Sperm heteromorphism

Last updated April 24, 2024

Sperm heteromorphism is the simultaneous production of two or more distinguishable types of sperm by a single male. The sperm types might differ in size, shape and/or chromosome complement. Sperm heteromorphism is also called sperm polymorphism or sperm dimorphism (for species with two sperm types). Typically, only one sperm type is capable of fertilizing eggs. Fertile types have been called "eusperm" or "eupyrene sperm" and infertile types "parasperm" or "apyrene sperm".

One interpretation of sperm polymorphism is the "kamikaze sperm" hypothesis (Baker and Bellis, 1988), which has been widely discredited in humans. The kamikaze sperm hypothesis states that the polymorphism of sperm is due to a subdivision of sperm into different functional groups. There are those that defend the egg from fertilization by other male sperm, and those that fertilize the egg. However, there is no evidence that the polymorphism of human sperm is for the purpose of antagonizing rival sperm.^[1]

Distribution

Sperm heteromorphism is known from several different groups of animals.

Insects

Lepidoptera (i.e. butterflies and moths): Almost all known species produce two sperm types. The fertilizing type has a longer tail and contains a nucleus. The other type is shorter and lacks a nucleus, meaning it contains no genetic information at all.
Drosophila (fruit-flies): the D. obscura group of species in the genus Drosophila is sperm heteromorphic. As with the Lepidoptera, there is a long, fertile type and a short, infertile type. However, the infertile type has a nucleus with a normal, haploid chromosome complement. It is not known why the shorter sperm are infertile, though it has been suggested that the slightly wider head of the infertile type might prevent it from entering the micropyle of the egg.
Diopsidae (stalk-eyed flies): several species have a long, fertile type and a shorter infertile type.
Carabidae (ground beetles): some species produce large, infertile sperm that may contain up to 100 sets of chromosomes.

Molluscs

Some prosobranch gastropods (snails) produce two or three sperm types. The infertile types may be large "carrier" types the fertile sperm attach to for transport, or "lancet" types. The lancet sperm sometimes contain many lysosomes.

Fish

Some Sculpin may be sperm heteromorphic. Their ejaculates appear to contain fertile sperm as well as disc-shaped, infertile sperm.

Possible functions of sperm heteromorphism

Non-adaptive

The non-fertilising morph(s) have no function, and are simply developmental errors. This is thought to be unlikely in many sperm heteromorphic species because the production of infertile sperm may be highly regulated, and infertile sperm can make up >90% of the total sperm in some Lepidoptera and Drosophila.

Provisioning

The non-fertilising morph(s) are a means in which males can provide nutrition to the female, her eggs or the fertilising sperm.

Facilitation

The non-fertilising sperm help the fertilising sperm by assisting their sexual transport or capacitation (i.e. the acquisition of fertilisation competence). This has been demonstrated in Bombyx mori.^[2]

In silkworms, there is good evidence that fertile sperm are unable to fertilise if the non-fertile sperm are not present. The researchers artificially inseminated fertile sperm, non-fertile sperm or a mixture of both. Only the last group resulted in offspring production.

Sperm competition

Non-fertile sperm increase the fertilisation success of the male producing them when sperm competition occurs. This might be offensive (e.g. displacing or even killing rival fertilising sperm) or defensive (e.g. by blocking areas of the female tract or creating a hostile pre-fertilisation environment).

"Cheap filler"

Non-fertile sperm delay or prevent the female mating again, thus allowing the male producing the non-fertile sperm a greater share of the paternity of her offspring (because the male avoids Sperm competition). For example, sperm might fill up the sperm storage organs so that female "perceives" that she does not need to re-mate to obtain more sperm. Alternatively, the sperm may transfer chemicals similar to sex peptide, a chemical carried on the sperm of Drosophila melanogaster that makes females less likely to accept mates (i.e. it is an anti-aphrodesiac).^[3]

There is correlational evidence for this theory in a butterfly, Pieris napi. Females that were receptive to a second mating had fewer of the non-fertile sperm type in storage than did non-receptive females. Thus, the infertile sperm may be responsible for delaying female remating.

This theory was also tested in the fruit-fly Drosophila pseudoobscura, but the results suggested that "cheap filler" was not important in that species.^[4]

Related Research Articles

Drosophila is a genus of flies, belonging to the family Drosophilidae, whose members are often called "small fruit flies" or pomace flies, vinegar flies, or wine flies, a reference to the characteristic of many species to linger around overripe or rotting fruit. They should not be confused with the Tephritidae, a related family, which are also called fruit flies ; tephritids feed primarily on unripe or ripe fruit, with many species being regarded as destructive agricultural pests, especially the Mediterranean fruit fly.

<span class="mw-page-title-main">Gametophyte</span> Haploid stage in the life cycle of plants and algae

A gametophyte is one of the two alternating multicellular phases in the life cycles of plants and algae. It is a haploid multicellular organism that develops from a haploid spore that has one set of chromosomes. The gametophyte is the sexual phase in the life cycle of plants and algae. It develops sex organs that produce gametes, haploid sex cells that participate in fertilization to form a diploid zygote which has a double set of chromosomes. Cell division of the zygote results in a new diploid multicellular organism, the second stage in the life cycle known as the sporophyte. The sporophyte can produce haploid spores by meiosis that on germination produce a new generation of gametophytes.

Sex is the trait that determines whether a sexually reproducing organism produces male or female gametes. During sexual reproduction, a male and a female gamete fuse to form a zygote, which develops into an offspring that inherits traits from each parent. By convention, organisms that produce smaller, more mobile gametes are called male, while organisms that produce larger, non-mobile gametes are called female. An organism that produces both types of gamete is hermaphrodite.

<span class="mw-page-title-main">Spermatozoon</span> Motile sperm cell

A spermatozoon is a motile sperm cell, or moving form of the haploid cell that is the male gamete. A spermatozoon joins an ovum to form a zygote.

<span class="mw-page-title-main">Fertilisation</span> Union of gametes of opposite sexes during the process of sexual reproduction to form a zygote

Fertilisation or fertilization, also known as generative fertilisation, syngamy and impregnation, is the fusion of gametes to give rise to a zygote and initiate its development into a new individual organism or offspring. While processes such as insemination or pollination, which happen before the fusion of gametes, are also sometimes informally referred to as fertilisation, these are technically separate processes. The cycle of fertilisation and development of new individuals is called sexual reproduction. During double fertilisation in angiosperms, the haploid male gamete combines with two haploid polar nuclei to form a triploid primary endosperm nucleus by the process of vegetative fertilisation.

<span class="mw-page-title-main">Egg cell</span> Female reproductive cell in most anisogamous organisms

The egg cell or ovum is the female reproductive cell, or gamete, in most anisogamous organisms. The term is used when the female gamete is not capable of movement (non-motile). If the male gamete (sperm) is capable of movement, the type of sexual reproduction is also classified as oogamous. A nonmotile female gamete formed in the oogonium of some algae, fungi, oomycetes, or bryophytes is an oosphere. When fertilized, the oosphere becomes the oospore.

The green-veined white is a butterfly of the family Pieridae.

Sperm competition is the competitive process between spermatozoa of two or more different males to fertilize the same egg 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. 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. Sperm competition results in a sexual conflict between males and females. 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. 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. For an example, see Gryllus bimaculatus.

Insemination is the introduction of sperm into a female's reproductive system for the purpose of impregnating, also called fertilizing, the female for sexual reproduction. The sperm is introduced into the uterus of a mammal or the oviduct of an oviparous (egg-laying) animal. In mammals, insemination normally occurs during sexual intercourse or copulation, but insemination can take place in other ways, such as by artificial insemination.

Sperm is the male reproductive cell, or gamete, in anisogamous forms of sexual reproduction. Animals produce motile sperm with a tail known as a flagellum, which are known as spermatozoa, while some red algae and fungi produce non-motile sperm cells, known as spermatia. Flowering plants contain non-motile sperm inside pollen, while some more basal plants like ferns and some gymnosperms have motile sperm.

The mechanisms of reproductive isolation are a collection of evolutionary mechanisms, behaviors and physiological processes critical for speciation. They prevent members of different species from producing offspring, or ensure that any offspring are sterile. These barriers maintain the integrity of a species by reducing gene flow between related species.

<span class="mw-page-title-main">Sexual conflict</span> Term in evolutionary biology

Sexual conflict or sexual antagonism occurs when the two sexes have conflicting optimal fitness strategies concerning reproduction, particularly over the mode and frequency of mating, potentially leading to an evolutionary arms race between males and females. In one example, males may benefit from multiple matings, while multiple matings may harm or endanger females, due to the anatomical differences of that species. Sexual conflict underlies the evolutionary distinction between male and female.

Drosophila pseudoobscura is a species of fruit fly, used extensively in lab studies of speciation. It is native to western North America.

Sperm Wars is a popular science book by evolutionary biologist Robin Baker about sperm competition. Originally published in English in 1996, it has since appeared in 25 languages and in 2006 a 10th anniversary edition was published in the United States.

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. This process takes place in some species of animals, but not in humans. 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 and bird sperm storage tubules, 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. Female sperm storage is an integral stage in the reproductive process for many animals with internal fertilization. It has several documented biological functions including:

Sexual antagonistic co-evolution is the relationship between males and females where sexual morphology changes over time to counteract the opposite's sex traits to achieve the maximum reproductive success. This has been compared to an arms race between sexes. In many cases, male mating behavior is detrimental to the female's fitness. 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. Females that possess traits to avoid multiple matings will be more likely to survive, resulting in a change in morphology. In males, genitalia is relatively simple and more likely to vary among generations compared to female genitalia. This results in a new trait that females have to avoid in order to survive.

Interlocus sexual conflict is a type of sexual conflict that occurs through the interaction of a set of antagonistic alleles at two or more different loci, or the location of a gene on a chromosome, in males and females, resulting in the deviation of either or both sexes from the fitness optima for the traits. A co-evolutionary arms race is established between the sexes in which either sex evolves a set of antagonistic adaptations that is detrimental to the fitness of the other sex. The potential for reproductive success in one organism is strengthened while the fitness of the opposite sex is weakened. Interlocus sexual conflict can arise due to aspects of male–female interactions such as mating frequency, fertilization, relative parental effort, female remating behavior, and female reproductive rate.

Drosophila subobscura is a species of fruit fly in the family Drosophilidae. Originally found around the Mediterranean, it has spread to most of Europe and the Near East. It has been introduced into the west coasts of Canada, the United States, and Chile. Its closest relative is Drosophila madeirensis, found in the Madeira Islands, followed by D. guanche, found in the Canary Islands. These three species form the D. subobscura species subgroup. When they mate, males and females perform an elaborate courtship dance, in which the female can either turn away to end the mating ritual, or stick out her proboscis in response to the male's, allowing copulation to proceed. D. subobscura has been regarded as a model organism for its use in evolutionary-biological studies.

Non-random segregation of chromosomes is a deviation from the usual distribution of chromosomes during meiosis, that is, during segregation of the genome among gametes. While usually according to the 2nd Mendelian rule homologous chromosomes are randomly distributed among daughter nuclei, there are various modes deviating from this in numerous organisms that are "normal" in the relevant taxa. They may involve single chromosome pairs (bivalents) or single chromosomes without mating partners (univalents), or even whole sets of chromosomes, in that these are separated according to their parental origin and, as a rule, only those of maternal origin are passed on to the offspring. It also happens that non-homologous chromosomes segregate in a coordinated manner. As a result, this is a form of Non-Mendelian inheritance.

Androgenesis occurs when a zygote is produced with only paternal nuclear genes. During standard sexual reproduction, one female and one male parent each produce haploid gametes, which recombine to create offspring with genetic material from both parents. However, in androgenesis, there is no recombination of maternal and paternal chromosomes, and only the paternal chromosomes are passed down to the offspring. The offspring produced in androgenesis will still have maternally inherited mitochondria, as is the case with most sexually reproducing species.

References

↑ Moore, H. D. M., M. Martin and T. R. Birkhead, ‘No evidence for killer sperm or other selective interactions between human spermatozoa in ejaculates of different males in vitro’, Proceedings of the Royal Society of London (1999), B, 266: 2343-2350
↑ Sakai, Hiroki; Oshima, Hiroyuki; Yuri, Kodai; Gotoh, Hiroki; Daimon, Takaaki; Yaginuma, Toshinobu; Sahara, Ken; Niimi, Teruyuki (2019-05-21). "Dimorphic sperm formation by Sex-lethal". Proceedings of the National Academy of Sciences. 116 (21): 10412–10417. doi: 10.1073/pnas.1820101116 . ISSN 0027-8424. PMC 6535010 . PMID 31036645.
↑ Cook, P.A., and Wedell, N. 1999. Non-fertile sperm delay female remating. Nature 397: 486.
↑ Swallow, J.G., and G.S. Wilkinson. 2002. The long and the short of sperm polymorphisms in insects. Biological Reviews 77: 153-182.

Till-Bottraud, I., D. Joly, D. Lachaise and R.R. Snook. 2005. Pollen and sperm heteromorphism: convergence across kingdoms? Journal of Evolutionary Biology 18(1): 1-18.

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[1] Moore, H. D. M., M. Martin and T. R. Birkhead, ‘No evidence for killer sperm or other selective interactions between human spermatozoa in ejaculates of different males in vitro’, Proceedings of the Royal Society of London (1999), B, 266: 2343-2350

[2] Sakai, Hiroki; Oshima, Hiroyuki; Yuri, Kodai; Gotoh, Hiroki; Daimon, Takaaki; Yaginuma, Toshinobu; Sahara, Ken; Niimi, Teruyuki (2019-05-21). "Dimorphic sperm formation by Sex-lethal". Proceedings of the National Academy of Sciences. 116 (21): 10412–10417. doi: 10.1073/pnas.1820101116 . ISSN 0027-8424. PMC 6535010 . PMID 31036645.

[3] Cook, P.A., and Wedell, N. 1999. Non-fertile sperm delay female remating. Nature 397: 486.

[4] Swallow, J.G., and G.S. Wilkinson. 2002. The long and the short of sperm polymorphisms in insects. Biological Reviews 77: 153-182.

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