Remating, sperm transfer, and sperm displacement in the cactophilic species Drosophila buzzatii Patterson & Wheeler (Diptera: Drosophilidae)

The mating system of Drosophila buzzatii is characterized by short copulation duration, frequent remating in both males and females, and male ejaculate partitioning. Additional features of the system are strong sperm displacement and a high frequency of sterile matings. Remating frequencies and the effects of remating on various mating parameters were studied. In order to characterize variation, five isofemale lines from geographically distant localities in Australia (three localities), Brazil and the Canary Islands were used. Mating parameters studied were: premating time, copulation duration, interval between successive matings, and progeny number as a measure of sperm transfer. Variation for sperm displacement was studied in crosses between laboratory stocks and a number of isofemale lines from Australia. There were significant between‐line differences in female remating frequencies, premating time, copulation duration, interval between successive matings, and progeny numbers, indicating genetic variation for these traits. Females from the five lines mated on average 1.6 to 3.1 times in 4 h, with a maximum of eight matings for one female. The males were given a maximum of ten virgin females in sequence and more than one‐third of the males mated all ten females in the 2 h observation period. Copulation duration decreased and interval between matings increased with copulation number in multiply mated males. Mean copulation duration was c. 2 min. Sperm transfer, measured as the average number of progeny from a single mating, was low (c. 25) and multiply mated females gave more progeny than single mated females, although with much lower progeny numbers than observed in wild‐caught non‐virgin females. A surprisingly high proportion of observed matings gave no progeny, i.e. they were sterile matings. Sperm displacement was strong in most crosses and remained strong in multiply mated females. The results are discussed in relation to the evolution of mating patterns in Drosophila.     

Theoretical influence of female mating status and remating propensity on male sperm allocation patterns

Theoretical models predict that males should allocate more sperm in matings where the immediate risk of sperm competition is high. It has therefore often been argued that males should invest less sperm in matings with virgin females compared with matings with already mated females. However, with relatively polyandrous females, high sperm competition risk will covary with high sperm competition intensity leading to more unpredictable conditions, as high competition intensity should favour smaller ejaculates. With the use of a genetic algorithm, we found that males should allocate more sperm in matings with virgin females when female mating frequency is relatively high, whereas low remating rates will select for higher effort in matings with nonvirgin females. At higher remating rates, first male sperm precedence favours larger ejaculates in matings with virgin females and second male precedence favours the reverse. These results shed some light on several findings that have been difficult to explain adaptively by the hitherto developed theory on sperm allocation.     

Sperm competition in the melon fly,Bactrocera cucurbitae (Diptera: Tephritidae): Effects of sperm “longevity” on sperm precedence

Sperm competition inBactrocera cucurbitae was studied by double matings of one female with normal and sterile males, with different intervals between the first and the second matings and with or without allowing oviposition after the first or the second mating. When the interval was less than 4 days, the last-male sperm precedence,P ₂ , was not different from 0.5, but as the interval was prolonged,P ₂ was higher than 0.5. There was no significant difference between treatments in which females were allowed to oviposit after the first mating and only after the second mating. The reason for the higherP ₂ when the interval was long was therefore attributed not to sperm usage for egg fertilization during the two matings but, possibly, to sperm mortality. ThatP ₂ was 0.5 for shorter intervals suggests that particular sperm replacement mechanisms such as removal and inactivation are absent in B. cucurbitae. Our study is the first to demonstrate a significant effect of short sperm longevity on the last-male sperm precedence.     

Last male sperm precedence in a damselfly demonstrated by RAPD profiling

We used the random amplified polymorphic DNA technique to determine last male sperm precedence ( P ₂) in the damselfly Calopteryx splendens xanthostoma (Charpentier). We amplified DNA from mothers, putative fathers and from the embryos of individual offspring, and subsequently calculated band-matching coefficients between known first-order relatives (offspring within a clutch) and non-relatives (mothers and fathers) to estimate last-male paternity. The data indicate that, as in other Calopterygidae, P ₂ is high (0.98) in the bout of oviposition immediately following copulation, despite the fact that the males of this species do not completely remove the sperm of previous males (Siva-Jothy & Hooper 1995).     

Sperm competition and sperm precedence in the dragonfly Nanophya pygmaea

Abstract. The libellulid dragonfly, Nanophya pygmaea Rambur, has an average ejaculate volume of 0.16 mm³. During successive copulations the volume of sperm stored in the female's sperm storage organs increases in steps equivalent to this volume, suggesting that the sperm competition mechanism in this species is sperm repositioning, i.e. adding an ejaculate to what is already present in the female's sperm storage organ. By using sterile/normal males in double matings with females we have shown that this mechanism results in last male sperm precedence (P²= 0.979).     

Why it is difficult to model sperm displacement in Drosophila melanogaster: the relation between sperm transfer and copulation duration

Abstract.— We have investigated the effects of experimental manipulation of copulation duration on sperm displacement in Drosophila melanogaster . Both spermless and normal males were used as second (displacing) males in the experiments. Displacement induced in the absence of sperm, that is, by males that pass accessory gland fluid alone, was a relatively inefficient process and produced much lower levels of displacement than normal males. Therefore, the presence of second-male sperm is necessary (but unlikely sufficient) for the high levels of displacement commonly observed in D. melanogaster . Furthermore, when second matings were interrupted at various times after the initiation of copulation, the distribution of displacement was strongly bimodal. We conclude that sperm transfer is relatively rapid, beginning shortly after the initiation of copulation, and is essentially complete before the midpoint of copulation. Therefore, sperm transfer bears no simple relation to copulation duration. Because it would be difficult to manipulate the numbers of sperm transferred by manipulating copulation duration, methods used to study sperm displacement in other insect species are unlikely to be appropriate for D. melanogaster . We also investigated why males mate for more than twice the duration that appears to be necessary to complete sperm transfer. Experimental interruption of first matings indicated that the extra copulation time serves to delay female remating, rather than to increase that rate at which of offspring are sired before remating.     

Effect of gamma irradiation on sperm utilization in twice-mated female Phthorimaea operculella Zeller (Lep., Gelechiidae)

The effects of the second mating on fecundity and fertility of potato tuber moth (PTM) Phthorimaea operculella (Zeller), when females were mated with 450 Gy-irradiated and normal males or vice versa, were studied. The percentage of eggs fertilized by sperm of the second mating (P₂ value) was 0.99, indicating that sperm transferred during the last mating were predominantly utilized in egg fertilization. Females, mated first with irradiated males, remated after 2 days, whereas those mated with normal males, remated after 3.3 days. Fecundity of twice-mated females was higher than those mated only once. Females started to lay their eggs 1.9 days after the first mating, regardless of the type of male. However, virgin females did not lay eggs at all. Duration of copulation varied from 102 to 117 min for normal and irradiated males, respectively. The present study elucidated important aspects of mating behaviour of PTM which could improve the efficiency of its control by the sterile insect technique.     

Nuptial gift consumption influences female remating in a scorpionfly: male or female control of mating rate?

In the scorpionfly Panorpa cognata, males provide females with saliva secretions as nuptial food gifts. Consequently, females derive material benefits and possibly also genetic benefits from multiple matings. Females therefore generally should have a high motivation to remate. Males, on the other hand, do not share this interest, which will generate a sexual conflict over remating interval, possibly leading to male adaptations that prevent females from remating with other males. In this study, I found that mated females were less prone to copulate than virgin females, despite female benefits of multiple matings. Further, I found that the remating interval was significantly longer if the first copulation was long compared to shorter matings. This effect does not entirely depend on copulation duration per se, but on the amount of saliva, that a female is consuming during copulation. These results suggest a mating-induced refractory period and can be interpreted as male manipulation of female remating behaviour mediated through substances in the nuptial gift. Alternatively, receiving large nuptial gifts may decrease the prospective direct fitness benefits from further copulations, and thus change optimal female remating rate. Furthermore, gift size has been shown to correlate with male nutritional condition, which may be an indicator of male genetic quality. Females may therefore benefit indirectly by not remating following copulations involving large saliva gifts. In this scenario, female remating interval would be an effect of cryptic female choice.     

Last–male sperm precedence in the bushcricket Poecilimon veluchianus (Orthoptera, Tettigonioidea) demonstrated by DNA fingerprinting

Males of the bushcricket Poecilimon veluchianus pass a large spermatophore to the female during mating. The spermatophore is eaten by the female after copulation. Because females mate with several males during their reproductive life, the competition between spermatozoa of different males affects a male's reproductive success. In order to determine the outcome of sperm competition, the paternity of the progeny of double–mated females was established by DNA fingerprinting with the oligonucleotide (GATA)₄. Typical P. veluchianus DNA fingerprints consisted of 15 scoreable fragments per individual. The proportion of bands shared between presumably unrelated bushcrickets was 17%. After the second copulation the second mating male clearly predominated at fertilization. The mean proportion of eggs fertilized by the second male was 90.1%. There was no significant relationship between the level of sperm precedence and the time of ovipositions after the second mating. If female P. veluchianus increase the fitness of their offspring by the incorporation of spermatophore–derived substances in developing eggs, there is little chance for the feeding male to fertilize eggs containing his nutrients, because of the very short mating intervals of females and the observed high level of last–male sperm precedence in this species. Under such conditions the last mating male would fertilize many eggs containing nutrients from a prior male. Because nuptial gifts, like the tettigoniid spermatophore, function only as paternal investment if the donating male's progeny benefit from the gift, a paternal investment function of the P. veluchianus spermatophore seems to be unlikely.     

Last male sperm precedence in a polygamous squid

Differential sperm usage from consecutive matings, or sperm precedence, is vital in determining male reproductive success and the outcome of sperm competition for many organisms. Sperm precedence also has significant consequences for mating system dynamics, including both male and female adaptations for increasing reproductive success and avoiding the costs of mating. Despite sexual selection being a strong driver of reproductive behaviour and morphology in cephalopods, surprisingly few studies have investigated sperm dynamics in this group. To redress this gap, we experimentally quantified sperm precedence patterns in the dumpling squid, Euprymna tasmanica, controlling for recent male mating history (first vs. second mating), mating position, and mating frequency. We found that the last male to mate gains an advantage in this system, with the second mating male siring up to 75% of offspring at the beginning of the laying period. The proportion of offspring attributable to the second mating male decreases to 54% by the end of the laying period, potentially as a result of changes in the velocity or number of sperm released from spermatangia over time. There is also significant variation among females in patterns of sperm precedence. This variation was not associated with whether it was the male's first or second mating, male mass, the duration of copulation or the number of pumps (sperm removal behaviour) by the second male. If widespread in cephalopods, last male sperm precedence could help to explain the evolution of mate guarding (or long copulation duration) and sperm removal behaviour in this group.     

Male sperm donation consequences in single and double matings in Anisopteromalus calandrae

Abstract. The number of spermatozoa that a male transfers to the female during copulation is a main component of its individual fitness, especially under the pressure of sperm competition. This paper presents experimental results on the direct relationship between the male's sperm investment and its paternity in the offspring of dual-mated females. An eye colour mutant (red-eyed) is used to study the differences in the mating and fertilization abilities of males through observation of single and dual matings of females in Anisopteromalus calandrae (Hymenoptera, Chalcidoidea, Pteromalidae). Experimentally, females accept dual matings only in the simultaneous presence of two males. Counts of spermatozoa in the seminal vesicles of virgin males show that red-eyed males have more sperm than wild-eyed ones (approximately 1.46-fold greater). Red- and wild-eyed males do not differ in their mating behaviour and females mate indifferently with both phenotypes. Compared with once-mated females, double-mated females increase neither sperm storage nor lifetime fecundity, and the offspring sex ratio is female-biased. Females mated with two males of different phenotypes produce offspring of both phenotypes throughout their reproductive life, whatever the order of males in the copulation sequence. Any mating pattern appears to produce more red- than wild-eyed offspring (between 1.45- and 1.88-fold greater). Thus, proportions of offspring of each male match the proportions of their sperm potential. With no preference of female for red-eye or wild-eye males being demonstrated at either behavioural or physiological levels, a male's investment in sperm quantity appears to determine its individual reproductive success, at least in these experimental conditions.     

Securing paternity: mating plugs in the dwarf spider Oedothorax retusus (Araneae: Erigoninae)

One of the various male strategies to prevent or impede female remating is the production of a mating plug that covers the female genital opening or remains inside of the female genital tract after mating. Such structures have been described for many species in many animal taxa; however, in most cases, we know little or nothing about their specific adaptive value. Our investigations demonstrate that females of the dwarf spider species Oedothorax retusus (Westring, 1851) (Linyphiidae, Erigoninae) exhibit a substance on one or both of her paired genital openings only after copulation. We performed double-mating trials and forced the second male to mate into the previously used or unused spermathecal duct of the female by amputating one of his paired male gonopods (pedipalps). Furthermore, to investigate whether the duration of the first mating has an effect on the size and efficiency of the mating plug, we interrupted first matings after either 1 or 3 min, categorized plug size and recorded mating behaviour of subsequent males. The amount of secretion transferred was larger in long compared to short copulations. A long first copulation successfully prevented subsequent males from mating into the used ducts, whereas mating success after short first matings was similar to matings into unused copulatory ducts of the females. The present study demonstrates that a male O. retusus can prevent a rival from transferring sperm into the same spermatheca by applying a mating plug, but only if he mates for long enough.  © 2009 The Linnean Society of London, Biological Journal of the Linnean Society , 2009, 96 , 574–583.     

Sperm transfer during mating, movement of sperm in the female reproductive tract, and sperm precedence in the common cutworm Spodoptera litura

Abstract. Mating behaviour, sperm transfer and sperm precedence were studied in the moth Spodoptera litura (Fabr.) (Lepidoptera: Noctuidae). There existed a rhythmic, diel pattern of mating behaviour of this moth during the scotophase, presumably set with respect to an endogenous activity rhythm. Approximately 30 min after copulation had started, the formation of the corpus of the spermatophore began in the bursa copulatrix of the female moth, but full inflation of the corpus was not completed until 45–60 min after mating had started. The mature spermatophore contained about 350 eupyrene sperm bundles and a large number of individual (loose) apyrene spermatozoa. The mating status and the age of the male insect influenced the number of sperm transferred to the female within the spermatophore, and also affected the consequent fertility. There was no evidence of sperm reflux within the male tract. Within the female, dissociation of eupyrene sperm bundles was evident within the spermatophore less than 15 min after the completion of mating. Spermatozoa began to move from the bursa (in which the spermatophore is lodged) into the spermatheca 30–45 min after the end of the copulation, and the quantity of sperm in the spermatheca reached a plateau at 90 min after mating. Apyrene sperm reached the spermatheca first, followed by eupyrene sperm. Examination of total (apyrene plus eupyrene) sperm in the female tract showed that 86% of mated females received an apparently normal amount of total sperm from the male. Examination of eupyrene sperm alone showed that 81% of matings resulted in an apparently normal transfer of eupyrene sperm. A small proportion (approximately 8%) of the matings, however, were identified as transferring a clearly subnormal quantity of eupyrene sperm to the spermatheca. The eggs produced as a result of such pairings displayed much reduced fertility (about 43%) compared to those from matings confirmed to have transferred normal quantities of sperm, which showed about 92% fertility. This shows that the availability of eupyrene sperm in the spermatheca may be an important constraint on fertility in normal populations of insects. In the laboratory, S. litura females exhibited multiple matings. Of the females, 93% mated, and the mean frequency of mating was 1.69. Mating with a fertile male led to the oviposition of an increased number of eggs. This effect continued even when the female subsequently mated with an infertile male. Displacement of sperm from previous matings is known to be an important factor in the evolution of multiple mating strategies. Our results on sperm utilization by S. litura indicated that after a second mating, the sperm utilized for subsequent fertilization were almost exclusively from the last mating with little mixing. The proportion of eggs fertilized by sperm from the second mating (P₂) was calculated as 0.95, indicating almost complete sperm precedence from the last mating.     

Multiple paternity in wild-caught Drosophila mojavensis

Female remating frequency and sperm allocation patterns can strongly influence levels of sperm competition and reproductive success in natural populations. In the laboratory, Drosophila mojavensis males transfer very few sperm per copulation and females remate often, suggesting multiple paternity should be common in nature. Here, we examine female sperm loads, incidence of multiple paternity, and sperm utilization by genotyping progeny from 20 wild-caught females at four highly polymorphic microsatellite loci. Based on indirect paternity analyses of 814 flies, we found evidence for high levels of multiple paternity coupled with relatively low reproductive output, consistent with the high levels of female remating predicted in this sperm-limited species. Overall, we found little evidence for last -- male sperm precedence though some temporal variation in sperm utilization was observed, consistent with laboratory findings.     

Effects of different male remating intervals on the reproductive success of Choristoneura rosaceana males and females

The mass of the spermatophore transferred by a previously mated Choristoneura rosaceana male increases with time elapsed since the last mating but, even after 4 days, it never reaches the mass of the spermatophore of a virgin male. However, spermatophore mass is clearly not a good indicator of the male reproductive investment as the quantity of sperm in the second ejaculate of a previously mated male is the same as that of his first, if he is allowed a 2 (eupyrene sperm) to 3 day (apyrene sperm) recovery period. The interval between the first two matings had no influence on female fecundity or longevity but significantly affected fertility if the male had only 1 day to recover. The length of the post-copulatory refractory period was also shorter in females mated with previously mated males than in those mated with virgins, regardless of the male's remating interval. Furthermore, a significant variation in the eupyrene sperm content of the spermatophore transferred by virgin males had no influence on the length of the female refractory period. Globally, these results support the hypothesis that a factor, other than sperm numbers in the spermatheca, is responsible for maintaining the inhibition of pheromone production in this species.     

Sperm precedence in the dragonfly Erythemis simplicicollis

Females of the dragonfly Erythemis simplicicollis (Say) (Odonata, Libellulidae) store enough sperm to fertilize 6–13 clutches of eggs laid on consecutive days. Nonetheless, they usually mate one or more times per day. Males wait for females at ponds containing surface vegetation on which the females lay eggs. Some males defend vegetation while other act as satellites. After mating, both types of males attempt to guard females against takeover by other males. Sperm precedence by male E. simplicicollis was studied using sterility produced by gamma irradiation to label sperm. After a dose-response analysis, males receiving a dose of 25 kiloroentgens (>99.9% sterile) were returned to their home pond as territory residents and satellites. Both types of males fertilized an average of 99.5% (range 97.3–100%) of the female's remaining clutch. After mating with a sterile male, females were isolated in a large cage, and eggs collected for several consecutive days. These clutches revealed that sperm mixing in the bursa of the females is essentially complete after 24 to 48 h and that the last male to mate had replaced an average of more than 57–75% of the sperm stored by female from previous matings. Thus, the last sperm in is the first sperm out fertilizing essentially all of the eggs laid soon (5–6 min) after the mating. Sperm from the most recent mating competes for fertilizations with sperm stored from previous matings only if the female oviposits on the following day without remating.     

The benefits of male ejaculate sex peptide transfer in Drosophila melanogaster

The accessory gland protein (Acp) ejaculate molecules of male Drosophila melanogaster mediate sexual selection and sexual conflict at the molecular level. However, to date no studies have comprehensively measured the timing and magnitude of fitness benefits to males of transferring specific Acps. This is an important omission because without this information it is not possible to fully understand the strength and form of selection acting on adaptations such as Acps. Here, we measured the fitness benefits to males of ejaculate sex peptide (SP) transfer. SP is of interest because it is a candidate for mediating sexual conflict: its frequent receipt reduces female fitness. In single matings with virgin females SP is known to increase egg laying and decrease receptivity. Hence, we predicted that SP could: (i) boost a male’s absolute paternity by increasing offspring production and delaying female remating and/or (ii) boost relative paternity share. We tested these predictions using two different lines of SP‐lacking males, in both two‐mating and free‐mating assay conditions. SP transfer conferred higher absolute, but not relative, male reproductive success. In matings with virgin females, SP transfer increased mating productivity and delayed remating and hence the onset of sperm competition. In already mated females, SP transfer did not elevate absolute progeny production, but did increase intermating intervals and hence the period over which a male could gain paternity. Consistent with this, under free‐mating conditions over an extended period, we detected a ‘per‐mating’ fitness benefit for males transferring SP. These benefits are consistent with a role for SP in mediating conflict, with SP acting to maximize short‐term fitness benefits for males.     

Long-term study of female multiple mating indicates direct benefits in Tribolium castaneum

Polyandry or female mating with several different partners in a single fertile period is a widespread phenomenon possibly involving both costs and benefits. This study tested whether remating after weeks of initial copulation (periodic multiple mating) has fitness consequences for females of red flour beetle, Tribolium castaneum (Herbst) (Coleoptera: Tenebrionidae), a cosmopolitan storage pest. We hypothesize that females benefit from higher mating frequency and more mates through sperm replenishment and/or compatible sperm. Thus, offspring production and survivorship were examined of females that were mated to multiple males or the same male repeatedly at variable intervals (every 2 weeks, 1, 3, and 5 months). Our results suggest that remating, after months of initial copulation, confers direct benefits to females, likely by providing additional sperm or through an alternative mechanism such as better ability of fresh sperm to fertilize eggs, stimulation of oviposition from copulation itself, and/or hydration benefit of the ejaculate. We did not detect any additional benefit of female multiple mating.     

The role of sperm numbers in sperm competition and female remating in Drosophila melanogaster

Single mating productivities (used as estimates of the relative number of sperm transferred) are highly correlated with several parameters used to quantify sperm competition in D. melanogster. Matings that result in the transferal of large numbers of sperm are associated with longer delay of female remating than are matings that transfer fewer sperm. Males that transfer larger numbers of sperm also suffer a smaller proportional reduction in reproductive success (smaller COST) than males transferring fewer sperm. The number of sperm transferred by a female's second mate is not related to the COST to the first male. However, there is a high positive correlation between the number of sperm transferred by the second male and P₂ (the proportion of second male progeny following female remating). Thus, large sperm numbers apparently increase the reproductive success of males whether they mate with virgin or non-virgin females. Because female receptivity mediates these events, there is no need to invoke sperm displacement to explain the reproductive outcome of female remating.The timing of female remating is evaluated in terms of a receptivity-threshold model. This model suggests that female receptivity returns when some small, relatively constant, number of sperm remain in storage.     

Pattern of sperm storage and migration in the reproductive tract of the swallowtail butterfly Papilio xuthus: cryptic female choice after second mating

Females of the swallowtail butterfly Papilio xuthus L. (Lepidoptera: Papilionidae) mate multiply during their life span and use the spermatophores transferred to increase their longevity as well as fecundity. Sperm from different males may be stored in the sperm storage organs (bursa copulatrix and spermatheca). To clarify the pattern of sperm storage and migration in the reproductive tract, mated females are dissected after various intervals subsequent to the first mating, and the type and activity of sperm in the spermatheca are observed. When virgin females are mated with virgin males, the females store sperm in the spermatheca for more than 10 days. Sperm displacement is found in females that are remated 7 days after the first mating. Immediately after remating, these females flush out the sperm of the first male from the spermatheca before sperm migration of the second male has started. However, females receiving a small spermatophore at the second mating show little sperm displacement, and the sperm derived from the small spermatophore might not be able to enter the spermatheca. Females appear to use spermatophore size to monitor male quality.