We investigated the evolutionary relationship between spawning behaviour and sperm motility traits among Tanganyikan mouth-brooding cichlid species that have developed diverse mating behaviours and male sexual traits. Mouth-brooding behaviour is common among these fish, but different species demonstrate a range of spawning behaviours, bower construction, male sexual traits and timing of gamete release. We observed spawning behaviours and compared sperm motility traits of 28 Tanganyikan mouthbrooding cichlids to elucidate the evolutionary correlations between these traits. Sperm longevity was considerably longer in bower-building species that construct crater-shaped spawning sites compared with species that do not build bowers. Male bower builders released sperm in the pit of the bower prior to spawning, and the time from ejaculation to fertilization was longer. Conversely, most mouth-brooding cichlids deposited semen directly into the female buccal cavity, and spawned eggs were immediately picked up to be placed inside the cavity; thus, the time from ejaculation to fertilization was short. These observations suggest that increased sperm longevity is favoured in bower builders. Comparative phylogenetic analyses suggested that bower-building behaviour and greater time from ejaculation to fertilization are associated with the extension of sperm longevity, whereas sperm competition rank does not play a major role. In addition, bower-building behaviour preceded the emergence of increased sperm longevity. These results indicate that the extension of sperm longevity as a result of the emergence of bower builders may have acted as an evolutionary attractor for sperm longevity.
BackgroundSeminal plasma proteins are associated with successful fertilization. However, their evolutionary correlation with fertilization mechanisms remains unclear. Cichlids from Lake Tanganyika show a variety-rich spawning behavior that is associated with the transfer of the sperm to the egg for fertilization. One of these behaviors, called “oral fertilization,” emerged during their speciation. In oral fertilization, females nuzzle the milt from male genitalia and pick up the released eggs in their mouths, which are then fertilized inside the oral cavity. Thus, the success of the fertilization is dependent on the retention of sperm in the oral cavity during spawning. Sperm aggregation and immobilization in viscous seminal plasma may help retain the sperm inside the oral cavity, which ultimately determines the success of the fertilization. Seminal plasma glycoprotein 120 (SPP120) is one of the major seminal plasma proteins present in cichlids. SPP120 has been implicated to immobilize sperm and increase the milt viscosity. However, the functional linkage between oral fertilization and seminal plasma proteins has not been investigated.ResultsDuring trials of simulated oral fertilization, it was observed that milt viscosity contributed to fertilization success by facilitating longer retention of the milt inside the mouth during spawning. Glycosylation of SPP120 was associated with high milt viscosity. Its glycosylation was specifically present in the milt of cichlid species exhibiting oral fertilization. Moreover, recombinant SPP120 from several the oral fertilization species strongly immobilized/aggregated sperm. Therefore, the functions of SPP120 (immobilization/aggregation and its glycosylation) may contribute to success of oral fertilization, and these functions of SPP120 are more prominent in oral fertilization species. In addition, comparative phylogenetic analyses showed a positive evolutionary correlation between SPP120 function and oral fertilization. Hence, these evolutions may have occurred to keep up with the transition in the mode of fertilization. In addition, rapid evolution in the molecular sequence might be associated with functional modifications of SPP120.ConclusionThese results suggest that SPP120 might be associated with oral fertilization. In other words, reproductive traits that define the interaction between sperms and eggs could be the evolutionary selective force that cause the rapid functional modification of the fertilization-related reproductive protein, SPP120.Electronic supplementary materialThe online version of this article (10.1186/s12862-018-1292-0) contains supplementary material, which is available to authorized users.
Multi-specific synchronous spawning risks both sperm limitation, which reduces fertilization success, and hybridization with other species. If available sperm of conspecifics are limited, hybridization with heterospecific sperm could be an alternative. Some species of the reef-building coral Acropora produce hybrid offspring in vitro , and therefore hybridization between such species does sometimes occur in nature. Here, we report that the interbreeding species Acropora florida and A. intermedia preferentially bred with conspecifics at optimal gamete concentrations (10 6 cells ml −1 ), but when sperm concentration was low (10 4 cells ml −1 ), A . florida eggs displayed an increased incidence of fertilization by sperm of A . intermedia . However, A . intermedia eggs never crossed with heterospecific sperm, regardless of gamete concentrations. It appears that A . florida eggs conditionally hybridize with heterospecific sperm; in nature, this would allow A . florida to cross with later-spawning species such as A . intermedia . These results indicate that hybridization between some Acropora species could occur in nature according to the number of available sperm, and the choice of heterospecific sperm for fertilization could be one of the fertilization strategies in the sperm-limited condition.
Larval dispersal and postsettlement survival of corals play significant roles in the maintenance of coral populations. Most corals acquire their symbiotic algae (Symbiodiniaceae) from the environment in each generation (horizontal transmission). For horizontal transmitters, the quick establishment of symbiosis is important for their survival, since the photosynthetic activity of symbiotic algae provides energy.However, recent studies have indicated that oxidative stress resulting from photosynthesis might also harm coral larvae. Therefore, it remains unclear whether symbionts contribute energy sources along with intrinsic lipids from eggs and assist in settlement/metamorphosis in early life stages. In the present study, we show that symbiotic algae contribute supplemental energy and are also associated with settlement. Furthermore, although juveniles acquired symbiotic algae after settlement, the acquisition of symbiotic algae in the larval stages caused higher growth (number of polyps and size) and low mortality in the juvenile stage. Our data suggest that symbiotic larvae potentially have longer dispersal periods due to their lower lipid consumption rates, which make them better able to retain buoyancy and motility, increasing the ability of symbiotic larvae to settle in favored locations compared with aposymbiotic larvae. Moreover, postsettlement juveniles may continue to benefit from symbiotic relationships formed during the larval stage. Overall, these findings reveal that the effects of symbiotic algae on Acropora tenuis coral larvae are beneficial, particularly under normal seawater temperature conditions.
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