School of Mathematics and Statistics - Research Publications

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Author: Bowtell, David × Start date: 2000 ×

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    International network of cancer genome projects
    Hudson, TJ ; Anderson, W ; Aretz, A ; Barker, AD ; Bell, C ; Bernabe, RR ; Bhan, MK ; Calvo, F ; Eerola, I ; Gerhard, DS ; Guttmacher, A ; Guyer, M ; Hemsley, FM ; Jennings, JL ; Kerr, D ; Klatt, P ; Kolar, P ; Kusuda, J ; Lane, DP ; Laplace, F ; Lu, Y ; Nettekoven, G ; Ozenberger, B ; Peterson, J ; Rao, TS ; Remacle, J ; Schafer, AJ ; Shibata, T ; Stratton, MR ; Vockley, JG ; Watanabe, K ; Yang, H ; Yuen, MMF ; Knoppers, M ; Bobrow, M ; Cambon-Thomsen, A ; Dressler, LG ; Dyke, SOM ; Joly, Y ; Kato, K ; Kennedy, KL ; Nicolas, P ; Parker, MJ ; Rial-Sebbag, E ; Romeo-Casabona, CM ; Shaw, KM ; Wallace, S ; Wiesner, GL ; Zeps, N ; Lichter, P ; Biankin, AV ; Chabannon, C ; Chin, L ; Clement, B ; de Alava, E ; Degos, F ; Ferguson, ML ; Geary, P ; Hayes, DN ; Johns, AL ; Nakagawa, H ; Penny, R ; Piris, MA ; Sarin, R ; Scarpa, A ; van de Vijver, M ; Futreal, PA ; Aburatani, H ; Bayes, M ; Bowtell, DDL ; Campbell, PJ ; Estivill, X ; Grimmond, SM ; Gut, I ; Hirst, M ; Lopez-Otin, C ; Majumder, P ; Marra, M ; Ning, Z ; Puente, XS ; Ruan, Y ; Stunnenberg, HG ; Swerdlow, H ; Velculescu, VE ; Wilson, RK ; Xue, HH ; Yang, L ; Spellman, PT ; Bader, GD ; Boutros, PC ; Flicek, P ; Getz, G ; Guigo, R ; Guo, G ; Haussler, D ; Heath, S ; Hubbard, TJ ; Jiang, T ; Jones, SM ; Li, Q ; Lopez-Bigas, N ; Luo, R ; Pearson, JV ; Quesada, V ; Raphael, BJ ; Sander, C ; Speed, TP ; Stuart, JM ; Teague, JW ; Totoki, Y ; Tsunoda, T ; Valencia, A ; Wheeler, DA ; Wu, H ; Zhao, S ; Zhou, G ; Stein, LD ; Lathrop, M ; Ouellette, BFF ; Thomas, G ; Yoshida, T ; Axton, M ; Gunter, C ; McPherson, JD ; Miller, LJ ; Kasprzyk, A ; Zhang, J ; Haider, SA ; Wang, J ; Yung, CK ; Cross, A ; Liang, Y ; Gnaneshan, S ; Guberman, J ; Hsu, J ; Chalmers, DRC ; Hasel, KW ; Kaan, TSH ; Knoppers, BM ; Lowrance, WW ; Masui, T ; Rodriguez, LL ; Vergely, C ; Cloonan, N ; Defazio, A ; Eshleman, JR ; Etemadmoghadam, D ; Gardiner, BA ; Kench, JG ; Sutherland, RL ; Tempero, MA ; Waddell, NJ ; Wilson, PJ ; Gallinger, S ; Tsao, M-S ; Shaw, PA ; Petersen, GM ; Mukhopadhyay, D ; DePinho, RA ; Thayer, S ; Muthuswamy, L ; Shazand, K ; Beck, T ; Sam, M ; Timms, L ; Ballin, V ; Ji, J ; Zhang, X ; Chen, F ; Hu, X ; Yang, Q ; Tian, G ; Zhang, L ; Xing, X ; Li, X ; Zhu, Z ; Yu, Y ; Yu, J ; Tost, J ; Brennan, P ; Holcatova, I ; Zaridze, D ; Brazma, A ; Egevad, L ; Prokhortchouk, E ; Banks, RE ; Uhlen, M ; Viksna, J ; Ponten, F ; Skryabin, K ; Birney, E ; Borg, A ; Borresen-Dale, A-L ; Caldas, C ; Foekens, JA ; Martin, S ; Reis-Filho, JS ; Richardson, AL ; Sotiriou, C ; van't Veer, L ; Birnbaum, D ; Blanche, H ; Boucher, P ; Boyault, S ; Masson-Jacquemier, JD ; Pauporte, I ; Pivot, X ; Vincent-Salomon, A ; Tabone, E ; Theillet, C ; Treilleux, I ; Bioulac-Sage, P ; Decaens, T ; Franco, D ; Gut, M ; Samuel, D ; Zucman-Rossi, J ; Eils, R ; Brors, B ; Korbel, JO ; Korshunov, A ; Landgraf, P ; Lehrach, H ; Pfister, S ; Radlwimmer, B ; Reifenberger, G ; Taylor, MD ; von Kalle, C ; Majumder, PP ; Pederzoli, P ; Lawlor, RT ; Delledonne, M ; Bardelli, A ; Gress, T ; Klimstra, D ; Zamboni, G ; Nakamura, Y ; Miyano, S ; Fujimoto, A ; Campo, E ; de Sanjose, S ; Montserrat, E ; Gonzalez-Diaz, M ; Jares, P ; Himmelbaue, H ; Bea, S ; Aparicio, S ; Easton, DF ; Collins, FS ; Compton, CC ; Lander, ES ; Burke, W ; Green, AR ; Hamilton, SR ; Kallioniemi, OP ; Ley, TJ ; Liu, ET ; Wainwright, BJ (NATURE PORTFOLIO, 2010-04-15)
    The International Cancer Genome Consortium (ICGC) was launched to coordinate large-scale cancer genome studies in tumours from 50 different cancer types and/or subtypes that are of clinical and societal importance across the globe. Systematic studies of more than 25,000 cancer genomes at the genomic, epigenomic and transcriptomic levels will reveal the repertoire of oncogenic mutations, uncover traces of the mutagenic influences, define clinically relevant subtypes for prognosis and therapeutic management, and enable the development of new cancer therapies.
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    Statistical analysis of an RNA titration series evaluates microarray precision and sensitivity on a whole-array basis
    Holloway, AJ ; Oshlack, A ; Diyagama, DS ; Bowtell, DDL ; Smyth, GK (BMC, 2006-11-22)
    BACKGROUND: Concerns are often raised about the accuracy of microarray technologies and the degree of cross-platform agreement, but there are yet no methods which can unambiguously evaluate precision and sensitivity for these technologies on a whole-array basis. RESULTS: A methodology is described for evaluating the precision and sensitivity of whole-genome gene expression technologies such as microarrays. The method consists of an easy-to-construct titration series of RNA samples and an associated statistical analysis using non-linear regression. The method evaluates the precision and responsiveness of each microarray platform on a whole-array basis, i.e., using all the probes, without the need to match probes across platforms. An experiment is conducted to assess and compare four widely used microarray platforms. All four platforms are shown to have satisfactory precision but the commercial platforms are superior for resolving differential expression for genes at lower expression levels. The effective precision of the two-color platforms is improved by allowing for probe-specific dye-effects in the statistical model. The methodology is used to compare three data extraction algorithms for the Affymetrix platforms, demonstrating poor performance for the commonly used proprietary algorithm relative to the other algorithms. For probes which can be matched across platforms, the cross-platform variability is decomposed into within-platform and between-platform components, showing that platform disagreement is almost entirely systematic rather than due to measurement variability. CONCLUSION: The results demonstrate good precision and sensitivity for all the platforms, but highlight the need for improved probe annotation. They quantify the extent to which cross-platform measures can be expected to be less accurate than within-platform comparisons for predicting disease progression or outcome.
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    Deregulation of MYCN, LIN28B and LET7 in a Molecular Subtype of Aggressive High-Grade Serous Ovarian Cancers
    Helland, A ; Anglesio, MS ; George, J ; Cowin, PA ; Johnstone, CN ; House, CM ; Sheppard, KE ; Etemadmoghadam, D ; Melnyk, N ; Rustgi, AK ; Phillips, WA ; Johnsen, H ; Holm, R ; Kristensen, GB ; Birrer, MJ ; Pearson, RB ; Borresen-Dale, A-L ; Huntsman, DG ; deFazio, A ; Creighton, CJ ; Smyth, GK ; Bowtell, DDL ; Tan, P (PUBLIC LIBRARY SCIENCE, 2011-04-13)
    Molecular subtypes of serous ovarian cancer have been recently described. Using data from independent datasets including over 900 primary tumour samples, we show that deregulation of the Let-7 pathway is specifically associated with the C5 molecular subtype of serous ovarian cancer. DNA copy number and gene expression of HMGA2, alleles of Let-7, LIN28, LIN28B, MYC, MYCN, DICER1, and RNASEN were measured using microarray and quantitative reverse transcriptase PCR. Immunohistochemistry was performed on 127 samples using tissue microarrays and anti-HMGA2 antibodies. Fluorescence in situ hybridisation of bacterial artificial chromosomes hybridized to 239 ovarian tumours was used to measure translocation at the LIN28B locus. Short interfering RNA knockdown in ovarian cell lines was used to test the functionality of associations observed. Four molecular subtypes (C1, C2, C4, C5) of high-grade serous ovarian cancers were robustly represented in each dataset and showed similar pattern of patient survival. We found highly specific activation of a pathway involving MYCN, LIN28B, Let-7 and HMGA2 in the C5 molecular subtype defined by MYCN amplification and over-expression, over-expression of MYCN targets including the Let-7 repressor LIN28B, loss of Let-7 expression and HMGA2 amplification and over-expression. DICER1, a known Let-7 target, and RNASEN were over-expressed in C5 tumours. We saw no evidence of translocation at the LIN28B locus in C5 tumours. The reported interaction between LIN28B and Let-7 was recapitulated by siRNA knockdown in ovarian cancer cell lines. Our results associate deregulation of MYCN and downstream targets, including Let-7 and oncofetal genes, with serous ovarian cancer. We define for the first time how elements of an oncogenic pathway, involving multiple genes that contribute to stem cell renewal, is specifically altered in a molecular subtype of serous ovarian cancer. By defining the drivers of a molecular subtype of serous ovarian cancers we provide a novel strategy for targeted therapeutic intervention.
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    Copy Number Analysis Identifies Novel Interactions Between Genomic Loci in Ovarian Cancer
    Gorringe, KL ; George, J ; Anglesio, MS ; Ramakrishna, M ; Etemadmoghadam, D ; Cowin, P ; Sridhar, A ; Williams, LH ; Boyle, SE ; Yanaihara, N ; Okamoto, A ; Urashima, M ; Smyth, GK ; Campbell, IG ; Bowtell, DDL ; Jordan, IK (PUBLIC LIBRARY SCIENCE, 2010-09-10)
    Ovarian cancer is a heterogeneous disease displaying complex genomic alterations, and consequently, it has been difficult to determine the most relevant copy number alterations with the scale of studies to date. We obtained genome-wide copy number alteration (CNA) data from four different SNP array platforms, with a final data set of 398 ovarian tumours, mostly of the serous histological subtype. Frequent CNA aberrations targeted many thousands of genes. However, high-level amplicons and homozygous deletions enabled filtering of this list to the most relevant. The large data set enabled refinement of minimal regions and identification of rare amplicons such as at 1p34 and 20q11. We performed a novel co-occurrence analysis to assess cooperation and exclusivity of CNAs and analysed their relationship to patient outcome. Positive associations were identified between gains on 19 and 20q, gain of 20q and loss of X, and between several regions of loss, particularly 17q. We found weak correlations of CNA at genomic loci such as 19q12 with clinical outcome. We also assessed genomic instability measures and found a correlation of the number of higher amplitude gains with poorer overall survival. By assembling the largest collection of ovarian copy number data to date, we have been able to identify the most frequent aberrations and their interactions.
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    Amplicon-Dependent CCNE1 Expression Is Critical for Clonogenic Survival after Cisplatin Treatment and Is Correlated with 20q11 Gain in Ovarian Cancer
    Etemadmoghadam, D ; George, J ; Cowin, PA ; Cullinane, C ; Kansara, M ; Gorringe, KL ; Smyth, GK ; Bowtell, DDL ; Wong, N (PUBLIC LIBRARY SCIENCE, 2010-11-12)
    Genomic amplification of 19q12 occurs in several cancer types including ovarian cancer where it is associated with primary treatment failure. We systematically attenuated expression of genes within the minimally defined 19q12 region in ovarian cell lines using short-interfering RNAs (siRNA) to identify driver oncogene(s) within the amplicon. Knockdown of CCNE1 resulted in G1/S phase arrest, reduced cell viability and apoptosis only in amplification-carrying cells. Although CCNE1 knockdown increased cisplatin resistance in short-term assays, clonogenic survival was inhibited after treatment. Gain of 20q11 was highly correlated with 19q12 amplification and spanned a 2.5 Mb region including TPX2, a centromeric protein required for mitotic spindle function. Expression of TPX2 was highly correlated with gene amplification and with CCNE1 expression in primary tumors. siRNA inhibition of TPX2 reduced cell viability but this effect was not amplicon-dependent. These findings demonstrate that CCNE1 is a key driver in the 19q12 amplicon required for survival and clonogenicity in cells with locus amplification. Co-amplification at 19q12 and 20q11 implies the presence of a cooperative mutational network. These observations have implications for the application of targeted therapies in CCNE1 dependent ovarian cancers.
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    The Subclonal Architecture of Metastatic Breast Cancer: Results from a Prospective Community-Based Rapid Autopsy Program "CASCADE"
    Savas, P ; Teo, ZL ; Lefevre, C ; Flensburg, C ; Caramia, F ; Alsop, K ; Mansour, M ; Francis, PA ; Thorne, HA ; Silva, MJ ; Kanu, N ; Dietzen, M ; Rowan, A ; Kschischo, M ; Fox, S ; Bowtell, DD ; Dawson, S-J ; Speed, TP ; Swanton, C ; Loi, S ; Ladanyi, M (PUBLIC LIBRARY SCIENCE, 2016-12)
    BACKGROUND: Understanding the cancer genome is seen as a key step in improving outcomes for cancer patients. Genomic assays are emerging as a possible avenue to personalised medicine in breast cancer. However, evolution of the cancer genome during the natural history of breast cancer is largely unknown, as is the profile of disease at death. We sought to study in detail these aspects of advanced breast cancers that have resulted in lethal disease. METHODS AND FINDINGS: Three patients with oestrogen-receptor (ER)-positive, human epidermal growth factor receptor 2 (HER2)-negative breast cancer and one patient with triple negative breast cancer underwent rapid autopsy as part of an institutional prospective community-based rapid autopsy program (CASCADE). Cases represented a range of management problems in breast cancer, including late relapse after early stage disease, de novo metastatic disease, discordant disease response, and disease refractory to treatment. Between 5 and 12 metastatic sites were collected at autopsy together with available primary tumours and longitudinal metastatic biopsies taken during life. Samples underwent paired tumour-normal whole exome sequencing and single nucleotide polymorphism (SNP) arrays. Subclonal architectures were inferred by jointly analysing all samples from each patient. Mutations were validated using high depth amplicon sequencing. Between cases, there were significant differences in mutational burden, driver mutations, mutational processes, and copy number variation. Within each case, we found dramatic heterogeneity in subclonal structure from primary to metastatic disease and between metastatic sites, such that no single lesion captured the breadth of disease. Metastatic cross-seeding was found in each case, and treatment drove subclonal diversification. Subclones displayed parallel evolution of treatment resistance in some cases and apparent augmentation of key oncogenic drivers as an alternative resistance mechanism. We also observed the role of mutational processes in subclonal evolution. Limitations of this study include the potential for bias introduced by joint analysis of formalin-fixed archival specimens with fresh specimens and the difficulties in resolving subclones with whole exome sequencing. Other alterations that could define subclones such as structural variants or epigenetic modifications were not assessed. CONCLUSIONS: This study highlights various mechanisms that shape the genome of metastatic breast cancer and the value of studying advanced disease in detail. Treatment drives significant genomic heterogeneity in breast cancers which has implications for disease monitoring and treatment selection in the personalised medicine paradigm.