'TreeDist' is an R package that implements a suite of metrics that quantify the topological distance between pairs of unweighted phylogenetic trees. It also includes a simple 'Shiny' application to allow the visualization of distance-based tree spaces, and functions to calculate the information content of trees and splits.
'TreeDist' primarily employs metrics in the category of 'generalized Robinson–Foulds distances': they are based on comparing splits (bipartitions) between trees, and thus reflect the relationship data within trees, with no reference to branch lengths.
The Robinson-Foulds distance simply tallies the number of non-trivial splits (sometimes inaccurately termed clades, nodes or edges) that occur in both trees – any splits that are not perfectly identical contribute one point to the distance score of zero, however similar or different they are. By overlooking potential similarities between almost-identical splits, this conservative approach has undesirable properties.
'Generalized' RF metrics generate matchings that pair splits in one tree with similar splits in the other. Each pair of splits is assigned a similarity score; the sum of these scores in the optimal matching then quantifies the similarity between two trees.
Different ways of calculating the the similarity between a pair of splits lead to different tree distance metrics, implemented in the functions below:
-
MutualClusteringInfo()
,SharedPhylogeneticInfo()
Smith (2020) scores matchings based on the amount of information that one partition contains about the other. The Mutual Phylogenetic Information assigns zero similarity to split pairs that cannot both exist on a single tree; The Mutual Clustering Information metric is more forgiving, and exhibits more desirable behaviour; it is the recommended metric for tree comparison. (Its complement,
ClusteringInfoDistance()
, returns a tree distance.) -
Nye et al. (2006) score matchings according to the size of the largest split that is consistent with both of them, normalized against the Jaccard index. This approach is extended by Böcker et al. (2013) with the Jaccard-Robinson-Foulds metric (function
JaccardRobinsonFoulds()
). -
Bogdanowicz and Giaro (2012) and Lin et al. (2012) independently proposed counting the number of 'mismatched' leaves in a pair of splits.
MatchingSplitInfoDistance()
provides an information-based equivalent (Smith 2020).
The package also implements the variation of the path distance
proposed by Kendal and Colijn (2016) (function
KendallColijn()
),
approximations of the Nearest-Neighbour Interchange (NNI) distance (function
NNIDist()
;
following Li et al. (1996)), and calculates the size (function
MASTSize()
) and
information content (function
MASTInfo()
) of the
Maximum Agreement Subtree.
For an implementation of the Tree Bisection and Reconnection (TBR) distance, see the package 'TBRDist'.
Install and load the library from CRAN as follows:
install.packages('TreeDist')
library('TreeDist')
You can install the development version of the package with:
if (!require(devtools)) install.packages("devtools")
devtools::install_github('ms609/TreeDist')
Construct tree spaces and readily visualize projected landscapes, avoiding common analytical pitfalls (Smith, forthcoming), using the inbuilt graphical user interface:
TreeDist::MapTrees()
Serious analysts should consult the vignette for a command-line interface.
Other R packages implementing tree distance functions include:
- 'ape':
cophenetic.phylo()
: Cophenetic distancedist.topo()
: Path (topological) distance, Robinson-Foulds distance.
- 'phangorn'
treedist()
: Path, Robinson-Foulds and approximate SPR distances.
- 'Quartet': Triplet and Quartet distances, using the tqDist algorithm.
- 'TBRDist': TBR and SPR distances on unrooted trees, using the 'uspr' C library.
- 'distory' (unmaintained): Geodesic distance
-
Böcker, S. et al. (2013) The Generalized Robinson-Foulds metric. Algorithms in Bioinformatics. WABI 2013. Lecture Notes in Computer Science, 8126, 156–69.
-
Bogdanowicz, D. and Giaro, K. (2012) Matching split distance for unrooted binary phylogenetic trees. IEEE/ACM Transactions on Computational Biology and Bioinformatics, 9, 150–160.
-
Kendall, M. and Colijn, C. (2016) Mapping phylogenetic trees to reveal distinct patterns of evolution. Mol Biol Evol, 33, 2735–2743.
-
Li, M., Tromp, J. and Zhang, L.-X. (1996) Some notes on the nearest neighbour interchange distance. Computing and Combinatorics, Goos, G., Hartmanis, J., Leeuwen, J., Cai, J.-Y., and Wong, C. K., eds. Springer, Berlin. 343–351.
-
Nye, T.M.W. et al. (2006) A novel algorithm and web-based tool for comparing two alternative phylogenetic trees. Bioinformatics, 22, 117–119.
-
Smith, M.R. (2020) Information theoretic Generalized Robinson-Foulds metrics for comparing phylogenetic trees. Bioinformatics, 36, 5007–5013.
-
Smith, M.R. (forthcoming) The importance of methodology when analysing landscapes of phylogenetic trees.
Please note that the 'TreeDist' project is released with a Contributor Code of Conduct. By contributing to this project, you agree to abide by its terms.