Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:Numerous methods are available for the mapping of DNA lesions ranging from double-strand breaks (DSBs) to incorporated ribonucleotides. We now present a technology based on the Genomewide Ligation of 3’-OH Ends (GLOE-Seq) and an associated computational pipeline designed for single-stranded breaks (SSBs), but versatile enough to be applied to any lesion that is convertible into a free 3’-OH terminus. We demonstrate its applicability to the mapping of Okazaki fragments without prior size selection and detect biases and asymmetries in the distribution of spontaneous SSBs in budding yeast and human DNA.

Project description:DNA topoisomerases are required to resolve DNA topological stress. Despite this essential role, abortive topoisomerase activity generates aberrant protein-linked DNA breaks, jeopardising genome stability. Here, to understand the genomic distribution and mechanisms underpinning topoisomerase-induced DNA breaks, we map Top2 DNA cleavage with strand-specific nucleotide resolution across the S. cerevisiae and human genomes—and use the meiotic Spo11 protein to validate the broad applicability of this method to explore the role of diverse topoisomerase family members. Our data characterises Mre11-dependent repair in yeast and defines two strikingly different fractions of Top2 activity in humans: tightly localised CTCF-proximal, and broadly distributed transcription-proximal, the latter correlated with gene length and expression. Moreover, single nucleotide accuracy reveals the influence primary DNA sequence has upon Top2 cleavage—distinguishing sites likely to form canonical DNA double-strand breaks (DSBs) from those predisposed to form strand-biased DNA single-strand breaks (SSBs) induced by etoposide (VP16) in vivo.

Project description:DNA topoisomerases are required to resolve DNA topological stress. Despite this essential role, abortive topoisomerase activity generates aberrant protein-linked DNA breaks, jeopardising genome stability. Here, to understand the genomic distribution and mechanisms underpinning topoisomerase-induced DNA breaks, we map Top2 DNA cleavage with strand-specific nucleotide resolution across the S. cerevisiae and human genomes - and use the meiotic Spo11 protein to validate the broad applicability of this method to explore the role of diverse topoisomerase family members. Our data characterises Mre11-dependent repair in yeast, and defines two strikingly different fractions of Top2 activity in humans: tightly localised CTCF-proximal, and broadly distributed transcription-proximal, the latter correlated with gene length and expression. Moreover, single nucleotide accuracy enables us to reveal the influence primary DNA sequence has upon Top2 cleavage - distinguishing canonical DNA double-strand breaks (DSBs) from a major population of DNA single-strand breaks (SSBs) induced by etoposide (VP16) in vivo.

Project description:DNA topoisomerases are required to resolve DNA topological stress. Despite this essential role, abortive topoisomerase activity generates aberrant protein-linked DNA breaks, jeopardising genome stability. Here, to understand the genomic distribution and mechanisms underpinning topoisomerase-induced DNA breaks, we map Top2 DNA cleavage with strand-specific nucleotide resolution across the S. cerevisiae and human genomes—and use the meiotic Spo11 protein to validate the broad applicability of this method to explore the role of diverse topoisomerase family members. Our data characterises Mre11-dependent repair in yeast and defines two strikingly different fractions of Top2 activity in humans: tightly localised CTCF-proximal, and broadly distributed transcription-proximal, the latter correlated with gene length and expression. Moreover, single nucleotide accuracy reveals the influence primary DNA sequence has upon Top2 cleavage—distinguishing sites likely to form canonical DNA double-strand breaks (DSBs) from those predisposed to form strand-biased DNA single-strand breaks (SSBs) induced by etoposide (VP16) in vivo. This data set contains maps of Top2 CCs in the S. cerevisiae genome, generated by CC-seq of BY4741 cells -/+ etoposide (VP16).

Project description:Single strand breaks (SSBs) represent one of the most common types of DNA damage yet not much is known about the genome landscapes of this type of DNA lesions in mammalian cells. Here, we found that SSBs are more likely to occur in certain positions of the human genome — SSB hotspots — in different cells of the same cell type and in different cell types. We hypothesize that the hotspots are likely to represent biologically relevant breaks. And, we found that the hotspots had a prominent tendency to be enriched in the immediate vicinity of transcriptional start sites (TSSs). We show that these hotspots are not likely to represent technical artifacts, or be caused by common mechanisms previously found to cause DNA cleavage at promoters, such as apoptotic DNA fragmentation or topoisomerase type II (TOP2) activity. Therefore, such TSS-associated hotspots could potentially be generated using a novel mechanism, that could involve preferential cleavage at cytosines, and their existence is consistent with recent studies suggesting a complex relationship between DNA damage and regulation of gene expression.