Female sperm storage

From Infogalactic: the planetary knowledge core
Jump to: navigation, search
File:D.melanogaster Female Sperm Storage.jpg
Sperm storage organs in the fruit fly Drosophila melanogaster. Female was first mated with GFP-male and then re-mated with RFP-male.

Female sperm storage is a biological process and often a type of sexual selection in which sperm cells transferred to a female during mating are temporarily retained within a specific part of the reproductive tract before the oocyte, or egg, is fertilized. The site of storage is variable among different animal taxa and ranges from structures that appear to function solely for sperm retention, such as insect spermatheca[1] and bird sperm storage tubules (bird anatomy),[2][3] to more general regions of the reproductive tract enriched with receptors to which sperm associate before fertilization, such as the caudal portion of the cow oviduct containing sperm-associating annexins.[4] Female sperm storage is an integral stage in the reproductive process for many animals with internal fertilization. It has several documented biological functions including:

  • Supporting the sperm by: a.) enabling sperm to undergo biochemical transitions, called capacitation and motility hyperactivation, in which they become physiologically capable of fertilizing an oocyte (e.g. mammals)[5][6] and b.) maintaining sperm viability until an oocyte is ovulated (e.g. insects and mammals).[5][7]
  • Decreasing the incidence of polyspermy (e.g. some mammals such as pigs).[5][8]
  • Enabling mating, ovulation and/or fertilization to occur at different times or in different environments (e.g. many insects and some amphibians, reptiles, birds and mammals).[9][10][11]
  • Supporting prolonged and sustained female fertility (e.g. some insects).[12][13]
  • Having a role influencing offspring sex ratios among some insects possessing a haplodiploid sex-determination system (e.g. ants, bees, wasps and thrips as well as some true bugs and some beetles).[14][15][16]
  • Serving as an arena in which sperm from different mating males compete for access to oocytes, a process called sperm competition, and in which females may preferentially utilize sperm from some males over those of others, called female sperm preference or cryptic female choice (e.g. many invertebrate animals, birds and reptiles).[17][18][19]

Increased diversity of offspring

One important advantage female insects that store sperm gain is increased genetic diversity in their offspring. There are many ways that females can alter offspring genetics to increase their success and diversity. An example of how this can be accomplished is in female Scathophaga that preferentially fertilize eggs to survive in different environments. Since many environments require different traits for success, females are somehow able to match sperm (acquired from multiple mates) that have the best genes for whichever environment in which they will develop.[20] Many of the different properties of the environment, including temperature and thermal properties affect the female's sperm choice.[21] Studies have also shown that ovipositing is nonrandom and females lay eggs with varying PGM(phosphoglucomutase) genotypes in different environments in order to optimize offspring success. Females are acutely aware to their environment and manipulate the genetic diversity of their offspring in appropriate ways to ensure their success.

Another way sperm-storing females can alter the diversity of their offspring is controlling the relatedness to the males that provide them with sperm. Inbreeding depression can have a deleterious impact on populations of organisms and is due to mating of closely related individuals. To combat this effect, female insects appear to be able to sort out the sperm of relatives from the sperm of non-relatives to choose the best option to fertilize their eggs. Female crickets are able to preferentially store sperm of multiple unrelated males to that of their siblings; this results in more of the offspring having unrelated parentage. Being able to choose between sperm after coupling might be advantageous to females because choosing between mates precopulation may be more costly, or it may just be too difficult to tell males apart before mating.[22] Females possess remarkable abilities to select sperm to store and to fertilize their eggs that will make their offspring diverse. Though it has been shown that a majority of female insect species can store sperm, specific examples that have been studied could include field crickets,[22] dung flies [21] and Mediterranean fruit flies.[23] Females largely benefit from this mechanism, but males often can experience low fitness because their paternity is not secure.

Sperm stored often determines which male ends up fertilizing the most eggs. An example of this is seen in Red Flour Beetles, where most of the sperm is stored in the first mating. Another male can remove previously stored sperm to better chances of successful mating.

Antagonistic coevolution

Spiny genitalia, such as of this bean weevil, may help to remove sperm from the sperm storage structures

Antagonistic co-evolution is the relationship between males and females where sexual morphology changes over time to counteract the opposite's sex traits in order to achieve the maximum reproductive success.[24] This has been compared to an arms race between sexes. In many cases, male mating behavior is detrimental to the female's fitness.[25] For example, when insects reproduce by means of traumatic insemination, it is very disadvantageous to the female's health. During mating, males will try to inseminate as many females as possible. However, the more times a female's abdomen is punctured, the less likely she is to survive.[26] Females that possess traits to avoid multiple matings will be more likely to survive, resulting in those morphologies being retained in future generations. In males, genitalia are relatively simple and more likely to vary among generations than female genitalia. This results in a new trait that females have to counter in order to survive.

Females who possess traits where they can lessen the impacts of male behavior will be more likely to survive and reproduce. There are many methods that females have evolved over time to "defend" themselves against the onslaught of potential mates. One such development is alternative sperm storage sites, such as seminal receptacles, spermathecae, and pseudospermathecae, that are complex and extremely variable to allow for more choice in sperm selection.[27] In some cases, sperm storage sites can produce proteases that break down various proteins in male seminal fluid resulting in female selection in sperm.[28]

Like females, males have developed responses to counter evolutionary adaptations of the opposite sex. Responses in insects can vary in both genitalia and sperm structures, along with variations in behavior. Spiny male genitalia help to anchor the male to the female during copulation and remove sperm of previous males from female storage structures.[29] Males have also developed alternative ways to copulate. In the case of the bed bug, males traumatically inseminate females, which allows faster passage of sperm to female sperm storage sites.[26] In addition, shorter male developmental times allow them to emerge before females, eliminating females' mating choice.[30] At the microscopic level, Drosophila males have differing sperm tail lengths that correspond to various sizes of female seminal receptacles.[31] Longer male sperm tail length has shown a greater reproductive success with a larger female seminal receptacle while sperm with short tail lengths have been found to be more successful in smaller seminal receptacles.

Cryptic female choice

The ability to store and separate sperm from multiple males enables females to manipulate paternity by choosing which sperm fertilize their eggs, a process known as cryptic female choice. Evidence for this ability exists in many different taxa, including birds, reptiles, gastropods, arachnids, and perhaps most-notably, insects.[32][33][34][35][36] In combining long-term sperm storage with polyandrous behavior, female members of the tortoise family Testudinidae have access to sperm from a range of genetically different males and can potentially influence a clutch’s paternity during each fertilization event, not just through her mating choices alone. As a result of clutches with greater variation in paternal genes and increased sperm competition, females can maximize both the genetic quality and number of offspring.[37]

Cryptic choice allows females to preferentially choose sperm. Females are thus able to mate multiple times and allocate sperm to their eggs according to paternal phenotype, or according to other characteristics. In some cases, such as in the yellow dung fly, certain male traits will affect the fitness of eggs laid in particular environmental conditions. Females can choose sperm based on male quality as a function of its interaction with the environment.[38] In other species, such as the fly Dryomyza anilis, females preferentially choose sperm from one storage location over another. Males of this species have developed behaviors, such as abdominal tapping, to increase their number of sperm stored in the favored storage site.[39] Evidence for this pattern of storage, cryptic choice, and male behavior also exists in the flour beetle Tribolium castaneum.[40]

Mechanisms

Female muscular contractions

Muscle contraction as a means of moving spermatozoa through the reproductive system into and out of the storage structures has been examined in Diptera, Orthoptera, and Lepidoptera as well as in the species Rhodnius prolixus and the boll weevil. In R. prolixus, rhythmic peristaltic contractions of the oviduct cause contractions of the bursa copulatrix and spermatheca movement. This movement of the spermatheca results in spermatozoa migration into the spermathecal duct and into the spermatheca reservoir.[41][42][43] In the boll weevil, contractions are also used to move sperm from the spermathecae so they can fertilize the egg.[44] It has been observed in locusts, that the nervous system initiates female reproductive muscular contractions.[45] In some species, such as R. prolixus, the contractions that move spermatozoa into sperm storage are initiated by a male secretion in the ejaculate.[41] Male secretions, such as the glycoprotein ACP36D in Drosophila, can also play a role in preparing the female reproductive system for sperm storage. It causes changes in uterine shape allowing spermatozoa access to the sperm storage organs.[46]

Female insect nervous system

The female insect nervous system affects many of the processes involved in sperm storage. The nervous system may signal for muscular contractions, fluid absorption, and hormone release, all of which aid in moving the sperm into the storage organs.[47] When the nervous system of female fruit flies (Drosophila melanogaster) was replaced with a masculinized nervous system through genetic manipulation, sperm storage was affected suggesting that the female nervous system is unique and required to store sperm properly.[48]

The nervous system is responsible for several fertilization methods. In the migratory locust (Locusta migratoria), the presence of an egg in the genital chamber results in an increase of spermathecal contractions. As a result, sperm is released to fertilize the egg. A neural loop (from the VIIIth ganglion through the N2B nerve to N2B2, N2B3, N2B4, and N2B6b nerves) is then activated to direct the sperm to fertilize the egg via muscular contractions.[47] In the Caribbean fruit fly (Anastrepha suspensa), both the spermathecae and their ducts are innervated by an abdominal ganglion located under the first abdominal sternite.[49] This location suggests that the sperm receptacle can compress and influence the amount of sperm taken in or released by the female fly.[49]

References

  1. Klowden MJ. 2003. Spermatheca. In Resh VH and Cardé RT (eds.): Encyclopedia of Insects. San Diego, CA: Academic Press. 1266.
  2. Liem KL, Bemis WE, Walker WF & Grande L. 2001. Functional Anatomy of the Vertebrates, an Evolutionary Perspective 3rd ed. Belmont, CA: Brooks/Cole – Thomson Learning. Pp703.
  3. Birkhead TR. 1998. Sperm Competition in Birds: mechanisms and function. In Birkhead TR & Møller AP (eds.) 1998. Sperm Competition and Sexual Selection. San Diego, CA: Academic Press. Pp. 826.
  4. Ignotz GG, Cho MY & Suarez SS. 2007. Annexins are candidate oviductal receptors for bovine sperm surface proteins and thus may serve to hold bovine sperm in the oviductal reservoir. Biology of Reproduction 77:906–913.
  5. 5.0 5.1 5.2 Suarez SS. 2002. Formation of a reservoir of sperm in the oviduct. Reproduction in Domestic Animals 37:140–143.
  6. Suarez SS. 2008. Control of hyperactivation in sperm. Human Reproduction Update 14(6):647–657.
  7. Allen AK & Spradling AC. 2008. The Sf1-related nuclear hormone receptor Hr39 regulates Drosophila female reproductive tract development and function. Development. 135(2): 311–321.
  8. Hunter RHF & Léglise PC. 1971. Polyspermic fertilization following tubal surgery in pigs, with particular reference to the role of the isthmus. Journal of Reproduction and Fertility. 24:233–246.
  9. Kardong KV. 2009. Vertebrates: Comparative Anatomy, Function, Evolution. 5th ed. Boston, MA: McGraw Hill. Pp 779.
  10. Birkhead TR & Møller AP. 1993. Sexual selection and the temporal separation of reproductive events: sperm storage data from reptiles, birds and mammals. Biological Journal of the Linnean Society. 50:295–311.
  11. Holt W. 2011. Mechanisms of sperm storage in the female reproductive tract: an interspecies comparison. Reproduction in Domestic Animals 46:68-74.
  12. Ridley M. 1988. Mating frequency and fecundity in insects. Biological Reviews. 63:509–549.
  13. Den Boer SPA, Baer B, Dreier S, Aron S, Nash DR, Boomsma JJ. 2009. Prudent sperm use by leaf-cutter ant queens. Proceedings of the Royal Society B. 276: 3945–3953.
  14. Antolin MF & Henk AD. 2003. Sex Determination. In Resh VH and Cardé RT (eds.): Encyclopedia of Insects. San Diego, CA: Academic Press. 1266.
  15. Werren JH. 1980. Sex ratio adaptations to local mate competition in a parasitic wasp. Science 208:1157–1159.
  16. King PE. 1961. A possible method of sex ratio determination in the parasitic hymenopteran Nasonia vitripennis. Nature 189:330–331.
  17. Birkhead TR & Møller AP (eds.) 1998. Sperm Competition and Sexual Selection. San Diego, CA: Academic Press. Pp. 826.
  18. Eberhard WG. 1996. Female Control: Sexual Selection and Cryptic Female Choice. Princeton, NJ: Princeton University Press. Pp 501.
  19. Leonard J. & Cordoba-Aguilar A. 2010. The Evolution of Primary Sexual Characters in Animals (pp. 1–52). Oxford: Oxford University Press.
  20. Ward,P. 2000. Cryptic Female Choice in the Yellow Dung Fly Scathophaga stercoraria (L.) Evolution. 54(5):1680–1686
  21. 21.0 21.1 Ward P, VonWil J, Scholte E, Knop E. 2002. Field experiments on the distributions of eggs of different phosphoglucomutase(PGM) genotypes in the yellow dung fly Scathophaga stercoraria (L.). Molecular Ecology. 11:1781–1785
  22. 22.0 22.1 Bretman A, Newcombe D, Tregenza T. 2009. Promiscuous females avoid inbreeding by controlling sperm storage. Molecular Ecology. 18:3340–3345
  23. Taylor PW, Yuval B. 1999. Postcopulatory sexual selection in Mediterranean fruit flies: advantages for large and protein-fed males. Animal Behaviour. 58:247–254.
  24. Rowe, L. & Arnqvist, G. (2002) Sexually antagonistic coevolution in a mating system: combining experimental and comparative approaches to address evolutionary processes. Evolution 56(4): 754–767.
  25. Eberhard, W. (2005) Sexually antagonistic coevolution in insects is associated with only limited morphological diversity. Journal of Evolutionary Biology: 1–25
  26. 26.0 26.1 Siva-Jothy, M.T., and Stutt, A.D (February 2003). “A matter of taste: direct detection of female mating status in the bedbug.” Proc. R. Soc. Lond. B 270: 649–652.
  27. Marchini D., Del Bene G., and R. Dallai. 2010. Functional morphology of the female reproductive apparatus of Stephanitis pyrioides (Heteroptera, Tingidae): a novel role for the pseudospermathecae. Journal of Morphology 271:473–482
  28. Prokupek, A. et al. (November 2008). "An evolutionary expressed sequence tag analysis of Drosophila spermatheca genes." Evolution 62(11): 2936–2947.
  29. Rönn, J., Katvala, M., and Arnqvist, G (June 2007). “Coevolution between harmful male genitalia and female resistance in seed beetles.” PNAS 104(26) 10921–10925.
  30. Arnqvist, G., and Tuda, M (December 2009). “Sexual conflict and the gender load: correlated evolution between population fitness and sexual dimorphism in seed beetles.” Proc. R. Soc. B 277: 1345–1352.
  31. Miller, G.T., and Pitnick, S (November 2002). “Sperm-female coeveolution in Drosophila.” Science 298: 1230–1233.
  32. Wagner RH, Helfenstein F & Danchin E. 2004. Female choice of young sperm in a genetically monogamous bird. Proceedings of the Royal Society of London 271:134–137.
  33. Moore JA, Daugherty CH, Godfrey SS & Nelson NJ. 2009. Seasonal monogamy and multiple paternity in a wild population of a territorial reptile (tuatara). Biological Journal of the Linnean Society 98:161–170.
  34. Beese K, Armbruster GFJ, Beier K & Baur B. 2009. Evolution of female sperm-storage organs in the Carrefour of stylommatophoran gastropods. Journal of Zoological Systematics and Evolutionary Research 47:49–60.
  35. Welke K & Schneider JM. 2009. Inbreeding avoidance through cryptic female choice in the cannibalistic orb-web spider Argiope lobata. Behavioral Ecology 20:1056–1062.
  36. Ward PI. 2000. Cryptic female choice in the yellow dung fly Scathophaga sterocoraria. Evolution 54: 1680–1686.
  37. Holt W, & Lloyd R. 2010. Sperm storage in the vertebrate female reproductive tract: How does it work so well? Theriogenology 73:713-722.
  38. Ward PI, Vonwil J, Scholte EJ & Knop E. 2002. Field experiments on the distributions of eggs of different phosphoglucomutase (PGM) genotypes in the yellow dung fly Scathophaga stercorariea(L.). Molecular Ecology 11:1781–1785.
  39. Bussiere LF, Demont M, Pemberton AJ, Hall MD & Ward PI. 2010. The assessment of insemination success in yellow dung flies using competitive PCR. Molecular Ecology Resources 10:292–303.
  40. Bloch Qazi MC. 2003. A potential mechanism for cryptic female choice in a flour beetle. Journal of Evolutionary Biology 16:170–176.
  41. 41.0 41.1 Davey KG. The migration of spermatozoa in the female of Rhodnius prolixus stal. 1958: 694–701.
  42. Nonidez JF. The internal phenomena of reproduction in Drosophila. Biological Bulletin. 1920; 39(4):207–230.
  43. Omura S. Structure and function of the female genital system of Bombyx mori with special reference to the mechanism of fertilization. 1935:111–131.
  44. Villavaso EJ. Functions of the spermathecal muscle of the boll weevil, Anthonomus grandis. J. Insect Physiol. 1975;21:1275–1278.
  45. Clark J, Langea AB. Evidence of a neural loop involved in controlling spermathecal contractions in Locusta migratoria. J Insect Physiol. 2001;47(6):607–616.
  46. Avila FW, Wolfner MF. Acp36DE is required for uterine conformational changes in matted Drosophila females. PNAS. 2009;106(37):15796–15800.
  47. 47.0 47.1 Lua error in package.lua at line 80: module 'strict' not found.
  48. Lua error in package.lua at line 80: module 'strict' not found.
  49. 49.0 49.1 Lua error in package.lua at line 80: module 'strict' not found.