The non-homologous end-joining pathway of S. cerevisiae works effectively in G1-phase cells, and religates cognate ends correctly and non-randomly

Gao, Shujuan; Honey, Sangeet; Futcher, Bruce; Grollman, Arthur P.

doi:10.1016/j.dnarep.2016.03.013

Cited by 16 publications

(21 citation statements)

References 64 publications

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“…Using an in vivo plasmid rejoining assay, it was shown that yku80 null mutants were as defective as yku70, yku80 double mutants in repairing restriction endonuclease (EcoRI, Xho I, or PstI) induced DSBs [47]. Following association of Yku80 with Yku70, the Yku heterodimer binds DNA ends [48] to mediate nuclear DNA DSB repair via C-NHEJ, particularly in G1-phase haploid yeast cells when a homologous DNA template is unavailable for recombinational repair [49]. With regard to its role in mtDNA DSB repair, indirect evidence exists for the involvement of the Yku complex in suppressing mtDNA deletions [18].…”

Section: Discussionmentioning

confidence: 99%

Saccharomyces cerevisiae Mhr1 can bind Xho I-induced mitochondrial DNA double-strand breaks in vivo

et al. 2018

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Mitochondrial DNA (mtDNA) double-strand break (DSB) repair is essential for maintaining mtDNA integrity, but little is known about the proteins involved in mtDNA DSB repair. Here, we utilize Saccharomyces cerevisiae as a eukaryotic model to identify proteins involved in mtDNA DSB repair. We show that Mhr1, a protein known to possess homologous DNA pairing activity in vitro, binds to mtDNA DSBs in vivo, indicating its involvement in mtDNA DSB repair. Our data also indicate that Yku80, a protein previously implicated in mtDNA DSB repair, does not compete with Mhr1 for binding to mtDNA DSBs. In fact, C-terminally tagged Yku80 could not be detected in yeast mitochondrial extracts. Therefore, we conclude that Mhr1, but not Yku80, is a potential mtDNA DSB repair factor in yeast.

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Section: Discussionmentioning

confidence: 99%

Saccharomyces cerevisiae Mhr1 can bind Xho I-induced mitochondrial DNA double-strand breaks in vivo

et al. 2018

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“…Chromosome stability requires that DNA double-strand breaks (DSBs) are repaired by canonical NHEJ or homologous recombination. NHEJ is an efficient pathway directly resealing DSB ends, most often accurately (1)(2)(3)(4). In line with other DNA repair pathways, NHEJ repair sometimes comes with errors.…”

Section: Introductionmentioning

confidence: 99%

“…In line with other DNA repair pathways, NHEJ repair sometimes comes with errors. Its contribution to mutagenesis is twofold: sequence changes at the break sites and chromosomal rearrangements (1,2,(5)(6)(7)(8)(9)(10). NHEJdependent chromosomal rearrangements include dicentric chromosomes that lead to catastrophic mutational processes, namely chromosome breakage-fusion-bridge cycles and chromothripsis (11)(12)(13).…”

Section: Introductionmentioning

confidence: 99%

A New Assay Capturing Chromosome Fusions Shows a Protection Trade-off at Telomeres and NHEJ Vulnerability to Low Density Ionising Radiation

Pobiega

Alibert

Marcand

2021

Preprint

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Chromosome fusions threaten genome integrity and promote cancer by engaging catastrophic mutational processes, namely chromosome breakage-fusion-bridge cycles and chromothripsis. Chromosome fusions are frequent in cells incurring telomere dysfunctions or those exposed to DNA breakage. Their occurrence and therefore their contribution to genome instability in unchallenged cells is unknown. To address this issue, we constructed a genetic assay able to capture and quantify rare chromosome fusions in budding yeast. This chromosome fusion capture assay (CFC) relies on the controlled inactivation of one centromere to rescue unstable dicentric chromosome fusions. It is sensitive enough to quantify the basal rate of end-to-end chromosome fusions occurring in wild-type cells. These fusions depend on canonical nonhomologous end-joining (NHEJ). Our results show that chromosome end protection results from a trade-off at telomeres between positive effectors (Rif2, Sir4, telomerase) and a negative effector partially antagonizing them (Rif1). The CFC assay also captures NHEJ-dependent chromosome fusions induced by ionising radiation. It provides evidence for chromosomal rearrangements stemming from a single photon-matter interaction.

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“…Yeast has long served as an effective model for both pathways and provided numerous insights into the molecular mechanisms underlying DSB repair 124,131,190,191 . In haploid yeast, HR dominates from S-phase until division when a homologous chromosome is present while NHEJ is the preferred mechanism during G1 when a template sequence is generally not available 192 . Each pathway employs a unique set of proteins to facilitate repair and the highly amenable yeast model facilitates studies of both.…”

Section: Limitations Of the Studymentioning

confidence: 99%

“…No other DNA lesion is as severe as a DSB. When a breaks occur, cells halt cell cycle progression until this structural lesion is resolved 192…”

Section: Introductionmentioning

confidence: 99%

Functional Applications of Systems Biology Tools: Identification of Novel DNA Repair Factors and Peptide Design

Burnside¹

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The highly annotated budding yeast Saccharomyces cerevisiae has emerged as the primary model for systems biology, the study of how individual cellular components function within the context of a dynamic cellular system. Several genome/proteomescale tools developed using the S. cerevisiae model have produced extensive information on gene function and interaction networks that is stored in publicly accessible databases. Bioinformatic tools can exploit these databases to infer novel biological activity but these predictions must be tested in functioning cellular systems to assess the effectiveness of any method. The work herein uses systems-based computational tools to make predictions on novel protein/gene function that are tested using yeast functional genomic approaches. This thesis describes the development and validation of a new tool to design synthetic binding proteins that bind to and inhibit targeted yeast proteins Psk1 and Pin4 as well as the identification and functional analysis of three yeast DNA repair genes, PSK1, ARP6, and DEF1. The in-silico protein synthesizer, InSiPS successfully engineered two synthetic proteins known as anti-Psk1 and anti-Pin4. This demonstrated the ability of our approach to translate from computational prediction, to a specific biological interaction and importantly, a functionally significant phenotype. Chemical-genetic interaction analysis showed that cells expressing α-Psk1 and α-Pin4 phenocopy Δpsk1 and Δpin4 mutants and yeast-twohybrid confirmed binary interactions in vivo while in vitro assays verify that binding is iii occurring at predicted loci. Further analysis of the anti-Psk1/Psk1 interaction motif showed strong, specific binding. Psk1 was inferred to participate in yeast nonhomologous end-joining (NHEJ) repair of double-strand breaks (DSB), an essential DNA repair pathway. Our functional genetic analysis showed that PSK1 is an important novel NHEJ gene that contributes to repair fidelity while appearing to function through RAD27 activity. We also report that ARP6, affects NHEJ through the RSC chromatin remodeling complex. Lastly, we identify new properties of the Def1 DNA repair protein in yeast NHEJ and a physical and genetic interaction between Yku80 and Def1. Together, these findings demonstrate the ability to predict novel gene/protein function using computational tools and expand our understanding of eukaryotic DSB repair. iv Dedication This work is dedicated to my father Graham Burnside who never stopped teaching me, driving me and supporting me. Your incredible selflessness and patience cannot be matched. Thank you v xv 4.4.4 Overexpression of ARP6 rescued four deletion mutants that were sensitive to DNA damaging drugs …………………………………………………. 4.4.5 ARP6 function appears related to the RSC-C chromatin remodeling complex………………………………………………………………………………………. 4.4.6 Loss of ARP6 severely reduces the efficiency of homologous recombination……………………………………………………………………………… 4.5 Discussion………………………………………………………………………………………………….

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The non-homologous end-joining pathway of S. cerevisiae works effectively in G1-phase cells, and religates cognate ends correctly and non-randomly

Cited by 16 publications

References 64 publications

Saccharomyces cerevisiae Mhr1 can bind Xho I-induced mitochondrial DNA double-strand breaks in vivo

Saccharomyces cerevisiae Mhr1 can bind Xho I-induced mitochondrial DNA double-strand breaks in vivo

A New Assay Capturing Chromosome Fusions Shows a Protection Trade-off at Telomeres and NHEJ Vulnerability to Low Density Ionising Radiation

Functional Applications of Systems Biology Tools: Identification of Novel DNA Repair Factors and Peptide Design

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