Somatic structural rearrangements in genetically engineered mouse mammary tumors

Background: Here we present the first paired-end sequencing of tumors from genetically engineered mouse models of cancer to determine how faithfully these models recapitulate the landscape of somatic rearrangements found in human tumors. These were models of Trp53-mutated breast cancer, Brca1- and Brca2-associated hereditary breast cancer, and E-cadherin (Cdh1) mutated lobular breast cancer. Results: We show that although Brca1- and Brca2-deficient mouse mammary tumors have a defect in the homologous recombination pathway, there is no apparent difference in the type or frequency of somatic rearrangements found in these cancers when compared to other mouse mammary cancers, and tumors from all genetic backgrounds showed evidence of microhomology-mediated repair and non-homologous end-joining processes. Importantly, mouse mammary tumors were found to carry fewer structural rearrangements than human mammary cancers and expressed in-frame fusion genes. Like the fusion genes found in human mammary tumors, these were not recurrent. One mouse tumor was found to contain an internal deletion of exons of the Lrp1b gene, which led to a smaller in-frame transcript. We found internal in-frame deletions in the human ortholog of this gene in a significant number (4.2%) of human cancer cell lines. Conclusions: Paired-end sequencing of mouse mammary tumors revealed that they display significant heterogeneity in their profiles of somatic rearrangement but, importantly, fewer rearrangements than cognate human mammary tumors, probably because these cancers have been induced by strong driver mutations engineered into the mouse genome. Both human and mouse mammary cancers carry expressed fusion genes and conserved homozygous deletions.MediamaticsElectrical Engineering, Mathematics and Computer Scienc

Somatic SF3B1 Mutation in Myelodysplasia with Ring Sideroblasts

Chronic Myeloid Disorders Working Group of the International Cancer Genome Consortium.-- et al.The myelodysplastic syndromes are a heterogeneous group of hematologic cancers characterized by low blood counts, most commonly anemia, and a risk of progression to acute myeloid leukemia.1 These disorders have increased in prevalence and are expected to continue to do so. Blood films and bone marrow¿biopsy specimens from patients with myelodysplastic syndromes show dysplastic changes in myeloid cells, with abnormal proliferation and differentiation of one or more lineages. Target genes of recurrent chromosomal aberrations have been mapped,2,3 and several genes have been identified as recurrently mutated in these disorders, including NRAS (encoding neuroblastoma RAS viral oncogene homologue), TP53 (encoding tumor protein p53), RUNX1 (encoding runt-related transcription factor 1), CBL (encoding Cas-Br-M ecotropic retroviral transforming sequence),4,5 TET2 (encoding tet oncogene family member 2),6,7 ASXL1 (encoding additional sex combs¿like protein 1),8,9 and EZH2 (encoding enhancer of zeste homologue 2).10 With the exception of TET2, most of these genes are mutated in no more than 5 to 15% of cases, and generally the mutation rates are lower in the more benign subtypes of the disease. The myelodysplastic syndromes can be divided into several categories on the basis of bone marrow and peripheral-blood morphologic characteristics and cytogenetic changes.11 In low-risk disease, such as refractory anemia, cytopenias are the major clinical challenge, whereas high-risk disease, such as refractory anemia with excess blasts, is characterized by both cytopenias and a high rate of transformation to acute myeloid leukemia. More than a quarter of patients with myelodysplastic syndromes have large numbers of ring sideroblasts in the bone marrow,12 a sufficiently distinctive morphologic abnormality to warrant a separate designation. Ring sideroblasts are characteristically seen on iron staining of bone marrow aspirates as differentiating erythroid cells with a complete or partial ring of iron-laden mitochondria surrounding the nucleus. Several genetic lesions underpinning inherited sideroblastic anemias have been identified,13 including loss-of-function mutations in the genes ALAS2 (encoding delta aminolevulinate synthase 2), ABCB7 (encoding ATP-binding cassette, subfamily B, member 7), and SLC25A38 (solute carrier family 25, member 38). The pathogenesis of ring sideroblasts in myelodysplastic syndromes, however, remains obscure, although gene-expression studies have revealed up-regulation of genes involved in heme synthesis (including ALAS2) and down-regulation of ABCB7.14,15 We reasoned that the identification of recurrently mutated cancer genes in low-grade myelodysplastic syndromes could prove useful for the diagnosis of these disorders and provide new insights into the molecular pathogenesis of these syndromesSupported by grants from the Wellcome Trust (077012/Z/05/Z, for the overall study, as well as WT088340MA, to Dr. Campbell), the Kay Kendall Leukaemia Fund, Leukemia Lymphoma Research (for the overall study and to Drs. Boultwood, Green, Vyas, and Wainscoat), the Adenoid Cystic Carcinoma Research Foundation, the Medical Research Council (MRC) (to Dr. Warren), the Oxford National Institutes for Health Research Biomedical Research Centre (to Drs. Boultwood, Vyas, and Wainscoat), the Swedish Cancer Society (to Dr. Hellstrom-Lindburg), the International Human Frontier Science Program Organization (to Dr. Varela), the Department of Veterans Affairs and the National Institutes of Health (R01-124929, P01-155249, P50- 100007, and P01-78378, to Drs. Munshi and Anderson), the Association for International Cancer Research and the Leukemia Lymphoma Society (to Drs. Warren and Green), Associazione Italiana per la Ricerca sul Cancro (to the University of Pavia, the University of Milan Bicocca, and Dr. Cazzola), and Fondazione Cariplo (to the University of Pavia and the University of Milan Bicocca).Peer Reviewe

Extensive transduction of nonrepetitive DNA mediated by L1 retrotransposition in cancer genomes

Long interspersed nuclear element–1 (L1) retrotransposons are mobile repetitive elements that are abundant in the human genome. L1 elements propagate through RNA intermediates. In the germ line, neighboring, nonrepetitive sequences are occasionally mobilized by the L1 machinery, a process called 3′ transduction. Because 3′ transductions are potentially mutagenic, we explored the extent to which they occur somatically during tumorigenesis. Studying cancer genomes from 244 patients, we found that tumors from 53% of the patients had somatic retrotranspositions, of which 24% were 3′ transductions. Fingerprinting of donor L1s revealed that a handful of source L1 elements in a tumor can spawn from tens to hundreds of 3′ transductions, which can themselves seed further retrotranspositions. The activity of individual L1 elements fluctuated during tumor evolution and correlated with L1 promoter hypomethylation. The 3′ transductions disseminated genes, exons, and regulatory elements to new locations, most often to heterochromatic regions of the genome