Comparative Modeling Reveals the Molecular Determinants of Aneuploidy Fitness Cost in a Wild Yeast Model

Overview

Journal Cell Genom

Date 2024 Sep 24

PMID 39317188

Authors

Julie Rojas

James Hose

H Auguste Dutcher

Michael Place

John F Wolters

Chris Todd Hittinger

Audrey P Gasch

Affiliations

Soon will be listed here.

Abstract

Although implicated as deleterious in many organisms, aneuploidy can underlie rapid phenotypic evolution. However, aneuploidy will be maintained only if the benefit outweighs the cost, which remains incompletely understood. To quantify this cost and the molecular determinants behind it, we generated a panel of chromosome duplications in Saccharomyces cerevisiae and applied comparative modeling and molecular validation to understand aneuploidy toxicity. We show that 74%-94% of the variance in aneuploid strains' growth rates is explained by the cumulative cost of genes on each chromosome, measured for single-gene duplications using a genomic library, along with the deleterious contribution of small nucleolar RNAs (snoRNAs) and beneficial effects of tRNAs. Machine learning to identify properties of detrimental gene duplicates provided no support for the balance hypothesis of aneuploidy toxicity and instead identified gene length as the best predictor of toxicity. Our results present a generalized framework for the cost of aneuploidy with implications for disease biology and evolution.

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