The rate of facultative sex governs the number of expected mating types in isogamous species
It is unclear why sexually reproducing isogamous species frequently contain just two self-incompatible mating types. Deterministic theory suggests that since rare novel mating types experience a selective advantage (by virtue of their many potential partners), the number of mating types should consi...
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| Veröffentlicht in: | Nature ecology & evolution 2018-07, Vol.2 (7), p.1168-1175 |
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| creator | Constable, George W. A. Kokko, Hanna |
| description | It is unclear why sexually reproducing isogamous species frequently contain just two self-incompatible mating types. Deterministic theory suggests that since rare novel mating types experience a selective advantage (by virtue of their many potential partners), the number of mating types should consistently grow. However, in nature, species with thousands of mating types are exceedingly rare. Several competing theories for the predominance of species with two mating types exist, yet they lack an explanation for how many are possible and in which species to expect high numbers. Here, we present a theoretical null model that explains the distribution of mating type numbers using just three biological parameters: mutation rate, population size and the rate of sex. If the number of mating types results from a mutation–extinction balance, the rate of sexual reproduction plays a crucial role. If sex is facultative and rare (a very common combination in isogamous species), mating type diversity will remain low. In this rare sex regime, small fitness differences between the mating types lead to more frequent extinctions, further lowering mating type diversity. We also show that the empirical literature supports the role of drift and facultativeness of sex as a determinant of mating type dynamics.
While most sexually reproducing organisms with gametes of similar morphology have two mating types, some species have many. Here, the authors use a theoretical model to show that the distribution of mating type numbers can be explained by mutation rate, population size and the rate of sex. |
| doi_str_mv | 10.1038/s41559-018-0580-9 |
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While most sexually reproducing organisms with gametes of similar morphology have two mating types, some species have many. 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A.</au><au>Kokko, Hanna</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The rate of facultative sex governs the number of expected mating types in isogamous species</atitle><jtitle>Nature ecology & evolution</jtitle><stitle>Nat Ecol Evol</stitle><addtitle>Nat Ecol Evol</addtitle><date>2018-07-01</date><risdate>2018</risdate><volume>2</volume><issue>7</issue><spage>1168</spage><epage>1175</epage><pages>1168-1175</pages><issn>2397-334X</issn><eissn>2397-334X</eissn><abstract>It is unclear why sexually reproducing isogamous species frequently contain just two self-incompatible mating types. Deterministic theory suggests that since rare novel mating types experience a selective advantage (by virtue of their many potential partners), the number of mating types should consistently grow. However, in nature, species with thousands of mating types are exceedingly rare. Several competing theories for the predominance of species with two mating types exist, yet they lack an explanation for how many are possible and in which species to expect high numbers. Here, we present a theoretical null model that explains the distribution of mating type numbers using just three biological parameters: mutation rate, population size and the rate of sex. If the number of mating types results from a mutation–extinction balance, the rate of sexual reproduction plays a crucial role. If sex is facultative and rare (a very common combination in isogamous species), mating type diversity will remain low. In this rare sex regime, small fitness differences between the mating types lead to more frequent extinctions, further lowering mating type diversity. We also show that the empirical literature supports the role of drift and facultativeness of sex as a determinant of mating type dynamics.
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| subjects | 631/158/1745 631/181 631/181/2470 631/208/457 Biological and Physical Anthropology Biomedical and Life Sciences Ecology Evolutionary Biology Gametes Life Sciences Mating Mating types Morphology Mutation Mutation rates Paleontology Population number Reproduction (biology) Sex Sexual reproduction Species Species diversity Species extinction Zoology |
| title | The rate of facultative sex governs the number of expected mating types in isogamous species |
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