Genome-wide mapping of spontaneous genetic alterations in diploid yeast cells

Abstract: Genomic alterations including single-base mutations, deletions and duplications, translocations, mitotic recombination events, and chromosome aneuploidy generate genetic diversity. We examined the rates of all of these genetic changes in a diploid strain of Saccharomyces cerevisiae by whole-genome sequencing of many independent isolates (n = 93) subcloned about 100 times in unstressed growth conditions. The most common alterations were point mutations and small (<100 bp) insertion/deletions (n = 1,337) and … Show more

“…Most information about the rates of these events was based on the genetic assay system involving single genes or partial chromosomes [ 51 , 52 ]. More recently, subculturing of yeast strains over many generations for mutation accumulation (MA) followed by whole-genome sequencing has allowed a more global analysis of chromosomal rearrangements [ 53 , 54 , 55 , 56 ]. Sui et al [ 53 ] performed MA experiments in a diploid S. cerevisiae strain ( spo11/spo11 ; unable to enter meiosis), identifying chromosomal rearrangements throughout the genome by deep-coverage genome sequencing.…”

“…More recently, subculturing of yeast strains over many generations for mutation accumulation (MA) followed by whole-genome sequencing has allowed a more global analysis of chromosomal rearrangements [ 53 , 54 , 55 , 56 ]. Sui et al [ 53 ] performed MA experiments in a diploid S. cerevisiae strain ( spo11/spo11 ; unable to enter meiosis), identifying chromosomal rearrangements throughout the genome by deep-coverage genome sequencing. This study detected 47 chromosomal rearrangements including 35 deletions, 12 duplications, and 1 translocation.…”

“…It was calculated that spontaneous chromosomal rearrangements occur at a rate of 1.8 × 10 −4 per cell division. This rate is one magnitude lower than that of LOH events (4.6 × 10 −3 per cell division; gene conversion and crossover) resulted from SDSA and DSBR pathways ( Figure 1 ) [ 53 ]. They also showed certain regions are more susceptible to rearrangements than other regions.…”

“…They also showed certain regions are more susceptible to rearrangements than other regions. For example, the region of 184–195 Kb (including three genes RRN11 , CAT2 , and VPS71 ) located between two flanking Ty elements (standing for transposons of yeast, which are dispersed repeat retrotransposons in the yeast genome) on chromosome XIII, and the region of the RDL1/2 locus on chromosome XV are two hotspots for interstitial deletion or duplication [ 53 ]. Non-allelic recombination between two sister chromatids by the DSBR pathway might be responsible for those frequent interstitial deletions and duplications ( Figure 1 ).…”

“…SSA to repair a DSB located between two direct repeats can be an alternative mechanism underlying spontaneous interstitial deletion ( Figure 1 ). In one subcultured isolate, they also found recombination between two directly oriented Ty transposons on chromosome III that resulted in a circular DNA molecule [ 53 ]. Most strikingly, this work demonstrated that spontaneous chromosomal rearrangements generally involve homologous recombination between non-allelic dispersed repeats in the yeast genome.…”

Origin, Regulation, and Fitness Effect of Chromosomal Rearrangements in the Yeast Saccharomyces cerevisiae

“…Most information about the rates of these events was based on the genetic assay system involving single genes or partial chromosomes [ 51 , 52 ]. More recently, subculturing of yeast strains over many generations for mutation accumulation (MA) followed by whole-genome sequencing has allowed a more global analysis of chromosomal rearrangements [ 53 , 54 , 55 , 56 ]. Sui et al [ 53 ] performed MA experiments in a diploid S. cerevisiae strain ( spo11/spo11 ; unable to enter meiosis), identifying chromosomal rearrangements throughout the genome by deep-coverage genome sequencing.…”

“…More recently, subculturing of yeast strains over many generations for mutation accumulation (MA) followed by whole-genome sequencing has allowed a more global analysis of chromosomal rearrangements [ 53 , 54 , 55 , 56 ]. Sui et al [ 53 ] performed MA experiments in a diploid S. cerevisiae strain ( spo11/spo11 ; unable to enter meiosis), identifying chromosomal rearrangements throughout the genome by deep-coverage genome sequencing. This study detected 47 chromosomal rearrangements including 35 deletions, 12 duplications, and 1 translocation.…”

“…It was calculated that spontaneous chromosomal rearrangements occur at a rate of 1.8 × 10 −4 per cell division. This rate is one magnitude lower than that of LOH events (4.6 × 10 −3 per cell division; gene conversion and crossover) resulted from SDSA and DSBR pathways ( Figure 1 ) [ 53 ]. They also showed certain regions are more susceptible to rearrangements than other regions.…”

“…They also showed certain regions are more susceptible to rearrangements than other regions. For example, the region of 184–195 Kb (including three genes RRN11 , CAT2 , and VPS71 ) located between two flanking Ty elements (standing for transposons of yeast, which are dispersed repeat retrotransposons in the yeast genome) on chromosome XIII, and the region of the RDL1/2 locus on chromosome XV are two hotspots for interstitial deletion or duplication [ 53 ]. Non-allelic recombination between two sister chromatids by the DSBR pathway might be responsible for those frequent interstitial deletions and duplications ( Figure 1 ).…”

“…SSA to repair a DSB located between two direct repeats can be an alternative mechanism underlying spontaneous interstitial deletion ( Figure 1 ). In one subcultured isolate, they also found recombination between two directly oriented Ty transposons on chromosome III that resulted in a circular DNA molecule [ 53 ]. Most strikingly, this work demonstrated that spontaneous chromosomal rearrangements generally involve homologous recombination between non-allelic dispersed repeats in the yeast genome.…”

Origin, Regulation, and Fitness Effect of Chromosomal Rearrangements in the Yeast Saccharomyces cerevisiae

Loss of Heterozygosity and Its Importance in Evolution

A mapping platform for mitotic crossover by single-cell multi-omics