Whole genome sequencing of tumour sample for triple negative breast cancer patient SA595
Whole genome sequencing of tumour sample for triple negative breast cancer patient SA276
Whole genome sequencing of normal sample for triple negative breast cancer patient SA402
Whole genome sequencing of tumour sample for triple negative breast cancer patient SA655
Whole genome sequencing of normal sample for triple negative breast cancer patient SA535
Whole genome sequencing of normal sample for triple negative breast cancer patient SA665
Whole genome sequencing of normal sample for triple negative breast cancer patient SA404
Whole genome sequencing of tumour sample for triple negative breast cancer patient SA279
Targeted NanoSeq in buccal epithelium obtained longitudinally from a number of donors. A custom-designed panel of ~200 genes will be used to achieve high depth coverage (aiming for ~1000X at panel sites).As we age, many tissues become colonised by microscopic clones carrying somatic driver mutations. Some of these clones represent a first step towards cancer whereas others may contribute to ageing and other diseases. However, our understanding of the clonal landscapes of human tissues, and their impact on cancer risk, ageing and disease, remains limited due to the challenge of detecting somatic mutations present in small numbers of cells. Here, we introduce a new version of nanorate sequencing (NanoSeq), a duplex sequencing method with error rates of less than 55 per billion base pairs, which is compatible with whole-exome and targeted gene sequencing. Deep sequencing of polyclonal samples with single-molecule sensitivity enables the simultaneous detection of mutations in large numbers of clones, yielding accurate somatic mutation rates, mutational signatures and driver mutation frequencies in any tissue. Applying targeted NanoSeq to 1,042 non-invasive samples of oral epithelium and 371 samples of blood from a twin cohort, we found an unprecedentedly rich landscape of selection, with 46 genes under positive selection driving clonal expansions in the oral epithelium, over 62,000 driver mutations, and evidence of negative selection in some genes. The high number of positively selected mutations in multiple genes provides high-resolution maps of selection across coding and non-coding sites, a form of in vivo saturation mutagenesis. Multivariate regression models enable mutational epidemiology studies on how carcinogenic exposures and cancer risk factors, such as age, tobacco or alcohol, alter the acquisition and selection of somatic mutations. Accurate single-molecule sequencing has the potential to unveil the polyclonal landscape of any tissue, providing a powerful tool to study early carcinogenesis, cancer prevention and the role of somatic mutations in ageing and disease.
Genome and transcriptome sequence data from a metastatic neuroendocrine tumor, lung primary patient, generated as part of the BC Cancer Agency's Personalized OncoGenomics (POG) study
