Project description:Insertions and deletions (indels) are common sources of structural variation, and insertions originating from spontaneous DNA lesions are frequent in cancer. We developed a highly sensitive assay (Indel-Seq) to monitor rearrangements in human cells at the TRIM37 acceptor locus that reports indels stemming from experimentallyinduced and spontaneous genome instability. Templated insertions, which derive from sequences genome-wide, require contact between donor and acceptor loci, homologous recombination, and are stimulated by DNA end-processing. Insertions are facilitated by transcription and involve a DNA/RNA hybrid intermediate. Indel-Seq reveals that insertions are generated via multiple pathways. The broken acceptor site anneals with a resected DNA break or invades the displaced strand of a transcription bubble or R-loop followed by DNA synthesis, displacement and then ligation by nonhomologous end-joining. Our studies identify transcription-coupled insertions as a critical source of spontaneous genome instability that are distinct from cut-and-paste events

Project description:We used ChIP-seq to assess where p53 binds in the human genome and how that binding changes during the DNA double-strand break response. In particular, we considered the 1-Mb-wide window centered on the MYC locus. Contrary to previous reports, we found no evidence of p53 binding at the MYC promoter. Rather, we identified three locations downstream of MYC at which p53 was bound; binding at each of these regions increased during the DNA double-strand break response.

Project description:CGH of stage 13 amplifying follicle cells to measure changes in replication fork progression in double-strand break repair mutants Comparative genomic hybridization was performed to compare amplification gradients of stage 13 follicle cells from several double-strand break repair mutants to wild type (OrR) gradients. Two-three replicates were done for each genotype.

Project description:In the bacterium Escherichia coli, RecG directs DNA synthesis during the repair of DNA double-strand breaks by homologous recombination. Examination of RecA binding during double-strand break repair in Escherichia coli in the presence and absence of RecG protein

Project description:Reconstitution of SPO11-dependent double-strand break formation

Project description:RecG Directs DNA Synthesis During Double-Strand Break Repair

Project description:Here, we correlated and compared two different steps of the Double-Strand Break Repair pathway: RecA loading and Holliday junction formation

Project description:The effect of a site-specific DNA double-strand break on the abundance of E. coli chromosomal DNA during exponential growth was investigated by marker frequency analysis (MFA).

Project description:Here we developed BreakTag, a versatile, highly parallel and scissile-aware methodology for the profiling of Cas9-induced DNA double strand break (DSBs), to identify molecular determinants influencing Cas9 incisions

Project description:Here we developed BreakTag, a versatile, highly parallel and scissile-aware methodology for the profiling of Cas9-induced DNA double strand break (DSBs), to identify molecular determinants influencing Cas9 incisions