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Journal of Computational and Graphical Statistics Volume 27, 2018 - Issue 3
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Uncertainty in Phylogenetic Tree Estimates

Amy WillisDepartment of Biostatistics, University of Washington, Seattle, WACorrespondence[email protected]
&
Rayna BellSmithsonian Institution, National Museum of Natural History, Washington, DC
Pages 542-552 | Received 01 Dec 2016, Published online: 06 Jun 2018

References

  • Adkins, R. M., Gelke, E. L., Rowe, D., and Honeycutt, R. L. (2001), “Molecular Phylogeny and Divergence Time Estimates for Major Rodent Groups: Evidence From Multiple Genes,” Molecular Biology and Evolution, 18, 777–791.
  • Amenta, N., Datar, M., Dirksen, A., de Bruijne, M., Feragen, A., Ge, X., Pedersen, J. H., Howard, M., Owen, M., Petersen, J., Shi, J., and Xu, Q. (2015), “Quantification and Visualization of Variation in Anatomical Trees,” in Research in Shape Modeling, eds. K. Leonard and S. Tari, Springer, pp. 57–79.
  • Angielczyk, K. D., Feldman, C. R., and Miller, G. R. (2011), “Adaptive Evolution of Plastron Shape in Emydine Turtles,” Evolution, 65, 377–394.
  • Auguie, B. (2017), gridExtra: Miscellaneous Functions for ”Grid” Graphics, R package version 2.3., available at https://cran.r-project.org/web/packages/gridExtra/index.html
  • Bačák, M. (2014), “Computing Medians and Means in Hadamard Spaces,” SIAM Journal on Optimization, 24, 1542–1566.
  • Baeza, J. A., and Fuentes, M. S. (2013), “Exploring Phylogenetic Informativeness and Nuclear Copies of Mitochondrial DNA (numts) in Three Commonly Used Mitochondrial Genes: Mitochondrial Phylogeny of Peppermint, Cleaner, and Semi-Terrestrial Shrimps (Caridea: Lysmata, Exhippolysmata, and Merguia),” Zoological Journal of the Linnean Society, 168, 699–722.
  • Barden, D., Le, H., and Owen, M. (2018), “Limiting Behaviour of Fréchet Means in the Space of Phylogenetic Trees,” Annals of the Institute of Statistical Mathematics, 70, 99–129.
  • Benner, P., and Bačák, M. (2014), “Computing the Posterior Expectation of Phylogenetic Trees,” arXiv:1305.3692.
  • Benner, P., Bačák, M., and Bourguignon, P.-Y. (2014), “Point Estimates in Phylogenetic Reconstructions,” Bioinformatics, 30, 534–540.
  • Billera, L. J., Holmes, S. P., and Vogtmann, K. (2001), “Geometry of the Space of Phylogenetic Trees,” Advances in Applied Mathematics, 27, 733–767.
  • Binet, M., Gascuel, O., Scornavacca, C., Douzery, E. J., and Pardi, F. (2016), “Fast and Accurate Branch Lengths Estimation for Phylogenomic Trees,” BMC Bioinformatics, available at https://doi.org/10.1186/s12859-015-0821-8.
  • Bouckaert, R. R. (2010), “DensiTree: Making Sense of Sets of Phylogenetic Trees,” Bioinformatics, 26, 1372–1373.
  • Bouckaert, R., and Heled, J. (2014), “DensiTree 2: Seeing Trees Through the Forest,” bioRxiv, available at https://www.biorxiv.org/content/early/2014/12/08/012401.
  • Bouckaert, R., Heled, J., Kühnert, D., Vaughan, T., Wu, C.-H., Xie, D., Suchard, M. A., Rambaut, A., and Drummond, A. J. (2014), “BEAST 2: A Software Platform for Bayesian Evolutionary Analysis,” PLoS Computational Biology, 10, e1003537.
  • Bremm, S., von Landesberger, T., Hess, M., Schreck, T., Weil, P., and Hamacherk, K. (2011), “Interactive Visual Comparison of Multiple Trees,” in 2011 IEEE Conference on Visual Analytics Science and Technology (VAST), IEEE, pp. 31–40.
  • Carpenter, K. E., Barber, P. H., Crandall, E. D., Ablan-Lagman, M. C. A., Ambariyanto, Mahardika, G. N., Manjaji-Matsumoto, B. M., Juinio-Me nez, M. A., Santos, M. D., Starger, C. J., and Toha, A. H. A. (2011), “Comparative Phylogeography of the Coral Triangle and Implications for Marine Management,” Journal of Marine Biology, 2011, 1–14.
  • Chakerian, J., and Holmes, S. (2012), “Computational Tools for Evaluating Phylogenetic and Hierarchical Clustering Trees,” Journal of Computational and Graphical Statistics, 21, 581–599.
  • ——— (2017), distory: Distance Between Phylogenetic Histories, R package version 1.4.3, available at https://cran.r-project.org/web/packages/distory/index.html.
  • Dinh, V., Ho, L. S. T., Suchard, M. A., and Matsen, F. A. (2016), “Consistency and Convergence Rate of Phylogenetic Inference via Regularization,” Annals of Statistics, arXiv:1606.03059.
  • Douzery, E. J., Scornavacca, C., Romiguier, J., Belkhir, K., Galtier, N., Delsuc, F., and Ranwez, V. (2014), “OrthoMaM v8: A Database of Orthologous Exons and Coding Sequences for Comparative Genomics in Mammals,” Molecular Biology and Evolution, 31, 1923–1928.
  • Drummond, A. J., Suchard, M. A., Xie, D., and Rambaut, A. (2012), “Bayesian Phylogenetics With BEAUti and the BEAST 1.7,” Molecular Biology and Evolution, 29, 1969–1973.
  • Edwards, S. V., Xi, Z., Janke, A., Faircloth, B. C., McCormack, J. E., Glenn, T. C., Zhong, B., Wu, S., Lemmon, E. M., Lemmon, A. R., and others, (2016), “Implementing and Testing the Multispecies Coalescent Model: A Valuable Paradigm for Phylogenomics,” Molecular Phylogenetics and Evolution, 94, 447–462.
  • Efron, B. (2015), “Frequentist Accuracy of Bayesian Estimates,” Journal of the Royal Statistical Society, Series B, 77, 617–646.
  • Efron, B., Halloran, E., and Holmes, S. (1996), “Bootstrap Confidence Levels for Phylogenetic Trees,” Proceedings of the National Academy of Sciences, 93, 13429–13429.
  • Feragen, A., Petersen, J., Owen, M., Lo, P., Thomsen, L. H., Wille, M. M., Dirksen, A., and de Bruijne, M. (2012), “A Hierarchical Scheme for Geodesic Anatomical Labeling of Airway Trees,” in International Conference on Medical Image Computing and Computer-Assisted Intervention, Springer, pp. 147–155.
  • González-Candelas, F., Bracho, M. A., Wróbel, B., and Moya, A. (2013), “Molecular Evolution in Court: Analysis of a Large Hepatitis C Virus Outbreak From an Evolving Source,” BMC Biology, available at https://doi.org/10.1186/1741-7007-11-76.
  • Gori, K., Suchan, T., Alvarez, N., Goldman, N., and Dessimoz, C. (2016), “Clustering Genes of Common Evolutionary History,” Molecular Biology and Evolution, 33, 1590–1605.
  • Hess, M., Bremm, S., Weissgraeber, S., Hamacher, K., Goesele, M., Wiemeyer, J., and von Landesberger, T. (2014), “Visual Exploration of Parameter Influence on Phylogenetic Trees,” IEEE Computer Graphics and Applications, 34, 48–56.
  • Hillis, D. M., Heath, T. A., and St John, K. (2005), “Analysis and Visualization of Tree Space,” Systematic Biology, 54, 471–482.
  • Holmes, S. (2005), “Statistical Approach to Tests Involving Phylogenies,” in Mathematics of Evolution and Phylogeny, ed. O. Gascuel, Oxford, UK: Oxford University Press pp. 91–120.
  • Huang, W., Zhou, G., Marchand, M., Ash, J. R., Morris, D., Van Dooren, P., Brown, J. M., Gallivan, K. A., and Wilgenbusch, J. C. (2016), “TreeScaper: Visualizing and Extracting Phylogenetic Signal From Sets of Trees,” Molecular Biology and Evolution, 33, 3314.
  • Jombart, T., Kendall, M., Almagro-Garcia, J., and Colijn, C. (2017), “Treespace: Exploration of Landscapes of Phylogenetic Trees,” Moleculer Ecology Resources, 17, 1385–1392.
  • Kendall, M., and Colijn, C. (2016), “Mapping Phylogenetic Trees to Reveal Distinct Patterns of Evolution,” Molecular Biology and Evolution, 33, 2735–2743.
  • Kruskal, J. B. (1964), “Multidimensional Scaling by Optimizing Goodness of Fit to a Nonmetric Hypothesis,” Psychometrika, 29, 1–27.
  • Lanfear, R., Calcott, B., Ho, S. Y. W., and Guindon, S. (2012), “PartitionFinder: Combined Selection of Partitioning Schemes and Substitution Models for Phylogenetic Analyses,” Molecular Biology and Evolution, 29, 1695–1701.
  • Lang, D. T., and the CRAN Team (2017), XML: Tools for Parsing and Generating XML Within R and S-Plus, R Package Version 3.98-1.9, available at https://cran.r-project.org/web/packages/XML/index.html.
  • Larkin, M. A., Blackshields, G., Brown, N. P., Chenna, R., McGettigan, P. A., McWilliam, H., Valentin, F., Wallace, I. M., Wilm, A., Lopez, R., Thompson, J. D., Gibson, T. J., and Higgins, D. G. (2007), “Clustal W and Clustal X version 2.0,” Bioinformatics, 23, 2947–2948.
  • Leaché, A. D., Chavez, A. S., Jones, L. N., Grummer, J. A., Gottscho, A. D., and Linkem, C. W. (2015), “Phylogenomics of Phrynosomatid Lizards: Conflicting Signals From Sequence Capture Versus Restriction Site Associated DNA Sequencing,” Genome Biology and Evolution, 7, 706–719.
  • Ligges, U., and Mächler, M. (2003), “Scatterplot3d—An R Package for Visualizing Multivariate Data,” Journal of Statistical Software, 8, 1–20.
  • Maddison, W. P. (1997), “Gene Trees in Species Trees,” Systematic Biology, 46, 523–536.
  • Marko, P. B., Nance, H. A., and Guynn, K. D. (2011), “Genetic Detection of Mislabeled Fish From a Certified Sustainable Fishery,” Current Biology, 21, 621–622.
  • Miller, E., Owen, M., and Provan, J. S. (2015), “Polyhedral Computational Geometry for Averaging Metric Phylogenetic Trees,” Advances in Applied Mathematics, 68, 51–91.
  • Mirarab, S., Reaz, R., Bayzid, M. S., Zimmermann, T., Swenson, M. S., and Warnow, T. (2014), “ASTRAL: Genome-Scale Coalescence Based Species Tree Estimation,” Bioinformatics, 30, 541–548.
  • Montealegre, I., and St John, K. (2002), “Visualizing Restricted Landscapes of Phylogenetic Trees,” in Proceedings of the European Conference for Computational Biology. Available at http://comet.lehman.cuny.edu/treeviz/papers/Evolu_Montealegre_20030601_061139.pdf
  • Nye, T. (2008), “Trees of Trees: An Approach to Comparing Multiple Alternative Phylogenies,” Systematic Biology, 57, 785–794.
  • ——— (2011), “Principal Components Analysis in the Space of Phylogenetic Trees,” The Annals of Statistics, 39, 2716–2739.
  • ——— (2015), “Convergence of Random Walks to Brownian Motion in Phylogenetic Tree-Space,” arXiv:1508.02906.
  • Paradis, E., Claude, J., and Strimmer, K. (2004), “APE: Analyses of Phylogenetics and Evolution in R Language,” Bioinformatics, 20, 289–290.
  • Puigbò, P., Garcia-Vallvé, S., and McInerney, J. O. (2007), “TOPD/FMTS: A New Software to Compare Phylogenetic Trees,” Bioinformatics, 23, 1556–1558.
  • R Core Team (2017), R: A Language and Environment for Statistical Computing, Vienna, Austria: R Foundation for Statistical Computing.
  • Rambaut, A., Drummond, A. J., Xie, D., Baele, G., and Suchard, M. A. (2018), Tracer 1.6. Available from http://tree.bio.ed.ac.uk/software/tracer/
  • Ranwez, V., Delsuc, F., Ranwez, S., Belkhir, K., Tilak, M.-K., and Douzery, E. J. (2007), “OrthoMaM: a Database of Orthologous Genomic Markers for Placental Mammal Phylogenetics,” BMC Evolutionary Biology, 7, 1.
  • Robinson, D. F., and Foulds, L. R. (1981), “Comparison of Phylogenetic Trees,” Mathematical Biosciences, 53, 131–147.
  • Ronquist, F., Teslenko, M., van der Mark, P., Ayres, D. L., Darling, A., Höhna, S., Larget, B., Liu, L., Suchard, M. A., and Huelsenbeck, J. P. (2012), “MrBayes 3.2: Efficient Bayesian Phylogenetic Inference and Model Choice Across a Large Model Space,” Systematic Biology, 61, 539–542.
  • Rosenberg, N. A., and Nordborg, M. (2002), “Genealogical Trees, Coalescent Theory and the Analysis of Genetic Polymorphisms,” Nature Reviews Genetics, 3, 380–390.
  • Sarkar, D. (2008), Lattice: Multivariate Data Visualization with R, New York: Springer, iSBN 978-0-387-75968-5.
  • Schliep, K. (2011), “Phangorn: Phylogenetic Analysis in R,” Bioinformatics, 27, 592–593.
  • Skwerer, S., and Provan, S. (2015), “Dynamic Geodesics in Treespace via Parametric Maximum Flow,” arXiv:1512.03115.
  • Skwerer, S., Provan, S., and Marron, J. S. (2015), “Relative Optimality Conditions and Algorithms for Treespace Fréchet Means,” arXiv:1605.02082.
  • Spinks, P. Q., and Shaffer, H. B. (2009), “Conflicting Mitochondrial and Nuclear Phylogenies for the Widely Disjunct Emys (Testudines: Emydidae) Species Complex, and What They Tell Us About Biogeography and Hybridization,” Systematic Biology, 58, 1–20.
  • Sundberg, K., Clement, M., and Snell, Q. (2009), “Visualizing Phylogenetic Treespace Using Cartographic Projections,” in Algorithms in Bioinformatics, eds. S. L. Salzberg and T. Warnow, Heidelberg, Berlin: Springer, pp. 321–332.
  • Torgerson, W. S. (1952), “Multidimensional Scaling: I. Theory and Method,” Psychometrika, 17, 401–419.
  • Tu, Y., and Shen, H.-W. (2007), “Visualizing Changes of Hierarchical Data Using Treemaps,” IEEE Transactions on Visualization and Computer Graphics, 13, 1286–1293.
  • Venables, W. N., and Ripley, B. D. (2002), Modern Applied Statistics With S (4th ed.), New York: Springer, iSBN 0-387-95457-0.
  • Wägele, J. W., and Mayer, C. (2007), “Visualizing Differences in Phylogenetic Information Content of Alignments and Distinction of Three Classes of Long-Branch Effects,” BMC Evolutionary Biology, 7, 1.
  • Wickham, H. (2009), ggplot2: Elegant Graphics for Data Analysis, New York: Springer-Verlag.
  • Wiens, J. J., Kuczynski, C. A., and Stephens, P. R. (2010), “Discordant Mitochondrial and Nuclear Gene Phylogenies in Emydid Turtles: Implications for Speciation and Conservation,” Biological Journal of the Linnean Society, 99, 445–461.
  • Willis, A. (2017), “Confidence Sets for Phylogenetic Trees,” Journal of the American Statistical Association, available at https://doi.org/10.1080/01621459.2017.1395342.
  • Zairis, S., Khiabanian, H., Blumberg, A. J., and Rabadan, R. (2016), “Genomic Data Analysis in Tree Spaces,” arXiv:1607.07503.

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