Abstract
Somatic transposon mutagenesis in mice is an efficient strategy to investigate the genetic mechanisms of tumorigenesis. The identification of tumor driving transposon insertions traditionally requires the generation of large tumor cohorts to obtain information about common insertion sites. Tumor driving insertions are also characterized by their clonal expansion in tumor tissue, a phenomenon that is facilitated by the slow and evolving transformation process of transposon mutagenesis. We describe here an improved approach for the detection of tumor driving insertions that assesses the clonal expansion of insertions by quantifying the relative proportion of sequence reads obtained in individual tumors. To this end, we have developed a protocol for insertion site sequencing that utilizes acoustic shearing of tumor DNA and Illumina sequencing. We analyzed various solid tumors generated by PiggyBac mutagenesis and for each tumor >106 reads corresponding to >104 insertion sites were obtained. In each tumor, 9 to 25 insertions stood out by their enriched sequence read frequencies when compared to frequencies obtained from tail DNA controls. These enriched insertions are potential clonally expanded tumor driving insertions, and thus identify candidate cancer genes. The candidate cancer genes of our study comprised many established cancer genes, but also novel candidate genes such as Mastermind-like1 (Mamld1) and Diacylglycerolkinase delta (Dgkd). We show that clonal expansion analysis by high-throughput sequencing is a robust approach for the identification of candidate cancer genes in insertional mutagenesis screens on the level of individual tumors.
Highlights
Somatic mutagenesis by DNA transposons in mice investigates the underlying genetics of tumorigenesis
Tumor driving candidate cancer genes are identified by common insertion site (CIS) analysis, a process of mapping insertions of multiple tumors and analysis of genes that are commonly hit in independent samples
CIS analysis has proven to be a successful approach for identification of candidate genes, it requires a considerable number of tumor samples (50-100 in most studies), and it delivers very little information about the mutation patterns in individual tumors
Summary
Somatic mutagenesis by DNA transposons in mice investigates the underlying genetics of tumorigenesis. Transposons harboring gene-activating or gene-trapping cassettes can activate oncogenes or disrupt tumor suppressors, thereby driving tumor growth [1]. In addition to their role in discovering novel cancer genes, transposon mutagenesis facilitates more detailed studies on genetic and cellular mechanisms of tumorigenesis by utilizing sensitizing background mutations and cell type-specific transposon activation [2]. Tumor driving candidate cancer genes are identified by common insertion site (CIS) analysis, a process of mapping insertions of multiple tumors and analysis of genes that are commonly hit in independent samples. CIS analysis has proven to be a successful approach for identification of candidate genes, it requires a considerable number of tumor samples (50-100 in most studies), and it delivers very little information about the mutation patterns in individual tumors
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