Crossover Homeostasis in Yeast Meiosis

Overview

Journal Cell

Publisher Cell Press

Specialty Cell Biology

Date 2006 Jul 29

PMID 16873061

Citations 210

Authors

Emmanuelle Martini

Robert L Diaz

Neil Hunter

Scott Keeney

Affiliations

Soon will be listed here.

Abstract

Crossovers produced by homologous recombination promote accurate chromosome segregation in meiosis and are controlled such that at least one forms per chromosome pair and multiple crossovers are widely spaced. Recombination initiates with an excess number of double-strand breaks made by Spo11 protein. Thus, crossover control involves a decision by which some breaks give crossovers while others follow a predominantly noncrossover pathway(s). To understand this decision, we examined recombination when breaks are reduced in yeast spo11 hypomorphs. We find that crossover levels tend to be maintained at the expense of noncrossovers and that genomic loci differ in expression of this "crossover homeostasis." These findings define a previously unsuspected manifestation of crossover control, i.e., that the crossover/noncrossover ratio can change to maintain crossovers. Our results distinguish between existing models of crossover control and support the hypothesis that an obligate crossover is a genetically programmed event tied to crossover interference.

Citing Articles

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The ATPase activity of yeast chromosome axis protein Hop1 affects the frequency of meiotic crossovers.

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Meiotic DNA break resection and recombination rely on chromatin remodeler Fun30.

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Multiple independent losses of crossover interference during yeast evolutionary history.

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