Hermaphrodite Explained

A hermaphrodite is a sexually reproducing organism that produces both male and female gametes.[1] Animal species in which individuals are either male or female are gonochoric, which is the opposite of hermaphroditic.[2]

The individuals of many taxonomic groups of animals, primarily invertebrates, are hermaphrodites, capable of producing viable gametes of both sexes. In the great majority of tunicates, mollusks, and earthworms, hermaphroditism is a normal condition, enabling a form of sexual reproduction in which either partner can act as the female or male. Hermaphroditism is also found in some fish species, but is rare in other vertebrate groups. Most hermaphroditic species exhibit some degree of self-fertilization. The distribution of self-fertilization rates among animals is similar to that of plants, suggesting that similar pressures are operating to direct the evolution of selfing in animals and plants.[3]

A rough estimate of the number of hermaphroditic animal species is 65,000, about 5% of all animal species, or 33% excluding insects. Insects are almost exclusively gonochoric, and no definitive cases of hermaphroditism have been demonstrated in this group.[4] There are no known hermaphroditic species among mammals[5] or birds.[6]

About 94% of flowering plant species are either hermaphroditic (all flowers produce both male and female gametes) or monoecious, where both male and female flowers occur on the same plant. There are also mixed breeding systems, in both plants and animals, where hermaphrodite individuals coexist with males (called androdioecy) or with females (called gynodioecy), or all three exist in the same species (called trioecy). Sometimes, both male and hermaphrodite flowers occur on the same plant (andromonoecy) or both female and hermaphrodite flowers occur on the same plant (gynomonoecy).

Hermaphrodism is not to be confused with ovotesticular syndrome in mammals, which is a separate and unrelated phenomenon. While people with the condition were previously called "true hermaphrodites" in medical literature, this usage is now considered to be outdated as of 2006 and misleading,[7] [8] as people with ovotesticular syndrome do not have functional sets of both male and female organs.[9]

Etymology

The term hermaphrodite derives from the Latin: hermaphroditus, from Greek, Ancient (to 1453);: ἑρμαφρόδιτος|hermaphroditos,[10] which derives from Hermaphroditus (Ἑρμαφρόδιτος), the son of Hermes and Aphrodite in Greek mythology. According to Ovid, he fused with the nymph Salmacis resulting in one individual possessing physical traits of male and female sexes.[11] According to the earlier Diodorus Siculus, he was born with a physical body combining male and female sexes.[12] The word hermaphrodite entered the English lexicon as early as the late fourteenth century.[13]

Animals

Sequential hermaphrodites

See main article: Sequential hermaphroditism.

Sequential hermaphrodites (dichogamy) occur in species in which the individual first develops as one sex, but can later change into the opposite sex.[14] (Definitions differ on whether sequential hermaphroditism encompasses serial hermaphroditism; for authors who exclude serial hermaphroditism, a sequential hermaphrodite is also stipulated to only change sex once.[15]) This contrasts with simultaneous hermaphrodites, in which an individual possesses fully functional male and female genitalia. Sequential hermaphroditism is common in fish (particularly teleost fish) and many gastropods (such as the common slipper shell). Sequential hermaphroditism can best be understood in terms of behavioral ecology and evolutionary life history theory, as described in the size-advantage mode[16] first proposed by Michael T. Ghiselin[17] which states that if an individual of a certain sex could significantly increase its reproductive success after reaching a certain size, it would be to their advantage to switch to that sex.

Sequential hermaphrodites can be divided into three broad categories:

Dichogamy can have both conservation-related implications for humans, as mentioned above, as well as economic implications. For instance, groupers are favoured fish for eating in many Asian countries and are often aquacultured. Since the adults take several years to change from female to male, the broodstock are extremely valuable individuals.

Simultaneous hermaphrodites

Simultaneous hermaphrodites (or homogamous hermaphrodites) are individuals in which both male and female sexual organs are present and functional at the same time.[14] Self-fertilization often occurs.

Pseudohermaphroditism

See main article: Pseudohermaphroditism.

When spotted hyenas were first scientifically observed by explorers, they were thought to be hermaphrodites. Early observations of wild spotted hyenas led researchers to believe that all spotted hyenas, male or female, were born with what looked to be a penis. A female spotted hyena's apparent penis is in fact an enlarged clitoris, which contains an external birth canal.[28] [29] It can be difficult to determine the sex of spotted hyenas until sexual maturity, when they may become pregnant. When a female spotted hyena gives birth, she passes the cub through the cervix internally, but then passes it out through the elongated clitoris.[30]

Plants

See main article: Sexual reproduction in plants and Monoicy.

The term hermaphrodite is used in botany to describe, for example, a perfect flower that has both staminate (male, pollen-producing) and carpellate (female, ovule-producing) parts. The overwhelming majority of flowering plant species are hermaphroditic.[31]

Monoecy

Flowering plant species with separate, imperfect, male and female flowers on the same individual are called monoecious. Monoecy only occurs in about 7% of flowering plant species.[32] Monoecious plants are often referred to as hermaphroditic because they produce both male and female gametes. However, the individual flowers are not hermaphroditic if they only produce gametes of one sex.[33] 65% of gymnosperm species are dioecious, but conifers are almost all monoecious.[34] Some plants can change their sex throughout their lifetime, a phenomenon called sequential hermaphroditism.

Andromonoecy

In andromonoecious species, the plants produce perfect (hermaphrodite) flowers and separate fertile male flowers that are sterile as female.[35] [36] Andromonoecy occurs in about 4000 species of flowering plants (2% of flowering plants).[37]

Gynomonoecy

In gynomonoecious species, the plants produce hermaphrodite flowers and separate male-sterile pistillate flowers.[35] One example is the meadow saxifrage, Saxifraga granulata.[38] Charles Darwin gave several other examples in his 1877 book "The Different Forms of Flowers on Plants of the Same Species".[39]

About 57% of moss species and 68% of liverworts are unisexual, meaning that their gametophytes produce either male or female gametes, but not both.[40]

Sequential hermaphroditism is common in bryophytes and some vascular plants.

Use regarding humans

See main article: Disorders of sex development and Intersex.

Historically, the term hermaphrodite was used in law to refer to people whose sex was in doubt. The 12th-century Latin: [[Decretum Gratiani]] states that "Whether an hermaphrodite may witness a testament, depends on which sex prevails" ("Hermafroditus an ad testamentum adhiberi possit, qualitas sexus incalescentis ostendit.").[41] [42]

Alexander ab Alexandro (1461–1523) stated, using the term hermaphrodite, that the people who bore the sexes of both man and woman were regarded by the Athenians and the Romans as monsters, and thrown into the sea at Athens and into the Tiber at Rome.[43] Similarly, the 17th-century English jurist and judge Edward Coke (Lord Coke), wrote in his Institutes of the Lawes of England on laws of succession stating, "Every heire is either a male, a female, or an hermaphrodite, that is both male and female. And an hermaphrodite (which is also called Androgynus) shall be heire, either as male or female, according to that kind of sexe which doth prevaile."[44] [45]

During the Victorian era, medical authors attempted to ascertain whether or not humans could be hermaphrodites, adopting a precise biological definition to the term.[46] From that period until the early 21st century, individuals with ovotesticular syndrome were termed true hermaphrodites if their gonadal tissue contained both testicular and ovarian tissue, and pseudohermaphrodites if their external appearance (phenotype) differed from sex expected from internal gonads. This language has fallen out of favor due to misconceptions and stigma associated with the terms,[47] [48] and also a shift to nomenclature based on genetics.

The term "intersex" described a wide variety of combinations of what are ambiguous biological characteristics. Intersex biology may include, for example, ambiguous-looking external genitalia, karyotypes that include mixed XX and XY chromosome pairs (46XX/46XY, 46XX/47XXY or 45X/XY mosaic). Clinically, medicine currently uses the terminology "disorders of sex development" [49] (also known as variations in sex characteristics.)[50] This is particularly significant because of the relationship between medical terminology and medical intervention.

Intersex civil society organizations, and many human rights institutions, have criticized medical interventions designed to make bodies more typically male or female.

In some cases, variations in sex characteristics are caused by unusual levels of sex hormones, which may be the result of an atypical set of sex chromosomes. One common cause of variations in sex characteristics traits is the crossing over of the testis-determining factor (SRY) from the Y chromosome to the X chromosome during meiosis. The SRY is then activated in only certain areas, causing development of testes in some areas by beginning a series of events starting with the upregulation of the transcription factor (SOX9), and in other areas not being active (causing the growth of ovarian tissues). Thus, testicular and ovarian tissues will both be present in the same individual.[51] Though of all total recorded cases of ovotesticular DSD, in only 8% percent of all cases was SRY present, leaving the rest of cases that could be explained to other or less common causes, with the vast majority simply being currently unexplainable.

Fetuses were previously thought to be phenotypically female before the sexual differentiation stage;[52] however, this is now known to be incorrect, as humans are simply undifferentiated before this stage and possess a paramesonephric duct, a mesonephric duct, and a genital tubercle.[53] [54]

Evolution

The evolution of anisogamy may have contributed to the evolution of simultaneous hermaphroditism and sequential hermaphroditism,[55] it remains unclear if the evolution of anisogamy first led to hermaphroditism or gonochorism.[56]

A 2023 study argued that hermaphroditism can evolve directly from mating types under certain circumstances, such as if the fertilization is well organized and the average size of groups is small.[57] Simultaneous hermaphroditism that exclusively reproduces through self-fertilization has evolved many times in plants and animals, but it might not last long evolutionarily.[58]

In animals

Joan Roughgarden and Priya Iyer argued that the last common ancestor for animals was hermaphroditic and that transitions from hermaphroditism to gonochorism were more numerous than the reverse. Other scientists have criticized this argument; saying it’s based on paraphyletic Spiralia, assignments of sexual modes for the phylum level than the species level, and methods exclusively based on maximum parsimony.[59]

Hermaphroditism is polyphyletic in invertebrates where it evolved from gonochorism[1] and gonochorism is also ancestral to hermaphroditic fishes.[60] According to Nelson Çabej simultaneous hermaphroditism in animals most likely evolved due to a limited number of mating partners.[61]

In plants

It is widely accepted that the first vascular plants were outcrossing hermaphrodites.[62] In flowering plants, hermaphroditism is ancestral to dioecy.[63]

Hermaphroditism in plants may promote self fertilization in pioneer populations.[64] However, plants have evolved multiple different mechanisms to avoid self-fertilization in hermaphrodites, including sequential hermaphroditism, molecular recognition systems and mechanical or morphological mechanisms such as heterostyly.[65]

See also

Further reading

External links

Notes and References

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  2. Book: Encyclopedia of Animal Cognition and Behavior. Holub AM, Shackelford TK. 2020. Springer International Publishing. 978-3-319-47829-6. Vonk J, Shackelford TK. Cham. 1–3. en. Gonochorism. 10.1007/978-3-319-47829-6_305-1. 240938739. Todd K. Shackelford.
  3. Jarne P, Auld JR . Animals mix it up too: the distribution of self-fertilization among hermaphroditic animals . Evolution; International Journal of Organic Evolution . 60 . 9 . 1816–24 . September 2006 . 17089966 . 10.1554/06-246.1 . 23849389 .
  4. Book: Royer M . Hermaphroditism in Insects. Studies on Icerya purchasi . 1975 . Reinboth R . Intersexuality in the Animal Kingdom . 135–145 . Springer . Berlin, Heidelberg . 10.1007/978-3-642-66069-6_14 . 978-3-642-66071-9 .
  5. Book: Gorshkov V . Physical and Biological Bases of Life Stability: Man, Biota, Environment. 2012-12-06. Springer Science & Business Media. 978-3-642-85001-1. en.
  6. Schärer L. February 2017. The varied ways of being male and female. Molecular Reproduction and Development. 84. 2. 94–104. 10.1002/mrd.22775. 28032683. Of note, the otherwise well-studied insects, birds, and mammals are strikingly absent here—with not a single species among these groups showing hermaphroditism (for details on a supposedly hermaphroditic scale insect, however, see Gardner and Ross, 2011).. free.
  7. Web site: Herndon A . Getting Rid of "Hermaphroditism" Once and For All. live. https://web.archive.org/web/20110927013509/http://www.isna.org/node/979. 27 September 2011. 2 October 2011. Intersex Society of North America.
  8. Web site: Is a person who is intersex a hermaphrodite? . 2024-01-20 . Intersex Society of North America . The mythological term “hermaphrodite” implies that a person is both fully male and fully female. This is a physiologic impossibility. The words “hermaphrodite” and “pseudo-hermaphrodite” are stigmatizing and misleading words..
  9. Book: Biology of Sex . Mills A . 2018-01-01 . University of Toronto Press . 978-1-4875-9337-7 . 309 . en . In the past, the term hermaphrodite was widely applied in such cases, but humans are not hermaphroditic. In a truly hermaphroditic species, individuals have functional sets of male and female organs..
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