Phylogenetic analysis of multiprobe fluorescence <i>in situ</i> hybridization data from tumor cell populations

Chowdhury, Saiful M.; Shackney, Stanley E.; Heselmeyer‐Haddad, Kerstin; Ried, Thomas; Schäffer, Alejandro A.; Schwartz, Russell

doi:10.1093/bioinformatics/btt205

Cited by 44 publications

(67 citation statements)

References 46 publications

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“…Only recently have new phylogeny algorithms emerged to deal with the peculiarities of tumour versus species evolution 84–88 . In the next section, we survey the diversity of methods available, with particular focus on those suited to modern sequencing technologies.…”

Section: Overview Of Tumour Phylogeneticsmentioning

confidence: 99%

“…1c). Single-cell tumour phylogenetics predates single-cell sequencing (scSeq), as it was applied through various older methods offering more limited profiling of single cells via microsatellite 76 or FISH 69 markers; such approaches remain valuable owing to their ability to examine much larger numbers of cells than scSeq 39,84,149 (TABLE 3). Nevertheless, the introduction of scSeq to tumour phylogenetics by Navin et al 71 deserves much of the credit for bringing tumour phylogenetics into the mainstream of cancer research.…”

Section: Variations On Tumour Phylogeneticsmentioning

confidence: 99%

“…The majority of published tools for single-cell phylogenetics are still based on pre-scSeq technologies 84,148,151–153 , with just a handful having been developed specifically for scSeq. Kim and Simon 89 introduced the muttree program, which uses a custom combinatorial inference to find trees optimized for a specialized probabilistic model that differs from the models used by other tools which accept the same input.…”

Section: Variations On Tumour Phylogeneticsmentioning

confidence: 99%

“…There are models for representing the more complex nature of evolution by CNVs versus evolution by SNVs 51 , and there are some custom-designed phylogeny tools for specific variants of CNV evolution 43,69,84,85,151,152 . A Bayesian probabilistic model, as has been used in many tumour phylogeny approaches 47,79,86,135 , can handle arbitrarily complex evolutionary scenarios and is well suited to learning the complicated lineage-specific rate parameters one would need for such a model 78,101,152 , given the diversity of CNV hypermutability mechanisms any given tumour might exhibit 20,25,94,161 .…”

Section: An Illustrative Tutorialmentioning

confidence: 99%

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The evolution of tumour phylogenetics: principles and practice

2017

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Rapid advances in high-throughput sequencing and a growing realization of the importance of evolutionary theory to cancer genomics have led to a proliferation of phylogenetic studies of tumour progression. These studies have yielded not only new insights but also a plethora of experimental approaches, sometimes reaching conflicting or poorly supported conclusions. Here, we consider this body of work in light of the key computational principles underpinning phylogenetic inference, with the goal of providing practical guidance on the design and analysis of scientifically rigorous tumour phylogeny studies. We survey the range of methods and tools available to the researcher, their key applications, and the various unsolved problems, closing with a perspective on the prospects and broader implications of this field.

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Section: Overview Of Tumour Phylogeneticsmentioning

confidence: 99%

Section: Variations On Tumour Phylogeneticsmentioning

confidence: 99%

Section: Variations On Tumour Phylogeneticsmentioning

confidence: 99%

Section: An Illustrative Tutorialmentioning

confidence: 99%

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The evolution of tumour phylogenetics: principles and practice

2017

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“…The trees allow us to learn markers of progression driving key steps in tumor evolution, identify and classify tumor subtypes with possibly different underlying mechanisms of action, and enable predictive modeling of future stages of progression. Much prior work has shown the utility of tumor phylogenies using data from singlecell Fluorescent In-Situ Hybridization (FISH) [12][13][14][15] and microarray technologies [16,17]. Advances in deep sequencing technology, particularly single-cell sequencing [18,19], have extended this interest by promising a granular view of heterogeneity and progression within a single tumor.…”

Section: Introductionmentioning

confidence: 99%

Reference-free inference of tumor phylogenies from single-cell sequencing data

Subramanian

Schwartz

2014

2014 IEEE 4th International Conference on Computational Advances in Bio and Medical Sciences (ICCABS)

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Background: Effective management and treatment of cancer continues to be complicated by the rapid evolution and resulting heterogeneity of tumors. Phylogenetic study of cell populations in single tumors provides a way to delineate intra-tumoral heterogeneity and identify robust features of evolutionary processes. The introduction of single-cell sequencing has shown great promise for advancing single-tumor phylogenetics; however, the volume and high noise in these data present challenges for inference, especially with regard to chromosome abnormalities that typically dominate tumor evolution. Here, we investigate a strategy to use such data to track differences in tumor cell genomic content during progression. Results: We propose a reference-free approach to mining single-cell genome sequence reads to allow predictive classification of tumors into heterogeneous cell types and reconstruct models of their evolution. The approach extracts k-mer counts from single-cell tumor genomic DNA sequences, and uses differences in normalized k-mer frequencies as a proxy for overall evolutionary distance between distinct cells. The approach computationally simplifies deriving phylogenetic markers, which normally relies on first aligning sequence reads to a reference genome and then processing the data to extract meaningful progression markers for constructing phylogenetic trees. The approach also provides a way to bypass some of the challenges that massive genome rearrangement typical of tumor genomes presents for reference-based methods. We illustrate the method on a publicly available breast tumor single-cell sequencing dataset.

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Intravital biobank and personalized cancer therapy: The correlation with omics

Luo

Guo

Tang

et al. 2013

Intl Journal of Cancer

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Biobanks have played a decisive role in all aspects of the field of cancer, including pathogenesis, diagnosis, prognosis and treatment. The significance of cancer biobanks is epitomized through the appropriate application of various “‐omic” techniques (omics). The mutually motivated relationship between biobanks and omics has intensified the development of cancer research. Human cancer tissues that are maintained in intravital biobanks (or living tissue banks) retain native tumor microenvironment, tissue architecture, hormone responsiveness and cell‐to‐cell signalling properties. Intravital biobanks replicate the structural complexity and heterogeneity of human cancers, making them an ideal platform for preclinical studies. The application of omics with intravital biobanks renders them more active, which makes it possible for the cancer‐related evaluations to be dynamically monitored on a real‐time basis. Integrating intravital biobank and modern omics will provide a useful tool for the discovery and development of new drugs or novel therapeutic strategies. More importantly, intravital biobanks may play an essential role in the creation of meaningful patient‐tailored therapies as for personalized medicine.

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Phylogenetic analysis of multiprobe fluorescence in situ hybridization data from tumor cell populations

Cited by 44 publications

References 46 publications

The evolution of tumour phylogenetics: principles and practice

The evolution of tumour phylogenetics: principles and practice

Reference-free inference of tumor phylogenies from single-cell sequencing data

Intravital biobank and personalized cancer therapy: The correlation with omics

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