Experimental evolution reveals that high relatedness protects multicellular cooperation from cheaters

In multicellular organisms, there is a potential risk that cheating mutants gain access to the germline. Development from a single-celled zygote resets relatedness among cells to its maximum value each generation, which should accomplish segregation of cheating mutants from non-cheaters and thereby...

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Bibliographic Details
Published in:Nature communications 2016-05, Vol.7 (1), p.11435-11435, Article 11435
Main Authors: Bastiaans, Eric, Debets, Alfons J. M., Aanen, Duur K.
Format: Article
Language:English
Subjects:
631/181/2474
631/181/2475
631/326/325/2484
Ascomycete fungi
Biologi
Biology
Cell Proliferation
Cheating
Clonal Evolution
Cooperation
Fungi
heterokaryon incompatibility
Humanities and Social Sciences
Hypotheses
Independent sample
kin selection
Laboratorium voor Erfelijkheidsleer
Laboratory of Genetics
Microbial Interactions
multicellularity
multidisciplinary
Mutation
Neurospora crassa - genetics
Neurospora crassa - growth & development
Organismal biology
PE&RC
Science
Science (multidisciplinary)
social evolution
Spores, Fungal - genetics
Spores, Fungal - growth & development
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Summary:In multicellular organisms, there is a potential risk that cheating mutants gain access to the germline. Development from a single-celled zygote resets relatedness among cells to its maximum value each generation, which should accomplish segregation of cheating mutants from non-cheaters and thereby protect multicellular cooperation. Here we provide the crucial direct comparison between high- and low-relatedness conditions to test this hypothesis. We allow two variants of the fungus Neurospora crassa to evolve, one with and one without the ability to form chimeras with other individuals, thus generating two relatedness levels. While multicellular cooperation remains high in the high-relatedness lines, it significantly decreases in all replicate low-relatedness lines, resulting in an average threefold decrease in spore yield. This reduction is caused by cheating mutants with reduced investment in somatic functions, but increased competitive success when fusing with non-cheaters. Our experiments demonstrate that high genetic relatedness is crucial to sustain multicellular cooperation. Maintenance of cooperation in multicellular organisms is hypothesized to depend on high relatedness among cells. Here, Bastiaans et al . provide empirical support for this hypothesis by directly comparing the evolutionary stability of multicellular cooperation in experimental lines of a fungus kept at either high or low relatedness.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms11435