期刊论文详细信息
BMC Bioinformatics
Applying unmixing to gene expression data for tumor phylogeny inference
Methodology Article
Russell Schwartz1  Stanley E Shackney2 
[1] Department of Biological Sciences, Carnegie Mellon University, Pittsburgh, PA, USA;Departments of Human Oncology and Human Genetics, Drexel University School of Medicine, Pittsburgh, PA, USA;
关键词: Independent Component Analysis;    Carcinoid Tumor;    Mixture Component;    Steiner Tree;    Mixture Fraction;   
DOI  :  10.1186/1471-2105-11-42
 received in 2009-07-27, accepted in 2010-01-20,  发布年份 2010
来源: Springer
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【 摘 要 】

BackgroundWhile in principle a seemingly infinite variety of combinations of mutations could result in tumor development, in practice it appears that most human cancers fall into a relatively small number of "sub-types," each characterized a roughly equivalent sequence of mutations by which it progresses in different patients. There is currently great interest in identifying the common sub-types and applying them to the development of diagnostics or therapeutics. Phylogenetic methods have shown great promise for inferring common patterns of tumor progression, but suffer from limits of the technologies available for assaying differences between and within tumors. One approach to tumor phylogenetics uses differences between single cells within tumors, gaining valuable information about intra-tumor heterogeneity but allowing only a few markers per cell. An alternative approach uses tissue-wide measures of whole tumors to provide a detailed picture of averaged tumor state but at the cost of losing information about intra-tumor heterogeneity.ResultsThe present work applies "unmixing" methods, which separate complex data sets into combinations of simpler components, to attempt to gain advantages of both tissue-wide and single-cell approaches to cancer phylogenetics. We develop an unmixing method to infer recurring cell states from microarray measurements of tumor populations and use the inferred mixtures of states in individual tumors to identify possible evolutionary relationships among tumor cells. Validation on simulated data shows the method can accurately separate small numbers of cell states and infer phylogenetic relationships among them. Application to a lung cancer dataset shows that the method can identify cell states corresponding to common lung tumor types and suggest possible evolutionary relationships among them that show good correspondence with our current understanding of lung tumor development.ConclusionsUnmixing methods provide a way to make use of both intra-tumor heterogeneity and large probe sets for tumor phylogeny inference, establishing a new avenue towards the construction of detailed, accurate portraits of common tumor sub-types and the mechanisms by which they develop. These reconstructions are likely to have future value in discovering and diagnosing novel cancer sub-types and in identifying targets for therapeutic development.

【 授权许可】

CC BY   
© Schwartz and Shackney; licensee BioMed Central Ltd. 2010

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