Project description:DNA WGS Long Read Sequence (PromethION) for manuscript titled: "Performance of Somatic Structural Variant Calling in Lung Cancer using Oxford Nanopore Sequencing Technology"
Project description:DNA WGS Short Read Sequence (Illumina NovaSeq) for manuscript titled: "Performance of Somatic Structural Variant Calling in Lung Cancer using Oxford Nanopore Sequencing Technology"
Project description:Transposon insertion site sequencing (TIS) is a powerful method for associating genotype to phenotype. However, all TIS methods described to date use short nucleotide sequence reads which cannot uniquely determine the locations of transposon insertions within repeating genomic sequences where the repeat units are longer than the sequence read length. To overcome this limitation, we have developed a TIS method using Oxford Nanopore sequencing technology that generates and uses long nucleotide sequence reads; we have called this method LoRTIS (Long Read Transposon Insertion-site Sequencing). This experiment data contains sequence files generated using Nanopore and Illumina platforms. Biotin1308.fastq.gz and Biotin2508.fastq.gz are fastq files generated from nanopore technology. Rep1-Tn.fastq.gz and Rep1-Tn.fastq.gz are fastq files generated using Illumina platform. In this study, we have compared the efficiency of two methods in identification of transposon insertion sites.
Project description:DNA methylation in the form of 5-methylcytosine (5mC) is widespread in eukaryotes, while the presence of N6-methyladenine (6mA) has sparked considerable debate. Methodological disparities in quantifying and mapping 6mA in genomic DNA have fueled this controversy. Yet, the distantly related early branching fungi, ciliates and the algae Chlamydomonas reinhardtii exhibit robust 6mA methylation patterns, but the origin and evolution of 6mA remain unknown. Here we use Oxford Nanopore modified base calling to profile 6mA at base pair resolution in 18 unicellular eukaryotes spanning all major eukaryotic supergroups. Our results reveal that only species encoding the adenine methyltransferase AMT1 display robust genomic 6mA patterns. Notably, 6mA consistently accumulates downstream of transcriptional start sites, aligning with H3K4me3-enriched nucleosomes, suggesting a conserved role in placing transcriptionally permissive nucleosomes. Intriguingly, the recurrent loss of the 6mA pathway across eukaryotes, particularly in major multicellular lineages, implies a convergent alteration in the dual methylation system of the Last Eukaryotic Common Ancestor, which featured transcription-associated 6mA and repression-associated 5mC.
