Wade M. Hicks scite author profile

To examine the fidelity of DNA synthesis during double-strand break (DSB) repair in S. cerevisiae we studied gene conversion (GC) in which both strands of DNA are newly synthesized. The mutation rate increases up to 1400 times over spontaneous events, with a significantly different mutation signature. Especially prominent are microhomology-mediated template switches. Recombination-induced mutations are largely independent of mismatch repair, Polζ, Polη, and Pol32, but result from errors made by Polδ and Polε. These observations suggest that increased DSB frequencies in oncogene-activated mammalian cells may also increase the probability of acquiring mutations required for transition to a cancerous state.

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Real-time analysis of double-strand DNA break repair by homologous recombination

Hicks

Yamaguchi

Haber

2011

Proc. Natl. Acad. Sci. U.S.A.

109

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The ability to induce synchronously a single site-specific doublestrand break (DSB) in a budding yeast chromosome has made it possible to monitor the kinetics and genetic requirements of many molecular steps during DSB repair. Special attention has been paid to the switching of mating-type genes in Saccharomyces cerevisiae, a process initiated by the HO endonuclease by cleaving the MAT locus. A DSB in MATa is repaired by homologous recombinationspecifically, by gene conversion-using a heterochromatic donor, HMLα. Repair results in the replacement of the a-specific sequences (Ya) by Yα and switching from MATa to MATα. We report that MAT switching requires the DNA replication factor Dpb11, although it does not require the Cdc7-Dbf4 kinase or the Mcm and Cdc45 helicase components. Using Southern blot, PCR, and ChIP analysis of samples collected every 10 min, we extend previous studies of this process to identify the times for the loading of Rad51 recombinase protein onto the DSB ends at MAT, the subsequent strand invasion by the Rad51 nucleoprotein filament into the donor sequences, the initiation of new DNA synthesis, and the removal of the nonhomologous Y sequences. In addition we report evidence for the transient displacement of well-positioned nucleosomes in the HML donor locus during strand invasion.yeast mating type switching | DNA repair kinetics | nucleosome displacement | MAT switching

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Protein Phosphatases Pph3, Ptc2, and Ptc3 Play Redundant Roles in DNA Double-Strand Break Repair by Homologous Recombination

Kim

Hicks

et al. 2011

Molecular and Cellular Biology

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In response to a DNA double-strand break (DSB), cells undergo a transient cell cycle arrest prior to mitosis until the break is repaired. In budding yeast (Saccharomyces cerevisiae), the DNA damage checkpoint is regulated by a signaling cascade of protein kinases, including Mec1 and Rad53. When DSB repair is complete, cells resume cell cycle progression (a process called "recovery") by turning off the checkpoint. Recovery involves two members of the protein phosphatase 2C (PP2C) family, Ptc2 and Ptc3, as well as the protein phosphatase 4 (PP4) enzyme, Pph3. Here, we demonstrate a new function of these three phosphatases in DSB repair. Cells lacking all three phosphatases Pph3, Ptc2, and Ptc3 exhibit synergistic sensitivities to the DNA-damaging agents camptothecin and methyl methanesulfonate, as well as hydroxyurea but not to UV light. Moreover, the simultaneous absence of Pph3, Ptc2, and Ptc3 results in defects in completing DSB repair, whereas neither single nor double deletion of the phosphatases causes a repair defect. Specifically, cells lacking all three phosphatases are defective in the repair-mediated DNA synthesis. Interestingly, the repair defect caused by the triple deletion of Pph3, Ptc2, and Ptc3 is most prominent when a DSB is slowly repaired and the DNA damage checkpoint is fully activated.

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A distributed cell division counter reveals growth dynamics in the gut microbiota

et al. 2015

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Microbial population growth is typically measured when cells can be directly observed, or when death is rare. However, neither of these conditions hold for the mammalian gut microbiota, and, therefore, standard approaches cannot accurately measure the growth dynamics of this community. Here we introduce a new method (distributed cell division counting, DCDC) that uses the accurate segregation at cell division of genetically encoded fluorescent particles to measure microbial growth rates. Using DCDC, we can measure the growth rate of Escherichia coli for >10 consecutive generations. We demonstrate experimentally and theoretically that DCDC is robust to error across a wide range of temperatures and conditions, including in the mammalian gut. Furthermore, our experimental observations inform a mathematical model of the population dynamics of the gut microbiota. DCDC can enable the study of microbial growth during infection, gut dysbiosis, antibiotic therapy or other situations relevant to human health.

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Wade M. Hicks

Increased Mutagenesis and Unique Mutation Signature Associated with Mitotic Gene Conversion

Real-time analysis of double-strand DNA break repair by homologous recombination

Protein Phosphatases Pph3, Ptc2, and Ptc3 Play Redundant Roles in DNA Double-Strand Break Repair by Homologous Recombination

A distributed cell division counter reveals growth dynamics in the gut microbiota

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