Project description:Whole Genome Bisulfite Sequencing (WGBS) is the current standard for DNA methylation profiling; however, WGBS is costly as it requires sequencing coverage over the entire genome. Here we introduce Anchor-Based Bisulfite Sequencing (ABBS). We show that ABBS captures accurate DNA methylation information in Escherichia coli and mammalian cells, while requiring approximately 20 times fewer sequencing reads than WGBS. The ABBS protocol is simple and can be performed in a single day.
Project description:We developed a genome-wide DNA methylation profiling technology that determines methylation patterns using small amounts of starting material. This process involves a novel amplification step for DNA subjected to bisulfite-mediated cytosine conversion and generates highly reproducible datasets with low technical variation. The technology, named BiMP (for Bisulfite Methylation Profiling), is more cost-effective than mC immunoprecipitation techniques (mCIP) and can be applied to as little as 100 ng of Arabidopsis DNA. It is anticipated that this technology can be applied to mammalian genomes and may allow methylation profiling of a small number of physiologically uniform cells. Keywords: bisulfite DNA methylation profiling, Arabidopsis, methylation polymorphisms, met1-3,
Project description:We demonstrated the reliability of the tagmentation-based whole genome bisulfite sequencing in direct comparison with the conventional whole genome bisulfite sequencing.
Project description:This SuperSeries is composed of the following subset Series: GSE30971: The Histone Methyltransferase Wbp7 Controls Macrophage Function through GPI Glycolipid Anchor Synthesis. [Expression Profile] GSE30972: The Histone Methyltransferase Wbp7 Controls Macrophage Function through GPI Glycolipid Anchor Synthesis. [ChIP_seq] Refer to individual Series
Project description:Methylation-based liquid biopsies show promise in detecting cancer from circulating cell-free DNA, but current limitations impede clinical application. Most assays necessitate substantial DNA inputs, posing challenges. Underrepresented tumor DNA fragments may go undetected during exponential amplification steps of traditional sequencing methods. Here we report LABS (Linear Amplification based Bisulfite Sequencing), enabling linear amplification of bisulfite-treated DNA fragments in a genome-wide, unbiased fashion, detecting cancer abnormalities with sub-nanogram inputs. Applying LABS to 100 patient samples revealed cancer-specific patterns, copy number alterations, and enhanced cancer detection accuracy by identifying tissue-of-origin and immune cell composition.
Project description:Bisulfite and oxidative bisulfite treated sample methylation analysis of IDH1 mutant and wild-type high grade human gliomas, to profile 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC). Genomic DNA isolated directly from fresh-frozen human high grade glioma specimens.
Project description:Single-cell transcriptomics, reliant on the incorporation of barcodes and unique molecular identifiers (UMIs) into captured polyA+ mRNA, faces a significant challenge due to synthesis errors in oligonucleotide capture sequences. These inaccuracies, which are especially problematic in long-read sequencing, impair the precise identification of sequences and result in inaccuracies in UMI deduplication. To mitigate this issue, we have modified the oligonucleotide capture design, which integrates an interposed anchor between the barcode and UMI, and a 'V' base anchor adjacent to the polyA capture region. This configuration is devised to ensure compatibility with both short and long-read sequencing technologies, facilitating improved UMI recovery and enhanced feature detection, thereby improving the efficacy of droplet-based sequencing methods.