Project description:Somatic genome rearrangements are thought to play important roles in cancer development. We optimized a long span paired-end-tag (PET) sequencing approach using 10 Kb genomic DNA inserts to study human genome structural variations (SVs). The use of 10 Kb insert size allows the identification of breakpoints within repetitive or homology containing regions of a few Kb in size and results in a higher physical coverage compared to small insert libraries with the same sequencing effort. We have applied this approach to comprehensively characterize the SVs of 15 cancer and 2 non-cancer genomes and used a filtering approach to strongly enrich for somatic SVs in the cancer genomes. Our analyses revealed that most inversions, deletions, and insertions are germline SVs, whereas tandem duplications, unpaired inversions, inter-chromosomal translocations, and complex rearrangements are overrepresented among somatic rearrangements in cancer genomes. We demonstrate that the quantitative and connective nature of DNA-PET data is precise in delineating the genealogy of complex rearrangement events, we observe signatures which are compatible with breakage-fusion-bridge cycles, and discover that large duplications are among the initial rearrangements that trigger genome instability for extensive amplification in epithelial cancers. Structural variations of 15 human cancer samples and 2 human normal samples were identified by long span paired-end sequencing

Project description:Somatic genome rearrangements are thought to play important roles in cancer development. We optimized a long span paired-end-tag (PET) sequencing approach using 10 Kb genomic DNA inserts to study human genome structural variations (SVs). The use of 10 Kb insert size allows the identification of breakpoints within repetitive or homology containing regions of a few Kb in size and results in a higher physical coverage compared to small insert libraries with the same sequencing effort. We have applied this approach to comprehensively characterize the SVs of 15 cancer and 2 non-cancer genomes and used a filtering approach to strongly enrich for somatic SVs in the cancer genomes. Our analyses revealed that most inversions, deletions, and insertions are germline SVs, whereas tandem duplications, unpaired inversions, inter-chromosomal translocations, and complex rearrangements are overrepresented among somatic rearrangements in cancer genomes. We demonstrate that the quantitative and connective nature of DNA-PET data is precise in delineating the genealogy of complex rearrangement events, we observe signatures which are compatible with breakage-fusion-bridge cycles, and discover that large duplications are among the initial rearrangements that trigger genome instability for extensive amplification in epithelial cancers.

Project description:A key limitation of the commonly-used CRISPR enzyme S. pyogenes Cas9 is the strict requirement of an NGG protospacer-adjacent motif (PAM) at the target site, which reduces the number of accessible genomic loci. This constraint can be limiting for genome editing applications that require precise Cas9 positioning. Recently, two Cas9 variants with a relaxed PAM requirement (NG) have been developed (xCas9 and Cas9-NG) but their activity has been measured at only a small number of endogenous sites. Here we devised a high-throughput Cas9 pooled competition screen to compare the performance of both PAM-flexible Cas9 variants and wild-type Cas9 at thousands of genomic loci and across 3 modalities (gene knock-out, transcriptional activation and suppression). We show that PAM flexibility comes at a substantial cost of decreased DNA targeting and cutting. Of the PAM-flexible variants, we found that Cas9-NG outperforms xCas9 regardless of genome engineering modality or PAM. Finally, we combined xCas9 mutations with those of Cas9-NG, creating a stronger transcriptional modulator than existing PAM-flexible Cas9 variants.

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

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

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

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