Sir Peter MacCallum Department of Oncology - Research Publications

Permanent URI for this collection

http://hdl.handle.net/11343/274

Filters

2013 - 2020 5
4 1
Reset filters

Settings
Statistics
Citations
Author: Goode, David × Author: Doyle, Maria ×

Search Results

Now showing 1 - 5 of 5
  • Item
    Thumbnail Image
    Atypical ductal hyperplasia is a multipotent precursor of breast carcinoma
    Kader, T ; Hill, P ; Zethoven, M ; Goode, DL ; Elder, K ; Thio, N ; Doyle, M ; Semple, T ; Sufyan, W ; Byrne, DJ ; Pang, J-MB ; Murugasu, A ; Miligy, IM ; Green, AR ; Rakha, EA ; Fox, SB ; Mann, GB ; Campbell, IG ; Gorringe, KL (WILEY, 2019-07)
  • Item
    Thumbnail Image
    A TOOLKIT FOR THE QUANTITATIVE ANALYSIS OF THE SPATIAL DISTRIBUTION OF CELLS OF THE TUMOR IMMUNE MICROENVIRONMENT
    Trigos, A ; Yang, T ; Feng, Y ; Ozcoban, V ; Doyle, M ; Pasam, A ; Kocovski, N ; Pizzolla, A ; Huang, Y-K ; Bass, G ; Keam, S ; Speed, T ; Neeson, P ; Sandhu, S ; Goode, D (BMJ PUBLISHING GROUP, 2020-11)
  • Item
    Thumbnail Image
    A simple consensus approach improves somatic mutation prediction accuracy
    Goode, DL ; Hunter, SM ; Doyle, MA ; Ma, T ; Rowley, SM ; Choong, D ; Ryland, GL ; Campbell, IG (BMC, 2013-09-30)
    Differentiating true somatic mutations from artifacts in massively parallel sequencing data is an immense challenge. To develop methods for optimal somatic mutation detection and to identify factors influencing somatic mutation prediction accuracy, we validated predictions from three somatic mutation detection algorithms, MuTect, JointSNVMix2 and SomaticSniper, by Sanger sequencing. Full consensus predictions had a validation rate of >98%, but some partial consensus predictions validated too. In cases of partial consensus, read depth and mapping quality data, along with additional prediction methods, aided in removing inaccurate predictions. Our consensus approach is fast, flexible and provides a high-confidence list of putative somatic mutations.
  • Item
    Thumbnail Image
    Loss of heterozygosity: what is it good for?
    Ryland, GL ; Doyle, MA ; Goode, D ; Boyle, SE ; Choong, DYH ; Rowley, SM ; Li, J ; Bowtell, DDL ; Tothill, RW ; Campbell, IG ; Gorringe, KL (BMC, 2015-08-01)
    BACKGROUND: Loss of heterozygosity (LOH) is a common genetic event in cancer development, and is known to be involved in the somatic loss of wild-type alleles in many inherited cancer syndromes. The wider involvement of LOH in cancer is assumed to relate to unmasking a somatically mutated tumour suppressor gene through loss of the wild type allele. METHODS: We analysed 86 ovarian carcinomas for mutations in 980 genes selected on the basis of their location in common regions of LOH. RESULTS: We identified 36 significantly mutated genes, but these could only partly account for the quanta of LOH in the samples. Using our own and TCGA data we then evaluated five possible models to explain the selection for non-random accumulation of LOH in ovarian cancer genomes: 1. Classic two-hit hypothesis: high frequency biallelic genetic inactivation of tumour suppressor genes. 2. Epigenetic two-hit hypothesis: biallelic inactivation through methylation and LOH. 3. Multiple alternate-gene biallelic inactivation: low frequency gene disruption. 4. Haplo-insufficiency: Single copy gene disruption. 5. Modified two-hit hypothesis: reduction to homozygosity of low penetrance germline predisposition alleles. We determined that while high-frequency biallelic gene inactivation under model 1 is rare, regions of LOH (particularly copy-number neutral LOH) are enriched for deleterious mutations and increased promoter methylation, while copy-number loss LOH regions are likely to contain under-expressed genes suggestive of haploinsufficiency. Reduction to homozygosity of cancer predisposition SNPs may also play a minor role. CONCLUSION: It is likely that selection for regions of LOH depends on its effect on multiple genes. Selection for copy number neutral LOH may better fit the classic two-hit model whereas selection for copy number loss may be attributed to its effect on multi-gene haploinsufficiency. LOH mapping alone is unlikely to be successful in identifying novel tumour suppressor genes; a combined approach may be more effective.
  • Item
    Thumbnail Image
    Bioinformatics Pipelines for Targeted Resequencing and Whole-Exome Sequencing of Human and Mouse Genomes: A Virtual Appliance Approach for Instant Deployment
    Li, J ; Doyle, MA ; Saeed, I ; Wong, SQ ; Mar, V ; Goode, DL ; Caramia, F ; Doig, K ; Ryland, GL ; Thompson, ER ; Hunter, SM ; Halgamuge, SK ; Ellul, J ; Dobrovic, A ; Campbell, IG ; Papenfuss, AT ; McArthur, GA ; Tothill, RW ; Calogero, RA (PUBLIC LIBRARY SCIENCE, 2014-04-21)
    Targeted resequencing by massively parallel sequencing has become an effective and affordable way to survey small to large portions of the genome for genetic variation. Despite the rapid development in open source software for analysis of such data, the practical implementation of these tools through construction of sequencing analysis pipelines still remains a challenging and laborious activity, and a major hurdle for many small research and clinical laboratories. We developed TREVA (Targeted REsequencing Virtual Appliance), making pre-built pipelines immediately available as a virtual appliance. Based on virtual machine technologies, TREVA is a solution for rapid and efficient deployment of complex bioinformatics pipelines to laboratories of all sizes, enabling reproducible results. The analyses that are supported in TREVA include: somatic and germline single-nucleotide and insertion/deletion variant calling, copy number analysis, and cohort-based analyses such as pathway and significantly mutated genes analyses. TREVA is flexible and easy to use, and can be customised by Linux-based extensions if required. TREVA can also be deployed on the cloud (cloud computing), enabling instant access without investment overheads for additional hardware. TREVA is available at http://bioinformatics.petermac.org/treva/.