Genome-destabilizing and Mutagenic Effects of Break-induced Replication in Saccharomyces cerevisiae

Deem, Angela Kay

19 August 2011

Indiana University-Purdue University Indianapolis (IUPUI) / DNA suffers constant damage, leading to a variety of lesions that require repair. One of the most devastating lesions is a double-strand break (DSB), which results in physical dissociation of two pieces of a chromosome. Necessarily, cells have evolved a number of DSB repair mechanisms. One mechanism of DSB repair is break-induced replication (BIR), which involves invasion of one side of the broken chromosome into a homologous template, followed by copying of the donor molecule through telomeric sequences. BIR is an important cellular process implicated in the restart of collapsed replication forks, as well as in various chromosomal instabilities. Furthermore, BIR uniquely combines processive replication involving a replication fork with DSB repair. This work employs a system in Saccharomyces cerevisiae to investigate genetic control, physical outcomes, and frameshift mutagenesis associated with BIR initiated by a controlled HO-endonuclease break in a chromosome. Mutations in POL32, which encodes a third, non-essential subunit of polymerase delta (Pol delta), as well as RAD9 and RAD24, which participate in the DNA damage checkpoint response, resulted in a BIR defect characterized by decreased BIR repair and increased loss of the broken chromosome. Also, increased incidence of chromosomal fusions determined to be half-crossover (HCO) molecules was confirmed in pol32 and rad24, as well as a rad9rad50S double mutant. HCO formation was also stimulated by addition of a replication-inhibiting drug, methyl-methane sulfonate (MMS), to cells undergoing BIR repair. Based on these data, it is proposed that interruption of BIR after it has initiated is one mechanism of HCO formation. Addition of a frameshift mutation reporter to this system allowed mutagenesis associated with BIR DNA synthesis to be measured. It is demonstrated that BIR DNA synthesis is intrinsically inaccurate over the entire path of the replication fork, as the rate of frameshift mutagenesis during BIR is up to 2800-fold higher than normal replication. Importantly, this high rate of mutagenesis was observed not only close to the DSB where BIR is less stable, but also far from the DSB where the BIR replication fork is fast and stabilized. Pol  proofreading and mismatch repair (MMR) are confirmed to correct BIR errors. Based on these data, it is proposed that a high level of DNA polymerase errors that is not fully compensated by error-correction mechanisms is largely responsible for mutagenesis during BIR. Pif1p, a helicase that is non-essential for DNA replication, and elevated dNTP levels during BIR also contributed to BIR mutagenesis. Taken together, this work characterizes BIR as an essential repair process that also poses risks to a cell, including genome destabilization and hypermutagenesis.

DNA replication -- Research

Mutagenesis -- Research

Cascades of genetic instability resulting from compromised break-induced replication

Vasan, Soumini

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Break-induced replication (BIR) is a mechanism to repair double-strand breaks (DSBs) that possess only a single end that can find homology in the genome. This situation can result from the collapse of replication forks or telomere erosion. BIR frequently produces various genetic instabilities including mutations, loss of heterozygosity, deletions, duplications, and template switching that can result in copy-number variations (CNVs). An important type of genomic rearrangement specifically linked to BIR is half crossovers (HCs), which result from fusions between parts of recombining chromosomes. Because HC formation produces a fused molecule as well as a broken chromosome fragment, these events could be highly destabilizing. Here I demonstrate that HC formation results from the interruption of BIR caused by a defective replisome or premature onset of mitosis. Additionally, I document the existence of half crossover instability cascades (HCC) that resemble cycles of non-reciprocal translocations (NRTs) previously described in human tumors. I postulate that HCs represent a potent source of genetic destabilization with significant consequences that mimic those observed in human diseases, including cancer.

Comparative Genomic Hybridization

Break-induced Replication

Copy Number Variations

Chromosomal Rearrangements

Double-strand Break Repair

Half Crossover

Homologous Recombination

Non-reciprocal Translocation

Half crossover instability cascades

DNA double-strand break

DNA repair

Genetic instabilities

Array-CGH

DNA repair -- Research -- Analysis

DNA damage -- Research -- Analysis

DNA microarrays -- Research -- Analysis

DNA replication -- Regulation

DNA -- Analysis

Genetic recombination -- Research

Mutagenesis -- Research

Molecular biology -- Research

Mitosis -- Regulation -- Research

DNA polymerases

DNA -- Synthesis

Tumors -- Genetic aspects

Cancer -- Genetic aspects