Sperm competition
Sperm competition is the competitive process between spermatozoa of two or more different males to fertilize the same egg[1] during sexual reproduction. Competition can occur when females have multiple potential mating partners. Greater choice and variety of mates increases a female's chance to produce more viable offspring.[2] However, multiple mates for a female means each individual male has decreased chances of producing offspring. Sperm competition is an evolutionary pressure on males, and has led to the development of adaptations to increase male's chance of reproductive success.[3] Sperm competition results in a sexual conflict between males and females.[2] Males have evolved several defensive tactics including: mate-guarding, mating plugs, and releasing toxic seminal substances to reduce female re-mating tendencies to cope with sperm competition.[4] Offensive tactics of sperm competition involve direct interference by one male on the reproductive success of another male, for instance by mate guarding or by physically removing another male's sperm prior to mating with a female.[5][6] For an example, see Gryllus bimaculatus.
Sperm competition is often compared to having
Defensive adaptations
Mate-guarding is a defensive behavioral trait that occurs in response to sperm competition; males try to prevent other males from approaching the female (and/or vice versa) thus preventing their mate from engaging in further copulations.[2] Precopulatory and postcopulatory mate-guarding occurs in insects, lizards, birds and primates. Mate-guarding also exists in the fish species Neolamprologus pulcher, as some males try to "sneak" matings with females in the territory of other males. In these instances, the males guard their female by keeping her in close enough proximity so that if an opponent male shows up in his territory he will be able to fight off the rival male which will prevent the female from engaging in extra-pair copulation with the rival male.[9]
Organisms with polygynous mating systems are controlled by one dominant male. In this type of mating system, the male is able to mate with more than one female in a community.[10] The dominant males will reign over the community until another suitor steps up and overthrows him.[10] The current dominant male will defend his title as the dominant male and he will also be defending the females he mates with and the offspring he sires. The elephant seal falls into this category since he can participate in bloody violent matches in order to protect his community and defend his title as the alpha male.[11] If the alpha male is somehow overthrown by the newcomer, his children will most likely be killed and the new alpha male will start over with the females in the group so that his lineage can be passed on.[12]
Strategic mate-guarding occurs when the male only guards the female during her fertile periods. This strategy can be more effective because it may allow the male to engage in both extra-pair paternity and within-pair paternity.[13] This is also because it is energetically efficient for the male to guard his mate at this time. There is a lot of energy that is expended when a male is guarding his mate. For instance, in polygynous mate-guarding systems, the energetic costs of males is defending their title as alpha male of their community.[11] Fighting is very costly in regards to the amount of energy used to guard their mate. These bouts can happen more than once which takes a toll on the physical well-being of the male. Another cost of mate-guarding in this type of mating system is the potential increase of the spread of disease.[14] If one male has an STD, he can pass that on to the females that he's copulating with, potentially resulting in a depletion of the harem. This would be an energetic cost towards both sexes for the reason that instead of using the energy for reproduction, they are redirecting it towards ridding themselves of this illness. Some females also benefit from polygyny because extra pair copulations in females increase the genetic diversity with the community of that species.[15] This occurs because the male is not able to watch over all of the females and some will become promiscuous. Eventually, the male will not have proper nutrition, which makes the male unable to produce sperm.[16] For instance, male amphipods will deplete their reserves of glycogen and triglycerides only to have it replenished after the male is done guarding that mate.[17] Also, if the amount of energy intake does not equal the energy expended, then this could be potentially fatal to the male. Males may even have to travel long distances during the breeding season in order to find a female, which significantly drains their energy supply. Studies were conducted to compare the cost of foraging of fish that migrate and animals that are residential. The studies concluded that fish that were residential had fuller stomachs containing higher quality of prey compared to their migrant counterparts.[18] With all of these energy costs that go along with guarding a mate, timing is crucial so that the male can use the minimal amount of energy. This is why it is more efficient for males to choose a mate during their fertile periods.[13] Also, males will be more likely to guard their mate when there is a high density of males in the proximity.[2] Sometimes, organisms put in all this time and planning into courting a mate in order to copulate and she may not even be interested. There is a risk of cuckoldry of some sort, since a rival male can successfully court the female that the male originally courting her could not do.[19]
However, there are benefits that are associated with mate-guarding. In a mate-guarding system, both parties, male and female, are able to directly and indirectly benefit from this. For instance, females can indirectly benefit from being protected by a mate.[20] The females can appreciate a decrease in predation and harassment from other males while being able to observe her male counterpart.[20] This will allow her to recognize particular traits that she finds ideal so that she'll be able to find another male that emulates those qualities. In polygynous relationships, the dominant male of the community benefits because he has the best fertilization success.[12] Communities can include 30 up to 100 females and, compared to the other males, will greatly increase his chances of mating success.[11]
Males who have successfully courted a potential mate will attempt to keep them out of sight of other males before copulation. One way organisms accomplish this is to move the female to a new location. Certain butterflies, after enticing the female, will pick her up and fly her away from the vicinity of potential males.[21] In other insects, the males will release a pheromone in order to make their mate unattractive to other males, or to mask her scent completely.[21] The male of certain cricket species will court a female loudly, until she accepts his gesture, when he suddenly becomes silent.[22] Some insects, prior to mating, will assume tandem positions to their mate or position themselves in a way to prevent other males from attempting to mate with that female.[21] The male checkerspot butterfly has developed a clever method in order to attract and guard a mate. He will situate himself near an area that possesses valuable resources that the female needs. He will then drive away any males that come near and this will greatly increase his chances of copulation with any female that comes to that area.[23]
In post-copulatory mate-guarding males are trying to prevent other males from mating with the female that they have mated with already. For example, male millipedes in Costa Rica will ride on the back of their mate letting the other males know that she's taken.[24] Japanese beetles will assume a tandem position to the female after copulation.[25] This can last up to several hours allowing him to ward off any rival males giving his sperm a high chance to fertilize that female's egg. These, and other, types of methods have the male playing defense by protecting his mate. Elephant seals are known to engage in bloody battles in order to retain their title as dominant male so that they are able to mate with all the females in their community.[11]
Similarly,
Another strategy, known as sperm partitioning, occurs when males conserve their limited supply of sperm by reducing the quantity of sperm ejected.[2] In Drosophila, ejaculation amount during sequential copulations is reduced; this results in half filled female sperm reserves following a single copulatory event, but allows the male to mate with a larger number of females without exhausting his supply of sperm.[2] To facilitate sperm partitioning, some males have developed complex ways to store and deliver their sperm.[29] In the blue headed wrasse, Thalassoma bifasciatum, the sperm duct is sectioned into several small chambers that are surrounded by a muscle that allows the male to regulate how much sperm is released in one copulatory event.[30]
A strategy common among insects is for males to participate in prolonged copulations. By engaging in prolonged copulations, a male has an increased opportunity to place more sperm within the female's reproductive tract and prevent the female from copulating with other males.[31]
It has been found that some male mollies (Poecilia) have developed deceptive social cues to combat sperm competition. Focal males will direct sexual attention toward typically non-preferred females when an audience of other males is present. This encourages the males that are watching to attempt to mate with the non-preferred female. This is done in an attempt to decrease mating attempts with the female that the focal male prefers, hence decreasing sperm competition.[32]
Offensive adaptations
Offensive adaptation behavior differs from defensive behavior because it involves an attempt to ruin the chances of another male's opportunity in succeeding in copulation by engaging in an act that tries to terminate the fertilization success of the previous male.
Mate choice
The "good sperm hypothesis" is very common in polyandrous mating systems.[37] The "good sperm hypothesis" suggests that a male's genetic makeup will determine the level of his competitiveness in sperm competition.[37] When a male has "good sperm" he is able to father more viable offspring than males that do not have the "good sperm" genes.[37] Females may select males that have these superior "good sperm" genes because it means that their offspring will be more viable and will inherit the "good sperm" genes which will increase their fitness levels when their sperm competes.[38]
Studies show that there is more to determining the competitiveness of the sperm in sperm competition in addition to a male's genetic makeup. A male's dietary intake will also affect sperm competition. An adequate diet consisting of increased amounts of diet and sometimes more specific ratio in certain species will optimize sperm number and fertility. Amounts of protein and carbohydrate intake were tested for its effects on sperm production and quality in adult fruit flies (Diptera: Tephritidae). Studies showed these flies need to constantly ingest carbohydrates and water to survive, but protein is also required to attain sexual maturity.[39] In addition, The Mediterranean fruit fly, male diet has been shown to affect male mating success, copula duration, sperm transfer, and male participation in leks.[40] These all require a good diet with nutrients for proper gamete production as well as energy for activities, which includes participation in leks.
In addition, protein and carbohydrate amounts were shown to have an effect on sperm production and fertility in the speckled cockroach. Holidic diets were used which allowed for specific protein and carbohydrate measurements to be taken, giving it credibility. A direct correlation was seen in sperm number and overall of food intake. More specifically, optimal sperm production was measured at a 1:2 protein to carbohydrate ratio. Sperm fertility was best at a similar protein to carbohydrate ratio of 1:2. This close alignment largely factors in determining male fertility in
Evolutionary consequences
One evolutionary response to sperm competition is the variety in
Evolution to increase ejaculate volume in the presence of sperm competition has a consequence on
In some insects and spiders, for instance Nephila fenestrate, the male copulatory organ breaks off or tears off at the end of copulation and remains within the female to serve as a copulatory plug.[49] This broken genitalia is believed to be an evolutionary response to sperm competition.[49] This damage to the male genitalia means that these males can only mate once.[50]
Female choice for males with competitive sperm
Female factors can influence the result of sperm competition through a process known as "sperm choice".[51] Proteins present in the female reproductive tract or on the surface of the ovum may influence which sperm succeeds in fertilizing the egg.[51] During sperm choice, females are able to discriminate and differentially use the sperm from different males. One instance where this is known to occur is inbreeding; females will preferentially use the sperm from a more distantly related male than a close relative.[51]
Post-copulatory inbreeding avoidance
Inbreeding ordinarily has negative fitness consequences (inbreeding depression), and as a result species have evolved mechanisms to avoid inbreeding. Inbreeding depression is considered to be due largely to the expression of homozygous deleterious recessive mutations.[52] Outcrossing between unrelated individuals ordinarily leads to the masking of deleterious recessive mutations in progeny.[53]
Numerous inbreeding avoidance mechanisms operating prior to mating have been described. However, inbreeding avoidance mechanisms that operate subsequent to copulation are less well known. In guppies, a post-copulatory mechanism of inbreeding avoidance occurs based on competition between sperm of rival males for achieving fertilization.[54] In competitions between sperm from an unrelated male and from a full sibling male, a significant bias in paternity towards the unrelated male was observed.[54]
In vitro fertilization experiments in the mouse, provided evidence of sperm selection at the gametic level.[55] When sperm of sibling and non-sibling males were mixed, a fertilization bias towards the sperm of the non-sibling males was observed. The results were interpreted as egg-driven sperm selection against related sperm.
Female fruit flies (Drosophila melanogaster) were mated with males of four different degrees of genetic relatedness in competition experiments.[56] Sperm competitive ability was negatively correlated with relatedness.
Female crickets (Teleogryllus oceanicus) appear to use post-copulatory mechanisms to avoid producing inbred offspring. When mated to both a sibling and an unrelated male, females bias paternity towards the unrelated male.[57]
Empirical support
It has been found that because of female choice (see
Evidence exists that illustrates the ability of genetically similar spermatozoa to cooperate so as to ensure the survival of their counterparts thereby ensuring the implementation of their genotypes towards fertilization. Cooperation confers a competitive advantage by several means, some of these include incapacitation of other competing sperm and aggregation of genetically similar spermatozoa into structures that promote effective navigation of the female reproductive tract and hence improve fertilization ability. Such characteristics lead to morphological adaptations that suit the purposes of cooperative methods during competition. For example, spermatozoa possessed by the wood mouse (Apodemus sylvaticus) possess an apical hook which is used to attach to other spermatozoa to form mobile trains that enhance motility through the female reproductive tract.[62] Spermatozoa that fail to incorporate themselves into mobile trains are less likely to engage in fertilization. Other evidence suggests no link between sperm competition and sperm hook morphology.[63]
Selection to produce more sperm can also select for the evolution of larger
Regarding sexual dimorphism among primates, humans fall into an intermediate group with moderate sex differences in body size but relatively large testes. This is a typical pattern of primates where several males and females live together in a group and the male faces an intermediate number of challenges from other males compared to exclusive polygyny and monogamy but frequent sperm competition.[65]
Other means of sperm competition could include improving the sperm itself or its packaging materials (spermatophore).[66]
The male black-winged damselfly provides a striking example of an adaptation to sperm competition. Female black-winged damselflies are known to mate with several males over the span of only a few hours and therefore possess a receptacle known as a spermatheca which stores the sperm. During the process of mating the male damselfly will pump his abdomen up and down using his specially adapted penis which acts as a scrub brush to remove the sperm of another male. This method proves quite successful and the male damselfly has been known to remove 90-100 percent of the competing sperm.[67]
A similar strategy has been observed in the dunnock, a small bird. Before mating with the polyandrous female, the male dunnock pecks at the female's cloaca in order to peck out the sperm of the previous male suitor.[68]
In the fly Dryomyza anilis, females mate with multiple males. It benefits the male to attempt to be the last one to mate with a given female.[69] This is because there seems to be a cumulative percentage increase in fertilization for the final male, such that the eggs laid in the last oviposition bout are the most successful.
A notion emerged in 1996 that in some species, including humans, a significant fraction of sperm cannot fertilize the egg; rather these sperm were theorized to stop the sperm from other males from reaching the egg, e.g. by killing them with enzymes or by blocking their access. This type of sperm specialization became known popularly as "kamikaze sperm" or "killer sperm", but most follow-up studies to this popularized notion have failed to confirm the initial papers on the matter.
In the parasitoid wasp Nasonia vitripennis, mated females can choose whether or not to lay a fertilized egg (which develops into a daughter) or an unfertilized egg (which develops into a son), therefore females suffer a cost from mating, as repeated matings constrain their ability to allocate sex in their offspring. The behaviour of these kamikaze-sperm is referred to in academic literature as "sperm-blocking", using basketball as a metaphor.[73]
Sperm competition has led to other adaptations such as larger
See also
- Concealed ovulation
- Strategic pluralism
- Sociobiological theories of rape
- Polygamy in house mouse
- Human sperm competition
- Sperm competition in mammals
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Further reading
- Alcock, John 1998. Animal Behavior. Sixth Edition. 429–519.
- Eberhard, William 1996 Female Control: Sexual Selection by Cryptic Female Choice ISBN 0-691-01084-6
- Freeman, Scott; Herron, Jon C.; (2007). Evolutionary Analysis (4th ed.). Pearson Education, Inc. ISBN 0-13-227584-8.
- Olsson, M.; Madsen, T.; Shine, R. (1997). "Is sperm really so cheap? Costs of reproduction in male adders, Vipera berus". PMC 1688262.
- Ryan, Christopher & Jethá, Calcilda. Sex at Dawn: The prehistoric origins of modern sexuality. New York: Harper, 2010.
- Shackelford, T. K. & Pound, N. 2005. Sperm Competition in Humans : Classic and Contemporary Readings ISBN 0-387-28036-7.
- Shackelford, T. K.; Pound, N.; Goetz, A. T. (2005). "Psychological and physiological adaptations to sperm competition in humans" (PDF). S2CID 37941662.
- Simmons, Leigh W. 2001. Sperm competition and its evolutionary consequences in the insects. Princeton University Press, ISBN 0-691-05987-X
- Singh, S R; Singh, Bashisth N.; Hoenigsberg, Hugo F. (2002). "Female remating, sperm competition and sexual selection in Drosophila" (PDF). Genet. Mol. Res. 1 (3): 178–215. S2CID 36236503. Archived from the original(PDF) on 2018-11-08.
- Snook, Rhonda R. Postcopulatory reproductive strategies. Encyclopedia of Life Sciences http://www.els.net Archived 2011-05-13 at the Wayback Machine