Biology:Androdioecy

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Short description: Presence of males and hermaphrodites in a population

Androdioecy is a reproductive system characterized by the coexistence of males and hermaphrodites. Androdioecy is rare in comparison with the other major reproductive systems: dioecy, gynodioecy and hermaphroditism.[1] In animals, androdioecy has been considered a stepping stone in the transition from dioecy to hermaphroditism, and vice versa.[2]

Androdioecy is sometimes referred to as a mixed breeding system with trioecy and gynodioecy.[3] It is a dimorphic sexual system in plants comparable with gynodioecy and dioecy.[4]

Evolution of androdioecy

The fitness requirements for androdioecy to arise and sustain itself are theoretically so improbable that it was long considered that such systems do not exist.[5][6] Particularly, males and hermaphrodites have to have the same fitness, in other words the same number of offspring, in order to be maintained. However, males only have offspring by fertilizing eggs or ovules of hermaphrodites, while hermaphrodites have offspring both through fertilizing eggs or ovules of other hermaphrodites and their own ovules. This means that all else being equal, males have to fertilize twice as many eggs or ovules as hermaphrodites to make up for the lack of female reproduction.[7][8]

Androdioecy can evolve either from hermaphroditic ancestors through the invasion of males or from dioecious ancestors through the invasion of hermaphrodites. The ancestral state is important because conditions under which androdioecy can evolve differ significantly.[citation needed]

Androdioecy with dioecious ancestry

In roundworms, clam shrimp, tadpole shrimp and cancrid shrimps, androdioecy has evolved from dioecy. In these systems, hermaphrodites can only fertilize their own eggs (self-fertilize) and do not mate with other hermaphrodites. Males are the only means of outcrossing. Hermaphrodites may be beneficial in colonizing new habitats, because a single hermaphrodite can generate many other individuals.[9]

In the well-studied roundworm Caenorhabditis elegans, males are very rare and only occur in populations that are in bad condition or stressed.[10] In Caenorhabditis elegans androdioecy is thought to have evolved from dioecy, through a trioecous intermediate.[11]

Androdioecy with hermaphroditic ancestry

In barnacles, androdioecy evolved from hermaphroditism.[3] Many plants self-fertilize, and males may be sustained in a population when inbreeding depression is severe because males guarantee outcrossing.[citation needed]

Types of androdioecy

The most common form of androdioecy in animals involves hermaphrodites that can reproduce by autogamy or allogamy through ovum with males. However, this type does not involve outcrossing with sperm. This type of androdioecy generally occurs in predominantly gonochoric taxonomy groups.[12](p21)

One type of androdioecy contains outcrossing hermaphrodites which is present in some angiosperms.[12](p21)

Another type of androdioecy has males and simultaneous hermaphrodites in a population due to developmental or conditional sex allocation. Like in some fish species small individuals are hermaphrodites and under circumstances of high density, large individuals become male.[12](p21)

Androdioecious species

Despite their unlikely evolution, 115 androdioecious animal and about 50 androdioecious plant species are known.[2][13] These species include

Anthozoa (Corals)

Nematoda (Roundworms)

Rhabditidae (Order Rhabditida)

Diplogastridae (Order Rhabditida)

Steinernematidae (Order Rhabditida)

  • Steinernema hermaphroditum

Allanotnematidae (Order Rhabditida)

Dorylaimida

  • Dorylaimus liratus

Nemertea (Ribbon worms)

Arthropoda

Clam shrimp

  • Eulimnadia texana[22]
  • Eulimnadia africana
  • Eulimnadia agassizii
  • Eulimnadia antlei
  • Eulimnadia braueriana
  • Eulimnadia brasiliensis
  • Eulimnadia colombiensis
  • Eulimnadia cylondrova
  • Eulimnadia dahli
  • Eulimnadia diversa
  • Eulimnadia feriensis
  • Eulimnadia follisimilis
  • Eulimnadia thompsoni
  • Eulimnadia sp. A
  • Eulimnadia sp. B
  • Eulimnadia sp. C

Tadpole shrimp

Barnacles

  • Paralepas klepalae
  • Paralepas xenophorae
  • Koleolepas avis
  • Koleolepas tinkeri
  • Ibla quadrivalvis
  • Ibla cumingii
  • Ibla idiotica
  • Ibla segmentata
  • Calantica studeri
  • Calantica siemensi
  • Calantica spinosa
  • Calantica villosa
  • Arcoscalpellum sp.
  • Euscalpellum squamuliferum
  • Scalpellum peronii
  • Scalpellum scalpellum
  • Scalpellum vulgare
  • Scillaelepas arnaudi
  • Scillaelepas bocquetae
  • Scillaelepas calyculacilla
  • Scillaelepas falcate
  • Scillaelepas fosteri
  • Smilium hastatum
  • Smilium peronii
  • Chelonibia patula[24]
  • Chelonibia testudinaria[25]
  • Bathylasma alearum[26]
  • Bathylasma corolliforme
  • Conopea galeata[27]
  • Conopea calceola[27]
  • Conopea merrilli[27]
  • Solidobalanus masignotus[28]
  • Tetrapachylasma trigonum
  • Megalasma striatum
  • Octolasmis warwickii[29]

Lysmata

Insects

Annelida (Ringed worms)

  • Salvatoria clavata
  • Ophryotrocha gracilis
  • Ophryotrocha hartmanni
  • Ophryotrocha diadema
  • Ophryotrocha bacci
  • Ophryotrocha maculata
  • Ophryotrocha socialis

Chordata

Angiosperms (Flowering plants)

See also

References

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  2. 2.0 2.1 Weeks, SC (2012). "The role of androdioecy and gynodioecy in mediating evolutionary transitions between dioecy and hermaphroditism in the Animalia". Evolution 66 (12): 3670–3686. doi:10.1111/j.1558-5646.2012.01714.x. PMID 23206127. 
  3. 3.0 3.1 Fusco, Giuseppe; Minelli, Alessandro (2019-10-10) (in en). The Biology of Reproduction. Cambridge University Press. pp. 134. ISBN 978-1-108-49985-9. https://books.google.com/books?id=AKGsDwAAQBAJ&q=Caenorhabditis+elegans+gonochoric. 
  4. Torices, Rubén; Méndez, Marcos; Gómez, José María (2011). "Where do monomorphic sexual systems fit in the evolution of dioecy? Insights from the largest family of angiosperms" (in en). New Phytologist 190 (1): 234–248. doi:10.1111/j.1469-8137.2010.03609.x. ISSN 1469-8137. PMID 21219336. 
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  6. Darwin C. 1877. The different forms of flowers and plants of the same species. New York: Appleton.
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  9. Pannell, J (2000). "A hypothesis for the evolution of androdioecy: the joint influence of reproductive assurance and local mate competition in a metapopulation". Evolutionary Ecology 14 (3): 195–211. doi:10.1023/A:1011082827809. 
  10. 10.0 10.1 Stewart, AD; Phillips, PC (2002). "Selection and maintenance of androdioecy in Caenorhabditis elegans". Genetics 160 (3): 975–982. doi:10.1093/genetics/160.3.975. PMID 11901115. 
  11. Kanzaki, Natsumi; Kiontke, Karin; Tanaka, Ryusei; Hirooka, Yuuri; Schwarz, Anna; Müller-Reichert, Thomas; Chaudhuri, Jyotiska; Pires-daSilva, Andre (2017-09-11). "Description of two three-gendered nematode species in the new genus Auanema (Rhabditina) that are models for reproductive mode evolution" (in en). Scientific Reports 7 (1): 11135. doi:10.1038/s41598-017-09871-1. ISSN 2045-2322. PMID 28894108. Bibcode2017NatSR...711135K. 
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  13. Weeks, SC; Benvenuto, C; Reed, SK (2006). "When males and hermaphrodites coexist: a review of androdioecy in animals". Integrative and Comparative Biology 46 (4): 449–464. doi:10.1093/icb/icj048. PMID 21672757. 
  14. Fürst von Lieven A (2008). "Koerneria sudhausi n. sp. (Nematoda: Diplogastridae); a hermaphroditic diplogastrid with an egg shell formed by zygote and uterine components". Nematology 10 (1): 27–45. doi:10.1163/156854108783360087. 
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  21. 21.0 21.1 "Sudhausia aristotokia n. gen., n. sp. and S. crassa n. gen., n. sp. (Nematoda: Diplogastridae): viviparous new species with precocious gonad development". Nematology 15 (8): 1001–1020. 2013. doi:10.1163/15685411-00002738. 
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