Rapid Evolution of Yeast Centromeres in the Absence of Drive

Douda Bensasson¹, Magdalena Zarowiecki², Austin Burt and Vassiliki Koufopanou³

Division of Biology, Imperial College London, Ascot SL5 7PY, United Kingdom

^³ Corresponding author: Division of Biology, Imperial College London, Silwood Park Campus, Ascot SL5 7PY, United Kingdom.
E-mail: v.koufopanou{at}imperial.ac.uk

To find the most rapidly evolving regions in the yeast genomewe compared most of chromosome III from three closely relatedlineages of the wild yeast Saccharomyces paradoxus. Unexpectedly,the centromere appears to be the fastest-evolving part of thechromosome, evolving even faster than DNA sequences unlikelyto be under selective constraint (i.e., synonymous sites aftercorrecting for codon usage bias and remnant transposable elements).Centromeres on other chromosomes also show an elevated rateof nucleotide substitution. Rapid centromere evolution has alsobeen reported for some plants and animals and has been attributedto selection for inclusion in the egg or the ovule at femalemeiosis. But Saccharomyces yeasts have symmetrical meioses withall four products surviving, thus providing no opportunity formeiotic drive. In addition, yeast centromeres show the highlevels of polymorphism expected under a neutral model of molecularevolution. We suggest that yeast centromeres suffer an elevatedrate of mutation relative to other chromosomal regions and theychange through a process of "centromere drift," not drive.

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ISSUE HIGHLIGHTS: Genetics 2008 178: NP. [Full Text]