Sex increases the efficacy of natural selection in experimental yeast populations

Goddard, Matthew R.; Godfray, H. C. J.; Burt, Austin

doi:10.1038/nature03405

Cited by 412 publications

(379 citation statements)

References 22 publications

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“…Sexual reproduction with some outcrossing maintains cohesion within species, whereas reproductive isolation leads to the formation of new species (Coyne & Orr 1998). Recombination has been shown to facilitate more rapid adaptation than clonality (Goddard et al 2005) and recombining organisms may show larger and more phenotypic differences among species. These effects may increase the chance that newly diverged species will have adapted to different niches and be able to coexist, provided that they are reproductively isolated in sympatry (Felsenstein 1981;Barraclough et al 2003).…”

Section: The Fungi a Kingdom Of Microbial Eukaryotesmentioning

confidence: 99%

“…Recently, Barraclough et al (2003) considered theoretical aspects of speciation by organisms that can recombine or that are strictly clonal to see if there were any fundamental differences. They conclude that both clonal and recombining organisms will form species, but that recombining organisms may form them faster because they respond more rapidly to selection (Goddard et al 2005). Barraclough et al (2003) note that speciation involves not only divergence, but also maintenance, particularly when newly derived species coexist.…”

Section: The Fungi a Kingdom Of Microbial Eukaryotesmentioning

confidence: 99%

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Eukaryotic microbes, species recognition and the geographic limits of species: examples from the kingdom Fungi

Taylor

Turner

Townsend

et al. 2006

Phil. Trans. R. Soc. B

304

249

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The claim that eukaryotic micro-organisms have global geographic ranges, constituting a significant departure from the situation with macro-organisms, has been supported by studies of morphological species from protistan kingdoms. Here, we examine this claim by reviewing examples from another kingdom of eukaryotic microbes, the Fungi. We show that inferred geographic range of a fungal species depends upon the method of species recognition. While some fungal species defined by morphology show global geographic ranges, when fungal species are defined by phylogenetic species recognition they are typically shown to harbour several to many endemic species. We advance two non-exclusive reasons to explain the perceived difference between the size of geographic ranges of microscopic and macroscopic eukaryotic species when morphological methods of species recognition are used. These reasons are that microbial organisms generally have fewer morphological characters, and that the rate of morphological change will be slower for organisms with less elaborate development and fewer cells. Both of these reasons result in fewer discriminatory morphological differences between recently diverged lineages. The rate of genetic change, moreover, is similar for both large and small organisms, which helps to explain why phylogenetic species of large and small organisms show a more similar distribution of geographic ranges. As a consequence of the different rates in fungi of genetic and morphological changes, genetic isolation precedes a recognizable morphological change. The final step in speciation, reproductive isolation, also follows genetic isolation and may precede morphological change.

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Section: The Fungi a Kingdom Of Microbial Eukaryotesmentioning

confidence: 99%

Section: The Fungi a Kingdom Of Microbial Eukaryotesmentioning

confidence: 99%

Eukaryotic microbes, species recognition and the geographic limits of species: examples from the kingdom Fungi

Taylor

Turner

Townsend

et al. 2006

Phil. Trans. R. Soc. B

304

249

View full text Add to dashboard Cite

show abstract

“…One of the earliest clues was the delineation, within just hours of the mainshock,of a band of large aftershocks arcing 1,300 km from northern Sumatra almost as far as Myanmar (Burma) 1 . This seemed to signal that about 25% of the Sunda megathrust, the great tectonic boundary along which the Australian and Indian plates begin their descent beneath Southeast Asia, had ruptured.…”

Section: Kerry Siehmentioning

confidence: 99%

What happened and what's next?

Sieh

2005

Nature

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“…A series of experimental evolution studies support the idea that sex speeds adaptive evolution [6][7][8] . However, much less work has focused on the molecular mechanisms underpinning this advantage.…”

mentioning

confidence: 93%

Sex accelerates adaptation

Goddard

2016

Nature

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Compared to the asexual alternative of simple cloning, sex seems like a complicated way of reproducing. Fast and efficient reproduction is at the heart of Darwinian natural selection, so why sex exists is a conundrum that has fascinated biologists for more than 100 years 1 . In a paper online in Nature, McDonald et al. 2 directly confirm the long-held theory that the advantage of sex lies in its ability to expose individual mutations to the actions of natural selection.Sex involves the shuffling (recombination) of chromosomes from different parents, followed by the separation of these newly-shuffled chromosomes into reproductive gametes, which then fuse through mating. As well as being more complicated than asexual reproduction, sex also risks breaking apart collections of genes that have proven effective. In animals, sex means that fewer offspring are produced as only females give birth, and mate finding and courtship impose further uncertainties. Given these disadvantages, it is not immediately clear why sexual reproduction is maintained.Mutations accrue in organisms' genomes over time, and some affect ability to reproduce and compete for resources (fitness). The net fitness of an individual is the sum of these various accrued mutations. In asexually reproducing populations classic theories 3,4 suggest selection only ever 'sees' this net genomic fitness value. When a positive mutation arises in a genome already harbouring negative ones, these might overwhelm the positive mutation, and the whole genome would be removed from the population by natural selection. The

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Sex increases the efficacy of natural selection in experimental yeast populations

Cited by 412 publications

References 22 publications

Eukaryotic microbes, species recognition and the geographic limits of species: examples from the kingdom Fungi

Eukaryotic microbes, species recognition and the geographic limits of species: examples from the kingdom Fungi

What happened and what's next?

Sex accelerates adaptation

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