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Comparative Lesions Analysis Through a Targeted Sequencing Approach
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A weighted distance-based approach for deriving consensus tumor evolutionary trees.

Ziyun Guang1, Matthew Smith-Erb1, Layla Oesper1

  • 1Department of Computer Science, Carleton College, Northfield, MN 55057, USA.

Bioinformatics (Oxford, England)
|June 30, 2023
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Summary
This summary is machine-generated.

We developed TuELiP, an algorithm to create a consensus tumor evolutionary tree from multiple inferred trees. This method improves accuracy by incorporating confidence weights, outperforming existing approaches on simulated and real cancer data.

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Area of Science:

  • Computational biology
  • Cancer genomics
  • Phylogenetics

Background:

  • Somatic mutations in tumors form evolutionary trees, but these are inferred, not directly observed.
  • Existing algorithms can yield conflicting tumor trees for the same patient.
  • Combining multiple inferred tumor trees into a consensus tree is crucial for accurate evolutionary history reconstruction.

Purpose of the Study:

  • To introduce the Weighted m-Tumor Tree Consensus Problem (W-m-TTCP) for creating consensus tumor trees.
  • To present TuELiP, an algorithm solving the W-m-TTCP using integer linear programming.
  • To enable differential weighting of input tumor trees for improved consensus.

Main Methods:

  • Integer linear programming formulation for the Weighted m-Tumor Tree Consensus Problem.
  • Development of the TuELiP algorithm to solve the W-m-TTCP.
  • Evaluation using simulated datasets and a Triple-Negative Breast Cancer dataset.

Main Results:

  • TuELiP demonstrated superior performance in identifying the true evolutionary tree compared to two existing methods on simulated data.
  • Incorporating confidence weights into the consensus process led to more accurate tree inference.
  • Analysis of a Triple-Negative Breast Cancer dataset highlighted the significant impact of confidence weights on the resulting consensus tree.

Conclusions:

  • TuELiP provides an effective method for constructing weighted consensus tumor evolutionary trees.
  • The use of confidence weights enhances the accuracy of phylogenetic inference in cancer genomics.
  • The TuELiP algorithm and associated data are publicly available for further research.