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Defining binary phylogenetic trees using parsimony

Populations and Evolution 2022-09-08 v2 Combinatorics
Authors: Mareike Fischer
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Abstract

Phylogenetic (i.e. leaf-labeled) trees play a fundamental role in evolutionary research. A typical problem is to reconstruct such trees from data like DNA alignments (whose columns are often referred to as characters), and a simple optimization criterion for such reconstructions is maximum parsimony. It is generally assumed that this criterion works well for data in which state changes are rare. In the present manuscript, we prove that each phylogenetic tree TT with n20kn\geq 20 k leaves is uniquely defined by the set Ak(T)A_k(T), which consists of all characters with parsimony score kk on TT. This can be considered as a promising first step towards showing that maximum parsimony as a tree reconstruction criterion is justified when the number of changes in the data is relatively small.

Keywords

phylogenetics population genetics and evolution

Cite

@article{arxiv.2111.04385,
  title  = {Defining binary phylogenetic trees using parsimony},
  author = {Mareike Fischer},
  journal= {arXiv preprint arXiv:2111.04385},
  year   = {2022}
}

Comments

arXiv admin note: text overlap with arXiv:1808.07098

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