When Do Species-Tree and Concatenated Estimates Disagree? an Empirical Analysis with Higher-Level Scincid Lizard Phylogeny ⇑ Shea M

When Do Species-Tree and Concatenated Estimates Disagree? an Empirical Analysis with Higher-Level Scincid Lizard Phylogeny ⇑ Shea M

Molecular Phylogenetics and Evolution 82 (2015) 146–155 Contents lists available at ScienceDirect Molecular Phylogenetics and Evolution journal homepage: www.elsevier.com/locate/ympev When do species-tree and concatenated estimates disagree? An empirical analysis with higher-level scincid lizard phylogeny ⇑ Shea M. Lambert a, , Tod W. Reeder b, John J. Wiens a a Department of Ecology and Evolutionary Biology, University of Arizona, Tucson, AZ 85721, USA b Department of Biology, San Diego State University, San Diego, CA 92182, USA article info abstract Article history: Simulation studies suggest that coalescent-based species-tree methods are generally more accurate than Received 17 April 2014 concatenated analyses. However, these species-tree methods remain impractical for many large datasets. Revised 9 September 2014 Thus, a critical but unresolved issue is when and why concatenated and coalescent species-tree estimates Accepted 2 October 2014 will differ. We predict such differences for branches in concatenated trees that are short, weakly Available online 12 October 2014 supported, and have conflicting gene trees. We test these predictions in Scincidae, the largest lizard fam- ily, with data from 10 nuclear genes for 17 ingroup taxa and 44 genes for 12 taxa. We support our initial Keywords: predictions, and suggest that simply considering uncertainty in concatenated trees may sometimes Concatenated analysis encompass the differences between these methods. We also found that relaxed-clock concatenated trees Phylogenetic methods Reptile can be surprisingly similar to the species-tree estimate. Remarkably, the coalescent species-tree esti- Scincidae mates had slightly lower support values when based on many more genes (44 vs. 10) and a small Species-tree analysis (30%) reduction in taxon sampling. Thus, taxon sampling may be more important than gene sampling Taxon sampling when applying species-tree methods to deep phylogenetic questions. Finally, our coalescent species-tree estimates tentatively support division of Scincidae into three monophyletic subfamilies, a result other- wise found only in concatenated analyses with extensive species sampling. Ó 2014 Elsevier Inc. All rights reserved. 1. Introduction widespread (e.g. according to Google Scholar April 12th, 2014: 580 citations for the paper proposing ⁄BEAST as compared to A major conundrum has arisen in the phylogenetic analysis of <200 each for BEST [Liu, 2008], STEM [Kubatko et al., 2009] and multi-locus sequence data. In recent years, there has been growing BUCKy [Larget et al., 2010]). However, it is widely known (if not appreciation for the idea that the evolutionary histories of species explicitly documented) that ⁄BEAST and similar methods can (species trees) and the genes that they carry (gene trees) can often become computationally intractable with large numbers of genes differ (e.g. Edwards, 2009; Maddison, 1997). To address this prob- or species. Unfortunately, such large matrices may be the most lem of discordance between gene and species trees, a variety of useful for accurately resolving phylogenies (e.g. Rannala et al., methods for explicit species-tree reconstruction have been devel- 1998) and for macroevolutionary analyses (e.g. Davis et al., oped (e.g. Edwards et al., 2007; Heled and Drummond, 2010; 2013). Other species-tree methods, while computationally more Kubatko et al., 2009; Larget et al., 2010; Liu, 2008). Simulation efficient (e.g. Kubatko et al., 2009; Larget et al., 2010), may require studies show that these methods, particularly those employing complete datasets (all species with data for all genes), making Bayesian coalescent models (i.e. BEST, ⁄BEAST), are more accurate them impractical in many cases. Furthermore, it is unclear whether than other approaches for inferring species trees, especially tradi- coalescent species-tree methods (e.g., ⁄BEAST) are preferable to tional concatenated analysis (e.g. Bayzid and Warnow, 2012; concatenation for deep phylogenetic questions, especially given Edwards et al., 2007; Heled and Drummond, 2010; Hovmöller limited sampling of species and individuals. These and other issues et al., 2013; Leaché and Rannala, 2011). The use of ⁄BEAST (Heled make choosing between concatenated and species-tree analyses an and Drummond, 2010), which coestimates gene and species trees increasingly common problem for empirical studies (McVay and using the multispecies coalescent, has become particularly Carstens, 2013). The current impracticality of coalescent species-tree methods for many phylogenetic studies leaves systematists with several ⇑ Corresponding author. important and unresolved questions: how similar are phylogenetic E-mail addresses: [email protected] (S.M. Lambert), twreeder@mail. sdsu.edu (T.W. Reeder), [email protected] (J.J. Wiens). estimates between concatenated and coalescent species-tree http://dx.doi.org/10.1016/j.ympev.2014.10.004 1055-7903/Ó 2014 Elsevier Inc. All rights reserved. S.M. Lambert et al. / Molecular Phylogenetics and Evolution 82 (2015) 146–155 147 approaches? In other words, do concatenated analyses offer a rea- genes versus species) on species-tree analyses of higher-level rela- sonable proxy? Can we make accurate predictions about when tionships is especially poorly known. estimates from concatenated and species-tree analyses will differ? Here we compare multispecies coalescent species-tree (i.e. Specifically, can we examine a tree from concatenated analysis and ⁄BEAST) and concatenated estimates using empirical datasets for predict which branches are most likely to be resolved differently higher-level scincid lizard phylogeny. Skinks are the most spe- using coalescent species-tree methods? Here, we make specific cies-rich family of lizards, containing >1560 species (Uetz et al., predictions regarding these questions and test them empirically 2013), and are relatively ancient (crown group 80–110 million using data from scincid lizards. years old; Mulcahy et al., 2012). Skink phylogeny and higher-level Species-tree methods generally rest on the assumptions that classification remain uncertain, despite recent studies based on gene trees and species trees disagree, that gene trees disagree with concatenated analyses of multiple nuclear and mitochondrial one another, and that species-tree methods deal with this discor- genes (e.g. Brandley et al., 2012; Pyron et al., 2013; Wiens et al., dance better than concatenation (e.g. Edwards, 2009; Edwards 2012). For example, Hedges and Conn (2012) divided Scincidae et al., 2007; Maddison and Knowles, 2006). Further, methods such into seven families (without estimating a large-scale phylogeny), as BEST and ⁄BEAST assume that this genealogical discordance is but Pyron et al. (2013) found some of these families to be non- due to incomplete lineage sorting (e.g. Edwards et al., 2007; monophyletic. Traditional classifications recognized four subfami- Heled and Drummond, 2010). Theory suggests incomplete lineage lies in Scincidae (Acontinae, Feylininae, Lygosominae, Scincinae; sorting will be more prevalent on shorter branches in the true spe- Greer, 1970 and subsequent authors). Brandley et al. (2012) ana- cies tree (all other things being equal; e.g. Degnan and Rosenberg, lyzed 56 scincid species and found Scincinae to be paraphyletic 2009; Maddison, 1997; Pamilo and Nei, 1988). Empirical multi- with respect to Lygosominae (with Acontinae as sister to the other locus analyses (e.g. Wiens et al., 2008, 2010a, 2012) show that subfamilies), but did not include Feylininae. In a broad analysis of shorter branches in concatenated trees tend to have weaker sup- squamate phylogeny, Wiens et al. (2012) analyzed 44 nuclear loci port (e.g. bootstrap proportions) and greater disagreement with and included 12 skink species and found Scincinae to be paraphy- their underlying gene trees (e.g. a smaller proportion of genes will letic with respect to Feylininae and Lygosominae, with Acontinae support the short branch in the concatenated tree, and the other as sister to all other scincids. In another large-scale analysis of genes will support trees that conflict with this branch). Therefore, squamate phylogeny, Pyron et al. (2013) included 683 scincid spe- we predict that estimates from concatenated analysis and species- cies for multiple nuclear and mitochondrial genes (but with rela- tree methods will tend to disagree most often on those branches of tively incomplete gene sampling) and supported monophyly of the concatenated tree that have: (1) shorter estimated branch Acontinae (as sister to all other scincids), Lygosominae, and Scinci- lengths (assuming that short branches in the concatenated tree nae (including Feylininae). We follow this latter classification here. reflect short branches in the underlying species tree, and short However, as of yet, no studies have used species-tree methods to branches in concatenated trees do seem to reflect short branches address higher-level relationships in Scincidae. in comparable gene trees; Wiens et al., 2008), (2) weaker support In this study, we analyze higher-level scincid phylogeny and (i.e. low bootstraps and/or Bayesian posterior probabilities), and test our predictions about concordance of species-tree and concat- (3) greater disagreement with the underlying gene trees. Although enated estimates using a dataset of 17 ingroup species and 10 these assumptions may seem simple and uncontroversial, they do nuclear protein-coding genes (combining published and new data). have important implications. For example,

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