Function of Prolonged Copulation in Nysius huttoni White (Heteroptera: Lygaeidae) Under Male-Biased Sex Ratio and High Population Density

Prolonged copulation as a response to sex ratio and population density has been demonstrated for a number of species but the functions behind it remain controversial. It is difficult to determine the function of prolonged copulations without examining the mechanisms of sperm transfer and storage, and fertilization success–copulation duration relationships. Here, we report our work on a polygamous seed bug, Nysius huttoni White (Heteroptera: Lygaeidae), where we manipulated the population density and sex ratio for a series of mating trials, quantified the relationship between copulation duration and ejaculate amount as well as reproductive outputs, and examined the sperm transfer and storage mechanisms. Our results suggest that males prolong copulations to increase their fertilization success relative to their rivals in response to high sperm competition intensity under male-biased sex ratio and high population density. The mechanism behind the positive correlation between copulation duration and fertilization success may be attributed to the characteristic structures of aedeagus and spermatheca in this insect, which allow direct transfer of sperm to a storage site of fixed size during copulation.     

Strategic ejaculation in the common dung fly Sepsis cynipsea

Sperm competition has been a major selective force acting on male and female behaviour. Theory predicts that when sperm compete numerically, selection will favour males that vary the number of sperm they transfer with sperm competition risk. This often leads to increased copula duration when sperm competition risk is high, the selective advantage of which is increased paternity. We investigated the copulatory behaviour of the common dung fly Sepsis cynipsea in relation to male and female size, female mating status, age, and presence or absence of dung. This fly is unusual in that males mate-guard before copula while females use the sperm of previous males for their current clutch. Body size had no effect on copula duration, but duration of first copulations depended on female age, with older females having longer copulations. For females that copulated twice, there was an interaction between female age and mating status influencing copula duration: old females had longer copulations than young females, but second copulas were longer for young females. Residual testis size of nonvirgin males was smaller than for virgins, and testis shrinkage was significantly associated with copula duration, which indicates that males transfer more ejaculate with longer copulations. We therefore conclude that copulation duration and ejaculate transfer vary in accordance with sperm competition theory.     

Patterns of Sperm Transfer in the Golden Orb‐Weaver Nephila edulis

Sperm competition studies typically identify copulation duration as an important predictor of paternity as it may determine the quantity of sperm transferred and thus paternity success. This study explores the relationship between copulation duration, male body size, male age and sperm transfer in the golden orb‐weaving spider, Nephila edulis. Paternity in this species is strongly associated with the relative frequency and duration of copulation, which is also influenced by male size. We determined the number of sperm transferred during copulation, by performing sperm counts in both the male copulatory organs (palps) and female sperm receptacle (spermatheca) of recently mated pairs. The total number of sperm recorded (the sum in the male palps and female spermathecae) was greater for younger males than older males, but did not vary with male body size. In general, younger males transferred more sperm and a greater proportion of their sperm supplies than older males and, among these younger males, larger individuals transferred more sperm. However, there were no significant size effects for older males. More sperm was transferred with longer copulations, but in contrast with previous studies, we found that larger males copulated for longer. The rate of sperm transferred was negatively correlated with the duration of copulation, suggesting that the variation in copulation duration in N. edulis may represent strategic investment by males to alter patterns of paternity, in addition to transferring additional sperm.     

Differential sperm expenditure reveals a possible role for post‐copulatory sexual selection in a lekking moth

Male reproductive success in the lesser wax moth Achroia grisella is strongly determined by pre‐copulatory mate choice, during which females choose among males aggregated in small leks based on the attractiveness of ultrasonic songs. Nothing is known about the potential of post‐copulatory mechanisms to affect male reproductive success. However, there is evidence that females at least occasionally remate with a second male and that males are unable to produce ejaculates quickly after a previous copulation. Here we investigated the effects of mating history on ejaculate size and demonstrate that the number of transferred sperm significantly decreased from first (i.e., virgin) to second (i.e., nonvirgin) copulation within individual males. For males of identical age, the number of sperm transferred was higher in virgin than in nonvirgin copulations, too, demonstrating that mating history, is responsible for the decrease in sperm numbers transferred and not the concomitant age difference. Furthermore, the number of transferred sperm was significantly repeatable within males. The demonstrated variation in ejaculate size both between subsequent copulations as well as among individuals suggests that there is allocation of a possibly limited amount of sperm. Because female fecundity is not limited by sperm availability in this system, post‐copulatory mechanisms, in particular sperm competition, may play a previously underappreciated role in the lesser wax moth mating system.     

Risk of Sperm Competition Mediates Copulation Duration, but not Paternity, of Male Burying Beetles

Males should increase their investment in ejaculates whenever they are faced with an increased risk of sperm competition. Burying beetles (Nicrophorus vespilloides), insects that breed on small vertebrate carcasses, offer an ideal model with which to examine sperm allocation tactics because females typically mate with many males prior to laying eggs. Males compete directly for control of carcasses, and males losing such contests often become satellites, lurking in the vicinity of the carcass and attempting surreptitious copulations with the resident female. We predicted that both the dominant resident male and the satellite male would increase their sperm allocation in the presence of the other, but that relative to dominant males, satellite males would allocate a greater number of sperm per ejaculate. We employed a repeated-measures design in which two full-sib rival males, differing only in their dominance status, were each mated a single time to a previously-inseminated female under two conditions, once in the absence of their rival and once in the presence of their rival. Satellite males exhibited longer copulation durations than dominant resident males when both males were present on a carcass. Copulation durations of dominant males did not differ in the presence or absence of satellite males. Contrary to expectation, the increased copulation durations of satellite males did not result in a greater share of paternity relative to dominant males. The absence of any discernible effect of increased copulation durations on paternity in satellite males could be due to post-copulatory preferences of females or, alternatively, satellite males may require longer durations of copulation to transfer the same amount of sperm as dominant males.     

Determinants of sperm transfer in the scorpionfly Panorpa cognate: male variation, female condition and copulation duration

Recent studies suggest that sperm production and transfer may have significant costs to males. Male sperm investment into a current copulation may therefore influence resources available for future matings, which selects for male strategic mating investment. In addition, females may also benefit from actively or passively altering the number of sperm transferred by males. In the scorpionfly Panorpa cognata, the number of sperm transferred during copulation depended on copulation duration and males in good condition (residual weight) copulated longer and also transferred more sperm. Moreover, sperm transferred and stored per unit time was higher in copulations with females in good condition than in copulations with females in poor condition. Males varied greatly and consistently in their sperm transfer rate, indicative of costs associated with this trait. The duration of the pairing prelude also varied between males and correlated negatively with the male's sperm transfer rate, but no other male character correlated significantly with male sperm transfer rate. The results are consistent with strategic mating effort but sperm transfer could also be facilitated by the physical size of females and/or females in good condition may be more cooperative during sperm transfer.     

Postmating sexual selection: the effects of male body size and recovery period on paternity and egg production rate in a water strider

The role of male body size in postmating sexual selection wasexplored in a semiaquatic insect, the water strider Gerris lateralis.To separate effects of male size per se from those due to numericsperm competition, male recovery period (shown here to be proportionalto ejaculate size) was manipulated independently of body sizein a factorial experiment where virgin females were mated firstwith sterile males and then with focal males. Both relativemale fertilization success and female reproductive rate were measured.The number of sperm transferred increased with male recoveryperiod, an effect that was mediated by longer copulation duration,but there were no effects of body size on ejaculate size. Neithermale size nor recovery period had any significant direct effectson male fertilization success. However, copulation durationinfluenced relative fertilization success, suggesting that malesable to transfer more sperm also achieved higher fertilizationsuccess. Females exercised cryptic female choice by modulatingtheir reproductive rate in a manner favoring large males andmales that were successful in terms of achieving high relativefertilization success. Thus, successful males gained a twofoldadvantage in postmating sexual selection. This study has important implicationsfor previous estimates of sexual selection in this group of insectsbecause pre- and postmating sexual selection will be antagonisticdue to limitations in male sperm production: males mating frequently(high mating success) will on average transfer fewer sperm ineach mating and will hence tend to fertilize fewer eggs permating (low fertilization success).     

Behavioral Interaction Between Males of Cephalonomia tarsalis (Ashmead) (Hymenoptera: Bethylidae) Competing for Females

Male Cephalonomia tarsalis (Ashmead) compete with one another for mates. The behavioral interactions between males for mates occur both on and off females. Males winning the first copulation do not exhibit apparent postcopulatory mate-guarding behaviors, and females accept subsequent copulations with losing males soon after separation. The duration of copulation when a second male is present is shorter than when only one male is present. However, females receive sufficient sperm for their life-time female progeny production in copulations disrupted artificially at 10 s (1/5 of the regular copulation duration) under normal noncompetition situations. This suggests that shorter copulations because of male–male competition could still result in adequate sperm transfer. Larger males were not more successful in competition than small males, but male competitive ability decreased with age.     

Strategic ejaculation in the egg parasitoid Trichogramma turkestanica (Hymenoptera: Trichogrammatidae)

Abstract.  1. Several parameters influence sperm allocation by males, including their size and sperm stock, intra-specific variability, quality of females', as well as the risk and intensity of sperm competition.
2. Models predict that males should invest the maximum ejaculate size when sperm competition intensity is low. As sperm competition intensity increases, males should decrease the number of sperm transferred during mating.
3. This decrease in sperm transfer to females occurs because the benefits gained by males with each extra unit of expenditure on sperm decrease. When sperm supply is not unlimited, males could expect a better return by keeping some or all sperm for mating under lower competition intensity.
4. In this study, the ejaculate size of males that were kept in groups of one, five or 10 males prior to mating, has been investigated in the haplodiploid egg parasitoid Trichogramma turkestanica Meyer (Hymenoptera: Trichogrammatidae).
5. As predicted by theory, the number of sperm transferred decreased significantly with an increase in the number of rivals.
6. This is the first study showing strategic sperm allocation depending on sperm competition intensity in a parasitoid.     

Cryptic reproductive isolation in the Drosophila simulans species complex

Forms of reproductive isolation that act after copulation but before fertilization are potentially important components of speciation, but are studied only infrequently. We examined postmating, prezygotic reproductive isolation in three hybridizations within the Drosophila simulans species complex. We allowed females to mate only once, observed and timed all copulations, dissected a subset of the females to track the storage and retention of sperm, examined the number and hatchability of eggs laid after insemination, counted all progeny produced, and measured the longevity of mated females. Each of the three hybridizations is characterized by a different set of cryptic barriers to heterospecific fertilization. When D. simulans females mate with D. sechellia males, few heterospecific sperm are transferred, even during long copulations. In contrast, copulations of D. simulans females with D. mauritiana males are often too short to allow sperm transfer. Those that are long enough to allow insemination, however, involve the transfer of many sperm, but only a fraction of these heterospecific sperm are stored by females, who also lay fewer eggs than do D. simulans females mated with conspecific males. Finally, when D. mauritiana females mate with D. simulans males, sperm are transferred and stored in abundance, but are lost rapidly from the reproductive tract and are therefore used inefficiently. These results add considerably to the list of reproductive isolating mechanisms in this well-studied clade and possibly to the list of evolutionary processes that could contribute to their reproductive isolation.     

Sex‐specific repeatabilities and effects of relatedness and mating status on copulation duration in an acridid grasshopper

In species with direct sperm transfer, copulation duration is a crucial trait that may affect male and female reproductive success and that may vary with the quality of the mating partner. Furthermore, traits such as copulation duration represent the outcome of behavioral interactions between the sexes, for which it is important—but often difficult—to determine which sex is in phenotypic control. Using a double‐mating protocol, we compared copulation durations between (1) virgin and nonvirgin and (2) sibling and nonsibling mating pairs in rufous grasshoppers Gomphocerippus rufus. Nonvirgin copulations took on average approximately 30% longer than virgin copulations, whereas relatedness of mating partners was not a significant predictor of copulation duration. Longer nonvirgin copulations may represent a male adaptation to sperm competition if longer copulations allow more sperm to be transferred or function as postinsemination mate guarding. The absence of differences between pairs with different degrees of relatedness suggests no precopulatory or preinsemination inbreeding avoidance mechanism has evolved in this species, perhaps because there is no inbreeding depression in this species, or because inbreeding avoidance occurs after copulation. Controlling for the effects of male and female mating status (virgin vs. nonvirgin) and relatedness (sibling vs. nonsibling), we found significant repeatabilities (R) in copulation duration for males (R = 0.33; 95% CI: 0.09–0.55) but not for females (R = 0.09; 95% CI: 0.00–0.30). Thus, copulation durations of males more strongly represent a nontransient trait expressed in a consistent manner with different mating partners, suggesting that some aspect of the male phenotype may determine copulation duration in this species. However, overlapping confidence intervals for our sex‐specific repeatability estimates indicate that higher sampling effort is required for conclusive evidence.     

Male Age,Copulation Duration and Insemination Success in Mystacides azurea (Leptoceridae,Trichoptera)

Time in copula in the swarming caddis fly Mystacides azurea L. (Trichoptera: Leptoceridae) ranged from 0.33 to 44.5 min. It increased with male age (wing wear) and male dry weight, but was independent of male and female size (forewing length), female wing wear and number of eggs in the females. Older males failed to transfer sperm during copulation more frequently than did younger ones. It is suggested that females benefit by interrupting prolonged copulations if sperm is not transferred rapidly, since being in copula might increase the risk of predation. Alternatively, young and old males follow different mating tactics; old males have a lower chance to acquire new mates and they do better by monopolizing a female, once they get one, by prolonging the copulation.     

Pattern of sperm transfer in redback spiders: implications for sperm competition and male sacrifice

Many sperm competition studies have identified copulation durationas an important predictor of paternity. This result is ofteninterpreted as a sperm transfer effect—it is assumed thatsperm transfer is limited by copulation duration. Here we testthe assumption of duration-dependent sperm transfer in the Australianredback spider, Latrodectus hasselti, in which a correlationbetween copulation duration and paternity has been implicatedin the evolution of a rare male self-sacrifice behavior. Maleredbacks facilitate sexual cannibalism by females during copulation.Sexual cannibalism is apparently adaptive for redback males,in part because it results in longer copulations (25 versus11 min.), and copulation duration is positively correlated withpaternity. We assessed sperm transfer in normal copulationsand in copulations that we terminated at 5, 10, or 20 min. Ourresults show that the paternity advantage of sexual cannibalismis not owing to time-dependent sperm transfer, as redback malestransfer the majority of their sperm within the first 5 minof copulation. This suggests that the link between copulationduration and paternity may instead be owing to cryptic femalechoice or the transfer of nongametic ejaculatory substances.Results further indicate that the act of cannibalism itselfmight play a role in mediating sperm transfer. This study highlightsthe importance of understanding mechanisms of sperm transferwhen attempting to interpret the outcome of sperm competitionstudies.     

Social status and availability of females determine patterns of sperm allocation in the fowl

Where sperm competition occurs, the number and quality of sperm males inseminate relative to rival males influences fertilization success. The number of sperm males produce, however, is limited, and theoretically males should allocate sperm according to the probability of gaining future reproductive opportunities and the reproductive benefits associated with copulations. However, the reproductive opportunities and value of copulations males obtain can change over their lifetime, but whether individuals respond to such changes by adjusting the way they allocate sperm is unclear. Here we show that, in the fowl, Gallus gallus, dominant males, which have preferential access to females, modulate the number of sperm they ejaculate according to the availability of females. When presented with two females, dominant males allocated more sperm to higher quality females, whereas when females were on their own, only copulation order had an affect on their sperm numbers. In contrast, subordinate males, whose mating activity is restricted by dominant males, allocated high numbers of sperm to initial copulations, irrespective of female availability. We further show, by manipulating male social status, that sperm allocation is both phenotypically plastic, with males adjusting their patterns of sperm allocation according to their dominance rank, and intrinsic, with males being consistently different in the way they allocate sperm, once the effects of social status are taken into account. This study suggests that males have evolved sophisticated patterns of sperm allocation to respond to frequent fluctuations in the value and frequency of reproductive opportunities.     

Mating biology of the leaf-cutting ants Atta colombica and A. cephalotes

Copulation behavior has often been shaped by sexually selected sperm competition or cryptic female choice. However, manipulation of previously deposited ejaculates is unknown in the social Hymenoptera and the degree to which sperm competes after insemination or is actively selected by females has remained ambiguous. We studied the mating process in the leaf-cutting ants Atta colombica and A. cephalotes, which belong to one of the few derived social insect lineages where obligate multiple mating has evolved. As copulations often occur at night and in remote places, direct observations were impossible, so we had to reconstruct the sequential copulation events by morphological analysis of the male and female genitalia and by tracking the process of sperm transfer and sperm storage. We show that Atta male genitalia have two external rows of spiny teeth, which fit into a specialized pouch organ in the female sexual tract. Reconstruction of the sperm storage process indicated that sperm is transferred to the spermatheca during or immediately after ejaculation and without being mixed with sperm and seminal fluids from other males. A convergent mechanism of direct sperm transfer to the spermatheca of queens is known from two species of dwarf honeybees. Direct sperm transfer may restrict female control over the sperm storage process and the number of males that contribute to the stored sperm.     

Can minor males of Dawson's burrowing bee, Amegilla dawsoni (Hymenoptera: Anthophorini) compensate for reduced access to virgin females through sperm competition?

Dawson's burrowing bees (Amegilla dawsoni) exhibit a conditional mating strategy with two alternative tactics. Large (major)males exclusively patrol emergence sites in search of about-to-emergefemales, whereas small (minor) males usually search the peripheryof emergence sites for females that escape patrollers. About80% of the male population are minors, despite the fact thatpatrolling emergence sites is apparently the more profitablemating tactic. We tested the hypothesis that minor males gainfitness by mating with nonvirgin females and engaging in spermcompetition with rival ejaculates. If the sperm competitionhypothesis applied, it would help explain why nesting femalesproduce so many minor sons. Contrary to this hypothesis, however,we found that minor males do not exhibit traits frequentlyassociated with sperm competition. Minor and major males didnot differ in testis mass after controlling for body size.Neither did they differ significantly in the duration or patternof copulation nor in the volume of ejaculate transferred. Inaddition, and also contrary to the sperm competition hypothesis,females apparently mated only once. Loss of female sexual receptivityoccurred quickly after the onset of copulation, and nestingfemales appeared completely unreceptive. Thus, all aspectsof the bee's mating system strongly indicate that sperm competitiondoes not occur in Dawson's burrowing bee, so that minors cannotcompensate even partially via sperm competition for their mating disadvantage with virgin females.     

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.     

Variation in the number of sperm transferred during mating among males of the Colorado potato beetle (Coleoptera: Chrysomelidae)

We suggest an explanation for the bimodal distribution in the number of sperm transferred into the female during mating by males of the Colorado potato beetle (Leptinotarsa decemlineata). While in most matings females receive 20,000 sperm, in others they receive less than 1000. A variety of potential proximate causes for this bimodal distribution including experimental procedures and several physiological and behavioral causes were examined: male body size, female body size, male mating history, socio-sexual environments, duration and number of mounts, and duration and number of copulations. Surprisingly, none of these explained the observed distribution. However, we did find that the total time spent in copulation was significantly less variable among males that transferred more than 20,000 sperm than among males that passed less than 1000 sperm. In addition, males transferring large amounts of sperm resulted in proportionally more sperm inside the female’s spermatheca within a short period of time than males passing less than 1000 sperm. The lack of pattern in male sperm ejaculate suggests definite differences in sperm delivery tactics and may be related to the female condition rather than the male.     

Male phenotype predicts insemination success in guppies

Theory predicts that mate choice can lead to an increase in female fecundity if the secondary sexual traits used by females to assess male quality covary with the number of sperm transferred during copulation. Where females mate multiply, such a relationship between male attractiveness and ejaculate size may, additionally (or alternatively), serve to augment the effect of indirect selection by biasing paternity in favour of preferred males. In either case, a positive correlation between male attractiveness and the size of ejaculates delivered at copulation is predicted. To date, some of the most convincing (indirect) evidence for this prediction comes from the guppy, a species of fish exhibiting a resource-free mating system in which attractive males tend to have larger sperm reserves. We show that, during solicited copulations, male guppies with preferred phenotypes actually transfer more sperm to females than their less-ornamented counterparts, irrespective of the size of their initial sperm stores. Our results also reveal that, during coercive copulations, the relationship between ejaculate size and the male's phenotype breaks down. This latter result, in conjunction with our finding that mating speed--a factor under the female's control-is a significant predictor of ejaculate size, leads us to speculate that females may exert at least partial control over the number of sperm inseminated during cooperative matings.     

The adaptive significance of mate guarding in the soapberry bug,Jadera Haematoloma (Hemiptera: Rhopalidae)

Male soapberry bugs (Jadera haematoloma)face severe mating competition at the northern edge of their range due to male-biased adult sex ratios. Copulations lasting up to 11 days may serve a mate guarding function (encompassing four or more ovipositions), but copulation duration is highly variable, with some pairings lasting as little as 10 min. Data were gathered to describe factors that influence the reproductive costs and benefits of prolonged copulation. Estimated copulation durations (mean ± SD) were 20 ± 23 h in the lab and 50 ± 8 h in the field and were only weakly affected by sex ratio. Females mated for 5 min produced as many fertile eggs as those mated for 600 min laid; they became depleted of fertile sperm after about 25 days. In twicemated females, the first male's paternity was reduced by about 60%, and all females (N = 13) whose mates were removed experimentally mated again within an average of 6 min. The outcome of sperm competition on a perclutch basis was not highly predictable. The possibility of increased sperm displacement in longer copulations was not tested. Males often guarded females during oviposition and successfully defended them from intruding single males by recopulating. Such intrusions occurred in the majority of oviposition attempts observed in nature. Even though most females mated promiscuously, in a focal aggregation with a mean sex ratio of 2.2 ± 0.4 males/female, the interval between matings by males was commonly several days. Males appeared to respond facultatively to several aspects of the distribution and availability of females. The intensities of mating competition and sperm competition indicate that monogamous mate guarding should be favored over nonguarding in nature. Unpredicted brief. pairings may result from assessment by males of female reproductive value or of their own physical condition, or from female resistance.