Cleavage-defective Topoisomerase I mutants sharply increase G-quadruplex-associated genomic instability
January 31, 2022
Topoisomerase 1 (Top1) removes transcription-associated helical stress to suppress G4-formation and its induced recombination at genomic loci containing guanine-run containing sequences. Interestingly, Top1 binds tightly to G4 structures, and its inhibition or depletion can cause elevated instability at these genomic loci. Top1 is targeted by the widely used anti-cancer chemotherapeutic camptothecin (CPT) and its derivatives, which stabilize Top1 covalently attached on a DNA nick and prevent the re-ligation step. Here we investigated how CPT-resistance conferring Top1 mutants, which emerge in cancer patients and cells treated with CPT, affect G4-induced genomic instability in S. cerevisiae. We found that Top1 mutants form stable complexes with G4 DNA and that expression of Top1 cleavage-defective mutants but not a DNA-binding-defective (...)
Histone H3E73Q and H4E53A mutations cause recombinogenic DNA damage
April 24, 2020
This study reveals that conserved residues H3E73 and H4E53 in histones H3 and H4 play a crucial role in maintaining genome stability. Mutations at these sites increase recombinogenic DNA damage, likely due to replication-associated issues rather than transcriptional activity, highlighting their importance in DNA damage prevention and repair.
Increased spontaneous recombination in RNase H2-deficient cells arises from multiple contiguous rNMPs and not from single rNMP residues incorporated by DNA polymerase epsilon
May 15, 2016
Ribonucleotides (rNMPs) can become embedded in DNA from insertion by DNA polymerases, failure to remove Okazaki fragment primers, R-loops that can prime replication, and RNA/cDNA-mediated recombination. We report here that recombination is not stimulated by rNMPs incorporated by the replicative polymerase epsilon. Instead, recombination seems to be stimulated by multiple contiguous rNMPs, which may arise from R-loops or replication priming events.
Mek1/Mre4 is a master regulator of meiotic recombination in budding yeast
February 22, 2016
This article comments on work published by Chen et al. (PLoS BIol, 2015), showing that the meiosis specific kinase Mek1 indirectly regulates the crossover/non-crossover decision between homologs as well as genetic interference and suggests Mek1 to be a "master regulator" of meiotic recombination in budding yeast.