Project description:Abasic (AP) sites are one of the most common forms of DNA damage which can lead to polymerase stalling, strand breaks and mutations. We developed snA-seq, a mapping method that reveals the location of abasic sites at base-resolution. Using synthetic DNA, we show that high selectivity for AP DNA is achieved. We use this method to explore the distribution of thymine modifications in the Leishmania major genome, by converting these into abasic sites using a glycosylase enzyme. We also apply snAP-seq to the human genome to study the distribution of endogenous AP sites, in both APE1 knockdown and control cells.

Project description:Thymidine glycol (Tg) is the most prevalent form of oxidatively induced pyrimidine lesion in DNA. Tg can arise from direct oxidation of thymidine in DNA. In addition, 5-methyl-2¢-deoxycytidine (5-mdC) can be oxidized to 5-mdC glycol and its subsequent deamination also yields Tg. However, its distribution in the human genome remains unknown. Here, we presented a DNA-protein cross-linking sequencing (DPC-Seq) method for genome-wide mapping of Tg in human cells. Our approach is capitalized on the specificity of a DNA glycosylase, i.e., NTHL1, for the covalent labeling, as well as DPC pulldown, SDS-PAGE fractionation, and membrane transfer for highly efficient and selective enrichment of Tg-bearing DNA. By employing DPC-Seq, we detected thousands of Tg sites in HEK293T cells and the isogenic NTHL1 and NEIL1 double knock out cell lines. We found that Tg is depleted in genomic regions associated with active transcription, but enriched at the nucleosome-binding sites, especially at heterochromatin sites. Collectively, our approach allows for comprehensive analysis of Tg in the human genome and provides a robust tool for future functional studies of Tg in DNA. It can be envisaged that the method can be adapted for mapping other modified nucleosides in genomic DNA in the future.

Project description:A methyl-specific metabolic labeling approach for global methylome mapping and found extensive His methylation at C3H1 zinc fingers.

Project description:Chromatin integration labeling for mapping multiple DNA binding proteins and modifications with low input.

Project description:We developed a novel method, AP-seq, capable of mapping apurinic sites and 8-oxo-7,8-dihydroguanine bases at approximately 250bp resolution on a genome-wide scale. We directly demonstrate that the accumulation rate of apurinic sites varies widely across the genome, with hot spots acquiring many times more damage than cold spots. The experiment was performed in triplicates on HepG2 cells, 30 min after X-ray treatment (6Gy). AP-Seq is an approach that specifically enriches AP-sites via a biotin-labelled aldehyde-reactive probe under pH neutral conditions, which has been well established for the specific detection of AP-sites since its development by Kubo et al. in 1992. Under neutral conditions (pH7), 1h at 37ºC, the probe is highly specific for the aldehydes occurring at AP-sites. After biotin labelling of genomic DNA, DNA is sonicated into ~250 bp fragments, enriched, in vitro repaired (PreCR, NEB), and used for Illumina short read sequencing (125 bp, paired end, HiSeq2000). To assess oxidative damage as the sum of AP-sites and 8-oxoG, we applied recombinant OGG1 in vitro to the extracted DNA (OGG1-AP-seq). Under the conditions chosen, any remaining 8-oxoG is excised in a largely sequence-independent fashion after DNA extraction to result in a set of secondary AP-sites and to a lesser extent the associated beta-elimination product.

Project description:Endogenous and exogenous chemical modifications in DNA have profound influences on genome function. We have developed a novel technology, Nick-seq, for mapping variety of DNA chemical modifications across the genomes at single-nucleotide resolution, by which we achieved quantitative profiling of single-strand breaks, phosphorothioate modifications, and oxidative DNA damage sites. This method is applicable for mapping of any DNA metabolism events that are involved in or can be converted, enzymatically or chemically, to DNA strand breaks such as DNA modifications, damages, genome replication, and chromatin structures.

Project description:Endogenous and exogenous chemical modifications in DNA have profound influences on genome function. We have developed a novel technology, Nick-seq, for mapping variety of DNA chemical modifications across the genomes at single-nucleotide resolution, by which we achieved quantitative profiling of single-strand breaks, phosphorothioate modifications, and oxidative DNA damage sites. This method is applicable for mapping of any DNA metabolism events that are involved in or can be converted, enzymatically or chemically, to DNA strand breaks such as DNA modifications, damages, genome replication, and chromatin structures.

Project description:Endogenous and exogenous chemical modifications in DNA have profound influences on genome function. We have developed a novel technology, Nick-seq, for mapping variety of DNA chemical modifications across the genomes at single-nucleotide resolution, by which we achieved quantitative profiling of single-strand breaks, phosphorothioate modifications, and oxidative DNA damage sites. This method is applicable for mapping of any DNA metabolism events that are involved in or can be converted, enzymatically or chemically, to DNA strand breaks such as DNA modifications, damages, genome replication, and chromatin structures.

Project description:The AP-seq provides a genome-wide method for detecting abasic sites among the human and mouse genomes Purpose: Abasic sites are one of the most frequent DNA damage among the genome , which often carries harmful consequences for the genome stability and the normal cell functions. So it is necessary to develop a whole genome abasic sites (AP sites) profiling method to detect all the AP sites among the genome, which we called the AP-seq. Methods: The human and mouse genome are processed with enzymatic fragmentation, damage repair, biotin-dU labeling, and pull-down steps. After the sequencing library preparation, the FASTQ files are produced by the Illumina HiSeq XTen platform. To guarantee the reproducibility, each case of the experiment is present with two biological replicates. Results: The reproducibility of our two biological replicates shows a high correlation which larger than 0.95. And the overlap AP site peaks between the HEK293T and MCF-7 cell line are over 50%, which show a great similarity between the different cell lines. Totally, we identified more than 2000 and 1000 abasic site peaks in human, and mouse cell lines separately. Moreover, the distribution of these AP sites prefer to locate in the intergenic regions and introns.

Project description:S-adenosylmethionine (SAM) is the principal biological methyl group donor for a diverse range of substrates. It is synthesised in the cytosolic methionine cycle and shuttled throughout the cell. The mitochondrial SAM (mitoSAM) pool depends on import through the inner-membrane S-adenosylmethionine carrier (SAMC) and supports the maturation of metabolites and mitochondrial RNAs. Mutations in SAMC in patients cause a severe metabolic crisis, however, the organellar regulation of mitoSAM and the protein methylation landscape within mitochondria are largely unknown. We developed a fly-compatible SILAC labelling technique and mapped mitochondrial protein methylation sites in Drosophila melanogaster, further showing that SAM is the sole methyl group donor for these modifications, with no contribution from folate-species. This dataset comprises MS-runs used for quality control of methyl-SILAF, the methylome mapping and exclusion of folates as protein methyl-group donors.