Small-world networks decrease the speed of Muller's ratchet

Jaime Combadão; Paulo R. A. Campos; Francisco Dionisio; Isabel Gordo

doi:10.1017/S0016672307008658

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Muller's ratchet is an evolutionary process that has been implicated in the extinction of asexual species, the evolution of non-recombining genomes, such as the mitochondria, the degeneration of the Y chromosome, and the evolution of sex and recombination. Here we study the speed of Muller's ratchet in a spatially structured population which is subdivided into many small populations (demes) connected by migration, and distributed on a graph. We studied different types of networks: regular networks (similar to the stepping-stone model), small-world networks and completely random graphs. We show that at the onset of the small-world network – which is characterized by high local connectivity among the demes but low average path length – the speed of the ratchet starts to decrease dramatically. This result is independent of the number of demes considered, but is more pronounced the larger the network and the stronger the deleterious effect of mutations. Furthermore, although the ratchet slows down with increasing migration between demes, the observed decrease in speed is smaller in the stepping-stone model than in small-world networks. As migration rate increases, the structured populations approach, but never reach, the result in the corresponding panmictic population with the same number of individuals. Since small-world networks have been shown to describe well the real contact networks among people, we discuss our results in the light of the evolution of microbes and disease epidemics.

Crossref Citations

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Gordo, Isabel and Campos, Paulo R A 2008. Sex and Deleterious Mutations. Genetics, Vol. 179, Issue. 1, p. 621.

Jain, Kavita 2008. Loss of Least-Loaded Class in Asexual Populations Due to Drift and Epistasis. Genetics, Vol. 179, Issue. 4, p. 2125.

Dolgin, Elie S and Charlesworth, Brian 2008. The Effects of Recombination Rate on the Distribution and Abundance of Transposable Elements. Genetics, Vol. 178, Issue. 4, p. 2169.

Whigham, Peter A. Dick, Grant C. and Spencer, Hamish G. 2008. Genetic drift on networks: Ploidy and the time to fixation. Theoretical Population Biology, Vol. 74, Issue. 4, p. 283.

Gordo, Isabel Gomes, M. Gabriela M. Reis, Daniel G. Campos, Paulo R. A. and DeSalle, Robert 2009. Genetic Diversity in the SIR Model of Pathogen Evolution. PLoS ONE, Vol. 4, Issue. 3, p. e4876.

Trindade, Sandra Perfeito, Lilia and Gordo, Isabel 2010. Rate and effects of spontaneous mutations that affect fitness in mutatorEscherichia coli. Philosophical Transactions of the Royal Society B: Biological Sciences, Vol. 365, Issue. 1544, p. 1177.

ZHOU, SHU-RONG and PANNELL, JOHN R. 2010. Inbreeding depression and genetic load at partially linked loci in a metapopulation. Genetics Research, Vol. 92, Issue. 2, p. 127.

Janko, Karel Drozd, Pavel and Eisner, Jan 2011. Do clones degenerate over time? Explaining the genetic variability of asexuals through population genetic models. Biology Direct, Vol. 6, Issue. 1, p. 17.

Broom, Mark and Voelkl, Bernhard 2012. TWO MEASURES OF EFFECTIVE POPULATION SIZE FOR GRAPHS. Evolution, Vol. 66, Issue. 5, p. 1613.

Takeuchi, Nobuto Kaneko, Kunihiko and Koonin, Eugene V 2014. Horizontal Gene Transfer Can Rescue Prokaryotes from Muller’s Ratchet: Benefit of DNA from Dead Cells and Population Subdivision. G3 Genes|Genomes|Genetics, Vol. 4, Issue. 2, p. 325.

Stolle, Eckart Pracana, Rodrigo Howard, Philip Paris, Carolina I Brown, Susan J Castillo-Carrillo, Claudia Rossiter, Stephen J Wurm, Yannick and Sayres, Melissa Wilson 2019. Degenerative Expansion of a Young Supergene. Molecular Biology and Evolution, Vol. 36, Issue. 3, p. 553.

Whitlock, Alexander O. B. Azevedo, Ricardo B. R. and Burch, Christina L. 2019. Population structure promotes the evolution of costly sex in artificial gene networks. Evolution, Vol. 73, Issue. 6, p. 1089.

Domingues, Célia P. F. Rebelo, João S. Pothier, Joël Monteiro, Francisca Nogueira, Teresa and Dionisio, Francisco 2021. The Perfect Condition for the Rising of Superbugs: Person-to-Person Contact and Antibiotic Use Are the Key Factors Responsible for the Positive Correlation between Antibiotic Resistance Gene Diversity and Virulence Gene Diversity in Human Metagenomes. Antibiotics, Vol. 10, Issue. 5, p. 605.

Whigham, Peter A. and Spencer, Hamish G. 2021. Graph-structured populations and the Hill–Robertson effect. Royal Society Open Science, Vol. 8, Issue. 3,

Dionisio, Francisco Domingues, Célia P. F. Rebelo, João S. Monteiro, Francisca and Nogueira, Teresa 2023. The Impact of Non-Pathogenic Bacteria on the Spread of Virulence and Resistance Genes. International Journal of Molecular Sciences, Vol. 24, Issue. 3, p. 1967.

Olofsson, Peter Chipkin, Logan Daileda, Ryan C. and Azevedo, Ricardo B. R. 2023. Mutational meltdown in asexual populations doomed to extinction. Journal of Mathematical Biology, Vol. 87, Issue. 6,

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Small-world networks decrease the speed of Muller's ratchet

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