the PG cells (i.e., enzymes, proteins, and small regulatory molecules) have not been functionally characterized, the molecular mechanisms underlying sex pheromone production in PG cells remain poorly understood. To address this, we have recently characterized some of the molecules involved in the biosynthesis of the sex pheromone bombykol in the silkmoth, Bombyx mori. Characterization of these, and other, key molecules will facilitate our understanding of the precise mechanisms underlying lepidopteran sex pheromone production.     

Male orientation to trail sex pheromones in parasitoid wasps: does the spatial distribution of virgin females matter?

We studied male locomotory response to trails and patches of sex pheromone (left respectively by free-ranging females and females constrained to stay on a small area) in the two parasitoids Aphelinus asychis (Hymenoptera: Aphelinidae) and Trichogramma brassicae (Hymenoptera: Trichogrammatidae). Under the hypothesis that the spatial distribution of virgin females differs between these species (scattered among host plants in A. asychis, gregarious at emergence sites in T. brassicae), we predicted that male locomotory response to their sex pheromones should also differ: A. asychis males should follow pheromone trails on plants in order to encounter the females along these trails, whereas T. brassicae males should stay on pheromone patches, at emergence sites, and mate the females on these patches. Using an improved video-tracking system, we found that males of both species respond to conspecific sex pheromone trails and patches, but that the response does not differ much between species. Males released on marked substrates walked in a more convoluted pattern (i.e. higher path fractal dimension and higher number of crossings within tracks) than males released on unmarked substrates. On pheromone patches, males turned persistently in the same direction when leaving the patch, which explains a higher number of visits on marked patches than on unmarked patches, and possibly, higher track convolution on pheromone trails. Contrary to our hypothesis, male A. asychis did not follow female trails more accurately than male T. brassicae, and male T. brassicae did not stay longer on pheromone patches than male A. asychis. We argue that these discrepancies between our predictions and the observed responses originates from discrepancies between the assumed spatial distribution of virgin females and their actual distribution in the wild.     

Pheromonal and behavioral cues trigger male-to-female aggression in Drosophila

Appropriate displays of aggression rely on the ability to recognize potential competitors. As in most species, Drosophila males fight with other males and do not attack females. In insects, sex recognition is strongly dependent on chemosensory communication, mediated by cuticular hydrocarbons acting as pheromones. While the roles of chemical and other sensory cues in stimulating male to female courtship have been well characterized in Drosophila, the signals that elicit aggression remain unclear. Here we show that when female pheromones or behavior are masculinized, males recognize females as competitors and switch from courtship to aggression. To masculinize female pheromones, a transgene carrying dsRNA for the sex determination factor transformer (traIR) was targeted to the pheromone producing cells, the oenocytes. Shortly after copulation males attacked these females, indicating that pheromonal cues can override other sensory cues. Surprisingly, masculinization of female behavior by targeting traIR to the nervous system in an otherwise normal female also was sufficient to trigger male aggression. Simultaneous masculinization of both pheromones and behavior induced a complete switch in the normal male response to a female. Control males now fought rather than copulated with these females. In a reciprocal experiment, feminization of the oenocytes and nervous system in males by expression of transformer (traF) elicited high levels of courtship and little or no aggression from control males. Finally, when confronted with flies devoid of pheromones, control males attacked male but not female opponents, suggesting that aggression is not a default behavior in the absence of pheromonal cues. Thus, our results show that masculinization of either pheromones or behavior in females is sufficient to trigger male-to-female aggression. Moreover, by manipulating both the pheromonal profile and the fighting patterns displayed by the opponent, male behavioral responses towards males and females can be completely reversed. Therefore, both pheromonal and behavioral cues are used by Drosophila males in recognizing a conspecific as a competitor.     

Contact sex pheromones identified for two species of longhorned beetles (Coleoptera: Cerambycidae) Tetropium fuscum and T. cinnamopterum in the subfamily Spondylidinae

Male Tetropium fuscum (F.) and T. cinnamopterum Kirby mated with live and dead (freeze-killed) conspecific females upon antennal contact, but did not respond to dead females after cuticular waxes were removed by hexane rinsing. Significantly fewer males of each species attempted to copulate with live or dead heterospecific females than with conspecifics, indicating that mate recognition was mediated by species-specific contact sex pheromones in the female's cuticular hydrocarbons. GC/MS analysis of T. fuscum elytra identified n-alkanes and mono-methyl branched alkanes of which 11-methylheptacosane and 3- and 5-methyltricosanes were dominant in females. Full male responses, including copulatory behavior, were restored with application of enantiomerically pure synthetic (S)-11-methyl-heptacosane at 40 μg/female (one female equivalent) but not with racemic or (R)-11-methyl-heptacosane. The cuticular hydrocarbons on T. cinnamopterum elytra included 11-methyl-heptacosane as well as n-alkanes, methyl-branched alkanes, mono-alkenes, and (Z, Z)-6, 9-alkadienes. (Z)-9-pentacosene, (Z)-9-heptacosene, and 11-methyl-heptacosane were female dominant, but only (Z)-9-pentacosene elicited precopulatory behaviors in conspecific males at levels similar to those behaviors elicited by unrinsed females, but elicited copulation in fewer than half of males. At female equivalent dosages (10 μg), neither (Z)-9-heptacosene nor (S)-11-methyl- heptacosane elicited responses in males that were significantly different from those responses to a rinsed female but when applied together, the proportion of males responding was significantly increased. 11-methyl-heptacosene is thus a contact pheromone component common to both species, which may explain the heterospecific mating attempts by some males.     

Effects of Carrion-Independent Pheromone Emission by Male Burying Beetles (Silphidae: Necrophorus)

All former publications on the reproductive biology of burying beetles (genus Necrophorus) state that in these species copulations take place on carcasses only, this being the only place for the sexes to meet. Our laboratory investigations have shown that males emit pheromones if no carrion is around. We now present data from a field investigation showing the effects of pheromone emission by males that have not secured a carcass. Such males are successful in attracting conspecific females. But conspecific males and individuals of other species are also attracted by the scent. Possible benefits for attracted individuals of different species and sex are discussed. Pheromone emission and attraction of conspecifics are restricted to a distinct species-specific period of the day in at least two of the common species.