The role of auditory stimuli in the courtship of Drosophila melanogaster

Simulated courtship song of male Drosophila melanogaster was played to males or females of this species. Upon receiving the song males increase their locomotor activity and start courting each other, whereas females reduce their locomotor activity. In wingless males the locomotor activity difference between the silent control and the experimental sound situation is much larger than in winged males, due to the inactivity of wingless males in the control situation. Males which had been kept singly up to the time of the experiment exhibit higher locomotor and sexual activity than group housed males. A second component of the male courtship song ‘sine song’ is described, together with experiments which investigate the sensory basis of the effect male courtship song has on males.     

Drosophila female precopulatory behavior is modulated by ecdysteroids

The effect of ecdysteroid signaling on Drosophila female precopulatory behavior was investigated using two types of mutants with either globally reduced ecdysteroid availability or reduced expression of ecdysone receptors in fruitless neurons, known to control sexual behavior. While being courted by males, mutant females performed significantly less full ovipositor extrusion behavior to reject male copulation attempts. Ecdysteroid depleted females (ecdysoneless(1)) performed male-like courtship behaviors, including unilateral wing extension and song production with patterns very similar to male courtship song. These results support the hypothesis that ecdysteroids modulate female sexual behavior, perhaps acting as a regulator of sexual motivation, and as a component affecting the performance of sex specific behavior patterns.     

Courtship song analysis of Drosophila muscle mutants

As part of the mating ritual, males of Drosophila species produce species-specific courtship songs through wing vibrations generated by the thoracic musculature. While previous studies have shown that indirect flight muscles (IFM) are neurally activated during courtship song production, the precise role of these muscles in song production has not been investigated. Fortunately, IFM mutants abound in Drosophila melanogaster and studies spanning several decades have shed light on the role of muscle proteins in IFM-powered flight. Analysis of courtship songs in these mutants offers the opportunity to uncover the role of the IFM in a behavior distinct than flight and subject to different evolutionary selection regimes. Here, we describe protocols for the recording and analysis of courtship behavior and mating song of D. melanogaster muscle transgenic and mutant strains. To record faint acoustic signal of courtship songs, an insulated mating compartment was used inside a recording device (INSECTAVOX) equipped with a modified electret microphone, a low-noise power supply, and noise filters. Songs recorded in the INSECTAVOX are digitized using Goldwave, whose several features enable extraction of critical song parameters, including carrier frequencies for pulse song and sine song. We demonstrate the utility of this approach by showing that deletion of the N-terminal region of the myosin regulatory light chain, a mutation known to decrease wing beat frequency and flight power, affects courtship song parameters.     

Behavioral Sequence Leading to Sexual Isolation Between <Emphasis Type="Italic">Drosophila ananassae</Emphasis> and <Emphasis Type="Italic">D. pallidosa</Emphasis>

Drosophila ananassae and D. pallidosa are closely related, sympatric species that lack postmating isolation. Sexual isolation has been considered important in maintaining them as independent species. To clarify the behavioral processes leading to sexual isolation, we analyzed behavioral sequences and examined the effect of courtship song on mating success and on behaviors of both sexes by surgically removing male wings (song generators), female aristae (song receivers), or female wings (means of fluttering). We found that heterospecific courtship songs evoked female wing fluttering, whereas conspecific courtship song did not. Furthermore, female wing fluttering made courting males discontinue courtship. These findings suggest that strong sexual isolation is achieved through the following behavioral sequence: heterospecific song→female wing fluttering→courtship discontinuation.     

Social effects on fruit fly courtship song

Courtship behavior in Drosophila has often been described as a classic innate behavioral repertoire, but more recently extensive plasticity has been described. In particular, prior exposure to acoustic signals of con‐ or heterspecific males can change courtship traits in both sexes that are liable to be important in reproductive isolation. However, it is unknown whether male courtship song itself is socially plastic. We examined courtship song plasticity of two species in the Drosophila melanogaster subgroup. Sexual isolation between the species is influenced by two male song traits, the interpulse interval (IPI) and sinesong frequency (SSF). Neither of these showed plasticity when males had prior experience of con‐ and heterospecific social partners. However, males of both species produced longer bursts of song during courtship when they were exposed to social partners (either con‐ or heterospecific) than when they were reared in isolation. D. melanogaster carrying mutations affecting short‐ or medium‐term memory showed a similar response to the social environment, not supporting a role for learning. Our results demonstrate that the amount of song a male produces during courtship is plastic depending on the social environment, which might reflect the advantage of being able to respond to variation in intrasexual competition, but that song structure itself is relatively inflexible, perhaps due to strong selection against hybridization.     

A Life History Trade-Off Between Flight Ability and Reproductive Behavior in Male Field Crickets (<Emphasis Type="Italic">Gryllus texensis</Emphasis>)

Male field crickets (Gryllus texensis) that differ in flight ability incur a life history trade-off between flight ability and reproduction, where flight ability comes with a male fitness cost. In courtship trials, flight-capable males produced courtship song, a necessary signal for mating success, with a significantly lower probability than flight-incapable males. The trade-off was evident in young males, and a similar trend occurred in older males. Males that lost the ability to fly through histolysis of flight muscles produced courtship song with a similar probability as males incapable of flight for their entire lives. Time of day did not affect the expression of the trade-off. Neither male morph nor time of day influenced female mating behavior.     

Copulatory courtship behavior and sine song as a mate recognition cue in Drosophila lini and its sibling species

Most Drosophila species sing species-specific pulse songs during their "precopulatory courtship." Three sibling species of the Drosophila montium species subgroup performed "copulatory courtship": males generated courtship songs by vibrating either wing only after mounting and during copulation. In these three species, strong sexual isolation was detected between D. ohnishii and D. lini and between D. ohnishii and D. ogumai, but not between D. lini and D. ogumai. Female showed strong repelling behavior when they were mounted by a heterospecific male in the species combinations including D. ohnishii, resulting in failure of the copulation attempt of the male. Acoustic analyses of courtship songs revealed that the pulse song was irregular, without any species-specific parameters, but that the frequency of the sine song was different among the three species in accordance with the modes of sexual isolation between them; it was significantly lower in D. ohnishii (mean ± SE = 193.0 ± 1.7 Hz) but higher in D. lini (253.4 ± 2.7 Hz) and D. ogumai (246.7 ± 5.3 Hz). We suggest that this difference in the sine song frequency is a sexual signal in the Specific Mate Recognition System (SMRS) among these three Drosophila species.     

ALTERED MATING BEHAVIOR IN A CARSONIAN POPULATION OF DROSOPHILA SECHELLIA

Mating behavior was studied in two laboratory populations of Drosophila sechellia and their reciprocal hybrids. The ancestral population was reared on a special medium, optimal for this species, while the derived population was reared on a standard Drosophila food, and underwent a bottleneck while adapting to this new medium, in a manner similar to the “founder-flush” process of Carson (1971). A significant tendency towards mating asymmetry was found, with ancestral females mating significantly less frequently with derived males than derived females with ancestral males. Analysis of hybrids suggested an important role for the male's X chromosome or for a maternal effect. No significant differences were found among parental types for their main female cuticular hydrocarbons, the proportion of courtship spent in various behavioral elements, body weight, or wing length. Significant differences were found in the structure of courtship, male locomotor activity, male cuticular hydrocarbon levels, and male courtship song inter-pulse interval (i.p.i.). None of these differences showed an X-linked effect in the reciprocal hybrids. Hypotheses put forward to explain interspecific mating asymmetries are discussed in the light of these results.     

Courtship song, male agonistic encounters, and female mate choice in the house cricket,Acheta domesticus (Orthoptera: Gryllidae)

Whether female crickets choose among males based on characteristics of the courtship song is uncertain, but in many species, males not producing courtship song do not mate. In the house cricket,Acheta domesticus, we examined whether a female chose or rejected a male based on his size, latency to chirp, latency to produce courtship song, or rate of the high-frequency pulse of courtship song (“court rate”). We confirmed that females mated only with males that produced courtship song, but we found no evidence that the other factors we measured affected a female’s decision to mate. In addition, we investigated whether the outcome of male agonistic encounters affected the subsequent production of courtship song. In one experiment, we observed courtship and mating behavior when a single female was placed with a pair of males following a 10-min interaction period between the two males. Winners of male agonistic encounters had higher mating success. However, winners and losers of agonistic encounters were not different in their likelihood or latency to produce courtship song or in the number of times they were disrupted by the other male in the pair. In a second experiment, we allowed two males to interact for a 10-min period, but following this interaction period, we placed a female with each male separately and observed courtship and mating behavior. The mating success of winners and losers was not different under these circumstances, and we found no differences between winners and losers in any subsequent courtship or mating behavior examined. We conclude that winning agonistic encounters influences a male’s mating success in ways other than his production of courtship song and this effect is lost when winning and losing males are separated and each is given an opportunity to mate.     

Genetic identification of neurons controlling a sexually dimorphic behaviour

In the fruit fly Drosophila melanogaster, locomotor activity is sexually dimorphic: female flies constantly modulate their activity pattern whereas males show a steadier, stereotyped walking pace [1]. Here, we mapped the area of the brain controlling this behavioural dimorphism. Adult male Drosophila expressing a dominant feminising transgene in a small cluster of neurons in the pars intercerebralis exhibited a female-like pattern of locomotor activity. Genetic ablation of these neurons prevented the feminisation of the locomotor activity of transgenic males. The results suggest that this cluster of neurons modulates sex-specific activity, but is not involved in initiating fly locomotion. Nor does it control male courtship behaviour, because feminisation of courtship was not correlated with the feminisation of locomotor activity.     

Effect of mutation-induced excess brain concentration of intermediates of the kynurenine pathway of tryptophan metabolism on stress resistance and courtship behavior and communicative sound production in male Drosophila melanogaster

The resistance of courtship behavior and communicative sound production to heat shock (37 degrees C, 30 min) was studied in wild-type Canton S (CS) male Drosophila melanogaster and males of two strains with defects in the kynurenine pathway of tryptophan metabolism (KPTM) caused by mutations cinnabar (block at the level of kynurenine-3-hydroxylase leading to accumulation of kynurenic acid, a neuroprotective metabolite, in the brain) and cardinal (block at the level of phenoxazinone synthetase causing accumulation of 3-hydroxykynurenine, an oxidative stress generator, in the brain). Males of each strain were divided into four groups. Males from control groups were not exposed to heat shock. The other groups were exposed to heat shock at the late embryonic/early larval (the first instar) developmental stage, when mushroom bodies are formed (HS1 groups); at the prepupal stage, when the brain central complex develops (HS2 groups); or at the imago stage 1 h before the experiment (HS groups). All males were tested at an age of five days. Virgin and fertilized five-day-old CS females served as courtship objects. The courtship behavior and singing of control CS and cinnabar males were similar. Control cardinal males also had high motivation, but their courtship efficiency was lower because of less precise movements (wing vibration was often not accompanied by sound production) and hyperexcitability. Exposure of first-instar larvae to heat shock had almost no effect on behavior or singing of adult males of any strain. In cardinal males exposed to heat shock at the prepupal stage or, especially, at the imago stage 1 h before the test (the HS2 and HS groups), courtship was strongly impaired, and various distortions appeared in their sound signals, which indicated disturbance of coordination between elements of the song center and their interaction with pacemakers. These effects were much milder or absent altogether in HS2 and HS wild-type males and, especially, cinnabar males. Thus, permanent excess of 3-hydroxykynurenine in the male brain dramatically decreased their stress resistance. In contrast, excess of kynurenic acid alleviated the consequences of stress.     

Song production in auditory mutants of Drosophila: the role of sensory feedback

To test the role of sensory feedback in song production. we analyzed the courtship songs of Drosophila males expressing auditory mutations. We compared the courtship songs of atonal (ato), beethoven (btv) and touch-insensitive-larva-B (tilB) to wild-type songs. These mutations have in common the fact that the chordotonal organs are disrupted. Since chordotonal organs subserve both hearing (in the antenna) and proprioception (from the wing), these two potential routes for sensory feedback are defective in the mutant flies. We measured six song characters: pulse number within a train, inter-pulse interval, pulse duration, sine burst duration, the carrier frequency of the sine song and the relative amplitude of the sine song. Using multivariate analysis, we found significant differences between mutant and normal songs. In addition many mutant flies exhibit an unusual wing position during singing. The results indicate that sensory feedback plays an important role in shaping the courtship song of Drosophila.     

The role of the mushroom bodies and of the central complex of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> brain in the organization of courtship behavior and communicative sound production

The role of the mushroom bodies and of the central complex of Drosophila melanogaster brain in the control of courtship behavior and sound production was studied by comparative analysis of courtship characteristics and singing parameters in wild type males (Canton S and Berlin), in Berlin males treated with hydroxyurea (HU) during development and thus devoid of the mushroom bodies (chemical ablation of the mushroom bodies) and in males from three mutant strains with anatomical defects in different parts of the central complex. It was shown that the mushroom bodies were practically not involved in this function, whereas the central complex plays a very important role in the organization of courtship behavior, in the control of accuracy of male following movements during the pursuit of a female, in the control of form stability of sound elements in courtship songs, in the control of rhythmic structure of courtship songs determined by the stability of the respective pacemakers and in setting up a correspondence between the current behavior and the context of the external situation. The contribution of different substructures of the central body to realization of these functions is different. So, despite the thoracic song center in Drosophila contains all the necessary elements for the generation of normal courtship signals of all types, modulating and stabilizing influences from the highest brain centers are necessary for the choice of its operating mode corresponding to the context of the external situation and for maintenance of its stability.Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 40, No. 6, 2004, pp. 521–530.     

Effect of mutation-induced excess brain concentration of intermediates of the kynurenine pathway of tryptophan metabolism on stress resistance of courtship behavior and communicative sound production in male Drosophila melanogaster

The resistance of courtship behavior and communicative sound production to heat shock (37°C, 30 min) was studied in wild-type Canton S (CS) male Drosophila melanogaster and males of two strains with defects in the kynurenine pathway of tryptophan metabolism (KPTM) caused by mutations cinnabar (block at the level of kynurenine-3-hydroxylase leading to accumulation of kynurenic acid, a neuroprotective metabolite, in the brain) and cardinal (block at the level of phenoxazinone synthetase causing accumulation of 3-hydroxykynurenine, an oxidative stress generator, in the brain). Males of each strain were divided into four groups. Males from control groups were not exposed to heat shock. The other groups were exposed to heat shock at the late embryonic/early larval (the first instar) developmental stage, when mushroom bodies are formed (HS1 groups); at the prepupal stage, when the brain central complex develops (HS2 groups); or at the imago stage 1 h before the experiment (HS groups). All males were tested at an age of five days. Virgin and fertilized five-day-old CS females served as courtship objects. The courtship behavior and singing of control CS and cinnabar males were similar. Control cardinal males also had high motivation, but their courtship efficiency was lower because of less precise movements (wing vibration was often not accompanied by sound production) and hyperexcitability. Exposure of first-instar larvae to heat shock had almost no effect on behavior or singing of adult males of any strain. In cardinal males exposed to heat shock at the prepupal stage or, especially, at the imago stage 1 h before the test (the HS2 and HS groups), courtship was strongly impaired, and various distortions appeared in their sound signals, which indicated disturbance of coordination between elements of the song center and their interaction with pacemakers. These effects were much milder or absent altogether in HS2 and HS wild-type males and, especially, cinnabar males. Thus, permanent excess of 3-hydroxykynurenine in the male brain dramatically decreased their stress resistance. In contrast, excess of kynurenic acid alleviated the consequences of stress.     

Correlation of acoustic and visual signals in the cichlid fish, <Emphasis Type="Italic">Tramitichromis intermedius</Emphasis>

We investigated acoustic and visual communication concurrently in wild caught adult and captive-born, first generation offspring of the East African Rift Lake cichlid fish Tramitichromis intermedius. Only males emit sound during courtship. Sound production is always accompanied by quivering, but quiver behavior is not always accompanied by sound. This separation of quivering and sound supports the hypothesis that sound production is intentional serving a communicative role. As spawning nears, both sound production and quiver behavior increase. In terms of the ontogeny of sound production, the first observation of courtship occurs just days before the first spawning event and the first sound emission accompanies the first courtship activity. The accompaniment of quivering with sound as well as the escalation of the two behaviors with the approach of spawning follows similar patterns in wild caught and captive-born males. The tight correlation between behavior and sound production in both groups indicates their simultaneous performance plays an important role in reproduction. It is probable that the ability to produce sound and perform quiver behavior at the same time may be a measure of mate quality.     

Analysis of temperature-sensitive mutants reveals new genes involved in the courtship song of Drosophila.

cacophony (cac), a mutation affecting the courtship song in Drosophila melanogaster, is revealed to cause temperature-sensitive (TS) abnormalities. When exposed to high temperatures (37 degrees), cac flies show frequent convulsions and pronounced locomotor defects. This TS phenotype seems consistent with the idea that cac is a mutation in a calcium-channel gene; it maps to the same X-chromosomal locus that encodes the polypeptide comprising the alpha-1 subunit of this membrane protein. Analysis of the courtship song of some TS physiological mutants showed that slowpoke mutations, which affect a calcium-activated potassium channel, cause severe song abnormalities. Certain additional TS mutants, in particular para(ts1) and nap(ts1), exhibit subtler song defects. The results therefore suggest that genes involved in ion-channel function are a potential source of intraspecific genetic variation for song parameters, such as the number of cycles present in "pulses" of tone or the rate at which pulses are produced by the male''s courtship wing vibrations. The implications of these findings from the perspective of interspecific lovesong variations in Drosophila are discussed.     

Behavioral and Cytogenetic Analysis of the cacophony Courtship Song Mutant and Interacting Genetic Variants in Drosophila melanogaster

The courtship song of a Drosophila melanogaster male consists of tone pulses interspersed with humming sounds. An X chromosomal mutation, cacophony (cac), causes the production of polycyclic pulses readily distinguishable from those in wild type, which are mono- or bicyclic. Yet, courtship hums and flight wing beats are normal in this mutant, suggesting a specific role of the cac gene in the neural program underlying one particular feature of the fly's wing vibrations. A precise cytogenetic localization of cac is presented; this was obtained by uncovering the song abnormality with deletions that are missing all or the distal part of region 11A; the flies tested were diplo-X adults that had been turned into males by the transformer mutation. Duplications including distal 11A covered cac. The possibility of behavioral specificity for cac's effects was examined by screening a variety of sexual and nonsexual behaviors; these experiments included tests of flies in which the mutation was uncovered by a small deletion. We conclude that cac causes only a limited array of well-defined defects: longer and louder tone pulses in the song and depressed locomotor activity. Further complementation tests involving cac and other closely linked genetic variants--the night-blind-A (nbA) visual mutation, l(1)L13 lethal mutations, and a series of X chromosomal breakpoints--suggested complex interactions among these factors: the breakpoints uncover all three types of mutations; cac and nbA appear to be alleles of l(1)L13, whereas the two behavioral mutations complement each other.     

Courtship Anomalies Caused by Doublesex Mutations in Drosophila Melanogaster

The role played by the sex-determining gene doublesex (dsx) and its influence on Drosophila courtship were examined. Against a background of subnormal male-like behavior that is reported to be an attribute of haplo-X flies homozygous for the original dsx mutation, and given that a sex-specific muscle is unaffected by genetic variation at this locus, analyses of several reproductive behaviors and control for genetic background effects indicated that XY dsx mutants are impaired in their willingness to court females. When they did court, certain behavioral actions were normal, including components of courtship song. However, these mutants never produced courtship humming sounds. Mature XY dsx flies elicited anomalously high levels of courtship; that this occurs merely because of a delay in imaginal development was experimentally discounted. The current analysis reconciled two ostensibly conflicting reports involving the courtship-stimulating qualities of this mutant type. Such experiments also uncovered a new behavioral anomaly: dsx mutations caused chromosomal males to court other males at abnormally high levels. These results are discussed from the perspective of doublesex's influence on internal tissues of adult Drosophila involved in the triggering and neural control of male- and female-like elements of courtship, reproductive pheromone production, or a combination of such factors.     

Courtship Behavior of Zaprionus indianus (Gupta) (Diptera: Drosophilidae) from Populations Colonizing South America

We describe for the first time the sexual behavior and the courtship song of males of the African fly Zaprionus indianus (Gupta), a recent invader of South America. The male courtship song is formed by monocyclic pulses and the courtship behavior is simple when compared to that of species of Drosophila. Two interpulse interval (IPI) distributions were observed: pre-mounting and mounting. No significant difference was observed between the pre-mounting IPIs of males that descended from three geographical populations from South America. We also observed the songs produced by females and the homosexual behavior exhibited by males. A sequence of bursts is produced by females as a refusal signal against males, while males emit a characteristic song that identifies sex genus, which differs from the courtship song. The short courtship and mating latencies recorded reveal vigorous males and receptive females, respectively.     

The nonA gene in Drosophila conveys species-specific behavioral characteristics

The molecular basis of species-specific differences in courtship behavior, a critical factor in preserving species boundaries, is poorly understood. Genetic analysis of all but the most closely related species is usually impossible, given the inviability of hybrids. We have therefore applied interspecific transformation of a single candidate behavioral locus, no-on-transient A (nonA), between Drosophila virilis and D. melanogaster, to investigate whether nonA, like the period gene, might encode species-specific behavioral information. Mutations in nonA can disrupt both visual behavior and the courtship song in D. melanogaster. The lovesong of nonA(diss) mutant males superficially resembles that of D. virilis, a species that diverged from D. melanogaster 40-60 mya. Transformation of the cloned D. virilis nonA gene into D. melanogaster hosts carrying a synthetic deletion of the nonA locus restored normal visual function (the phenotype most sensitive to nonA mutation). However, the courtship song of transformant males showed several features characteristic of the corresponding D. virilis signal, indicating that nonA can act as a reservoir for species-specific information. This candidate gene approach, together with interspecific transformation, can therefore provide a direct avenue to explore potential speciation genes in genetically and molecularly tractable organisms such as Drosophila.