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Parthenogenesis

January 20, 2023

Not to be confused with Pathogenesis.

Parthenogenesis (/ˌpɑːrθɪnˈɛnɪsɪs, -θɪnə-/;[1][2] from the Greek παρθένος, parthénos, 'virgin' + γένεσις, génesis, 'creation'[3]) is a natural form of asexual reproduction in which growth and development of embryos occur in a gamete (egg or sperm) without combining with another gamete (e.g., egg and sperm fusing).[4] In animals, parthenogenesis means development of an embryo from an unfertilized egg cell. In plants, parthenogenesis is a component process of apomixis. In algae, parthenogenesis can mean the development of an embryo from either an individual sperm or an individual egg.[4]

The asexual, all-female whiptail species Aspidoscelis neomexicanus (center), which reproduces via parthenogenesis, is shown flanked by two sexual species having males, A. inornatus (left) and A. tigris (right), which hybridized naturally to form A. neomexicanus.

Parthenogenesis occurs naturally in some plants, algae, invertebrate animal species (including nematodes, some tardigrades, water fleas, some scorpions, aphids, some mites, some bees, some Phasmatodea and parasitic wasps) and a few vertebrates (such as some fish,[5] amphibians, reptiles[6][7][8] and birds[9][10][11]). This type of reproduction has been induced artificially in a few species including fish, amphibians, and mice.[12][13]

Normal egg cells form in the process of meiosis and are haploid, with half as many chromosomes as their mother's body cells. Haploid individuals, however, are usually non-viable, and parthenogenetic offspring usually have the diploid chromosome number. Depending on the mechanism involved in restoring the diploid number of chromosomes, parthenogenetic offspring may have anywhere between all and half of the mother's alleles. In some types of parthenogenesis the offspring having all of the mother's genetic material are called full clones and those having only half are called half clones. Full clones are usually formed without meiosis. If meiosis occurs, the offspring will get only a fraction of the mother's alleles since crossing over of DNA takes place during meiosis, creating variation.

Parthenogenetic offspring in species that use either the XY or the X0 sex-determination system have two X chromosomes and are female. In species that use the ZW sex-determination system, they have either two Z chromosomes (male) or two W chromosomes (mostly non-viable but rarely a female), or they could have one Z and one W chromosome (female).

Parthenogenesis does not apply to isogamous species.[14]

Life history types

Further information: Origin and function of meiosis
 
A baby Komodo dragon, Varanus komodoensis, produced through parthenogenesis. Komodo dragons are an example of a species which can produce offspring both through sexual reproduction and parthenogenesis.

Some species reproduce exclusively by parthenogenesis (such as the bdelloid rotifers), while others can switch between sexual reproduction and parthenogenesis. This is called facultative parthenogenesis (other terms are cyclical parthenogenesis, heterogamy[15][16] or heterogony[17][18]). The switch between sexuality and parthenogenesis in such species may be triggered by the season (aphid, some gall wasps), or by a lack of males or by conditions that favour rapid population growth (rotifers and cladocerans like Daphnia). In these species asexual reproduction occurs either in summer (aphids) or as long as conditions are favourable. This is because in asexual reproduction a successful genotype can spread quickly without being modified by sex or wasting resources on male offspring who won't give birth. Some species can produce both sexually and through parthenogenesis, and offspring in the same clutch of a species of tropical lizard can be a mix sexually produced offspring and parthenogenically produced offspring.[19] In California Condors facultative parthenogenesis can occur even when a male is present and available for a female to breed with.[20] In times of stress, offspring produced by sexual reproduction may be fitter as they have new, possibly beneficial gene combinations. In addition, sexual reproduction provides the benefit of meiotic recombination between non-sister chromosomes, a process associated with repair of DNA double-strand breaks and other DNA damages that may be induced by stressful conditions.[21]

Many taxa with heterogony have within them species that have lost the sexual phase and are now completely asexual. Many other cases of obligate parthenogenesis (or gynogenesis) are found among polyploids and hybrids where the chromosomes cannot pair for meiosis.

The production of female offspring by parthenogenesis is referred to as thelytoky (e.g., aphids) while the production of males by parthenogenesis is referred to as arrhenotoky (e.g., bees). When unfertilized eggs develop into both males and females, the phenomenon is called deuterotoky.[22]

Types and mechanisms

Parthenogenesis can occur without meiosis through mitotic oogenesis. This is called apomictic parthenogenesis. Mature egg cells are produced by mitotic divisions, and these cells directly develop into embryos. In flowering plants, cells of the gametophyte can undergo this process. The offspring produced by apomictic parthenogenesis are full clones of their mother. Examples include aphids.

Parthenogenesis involving meiosis is more complicated. In some cases, the offspring are haploid (e.g., male ants). In other cases, collectively called automictic parthenogenesis, the ploidy is restored to diploidy by various means. This is because haploid individuals are not viable in most species. In automictic parthenogenesis, the offspring differ from one another and from their mother. They are called half clones of their mother.

Automictic

 
The effects of central fusion and terminal fusion on heterozygosity

Automixis[23] is a term that covers several reproductive mechanisms, some of which are parthenogenetic.[24]

Diploidy might be restored by the doubling of the chromosomes without cell division before meiosis begins or after meiosis is completed. This is referred to as an endomitotic cycle. This may also happen by the fusion of the first two blastomeres. Other species restore their ploidy by the fusion of the meiotic products. The chromosomes may not separate at one of the two anaphases (called restitutional meiosis) or the nuclei produced may fuse or one of the polar bodies may fuse with the egg cell at some stage during its maturation.

Some authors consider all forms of automixis sexual as they involve recombination. Many others classify the endomitotic variants as asexual and consider the resulting embryos parthenogenetic. Among these authors, the threshold for classifying automixis as a sexual process depends on when the products of anaphase I or of anaphase II are joined. The criterion for "sexuality" varies from all cases of restitutional meiosis,[25] to those where the nuclei fuse or to only those where gametes are mature at the time of fusion.[24] Those cases of automixis that are classified as sexual reproduction are compared to self-fertilization in their mechanism and consequences.

The genetic composition of the offspring depends on what type of automixis takes place. When endomitosis occurs before meiosis[26][27] or when central fusion occurs (restitutional meiosis of anaphase I or the fusion of its products), the offspring get all[26][28] to more than half of the mother's genetic material and heterozygosity is mostly preserved[29] (if the mother has two alleles for a locus, it is likely that the offspring will get both). This is because in anaphase I the homologous chromosomes are separated. Heterozygosity is not completely preserved when crossing over occurs in central fusion.[30] In the case of pre-meiotic doubling, recombination, if it happens, occurs between identical sister chromatids.[26]

If terminal fusion (restitutional meiosis of anaphase II or the fusion of its products) occurs, a little over half the mother's genetic material is present in the offspring and the offspring are mostly homozygous.[31] This is because at anaphase II the sister chromatids are separated and whatever heterozygosity is present is due to crossing over. In the case of endomitosis after meiosis, the offspring is completely homozygous and has only half the mother's genetic material.

This can result in parthenogenetic offspring being unique from each other and from their mother.

Sex of the offspring

In apomictic parthenogenesis, the offspring are clones of the mother and hence (except for aphids) are usually female. In the case of aphids, parthenogenetically produced males and females are clones of their mother except that the males lack one of the X chromosomes (XO).[32]

When meiosis is involved, the sex of the offspring will depend on the type of sex determination system and the type of apomixis. In species that use the XY sex-determination system, parthenogenetic offspring will have two X chromosomes and are female. In species that use the ZW sex-determination system the offspring genotype may be one of ZW (female),[28][29] ZZ (male), or WW (non-viable in most species[31] but a fertile,[dubious discuss] viable female in a few (e.g., boas)).[31] ZW offspring are produced by endoreplication before meiosis or by central fusion.[28][29] ZZ and WW offspring occur either by terminal fusion[31] or by endomitosis in the egg cell.

In polyploid obligate parthenogens like the whiptail lizard, all the offspring are female.[27]

In many hymenopteran insects such as honeybees, female eggs are produced sexually, using sperm from a drone father, while the production of further drones (males) depends on the queen (and occasionally workers) producing unfertilized eggs. This means that females (workers and queens) are always diploid, while males (drones) are always haploid, and produced parthenogenetically.

Facultative

Facultative parthenogenesis is the term for when a female can produce offspring either sexually or via asexual reproduction.[33] Facultative parthenogenesis is extremely rare in nature, with only a few examples of animal taxa capable of facultative parthenogenesis.[33] One of the best-known examples of taxa exhibiting facultative parthenogenesis are mayflies; presumably, this is the default reproductive mode of all species in this insect order.[34] Facultative parthenogenesis has generally been believed to be a response to a lack of a viable male. A female may undergo facultative parthenogenesis if a male is absent from the habitat or if it is unable to produce viable offspring. However, California condors and the tropical lizard Lepidophyma smithii both can produce parthenogenic offspring in the presence of males, indicating that facultative parthenogenesis may be more common than previously thought and is not simply a response to a lack of males.[19][35]

In aphids, a generation sexually conceived by a male and a female produces only females. The reason for this is the non-random segregation of the sex chromosomess X and O during spermatogenesis.[36]

Facultative parthenogenesis is often used to describe cases of spontaneous parthenogenesis in normally sexual animals.[37] For example, many cases of spontaneous parthenogenesis in sharks, some snakes, Komodo dragons and a variety of domesticated birds were widely attributed to facultative parthenogenesis.[38] These cases are examples of spontaneous parthenogenesis.[33][37] The occurrence of such asexually produced eggs in sexual animals can be explained by a meiotic error, leading to eggs produced via automixis.[37][39]

Obligate

Obligate parthenogenesis is the process in which organisms exclusively reproduce through asexual means.[40] Many species have been shown to transition to obligate parthenogenesis over evolutionary time. Well documented transitions to obligate parthenogenesis have been found in numerous metazoan taxa, albeit through highly diverse mechanisms. These transitions often occur as a result of inbreeding or mutation within large populations.[41] There are a number of documented species, specifically salamanders and geckos, that rely on obligate parthenogenesis as their major method of reproduction. As such, there are over 80 species of unisex reptiles (mostly lizards but including a single snake species), amphibians and fishes in nature for which males are no longer a part of the reproductive process.[42] A female will produce an ovum with a full set (two sets of genes) provided solely by the mother. Thus, a male is not needed to provide sperm to fertilize the egg. This form of asexual reproduction is thought in some cases to be a serious threat to biodiversity for the subsequent lack of gene variation and potentially decreased fitness of the offspring.[40]

Some invertebrate species that feature (partial) sexual reproduction in their native range are found to reproduce solely by parthenogenesis in areas to which they have been introduced.[43][44] Relying solely on parthenogenetic reproduction has several advantages for an invasive species: it obviates the need for individuals in a very sparse initial population to search for mates; and an exclusively female sex distribution allows a population to multiply and invade more rapidly (potentially twice as fast). Examples include several aphid species[43] and the willow sawfly, Nematus oligospilus, which is sexual in its native Holarctic habitat but parthenogenetic where it has been introduced into the Southern Hemisphere.[44]

Natural occurrence

Parthenogenesis is seen to occur naturally in aphids, Daphnia, rotifers, nematodes and some other invertebrates, as well as in many plants. Among vertebrates, strict parthenogenesis is only known to occur in lizards, snakes,[45] birds[46] and sharks,[47] with fish, amphibians and reptiles exhibiting various forms of gynogenesis and hybridogenesis (an incomplete form of parthenogenesis).[48] The first all-female (unisexual) reproduction in vertebrates was described in the fish Poecilia formosa in 1932.[49] Since then at least 50 species of unisexual vertebrate have been described, including at least 20 fish, 25 lizards, a single snake species, frogs, and salamanders.[48] Other usually sexual species may occasionally reproduce parthenogenetically; the Komodo dragon and hammerhead and blacktip sharks are recent additions to the known list of spontaneous parthenogenetic vertebrates. As with all types of asexual reproduction, there are both costs (low genetic diversity and therefore susceptibility to adverse mutations that might occur) and benefits (reproduction without the need for a male) associated with parthenogenesis.

Parthenogenesis is distinct from artificial animal cloning, a process where the new organism is necessarily genetically identical to the cell donor. In cloning, the nucleus of a diploid cell from a donor organism is inserted into an enucleated egg cell and the cell is then stimulated to undergo continued mitosis, resulting in an organism that is genetically identical to the donor. Parthenogenesis is different, in that it originates from the genetic material contained within an egg cell and the new organism is not necessarily genetically identical to the parent.

Parthenogenesis may be achieved through an artificial process as described below under the discussion of mammals.

Oomycetes

Apomixis can apparently occur in Phytophthora,[50] an oomycete. Oospores from an experimental cross were germinated, and some of the progeny were genetically identical to one or other parent, implying that meiosis did not occur and the oospores developed by parthenogenesis.

Velvet worms

No males of Epiperipatus imthurni have been found, and specimens from Trinidad were shown to reproduce parthenogenetically. This species is the only known velvet worm to reproduce via parthenogenesis.[51]

Rotifers

In bdelloid rotifers, females reproduce exclusively by parthenogenesis (obligate parthenogenesis),[52] while in monogonont rotifers, females can alternate between sexual and asexual reproduction (cyclical parthenogenesis). At least in one normally cyclical parthenogenetic species obligate parthenogenesis can be inherited: a recessive allele leads to loss of sexual reproduction in homozygous offspring.[53]

Flatworms

At least two species in the genus Dugesia, flatworms in the Turbellaria sub-division of the phylum Platyhelminthes, include polyploid individuals that reproduce by parthenogenesis.[54] This type of parthenogenesis requires mating, but the sperm does not contribute to the genetics of the offspring (the parthenogenesis is pseudogamous, alternatively referred to as gynogenetic). A complex cycle of matings between diploid sexual and polyploid parthenogenetic individuals produces new parthenogenetic lines.

Snails

Several species of parthenogenetic gastropods have been studied, especially with respect to their status as invasive species. Such species include the New Zealand mud snail (Potamopyrgus antipodarum),[55] the red-rimmed melania (Melanoides tuberculata),[56] and the Quilted melania (Tarebia granifera).[57]

Insects

Parthenogenesis in insects can cover a wide range of mechanisms.[58] The offspring produced by parthenogenesis may be of both sexes, only female (thelytoky, e.g. aphids and some hymenopterans[59]) or only male (arrhenotoky, e.g. most hymenopterans). Both true parthenogenesis and pseudogamy (gynogenesis or sperm-dependent parthenogenesis) are known to occur.[33] The egg cells, depending on the species may be produced without meiosis (apomictically) or by one of the several automictic mechanisms.

A related phenomenon, polyembryony is a process that produces multiple clonal offspring from a single egg cell. This is known in some hymenopteran parasitoids and in Strepsiptera.[58]

In automictic species the offspring can be haploid or diploid. Diploids are produced by doubling or fusion of gametes after meiosis. Fusion is seen in the Phasmatodea, Hemiptera (Aleurodids and Coccidae), Diptera, and some Hymenoptera.[58]

In addition to these forms is hermaphroditism, where both the eggs and sperm are produced by the same individual, but is not a type of parthenogenesis. This is seen in three species of Icerya scale insects.[58]

Parasitic bacteria like Wolbachia have been noted to induce automictic thelytoky in many insect species with haplodiploid systems. They also cause gamete duplication in unfertilized eggs causing them to develop into female offspring.[58]

 
Honey bee on a plum blossom

Among species with the haplo-diploid sex-determination system, such as hymenopterans (ants, bees and wasps) and thysanopterans (thrips), haploid males are produced from unfertilized eggs. Usually, eggs are laid only by the queen, but the unmated workers may also lay haploid, male eggs either regularly (e.g. stingless bees) or under special circumstances. An example of non-viable parthenogenesis is common among domesticated honey bees. The queen bee is the only fertile female in the hive; if she dies without the possibility of a viable replacement queen, it is not uncommon for the worker bees to lay eggs. This is a result of the lack of the queen's pheromones and the pheromones secreted by uncapped brood, which normally suppress ovarian development in workers. Worker bees are unable to mate, and the unfertilized eggs produce only drones (males), which can mate only with a queen. Thus, in a relatively short period, all the worker bees die off, and the new drones follow if they have not been able to mate before the collapse of the colony. This behavior is believed to have evolved to allow a doomed colony to produce drones which may mate with a virgin queen and thus preserve the colony's genetic progeny.

A few ants and bees are capable of producing diploid female offspring parthenogenetically. These include a honey bee subspecies from South Africa, Apis mellifera capensis, where workers are capable of producing diploid eggs parthenogenetically, and replacing the queen if she dies; other examples include some species of small carpenter bee, (genus Ceratina). Many parasitic wasps are known to be parthenogenetic, sometimes due to infections by Wolbachia.

The workers in five[30] ant species and the queens in some ants are known to reproduce by parthenogenesis. In Cataglyphis cursor, a European formicine ant, the queens and workers can produce new queens by parthenogenesis. The workers are produced sexually.[30]

In Central and South American electric ants, Wasmannia auropunctata, queens produce more queens through automictic parthenogenesis with central fusion. Sterile workers usually are produced from eggs fertilized by males. In some of the eggs fertilized by males, however, the fertilization can cause the female genetic material to be ablated from the zygote. In this way, males pass on only their genes to become fertile male offspring. This is the first recognized example of an animal species where both females and males can reproduce clonally resulting in a complete separation of male and female gene pools.[60] As a consequence, the males will only have fathers and the queens only mothers, while the sterile workers are the only ones with both parents of both sexes.

These ants get both the benefits of both asexual and sexual reproduction[30][60]—the daughters who can reproduce (the queens) have all of the mother's genes, while the sterile workers whose physical strength and disease resistance are important are produced sexually.

Other examples of insect parthenogenesis can be found in gall-forming aphids (e.g., Pemphigus betae), where females reproduce parthenogenetically during the gall-forming phase of their life cycle and in grass thrips. In the grass thrips genus Aptinothrips there have been, despite the very limited number of species in the genus, several transitions to asexuality.[61]

Crustaceans

Crustacean reproduction varies both across and within species. The water flea Daphnia pulex alternates between sexual and parthenogenetic reproduction.[62] Among the better-known large decapod crustaceans, some crayfish reproduce by parthenogenesis. "Marmorkrebs" are parthenogenetic crayfish that were discovered in the pet trade in the 1990s.[63] Offspring are genetically identical to the parent, indicating it reproduces by apomixis, i.e. parthenogenesis in which the eggs did not undergo meiosis.[64] Spinycheek crayfish (Orconectes limosus) can reproduce both sexually and by parthenogenesis.[65] The Louisiana red swamp crayfish (Procambarus clarkii), which normally reproduces sexually, has also been suggested to reproduce by parthenogenesis,[66] although no individuals of this species have been reared this way in the lab. Artemia parthenogenetica is a species or series of populations of parthenogenetic brine shrimps.[67]

Spiders

At least two species of spiders in the family Oonopidae (goblin spiders), Heteroonops spinimanus and Triaeris stenaspis, are thought to be parthenogenetic, as no males have ever been collected. Parthenogenetic reproduction has been demonstrated in the laboratory for T. stenaspis.[68]

Sharks

Parthenogenesis in sharks has been confirmed in at least three species, the bonnethead,[47] the blacktip shark,[69] and the zebra shark,[70] and reported in others.

A bonnethead, a type of small hammerhead shark, was found to have produced a pup, born live on December 14, 2001, at Henry Doorly Zoo in Nebraska, in a tank containing three female hammerheads, but no males. The pup was thought to have been conceived through parthenogenesis. The shark pup was apparently killed by a stingray within days of birth.[71] The investigation of the birth was conducted by the research team from Queen's University Belfast, Southeastern University in Florida, and Henry Doorly Zoo itself, and it was concluded after DNA testing that the reproduction was parthenogenetic. The testing showed the female pup's DNA matched only one female who lived in the tank, and that no male DNA was present in the pup. The pup was not a twin or clone of her mother, but rather, contained only half of her mother's DNA ("automictic parthenogenesis"). This type of reproduction had been seen before in bony fish, but never in cartilaginous fish such as sharks, until this documentation.

In the same year, a female Atlantic blacktip shark in Virginia reproduced via parthenogenesis.[72] On October 10, 2008, scientists confirmed the second case of a "virgin birth" in a shark. The Journal of Fish Biology reported a study in which scientists said DNA testing proved that a pup carried by a female Atlantic blacktip shark in the Virginia Aquarium & Marine Science Center contained no genetic material from a male.[69]

In 2002, two white-spotted bamboo sharks were born at the Belle Isle Aquarium in Detroit. They hatched 15 weeks after being laid. The births baffled experts as the mother shared an aquarium with only one other shark, which was female. The female bamboo sharks had laid eggs in the past. This is not unexpected, as many animals will lay eggs even if there is not a male to fertilize them. Normally, the eggs are assumed to be inviable and are discarded. This batch of eggs was left undisturbed by the curator as he had heard about the previous birth in 2001 in Nebraska and wanted to observe whether they would hatch. Other possibilities had been considered for the birth of the Detroit bamboo sharks including thoughts that the sharks had been fertilized by a male and stored the sperm for a period of time, as well as the possibility that the Belle Isle bamboo shark is a hermaphrodite, harboring both male and female sex organs, and capable of fertilizing its own eggs, but that is not confirmed.[73]

In 2008, a Hungarian aquarium had another case of parthenogenesis after its lone female shark produced a pup without ever having come into contact with a male shark.

The repercussions of parthenogenesis in sharks, which fails to increase the genetic diversity of the offspring, is a matter of concern for shark experts, taking into consideration conservation management strategies for this species, particularly in areas where there may be a shortage of males due to fishing or environmental pressures. Although parthenogenesis may help females who cannot find mates, it does reduce genetic diversity.[citation needed]

In 2011, recurring shark parthenogenesis over several years was demonstrated in a captive zebra shark, a type of carpet shark.[70][74] DNA genotyping demonstrated that individual zebra sharks can switch from sexual to parthenogenetic reproduction.[75]

Amphibians

Main article: Parthenogenesis in amphibians

Squamata

Main article: Parthenogenesis in squamata
 
Komodo dragon, Varanus komodoensis, rarely reproduces offspring via parthenogenesis.

Most reptiles of the squamatan order (lizards and snakes) reproduce sexually, but parthenogenesis has been observed to occur naturally in certain species of whiptails, some geckos, rock lizards,[6][76][77] Komodo dragons[78] and snakes.[79] Some of these like the mourning gecko Lepidodactylus lugubris, Indo-Pacific house gecko Hemidactylus garnotii, the hybrid whiptails Cnemidophorus, Caucasian rock lizards Darevskia, and the brahminy blindsnake, Indotyphlops braminus are unisexual and obligately parthenogenetic. Other reptiles, such as the Komodo dragon, other monitor lizards,[80] and some species of boas,[12][31][81] pythons,[29][82] filesnakes,[83][84] gartersnakes[85] and rattlesnakes[86][87] were previously considered as cases of facultative parthenogenesis, but may be cases of accidental parthenogenesis.[37]

In 2012, facultative parthenogenesis was reported in wild vertebrates for the first time by US researchers amongst captured pregnant copperhead and cottonmouth female pit-vipers.[88] The Komodo dragon, which normally reproduces sexually, has also been found able to reproduce asexually by parthenogenesis.[89] A case has been documented of a Komodo dragon reproducing via sexual reproduction after a known parthenogenetic event,[90] highlighting that these cases of parthenogenesis are reproductive accidents, rather than adaptive, facultative parthenogenesis.[37]

Some reptile species use a ZW chromosome system, which produces either males (ZZ) or females (ZW). Until 2010, it was thought that the ZW chromosome system used by reptiles was incapable of producing viable WW offspring, but a (ZW) female boa constrictor was discovered to have produced viable female offspring with WW chromosomes.[91]

Parthenogenesis has been studied extensively in the New Mexico whiptail in the genus Aspidoscelis of which 15 species reproduce exclusively by parthenogenesis. These lizards live in the dry and sometimes harsh climate of the southwestern United States and northern Mexico. All these asexual species appear to have arisen through the hybridization of two or three of the sexual species in the genus leading to polyploid individuals. The mechanism by which the mixing of chromosomes from two or three species can lead to parthenogenetic reproduction is unknown. Recently, a hybrid parthenogenetic whiptail lizard was bred in the laboratory from a cross between an asexual and a sexual whiptail.[92] Because multiple hybridization events can occur, individual parthenogenetic whiptail species can consist of multiple independent asexual lineages. Within lineages, there is very little genetic diversity, but different lineages may have quite different genotypes.

An interesting aspect to reproduction in these asexual lizards is that mating behaviors are still seen, although the populations are all female. One female plays the role played by the male in closely related species, and mounts the female that is about to lay eggs. This behaviour is due to the hormonal cycles of the females, which cause them to behave like males shortly after laying eggs, when levels of progesterone are high, and to take the female role in mating before laying eggs, when estrogen dominates. Lizards who act out the courtship ritual have greater fecundity than those kept in isolation, due to the increase in hormones that accompanies the mounting. So, although the populations lack males, they still require sexual behavioral stimuli for maximum reproductive success.[93]

Some lizard parthenogens show a pattern of geographic parthenogenesis, occupying high mountain areas where their ancestral forms have an inferior competition ability.[94] In Caucasian rock lizards of genus Darevskia, which have six parthenogenetic forms of hybrid origin[76][77][95] hybrid parthenogenetic form D. "dahli" has a broader niche than either of its bisexual ancestors and its expansion throughout the Central Lesser Caucasus caused decline of the ranges of both its maternal and paternal species.[96]

Birds

Parthenogenesis in birds is known mainly from studies of domesticated turkeys and chickens, although it has also been noted in the domestic pigeon.[46] In most cases the egg fails to develop normally or completely to hatching.[46][97] The first description of parthenogenetic development in a passerine was demonstrated in captive zebra finches, although the dividing cells exhibited irregular nuclei and the eggs did not hatch.[46]

Parthenogenesis in turkeys appears to result from a conversion of haploid cells to diploid;[97] most embryos produced in this way die early in development. Rarely, viable birds result from this process, and the rate at which this occurs in turkeys can be increased by selective breeding,[98] however male turkeys produced from parthenogenesis exhibit smaller testes and reduced fertility.[99]

In 2021, the San Diego Zoo reported that they had two unfertilized eggs from their California condor breeding program hatch. This is the first known example of parthenogenesis in this species, as well as one of the only known examples of parthenogenesis happening where males are still present.[10]

Mammals

There are no known cases of naturally occurring mammalian parthenogenesis in the wild. Parthenogenetic progeny of mammals would have two X chromosomes, and would therefore be genetically female.

In 1936, Gregory Goodwin Pincus reported successfully inducing parthenogenesis in a rabbit.[100]

In April 2004, scientists at Tokyo University of Agriculture used parthenogenesis successfully to create a fatherless mouse. Using gene targeting, they were able to manipulate two imprinted loci H19/IGF2 and DLK1/MEG3 to produce bi-maternal mice at high frequency[101] and subsequently show that fatherless mice have enhanced longevity.[102]

Induced parthenogenesis in mice and monkeys often results in abnormal development. This is because mammals have imprinted genetic regions, where either the maternal or the paternal chromosome is inactivated in the offspring in order for development to proceed normally. A mammal created by parthenogenesis would have double doses of maternally imprinted genes and lack paternally imprinted genes, leading to developmental abnormalities. It has been suggested[103] that defects in placental folding or interdigitation are one cause of swine parthenote abortive development. As a consequence, research on human parthenogenesis is focused on the production of embryonic stem cells for use in medical treatment, not as a reproductive strategy.

However, in 2022, researchers reported that they have achieved parthenogenesis in mice for viable offspring born from unfertilized eggs, addressing the problems of genomic imprinting by "targeted DNA methylation rewriting of seven imprinting control regions".[13]

Methods

Use of an electrical or chemical stimulus can produce the beginning of the process of parthenogenesis in the asexual development of viable offspring.[104]

 
Induction of parthenogenesis in swine. Parthenogenetic development of swine oocytes.[103] High metaphase promoting factor (MPF) activity causes mammalian oocytes to arrest at the metaphase II stage until fertilization by a sperm. The fertilization event causes intracellular calcium oscillations, and targeted degradation of cyclin B, a regulatory subunit of MPF, thus permitting the MII-arrested oocyte to proceed through meiosis. To initiate parthenogenesis of swine oocytes, various methods exist to induce an artificial activation that mimics sperm entry, such as calcium ionophore treatment, microinjection of calcium ions, or electrical stimulation. Treatment with cycloheximide, a non-specific protein synthesis inhibitor, enhances parthenote development in swine presumably by continual inhibition of MPF/cyclin B.[105] As meiosis proceeds, extrusion of the second polar is blocked by exposure to cytochalasin B. This treatment results in a diploid (2 maternal genomes) parthenote. Parthenotes can be surgically transferred to a recipient oviduct for further development, but will succumb by developmental failure after ≈30 days of gestation. The swine parthenote placentae often appears hypo-vascular and is approximately 50% smaller than biparental offspring placentae: see free image (Figure 1) in linked reference.[103]

During oocyte development, high metaphase promoting factor (MPF) activity causes mammalian oocytes to arrest at the metaphase II stage until fertilization by a sperm. The fertilization event causes intracellular calcium oscillations, and targeted degradation of cyclin B, a regulatory subunit of MPF, thus permitting the MII-arrested oocyte to proceed through meiosis.

To initiate parthenogenesis of swine oocytes, various methods exist to induce an artificial activation that mimics sperm entry, such as calcium ionophore treatment, microinjection of calcium ions, or electrical stimulation. Treatment with cycloheximide, a non-specific protein synthesis inhibitor, enhances parthenote development in swine presumably by continual inhibition of MPF/cyclin B.[105] As meiosis proceeds, extrusion of the second polar is blocked by exposure to cytochalasin B. This treatment results in a diploid (2 maternal genomes) parthenote[103] Parthenotes can be surgically transferred to a recipient oviduct for further development, but will succumb to developmental failure after ≈30 days of gestation. The swine parthenote placentae often appears hypo-vascular: see free image (Figure 1) in linked reference.[103]

Humans

Reports of human parthenogenesis have famously existed since ancient times, featuring prominently in Christianity and various other religions. More recently, Helen Spurway, a geneticist specializing in the reproductive biology of the guppy (Lebistes reticulatus), claimed in 1955 that parthenogenesis, which occurs in the guppy in nature, may also occur (though very rarely) in the human species, leading to so-called “virgin births”. This created some sensation among her colleagues and the lay public alike.[106] Sometimes an embryo may begin to divide without fertilisation, but it cannot fully develop on its own; so while it may create some skin and nerve cells, it cannot create others (such as skeletal muscle) and becomes a type of benign tumor called an ovarian teratoma.[107] Spontaneous ovarian activation is not rare and has been known about since the 19th century. Some teratomas can even become primitive fetuses (fetiform teratoma) with imperfect heads, limbs and other structures, but are non-viable.

In 1995, there was a reported case of partial human parthenogenesis; a boy was found to have some of his cells (such as white blood cells) to be lacking in any genetic content from his father. Scientists believe that an unfertilised egg began to self-divide but then had some (but not all) of its cells fertilised by a sperm cell; this must have happened early in development, as self-activated eggs quickly lose their ability to be fertilised. The unfertilised cells eventually duplicated their DNA, boosting their chromosomes to 46. When the unfertilised cells hit a developmental block, the fertilised cells took over and developed that tissue. The boy had asymmetrical facial features and learning difficulties but was otherwise healthy. This would make him a parthenogenetic chimera (a child with two cell lineages in his body).[108] While over a dozen similar cases have been reported since then (usually discovered after the patient demonstrated clinical abnormalities), there have been no scientifically confirmed reports of a non-chimeric, clinically healthy human parthenote (i.e. produced from a single, parthenogenetic-activated oocyte).[107]

On June 26, 2007, the International Stem Cell Corporation (ISCC), a California-based stem cell research company, announced that their lead scientist, Dr. Elena Revazova, and her research team were the first to intentionally create human stem cells from unfertilized human eggs using parthenogenesis. The process may offer a way for creating stem cells that are genetically matched to a particular female for the treatment of degenerative diseases that might affect her. In December 2007, Dr. Revazova and ISCC published an article[109] illustrating a breakthrough in the use of parthenogenesis to produce human stem cells that are homozygous in the HLA region of DNA. These stem cells are called HLA homozygous parthenogenetic human stem cells (hpSC-Hhom) and have unique characteristics that would allow derivatives of these cells to be implanted into millions of people without immune rejection.[110] With proper selection of oocyte donors according to HLA haplotype, it is possible to generate a bank of cell lines whose tissue derivatives, collectively, could be MHC-matched with a significant number of individuals within the human population.

On August 2, 2007, after an independent investigation, it was revealed that discredited South Korean scientist Hwang Woo-Suk unknowingly produced the first human embryos resulting from parthenogenesis. Initially, Hwang claimed he and his team had extracted stem cells from cloned human embryos, a result later found to be fabricated. Further examination of the chromosomes of these cells show indicators of parthenogenesis in those extracted stem cells, similar to those found in the mice created by Tokyo scientists in 2004. Although Hwang deceived the world about being the first to create artificially cloned human embryos, he contributed a major breakthrough to stem cell research by creating human embryos using parthenogenesis.[111] The truth was discovered in 2007, long after the embryos were created by him and his team in February 2004. This made Hwang the first, unknowingly, to successfully perform the process of parthenogenesis to create a human embryo and, ultimately, a human parthenogenetic stem cell line.

A US study conducted between 1995 and 2009 found that out of 7,870 young women who participated, 45 (0.5%) reported that they had had a virgin pregnancy and resulting birth. The alleged virgin mothers were found to be relatively unlikely to know how to use a condom, and 67.8% said they would endorse condom use. Additionally, they were relatively likely to have pledged chastity and to have had less communication with their parents about sex and birth control.[112]

Similar phenomena

Gynogenesis

See also: Gynogenesis and Parthenogenesis in amphibians § Gynogenesis

A form of asexual reproduction related to parthenogenesis is gynogenesis. Here, offspring are produced by the same mechanism as in parthenogenesis, but with the requirement that the egg merely be stimulated by the presence of sperm in order to develop. However, the sperm cell does not contribute any genetic material to the offspring. Since gynogenetic species are all female, activation of their eggs requires mating with males of a closely related species for the needed stimulus. Some salamanders of the genus Ambystoma are gynogenetic and appear to have been so for over a million years. It is believed[by whom?] that the success of those salamanders may be due to rare fertilization of eggs by males, introducing new material to the gene pool, which may result from perhaps only one mating out of a million. In addition, the amazon molly is known to reproduce by gynogenesis.[113]

Hybridogenesis

See also: Hybridogenesis in water frogs

Hybridogenesis is a mode of reproduction of hybrids. Hybridogenetic hybrids (for example AB genome), usually females, during gametogenesis exclude one of parental genomes (A) and produce gametes with unrecombined[114] genome of second parental species (B), instead of containing mixed recombined parental genomes. First genome (A) is restored by fertilization of these gametes with gametes from the first species (AA, sexual host,[114] usually male).[114][115][116]

So hybridogenesis is not completely asexual, but instead hemiclonal: half of genome is passed to the next generation clonally, unrecombined, intact (B), other half sexually, recombined (A).[114][117]

This process continues, so that each generation is half (or hemi-) clonal on the mother's side and has half new genetic material from the father's side.

This form of reproduction is seen in some live-bearing fish of the genus Poeciliopsis[115][118] as well as in some of the Pelophylax spp. ("green frogs" or "waterfrogs"):

and perhaps in P. demarchii.

 
Example crosses between pool frog (Pelophylax lessonae), marsh frog (P. ridibundus) and their hybrid – edible frog (P. kl. esculentus). First one is the primary hybridisation generating hybrid, second one is most widespread type of hybridogenesis.[114][121]

Other examples where hybridogenesis is at least one of modes of reproduction include i.e.

See also

  • Androgenesis - a form of quasi-sexual reproduction in which a male is the sole source of the nuclear genetic material in the embryo.
  • Charles Bonnet – Genevan botanist (1720–1793) – conducted experiments that established what is now termed parthenogenesis in aphids
  • Jan Dzierżon – Polish apiarist and a pioneer of parthenogenesis among bees
  • Jacques Loeb – caused the eggs of sea urchins to begin embryonic development without sperm
  • Miraculous births – Conceptions and births by miraculous circumstances
  • Parthenocarpy – Production of fruit without fertilisation which makes the fruit seedless – plants with seedless fruit

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Further reading

  • Dawley, Robert M. & Bogart, James P. (1989). Evolution and Ecology of Unisexual Vertebrates. Albany: New York State Museum. ISBN 1-55557-179-4.
  • Fangerau, H (2005). "Can artificial parthenogenesis sidestep ethical pitfalls in human therapeutic cloning? An historical perspective". Journal of Medical Ethics. 31 (12): 733–735. doi:10.1136/jme.2004.010199. PMC 1734065. PMID 16319240.
  • Futuyma, Douglas J. & Slatkin, Montgomery. (1983). Coevolution. Sunderland, Mass: Sinauer Associates. ISBN 0-87893-228-3.
  • Hore, T; Rapkins, R; Graves, J (2007). "Construction and evolution of imprinted loci in mammals". Trends in Genetics. 23 (9): 440–448. doi:10.1016/j.tig.2007.07.003. PMID 17683825.
  • Kono, T.; Obata, Y.; Wu, Q.; Niwa, K.; Ono, Y.; Yamamoto, Y.; Park, E.S.; Seo, J.-S.; Ogawa, H. (2004). "Birth of parthenogenetic mice that can develop to adulthood". Nature. 428 (6985): 860–864. Bibcode:2004Natur.428..860K. doi:10.1038/nature02402. PMID 15103378. S2CID 4353479.
  • Maynard Smith, John. (1978). The Evolution of Sex. Cambridge: Cambridge University Press. ISBN 0-521-29302-2.
  • Michod, Richard E. & Levin, Bruce R. (1988). The Evolution of Sex. Sunderland, Mass: Sinauer Associates. ISBN 0-87893-459-6.
  • Schlupp, Ingo (2005). "The Evolutionary Ecology of Gynogenesis". Annual Review of Ecology, Evolution, and Systematics. 36: 399–417. doi:10.1146/annurev.ecolsys.36.102003.152629.
  • Simon, J; Rispe, Claude; Sunnucks, Paul (2002). "Ecology and evolution of sex in aphids". Trends in Ecology & Evolution. 17: 34–39. doi:10.1016/S0169-5347(01)02331-X.
  • Stearns, Stephan C. (1988). The Evolution of Sex and Its Consequences (Experientia Supplementum, Vol. 55). Boston: Birkhauser. ISBN 0-8176-1807-4.

External links

  • Reproductive behavior in whiptails at Crews Laboratory
  • Types of asexual reproduction
  • Parthenogenesis in Incubated Turkey Eggs from Oregon State University
  • National Geographic News: Virgin Birth Expected at Christmas – By Komodo Dragon
  • BBC News: 'Virgin births' for giant lizards (Komodo dragon)
  • Reuther: Komodo dragon proud mum (and dad) of five
  • Female sharks capable of virgin birth
  • Scientists confirm shark's ‘virgin birth’ Article by Steve Szkotak AP updated 1:49 a.m. ET, Fri., Oct. 10, 2008

January 20, 2023
parthenogenesis, confused, with, pathogenesis, ɑːr, from, greek, παρθένος, parthénos, virgin, γένεσις, génesis, creation, natural, form, asexual, reproduction, which, growth, development, embryos, occur, gamete, sperm, without, combining, with, another, gamete. Not to be confused with Pathogenesis Parthenogenesis ˌ p ɑːr 8 ɪ n oʊ ˈ dʒ ɛ n ɪ s ɪ s 8 ɪ n e 1 2 from the Greek par8enos parthenos virgin genesis genesis creation 3 is a natural form of asexual reproduction in which growth and development of embryos occur in a gamete egg or sperm without combining with another gamete e g egg and sperm fusing 4 In animals parthenogenesis means development of an embryo from an unfertilized egg cell In plants parthenogenesis is a component process of apomixis In algae parthenogenesis can mean the development of an embryo from either an individual sperm or an individual egg 4 The asexual all female whiptail species Aspidoscelis neomexicanus center which reproduces via parthenogenesis is shown flanked by two sexual species having males A inornatus left and A tigris right which hybridized naturally to form A neomexicanus Parthenogenesis occurs naturally in some plants algae invertebrate animal species including nematodes some tardigrades water fleas some scorpions aphids some mites some bees some Phasmatodea and parasitic wasps and a few vertebrates such as some fish 5 amphibians reptiles 6 7 8 and birds 9 10 11 This type of reproduction has been induced artificially in a few species including fish amphibians and mice 12 13 Normal egg cells form in the process of meiosis and are haploid with half as many chromosomes as their mother s body cells Haploid individuals however are usually non viable and parthenogenetic offspring usually have the diploid chromosome number Depending on the mechanism involved in restoring the diploid number of chromosomes parthenogenetic offspring may have anywhere between all and half of the mother s alleles In some types of parthenogenesis the offspring having all of the mother s genetic material are called full clones and those having only half are called half clones Full clones are usually formed without meiosis If meiosis occurs the offspring will get only a fraction of the mother s alleles since crossing over of DNA takes place during meiosis creating variation Parthenogenetic offspring in species that use either the XY or the X0 sex determination system have two X chromosomes and are female In species that use the ZW sex determination system they have either two Z chromosomes male or two W chromosomes mostly non viable but rarely a female or they could have one Z and one W chromosome female Parthenogenesis does not apply to isogamous species 14 Contents 1 Life history types 2 Types and mechanisms 2 1 Automictic 2 2 Sex of the offspring 2 3 Facultative 2 4 Obligate 3 Natural occurrence 3 1 Oomycetes 3 2 Velvet worms 3 3 Rotifers 3 4 Flatworms 3 5 Snails 3 6 Insects 3 7 Crustaceans 3 8 Spiders 3 9 Sharks 3 10 Amphibians 3 11 Squamata 3 12 Birds 3 13 Mammals 3 13 1 Methods 3 13 2 Humans 4 Similar phenomena 4 1 Gynogenesis 4 2 Hybridogenesis 5 See also 6 References 7 Further reading 8 External linksLife history types EditFurther information Origin and function of meiosis A baby Komodo dragon Varanus komodoensis produced through parthenogenesis Komodo dragons are an example of a species which can produce offspring both through sexual reproduction and parthenogenesis Some species reproduce exclusively by parthenogenesis such as the bdelloid rotifers while others can switch between sexual reproduction and parthenogenesis This is called facultative parthenogenesis other terms are cyclical parthenogenesis heterogamy 15 16 or heterogony 17 18 The switch between sexuality and parthenogenesis in such species may be triggered by the season aphid some gall wasps or by a lack of males or by conditions that favour rapid population growth rotifers and cladocerans like Daphnia In these species asexual reproduction occurs either in summer aphids or as long as conditions are favourable This is because in asexual reproduction a successful genotype can spread quickly without being modified by sex or wasting resources on male offspring who won t give birth Some species can produce both sexually and through parthenogenesis and offspring in the same clutch of a species of tropical lizard can be a mix sexually produced offspring and parthenogenically produced offspring 19 In California Condors facultative parthenogenesis can occur even when a male is present and available for a female to breed with 20 In times of stress offspring produced by sexual reproduction may be fitter as they have new possibly beneficial gene combinations In addition sexual reproduction provides the benefit of meiotic recombination between non sister chromosomes a process associated with repair of DNA double strand breaks and other DNA damages that may be induced by stressful conditions 21 Many taxa with heterogony have within them species that have lost the sexual phase and are now completely asexual Many other cases of obligate parthenogenesis or gynogenesis are found among polyploids and hybrids where the chromosomes cannot pair for meiosis The production of female offspring by parthenogenesis is referred to as thelytoky e g aphids while the production of males by parthenogenesis is referred to as arrhenotoky e g bees When unfertilized eggs develop into both males and females the phenomenon is called deuterotoky 22 Types and mechanisms EditParthenogenesis can occur without meiosis through mitotic oogenesis This is called apomictic parthenogenesis Mature egg cells are produced by mitotic divisions and these cells directly develop into embryos In flowering plants cells of the gametophyte can undergo this process The offspring produced by apomictic parthenogenesis are full clones of their mother Examples include aphids Parthenogenesis involving meiosis is more complicated In some cases the offspring are haploid e g male ants In other cases collectively called automictic parthenogenesis the ploidy is restored to diploidy by various means This is because haploid individuals are not viable in most species In automictic parthenogenesis the offspring differ from one another and from their mother They are called half clones of their mother Automictic Edit The effects of central fusion and terminal fusion on heterozygosity Automixis 23 is a term that covers several reproductive mechanisms some of which are parthenogenetic 24 Diploidy might be restored by the doubling of the chromosomes without cell division before meiosis begins or after meiosis is completed This is referred to as an endomitotic cycle This may also happen by the fusion of the first two blastomeres Other species restore their ploidy by the fusion of the meiotic products The chromosomes may not separate at one of the two anaphases called restitutional meiosis or the nuclei produced may fuse or one of the polar bodies may fuse with the egg cell at some stage during its maturation Some authors consider all forms of automixis sexual as they involve recombination Many others classify the endomitotic variants as asexual and consider the resulting embryos parthenogenetic Among these authors the threshold for classifying automixis as a sexual process depends on when the products of anaphase I or of anaphase II are joined The criterion for sexuality varies from all cases of restitutional meiosis 25 to those where the nuclei fuse or to only those where gametes are mature at the time of fusion 24 Those cases of automixis that are classified as sexual reproduction are compared to self fertilization in their mechanism and consequences The genetic composition of the offspring depends on what type of automixis takes place When endomitosis occurs before meiosis 26 27 or when central fusion occurs restitutional meiosis of anaphase I or the fusion of its products the offspring get all 26 28 to more than half of the mother s genetic material and heterozygosity is mostly preserved 29 if the mother has two alleles for a locus it is likely that the offspring will get both This is because in anaphase I the homologous chromosomes are separated Heterozygosity is not completely preserved when crossing over occurs in central fusion 30 In the case of pre meiotic doubling recombination if it happens occurs between identical sister chromatids 26 If terminal fusion restitutional meiosis of anaphase II or the fusion of its products occurs a little over half the mother s genetic material is present in the offspring and the offspring are mostly homozygous 31 This is because at anaphase II the sister chromatids are separated and whatever heterozygosity is present is due to crossing over In the case of endomitosis after meiosis the offspring is completely homozygous and has only half the mother s genetic material This can result in parthenogenetic offspring being unique from each other and from their mother Sex of the offspring Edit In apomictic parthenogenesis the offspring are clones of the mother and hence except for aphids are usually female In the case of aphids parthenogenetically produced males and females are clones of their mother except that the males lack one of the X chromosomes XO 32 When meiosis is involved the sex of the offspring will depend on the type of sex determination system and the type of apomixis In species that use the XY sex determination system parthenogenetic offspring will have two X chromosomes and are female In species that use the ZW sex determination system the offspring genotype may be one of ZW female 28 29 ZZ male or WW non viable in most species 31 but a fertile dubious discuss viable female in a few e g boas 31 ZW offspring are produced by endoreplication before meiosis or by central fusion 28 29 ZZ and WW offspring occur either by terminal fusion 31 or by endomitosis in the egg cell In polyploid obligate parthenogens like the whiptail lizard all the offspring are female 27 In many hymenopteran insects such as honeybees female eggs are produced sexually using sperm from a drone father while the production of further drones males depends on the queen and occasionally workers producing unfertilized eggs This means that females workers and queens are always diploid while males drones are always haploid and produced parthenogenetically Facultative Edit Facultative parthenogenesis is the term for when a female can produce offspring either sexually or via asexual reproduction 33 Facultative parthenogenesis is extremely rare in nature with only a few examples of animal taxa capable of facultative parthenogenesis 33 One of the best known examples of taxa exhibiting facultative parthenogenesis are mayflies presumably this is the default reproductive mode of all species in this insect order 34 Facultative parthenogenesis has generally been believed to be a response to a lack of a viable male A female may undergo facultative parthenogenesis if a male is absent from the habitat or if it is unable to produce viable offspring However California condors and the tropical lizard Lepidophyma smithii both can produce parthenogenic offspring in the presence of males indicating that facultative parthenogenesis may be more common than previously thought and is not simply a response to a lack of males 19 35 In aphids a generation sexually conceived by a male and a female produces only females The reason for this is the non random segregation of the sex chromosomess X and O during spermatogenesis 36 Facultative parthenogenesis is often used to describe cases of spontaneous parthenogenesis in normally sexual animals 37 For example many cases of spontaneous parthenogenesis in sharks some snakes Komodo dragons and a variety of domesticated birds were widely attributed to facultative parthenogenesis 38 These cases are examples of spontaneous parthenogenesis 33 37 The occurrence of such asexually produced eggs in sexual animals can be explained by a meiotic error leading to eggs produced via automixis 37 39 Obligate Edit Obligate parthenogenesis is the process in which organisms exclusively reproduce through asexual means 40 Many species have been shown to transition to obligate parthenogenesis over evolutionary time Well documented transitions to obligate parthenogenesis have been found in numerous metazoan taxa albeit through highly diverse mechanisms These transitions often occur as a result of inbreeding or mutation within large populations 41 There are a number of documented species specifically salamanders and geckos that rely on obligate parthenogenesis as their major method of reproduction As such there are over 80 species of unisex reptiles mostly lizards but including a single snake species amphibians and fishes in nature for which males are no longer a part of the reproductive process 42 A female will produce an ovum with a full set two sets of genes provided solely by the mother Thus a male is not needed to provide sperm to fertilize the egg This form of asexual reproduction is thought in some cases to be a serious threat to biodiversity for the subsequent lack of gene variation and potentially decreased fitness of the offspring 40 Some invertebrate species that feature partial sexual reproduction in their native range are found to reproduce solely by parthenogenesis in areas to which they have been introduced 43 44 Relying solely on parthenogenetic reproduction has several advantages for an invasive species it obviates the need for individuals in a very sparse initial population to search for mates and an exclusively female sex distribution allows a population to multiply and invade more rapidly potentially twice as fast Examples include several aphid species 43 and the willow sawfly Nematus oligospilus which is sexual in its native Holarctic habitat but parthenogenetic where it has been introduced into the Southern Hemisphere 44 Natural occurrence EditParthenogenesis is seen to occur naturally in aphids Daphnia rotifers nematodes and some other invertebrates as well as in many plants Among vertebrates strict parthenogenesis is only known to occur in lizards snakes 45 birds 46 and sharks 47 with fish amphibians and reptiles exhibiting various forms of gynogenesis and hybridogenesis an incomplete form of parthenogenesis 48 The first all female unisexual reproduction in vertebrates was described in the fish Poecilia formosa in 1932 49 Since then at least 50 species of unisexual vertebrate have been described including at least 20 fish 25 lizards a single snake species frogs and salamanders 48 Other usually sexual species may occasionally reproduce parthenogenetically the Komodo dragon and hammerhead and blacktip sharks are recent additions to the known list of spontaneous parthenogenetic vertebrates As with all types of asexual reproduction there are both costs low genetic diversity and therefore susceptibility to adverse mutations that might occur and benefits reproduction without the need for a male associated with parthenogenesis Parthenogenesis is distinct from artificial animal cloning a process where the new organism is necessarily genetically identical to the cell donor In cloning the nucleus of a diploid cell from a donor organism is inserted into an enucleated egg cell and the cell is then stimulated to undergo continued mitosis resulting in an organism that is genetically identical to the donor Parthenogenesis is different in that it originates from the genetic material contained within an egg cell and the new organism is not necessarily genetically identical to the parent Parthenogenesis may be achieved through an artificial process as described below under the discussion of mammals Oomycetes Edit Apomixis can apparently occur in Phytophthora 50 an oomycete Oospores from an experimental cross were germinated and some of the progeny were genetically identical to one or other parent implying that meiosis did not occur and the oospores developed by parthenogenesis Velvet worms Edit No males of Epiperipatus imthurni have been found and specimens from Trinidad were shown to reproduce parthenogenetically This species is the only known velvet worm to reproduce via parthenogenesis 51 Rotifers Edit In bdelloid rotifers females reproduce exclusively by parthenogenesis obligate parthenogenesis 52 while in monogonont rotifers females can alternate between sexual and asexual reproduction cyclical parthenogenesis At least in one normally cyclical parthenogenetic species obligate parthenogenesis can be inherited a recessive allele leads to loss of sexual reproduction in homozygous offspring 53 Flatworms Edit At least two species in the genus Dugesia flatworms in the Turbellaria sub division of the phylum Platyhelminthes include polyploid individuals that reproduce by parthenogenesis 54 This type of parthenogenesis requires mating but the sperm does not contribute to the genetics of the offspring the parthenogenesis is pseudogamous alternatively referred to as gynogenetic A complex cycle of matings between diploid sexual and polyploid parthenogenetic individuals produces new parthenogenetic lines Snails Edit Several species of parthenogenetic gastropods have been studied especially with respect to their status as invasive species Such species include the New Zealand mud snail Potamopyrgus antipodarum 55 the red rimmed melania Melanoides tuberculata 56 and the Quilted melania Tarebia granifera 57 Insects Edit Parthenogenesis in insects can cover a wide range of mechanisms 58 The offspring produced by parthenogenesis may be of both sexes only female thelytoky e g aphids and some hymenopterans 59 or only male arrhenotoky e g most hymenopterans Both true parthenogenesis and pseudogamy gynogenesis or sperm dependent parthenogenesis are known to occur 33 The egg cells depending on the species may be produced without meiosis apomictically or by one of the several automictic mechanisms A related phenomenon polyembryony is a process that produces multiple clonal offspring from a single egg cell This is known in some hymenopteran parasitoids and in Strepsiptera 58 In automictic species the offspring can be haploid or diploid Diploids are produced by doubling or fusion of gametes after meiosis Fusion is seen in the Phasmatodea Hemiptera Aleurodids and Coccidae Diptera and some Hymenoptera 58 In addition to these forms is hermaphroditism where both the eggs and sperm are produced by the same individual but is not a type of parthenogenesis This is seen in three species of Icerya scale insects 58 Parasitic bacteria like Wolbachia have been noted to induce automictic thelytoky in many insect species with haplodiploid systems They also cause gamete duplication in unfertilized eggs causing them to develop into female offspring 58 Honey bee on a plum blossom Among species with the haplo diploid sex determination system such as hymenopterans ants bees and wasps and thysanopterans thrips haploid males are produced from unfertilized eggs Usually eggs are laid only by the queen but the unmated workers may also lay haploid male eggs either regularly e g stingless bees or under special circumstances An example of non viable parthenogenesis is common among domesticated honey bees The queen bee is the only fertile female in the hive if she dies without the possibility of a viable replacement queen it is not uncommon for the worker bees to lay eggs This is a result of the lack of the queen s pheromones and the pheromones secreted by uncapped brood which normally suppress ovarian development in workers Worker bees are unable to mate and the unfertilized eggs produce only drones males which can mate only with a queen Thus in a relatively short period all the worker bees die off and the new drones follow if they have not been able to mate before the collapse of the colony This behavior is believed to have evolved to allow a doomed colony to produce drones which may mate with a virgin queen and thus preserve the colony s genetic progeny A few ants and bees are capable of producing diploid female offspring parthenogenetically These include a honey bee subspecies from South Africa Apis mellifera capensis where workers are capable of producing diploid eggs parthenogenetically and replacing the queen if she dies other examples include some species of small carpenter bee genus Ceratina Many parasitic wasps are known to be parthenogenetic sometimes due to infections by Wolbachia The workers in five 30 ant species and the queens in some ants are known to reproduce by parthenogenesis In Cataglyphis cursor a European formicine ant the queens and workers can produce new queens by parthenogenesis The workers are produced sexually 30 In Central and South American electric ants Wasmannia auropunctata queens produce more queens through automictic parthenogenesis with central fusion Sterile workers usually are produced from eggs fertilized by males In some of the eggs fertilized by males however the fertilization can cause the female genetic material to be ablated from the zygote In this way males pass on only their genes to become fertile male offspring This is the first recognized example of an animal species where both females and males can reproduce clonally resulting in a complete separation of male and female gene pools 60 As a consequence the males will only have fathers and the queens only mothers while the sterile workers are the only ones with both parents of both sexes These ants get both the benefits of both asexual and sexual reproduction 30 60 the daughters who can reproduce the queens have all of the mother s genes while the sterile workers whose physical strength and disease resistance are important are produced sexually Other examples of insect parthenogenesis can be found in gall forming aphids e g Pemphigus betae where females reproduce parthenogenetically during the gall forming phase of their life cycle and in grass thrips In the grass thrips genus Aptinothrips there have been despite the very limited number of species in the genus several transitions to asexuality 61 Crustaceans Edit Crustacean reproduction varies both across and within species The water flea Daphnia pulex alternates between sexual and parthenogenetic reproduction 62 Among the better known large decapod crustaceans some crayfish reproduce by parthenogenesis Marmorkrebs are parthenogenetic crayfish that were discovered in the pet trade in the 1990s 63 Offspring are genetically identical to the parent indicating it reproduces by apomixis i e parthenogenesis in which the eggs did not undergo meiosis 64 Spinycheek crayfish Orconectes limosus can reproduce both sexually and by parthenogenesis 65 The Louisiana red swamp crayfish Procambarus clarkii which normally reproduces sexually has also been suggested to reproduce by parthenogenesis 66 although no individuals of this species have been reared this way in the lab Artemia parthenogenetica is a species or series of populations of parthenogenetic brine shrimps 67 Spiders Edit At least two species of spiders in the family Oonopidae goblin spiders Heteroonops spinimanus and Triaeris stenaspis are thought to be parthenogenetic as no males have ever been collected Parthenogenetic reproduction has been demonstrated in the laboratory for T stenaspis 68 Sharks Edit Parthenogenesis in sharks has been confirmed in at least three species the bonnethead 47 the blacktip shark 69 and the zebra shark 70 and reported in others A bonnethead a type of small hammerhead shark was found to have produced a pup born live on December 14 2001 at Henry Doorly Zoo in Nebraska in a tank containing three female hammerheads but no males The pup was thought to have been conceived through parthenogenesis The shark pup was apparently killed by a stingray within days of birth 71 The investigation of the birth was conducted by the research team from Queen s University Belfast Southeastern University in Florida and Henry Doorly Zoo itself and it was concluded after DNA testing that the reproduction was parthenogenetic The testing showed the female pup s DNA matched only one female who lived in the tank and that no male DNA was present in the pup The pup was not a twin or clone of her mother but rather contained only half of her mother s DNA automictic parthenogenesis This type of reproduction had been seen before in bony fish but never in cartilaginous fish such as sharks until this documentation In the same year a female Atlantic blacktip shark in Virginia reproduced via parthenogenesis 72 On October 10 2008 scientists confirmed the second case of a virgin birth in a shark The Journal of Fish Biology reported a study in which scientists said DNA testing proved that a pup carried by a female Atlantic blacktip shark in the Virginia Aquarium amp Marine Science Center contained no genetic material from a male 69 In 2002 two white spotted bamboo sharks were born at the Belle Isle Aquarium in Detroit They hatched 15 weeks after being laid The births baffled experts as the mother shared an aquarium with only one other shark which was female The female bamboo sharks had laid eggs in the past This is not unexpected as many animals will lay eggs even if there is not a male to fertilize them Normally the eggs are assumed to be inviable and are discarded This batch of eggs was left undisturbed by the curator as he had heard about the previous birth in 2001 in Nebraska and wanted to observe whether they would hatch Other possibilities had been considered for the birth of the Detroit bamboo sharks including thoughts that the sharks had been fertilized by a male and stored the sperm for a period of time as well as the possibility that the Belle Isle bamboo shark is a hermaphrodite harboring both male and female sex organs and capable of fertilizing its own eggs but that is not confirmed 73 In 2008 a Hungarian aquarium had another case of parthenogenesis after its lone female shark produced a pup without ever having come into contact with a male shark The repercussions of parthenogenesis in sharks which fails to increase the genetic diversity of the offspring is a matter of concern for shark experts taking into consideration conservation management strategies for this species particularly in areas where there may be a shortage of males due to fishing or environmental pressures Although parthenogenesis may help females who cannot find mates it does reduce genetic diversity citation needed In 2011 recurring shark parthenogenesis over several years was demonstrated in a captive zebra shark a type of carpet shark 70 74 DNA genotyping demonstrated that individual zebra sharks can switch from sexual to parthenogenetic reproduction 75 Amphibians Edit Main article Parthenogenesis in amphibians Squamata Edit Main article Parthenogenesis in squamata Komodo dragon Varanus komodoensis rarely reproduces offspring via parthenogenesis Most reptiles of the squamatan order lizards and snakes reproduce sexually but parthenogenesis has been observed to occur naturally in certain species of whiptails some geckos rock lizards 6 76 77 Komodo dragons 78 and snakes 79 Some of these like the mourning gecko Lepidodactylus lugubris Indo Pacific house gecko Hemidactylus garnotii the hybrid whiptails Cnemidophorus Caucasian rock lizards Darevskia and the brahminy blindsnake Indotyphlops braminus are unisexual and obligately parthenogenetic Other reptiles such as the Komodo dragon other monitor lizards 80 and some species of boas 12 31 81 pythons 29 82 filesnakes 83 84 gartersnakes 85 and rattlesnakes 86 87 were previously considered as cases of facultative parthenogenesis but may be cases of accidental parthenogenesis 37 In 2012 facultative parthenogenesis was reported in wild vertebrates for the first time by US researchers amongst captured pregnant copperhead and cottonmouth female pit vipers 88 The Komodo dragon which normally reproduces sexually has also been found able to reproduce asexually by parthenogenesis 89 A case has been documented of a Komodo dragon reproducing via sexual reproduction after a known parthenogenetic event 90 highlighting that these cases of parthenogenesis are reproductive accidents rather than adaptive facultative parthenogenesis 37 Some reptile species use a ZW chromosome system which produces either males ZZ or females ZW Until 2010 it was thought that the ZW chromosome system used by reptiles was incapable of producing viable WW offspring but a ZW female boa constrictor was discovered to have produced viable female offspring with WW chromosomes 91 Parthenogenesis has been studied extensively in the New Mexico whiptail in the genus Aspidoscelis of which 15 species reproduce exclusively by parthenogenesis These lizards live in the dry and sometimes harsh climate of the southwestern United States and northern Mexico All these asexual species appear to have arisen through the hybridization of two or three of the sexual species in the genus leading to polyploid individuals The mechanism by which the mixing of chromosomes from two or three species can lead to parthenogenetic reproduction is unknown Recently a hybrid parthenogenetic whiptail lizard was bred in the laboratory from a cross between an asexual and a sexual whiptail 92 Because multiple hybridization events can occur individual parthenogenetic whiptail species can consist of multiple independent asexual lineages Within lineages there is very little genetic diversity but different lineages may have quite different genotypes An interesting aspect to reproduction in these asexual lizards is that mating behaviors are still seen although the populations are all female One female plays the role played by the male in closely related species and mounts the female that is about to lay eggs This behaviour is due to the hormonal cycles of the females which cause them to behave like males shortly after laying eggs when levels of progesterone are high and to take the female role in mating before laying eggs when estrogen dominates Lizards who act out the courtship ritual have greater fecundity than those kept in isolation due to the increase in hormones that accompanies the mounting So although the populations lack males they still require sexual behavioral stimuli for maximum reproductive success 93 Some lizard parthenogens show a pattern of geographic parthenogenesis occupying high mountain areas where their ancestral forms have an inferior competition ability 94 In Caucasian rock lizards of genus Darevskia which have six parthenogenetic forms of hybrid origin 76 77 95 hybrid parthenogenetic form D dahli has a broader niche than either of its bisexual ancestors and its expansion throughout the Central Lesser Caucasus caused decline of the ranges of both its maternal and paternal species 96 Birds Edit Parthenogenesis in birds is known mainly from studies of domesticated turkeys and chickens although it has also been noted in the domestic pigeon 46 In most cases the egg fails to develop normally or completely to hatching 46 97 The first description of parthenogenetic development in a passerine was demonstrated in captive zebra finches although the dividing cells exhibited irregular nuclei and the eggs did not hatch 46 Parthenogenesis in turkeys appears to result from a conversion of haploid cells to diploid 97 most embryos produced in this way die early in development Rarely viable birds result from this process and the rate at which this occurs in turkeys can be increased by selective breeding 98 however male turkeys produced from parthenogenesis exhibit smaller testes and reduced fertility 99 In 2021 the San Diego Zoo reported that they had two unfertilized eggs from their California condor breeding program hatch This is the first known example of parthenogenesis in this species as well as one of the only known examples of parthenogenesis happening where males are still present 10 Mammals Edit There are no known cases of naturally occurring mammalian parthenogenesis in the wild Parthenogenetic progeny of mammals would have two X chromosomes and would therefore be genetically female In 1936 Gregory Goodwin Pincus reported successfully inducing parthenogenesis in a rabbit 100 In April 2004 scientists at Tokyo University of Agriculture used parthenogenesis successfully to create a fatherless mouse Using gene targeting they were able to manipulate two imprinted loci H19 IGF2 and DLK1 MEG3 to produce bi maternal mice at high frequency 101 and subsequently show that fatherless mice have enhanced longevity 102 Induced parthenogenesis in mice and monkeys often results in abnormal development This is because mammals have imprinted genetic regions where either the maternal or the paternal chromosome is inactivated in the offspring in order for development to proceed normally A mammal created by parthenogenesis would have double doses of maternally imprinted genes and lack paternally imprinted genes leading to developmental abnormalities It has been suggested 103 that defects in placental folding or interdigitation are one cause of swine parthenote abortive development As a consequence research on human parthenogenesis is focused on the production of embryonic stem cells for use in medical treatment not as a reproductive strategy However in 2022 researchers reported that they have achieved parthenogenesis in mice for viable offspring born from unfertilized eggs addressing the problems of genomic imprinting by targeted DNA methylation rewriting of seven imprinting control regions 13 Methods Edit This article may be too technical for most readers to understand Please help improve it to make it understandable to non experts without removing the technical details December 2021 Learn how and when to remove this template message Use of an electrical or chemical stimulus can produce the beginning of the process of parthenogenesis in the asexual development of viable offspring 104 Induction of parthenogenesis in swine Parthenogenetic development of swine oocytes 103 High metaphase promoting factor MPF activity causes mammalian oocytes to arrest at the metaphase II stage until fertilization by a sperm The fertilization event causes intracellular calcium oscillations and targeted degradation of cyclin B a regulatory subunit of MPF thus permitting the MII arrested oocyte to proceed through meiosis To initiate parthenogenesis of swine oocytes various methods exist to induce an artificial activation that mimics sperm entry such as calcium ionophore treatment microinjection of calcium ions or electrical stimulation Treatment with cycloheximide a non specific protein synthesis inhibitor enhances parthenote development in swine presumably by continual inhibition of MPF cyclin B 105 As meiosis proceeds extrusion of the second polar is blocked by exposure to cytochalasin B This treatment results in a diploid 2 maternal genomes parthenote Parthenotes can be surgically transferred to a recipient oviduct for further development but will succumb by developmental failure after 30 days of gestation The swine parthenote placentae often appears hypo vascular and is approximately 50 smaller than biparental offspring placentae see free image Figure 1 in linked reference 103 During oocyte development high metaphase promoting factor MPF activity causes mammalian oocytes to arrest at the metaphase II stage until fertilization by a sperm The fertilization event causes intracellular calcium oscillations and targeted degradation of cyclin B a regulatory subunit of MPF thus permitting the MII arrested oocyte to proceed through meiosis To initiate parthenogenesis of swine oocytes various methods exist to induce an artificial activation that mimics sperm entry such as calcium ionophore treatment microinjection of calcium ions or electrical stimulation Treatment with cycloheximide a non specific protein synthesis inhibitor enhances parthenote development in swine presumably by continual inhibition of MPF cyclin B 105 As meiosis proceeds extrusion of the second polar is blocked by exposure to cytochalasin B This treatment results in a diploid 2 maternal genomes parthenote 103 Parthenotes can be surgically transferred to a recipient oviduct for further development but will succumb to developmental failure after 30 days of gestation The swine parthenote placentae often appears hypo vascular see free image Figure 1 in linked reference 103 Humans Edit Reports of human parthenogenesis have famously existed since ancient times featuring prominently in Christianity and various other religions More recently Helen Spurway a geneticist specializing in the reproductive biology of the guppy Lebistes reticulatus claimed in 1955 that parthenogenesis which occurs in the guppy in nature may also occur though very rarely in the human species leading to so called virgin births This created some sensation among her colleagues and the lay public alike 106 Sometimes an embryo may begin to divide without fertilisation but it cannot fully develop on its own so while it may create some skin and nerve cells it cannot create others such as skeletal muscle and becomes a type of benign tumor called an ovarian teratoma 107 Spontaneous ovarian activation is not rare and has been known about since the 19th century Some teratomas can even become primitive fetuses fetiform teratoma with imperfect heads limbs and other structures but are non viable In 1995 there was a reported case of partial human parthenogenesis a boy was found to have some of his cells such as white blood cells to be lacking in any genetic content from his father Scientists believe that an unfertilised egg began to self divide but then had some but not all of its cells fertilised by a sperm cell this must have happened early in development as self activated eggs quickly lose their ability to be fertilised The unfertilised cells eventually duplicated their DNA boosting their chromosomes to 46 When the unfertilised cells hit a developmental block the fertilised cells took over and developed that tissue The boy had asymmetrical facial features and learning difficulties but was otherwise healthy This would make him a parthenogenetic chimera a child with two cell lineages in his body 108 While over a dozen similar cases have been reported since then usually discovered after the patient demonstrated clinical abnormalities there have been no scientifically confirmed reports of a non chimeric clinically healthy human parthenote i e produced from a single parthenogenetic activated oocyte 107 On June 26 2007 the International Stem Cell Corporation ISCC a California based stem cell research company announced that their lead scientist Dr Elena Revazova and her research team were the first to intentionally create human stem cells from unfertilized human eggs using parthenogenesis The process may offer a way for creating stem cells that are genetically matched to a particular female for the treatment of degenerative diseases that might affect her In December 2007 Dr Revazova and ISCC published an article 109 illustrating a breakthrough in the use of parthenogenesis to produce human stem cells that are homozygous in the HLA region of DNA These stem cells are called HLA homozygous parthenogenetic human stem cells hpSC Hhom and have unique characteristics that would allow derivatives of these cells to be implanted into millions of people without immune rejection 110 With proper selection of oocyte donors according to HLA haplotype it is possible to generate a bank of cell lines whose tissue derivatives collectively could be MHC matched with a significant number of individuals within the human population On August 2 2007 after an independent investigation it was revealed that discredited South Korean scientist Hwang Woo Suk unknowingly produced the first human embryos resulting from parthenogenesis Initially Hwang claimed he and his team had extracted stem cells from cloned human embryos a result later found to be fabricated Further examination of the chromosomes of these cells show indicators of parthenogenesis in those extracted stem cells similar to those found in the mice created by Tokyo scientists in 2004 Although Hwang deceived the world about being the first to create artificially cloned human embryos he contributed a major breakthrough to stem cell research by creating human embryos using parthenogenesis 111 The truth was discovered in 2007 long after the embryos were created by him and his team in February 2004 This made Hwang the first unknowingly to successfully perform the process of parthenogenesis to create a human embryo and ultimately a human parthenogenetic stem cell line A US study conducted between 1995 and 2009 found that out of 7 870 young women who participated 45 0 5 reported that they had had a virgin pregnancy and resulting birth The alleged virgin mothers were found to be relatively unlikely to know how to use a condom and 67 8 said they would endorse condom use Additionally they were relatively likely to have pledged chastity and to have had less communication with their parents about sex and birth control 112 Similar phenomena EditGynogenesis Edit See also Gynogenesis and Parthenogenesis in amphibians Gynogenesis A form of asexual reproduction related to parthenogenesis is gynogenesis Here offspring are produced by the same mechanism as in parthenogenesis but with the requirement that the egg merely be stimulated by the presence of sperm in order to develop However the sperm cell does not contribute any genetic material to the offspring Since gynogenetic species are all female activation of their eggs requires mating with males of a closely related species for the needed stimulus Some salamanders of the genus Ambystoma are gynogenetic and appear to have been so for over a million years It is believed by whom that the success of those salamanders may be due to rare fertilization of eggs by males introducing new material to the gene pool which may result from perhaps only one mating out of a million In addition the amazon molly is known to reproduce by gynogenesis 113 Hybridogenesis Edit See also Hybridogenesis in water frogs Hybridogenesis is a mode of reproduction of hybrids Hybridogenetic hybrids for example AB genome usually females during gametogenesis exclude one of parental genomes A and produce gametes with unrecombined 114 genome of second parental species B instead of containing mixed recombined parental genomes First genome A is restored by fertilization of these gametes with gametes from the first species AA sexual host 114 usually male 114 115 116 So hybridogenesis is not completely asexual but instead hemiclonal half of genome is passed to the next generation clonally unrecombined intact B other half sexually recombined A 114 117 This process continues so that each generation is half or hemi clonal on the mother s side and has half new genetic material from the father s side This form of reproduction is seen in some live bearing fish of the genus Poeciliopsis 115 118 as well as in some of the Pelophylax spp green frogs or waterfrogs P kl esculentus edible frog P lessonae P ridibundus 114 119 120 P kl grafi Graf s hybrid frog P perezi P ridibundus 114 P kl hispanicus Italian edible frog unknown origin P bergeri P ridibundus or P kl esculentus 114 and perhaps in P demarchii Example crosses between pool frog Pelophylax lessonae marsh frog P ridibundus and their hybrid edible frog P kl esculentus First one is the primary hybridisation generating hybrid second one is most widespread type of hybridogenesis 114 121 Other examples where hybridogenesis is at least one of modes of reproduction include i e Iberian minnow Tropidophoxinellus alburnoides Squalius pyrenaicus hypothetical ancestor related with Anaecypris hispanica 122 spined loaches Cobitis hankugensis C longicorpus 123 Bacillus stick insects B rossius Bacillus grandii benazzii 124 See also EditAndrogenesis a form of quasi sexual reproduction in which a male is the sole source of the nuclear genetic material in the embryo Charles Bonnet Genevan botanist 1720 1793 conducted experiments that established what is now termed parthenogenesis in aphids Jan Dzierzon Polish apiarist and a pioneer of parthenogenesis among bees Jacques Loeb caused the eggs of sea urchins to begin embryonic development without sperm Miraculous births Conceptions and births by miraculous circumstances Parthenocarpy Production of fruit without fertilisation which makes the fruit seedless plants with seedless fruitReferences Edit parthenogenesis Merriam Webster Dictionary parthenogenesis definition of parthenogenesis in English from the Oxford dictionary OxfordDictionaries com Archived from the original on 2012 09 12 Retrieved 2016 01 20 Liddell Scott Jones genesis A II A Greek English Lexicon Oxford Clarendon Press 1940 q v a b Heesch Svenja Serrano Serrano Martha Barrera Redondo Josue Luthringer Remy Peters Akira F Destombe Christophe Cock J Mark Valero Myriam Roze Denis Salamin Nicolas Coelho Susana M July 2021 Evolution of life cycles and reproductive traits Insights from the brown algae Journal of 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Pelophylax esculentus complex Biological Invasions 12 1 13 doi 10 1007 s10530 009 9427 2 ISSN 1387 3547 S2CID 23535815 a b Schultz R Jack November December 1969 Hybridization unisexuality and polyploidy in the teleost Poeciliopsis Poeciliidae and other vertebrates The American Naturalist 103 934 605 619 doi 10 1086 282629 JSTOR 2459036 S2CID 84812427 Vrijenhoek Robert C 1998 Parthenogenesis and Natural Clones PDF In Knobil Ernst Neill Jimmy D eds Encyclopedia of Reproduction Vol 3 Academic Press pp 695 702 ISBN 978 0 12 227020 8 Simon J C Delmotte F Rispe C Crease T 2003 Phylogenetic relationships between parthenogens and their sexual relatives the possible routes to parthenogenesis in animals PDF Biological Journal of the Linnean Society 79 151 163 doi 10 1046 j 1095 8312 2003 00175 x Retrieved 2015 06 21 Vrijenhoek J M J C Avise R C Vrijenhoek January 1 1992 An Ancient Clonal Lineage in the Fish Genus Poeciliopsis Atheriniformes Poeciliidae Proceedings of the National Academy of Sciences USA 89 1 348 352 Bibcode 1992PNAS 89 348Q doi 10 1073 pnas 89 1 348 ISSN 0027 8424 PMC 48234 PMID 11607248 Hybridogenesis in Water Frogs tolweb org Beukeboom L W R C Vrijenhoek 1998 Evolutionary genetics and ecology of sperm dependent parthenogenesis Journal of Evolutionary Biology 11 6 755 782 doi 10 1046 j 1420 9101 1998 11060755 x ISSN 1420 9101 S2CID 85833296 Vorburger Christoph Reyer Heinz Ulrich 2003 A genetic mechanism of species replacement in European waterfrogs PDF Conservation Genetics 4 2 141 155 doi 10 1023 A 1023346824722 ISSN 1566 0621 S2CID 20453910 Retrieved 2015 06 21 Inacio A Pinho J Pereira PM Comai L Coelho MM 2012 Global Analysis of the Small RNA Transcriptome in Different Ploidies and Genomic Combinations of a Vertebrate Complex The Squalius alburnoides PLOS ONE 7 7 e41158 359 368 Bibcode 2012PLoSO 741158I doi 10 1371 journal pone 0041158 PMC 3399795 PMID 22815952 Saitoh K Kim I S Lee E H 2004 Mitochondrial gene introgression between spined loaches via hybridogenesis Zoological Science 21 7 795 798 doi 10 2108 zsj 21 795 PMID 15277723 S2CID 40846660 Mantovani Barbara Scali Valerio 1992 Hybridogenesis and androgenesis in the stick insect Bacillus rossius Grandii benazzii Insecta Phasmatodea Evolution 46 3 783 796 doi 10 2307 2409646 JSTOR 2409646 PMID 28568678 Further reading EditDawley Robert M amp Bogart James P 1989 Evolution and Ecology of Unisexual Vertebrates Albany New York State Museum ISBN 1 55557 179 4 Fangerau H 2005 Can artificial parthenogenesis sidestep ethical pitfalls in human therapeutic cloning An historical perspective Journal of Medical Ethics 31 12 733 735 doi 10 1136 jme 2004 010199 PMC 1734065 PMID 16319240 Futuyma Douglas J amp Slatkin Montgomery 1983 Coevolution Sunderland Mass Sinauer Associates ISBN 0 87893 228 3 Hore T Rapkins R Graves J 2007 Construction and evolution of imprinted loci in mammals Trends in Genetics 23 9 440 448 doi 10 1016 j tig 2007 07 003 PMID 17683825 Kono T Obata Y Wu Q Niwa K Ono Y Yamamoto Y Park E S Seo J S Ogawa H 2004 Birth of parthenogenetic mice that can develop to adulthood Nature 428 6985 860 864 Bibcode 2004Natur 428 860K doi 10 1038 nature02402 PMID 15103378 S2CID 4353479 Maynard Smith John 1978 The Evolution of Sex Cambridge Cambridge University Press ISBN 0 521 29302 2 Michod Richard E amp Levin Bruce R 1988 The Evolution of Sex Sunderland Mass Sinauer Associates ISBN 0 87893 459 6 Schlupp Ingo 2005 The Evolutionary Ecology of Gynogenesis Annual Review of Ecology Evolution and Systematics 36 399 417 doi 10 1146 annurev ecolsys 36 102003 152629 Simon J Rispe Claude Sunnucks Paul 2002 Ecology and evolution of sex in aphids Trends in Ecology amp Evolution 17 34 39 doi 10 1016 S0169 5347 01 02331 X Stearns Stephan C 1988 The Evolution of Sex and Its Consequences Experientia Supplementum Vol 55 Boston Birkhauser ISBN 0 8176 1807 4 External links EditReproductive behavior in whiptails at Crews Laboratory Types of asexual reproduction Parthenogenesis in Incubated Turkey Eggs from Oregon State University National Geographic News Virgin Birth Expected at Christmas By Komodo Dragon BBC News Virgin births for giant lizards Komodo dragon Reuther Komodo dragon proud mum and dad of five Female sharks capable of virgin birth Scientists confirm shark s virgin birth Article by Steve Szkotak AP updated 1 49 a m ET Fri Oct 10 2008 Retrieved from https en wikipedia org w index php title Parthenogenesis amp oldid 1130679805, wikipedia, wiki, book, books, library,

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