An empirical evaluation of two-stage species tree inference strategies using a multilocus dataset from North American pines

DeGiorgio, Michael; Syring, John; Eckert, Andrew J.; Liston, Aaron; Cronn, Richard; Neale, David B.; Rosenberg, Noah A.

doi:10.1186/1471-2148-14-67

Cited by 21 publications

(15 citation statements)

References 87 publications

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“…When the species tree had a pseudocaterpillar shape, the correct species tree was returned 85% and 100% of the time with branch lengths of 0.1 and 1.0, respectively. Strong shape biases have been known to exist for rooted MDC in previous research (Than and Rosenberg, 2011; DeGiorgio et al , 2014), and more work would be needed to understand its behavior in the unrooted setting.…”

Section: Discussionmentioning

confidence: 96%

Inferring rooted species trees from unrooted gene trees using approximate Bayesian computation

Alanzi

Degnan

2017

Molecular Phylogenetics and Evolution

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Methods for inferring species trees from gene trees motivated by incomplete lineage sorting typically use either rooted gene trees to infer a rooted species tree, or use unrooted gene trees to infer an unrooted species tree, which is then typically rooted using one or more outgroups. Theoretically, however, it has been known since 2011 that it is possible to consistently infer the root of the species tree directly from unrooted gene trees without assuming an outgroup. Here, we use approximate Bayesian computation to infer the root of the species tree from unrooted gene trees assuming the multispecies coalescent model. It is hoped that this approach will be useful in cases where an appropriate outgroup is difficult to find and gene trees do not follow a molecular clock. We use approximate Bayesian computation to infer the root of the species tree from unrooted gene trees. This approach could also be useful when there is prior information that makes a small number of root locations plausible in an unrooted species tree.

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Section: Discussionmentioning

confidence: 96%

Inferring rooted species trees from unrooted gene trees using approximate Bayesian computation

Alanzi

Degnan

2017

Molecular Phylogenetics and Evolution

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“…; DeGiorgio et al . ; reviewed in Edwards ). These methods are known to vary in their efficiency and also in their ability to handle large data sets, with Bayesian methods being the desired goal, specifying the MSC completely but unable to handle large data sets, and summary statistic methods being less efficient, but still statistically consistent and able to handle data sets befitting the title ‘phylogenomics’.…”

Section: Phylogenomic Subsampling and Species Treesmentioning

confidence: 99%

“…We use a model, the multispecies coalescent (MSC) model, that provides an elegant means of assessing the likelihood of an overarching species tree in the presence of gene tree variation that is dominated by incomplete lineage sorting (ILS; Rannala & Yang 2003, 2008Degnan & Rosenberg 2009;Liu et al 2009aLiu et al , 2015b. As reviewed extensively elsewhere, there is now a diverse ecosystem of species tree methods, ranging from Bayesian to likelihood to summary statistic methods, and which can handle a variety of data types, from multiple SNPs linked into single loci to multiple unlinked SNPs (Bryant et al 2012;DeGiorgio et al 2014;reviewed in Edwards 2016). These methods are known to vary in their efficiency and also in their ability to handle large data sets, with Bayesian methods being the desired goal, specifying the MSC completely but unable to handle large data sets, and summary statistic methods being less efficient, but still statistically consistent and able to handle data sets befitting the title 'phylogenomics'.…”

Section: Phylogenomic Subsampling and Species Treesmentioning

confidence: 99%

Phylogenomic subsampling: a brief review

Edwards

2016

Zoologica Scripta

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Edwards, S.V. (2016). Phylogenomic subsampling: a brief review. -Zoologica Scripta, 45, 63-74. Phylogenomic subsampling is a method for studying the stability of phylogenetic analyses by taking random or ordered subsamples of loci and comparing phylogenetic analyses of those subsamples. The method is made possible by the large number of loci made available by application of next-generation sequencing methods to phylogenetic questions. My laboratory has used phylogenomic subsampling to investigate the consistency and stability of various methods of phylogenetic analysis of multilocus data sets, including the so-called species tree methods, which use the multispecies coalescent as a framework for interpreting gene tree heterogeneity. I was inspired to focus on this method for this symposium volume because my Harvard colleague Gonzalo Giribet had independently been using phylogenomic subsampling to explore various questions in invertebrate phylogenomics. Phylogenomic subsampling has many useful applications in phylogenomics, yet when reporting the particulars of the results of such analyses, care should be taken to focus primarily on discrepancies that achieve a high level of support by the bootstrap or other methods. Using a recently published example, I show that the methods used to summarize the results of a subsampling experiment, such as the threshold for reporting support for one or another tree or clade, can influence the perceived success or failure of concatenation or species tree methods. Single-versus double-bootstrapping is also shown to produce different subsampling results. I suggest guidelines for analysing and reporting the results of phylogenomic subsampling and suggest that it should become a routine part of phylogenetic analysis in the next-generation era.

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“…3c), despite the shared polymorphism observed. Shared polymorphism and contrasting genealogical signals among genes, have been observed for this species complex in a recent study by DeGiorgio et al (2014). Under a scenario of drift and gene flow (Knowles and Carstens 2007;Yeaman and Whitlock 2011), we would expect to see a similar pattern of differentiation across different loci between species, as gene flow would act on entire genomes (Shafer and Wolf 2013).…”

Section: Genetic Structure and Isolation Testsmentioning

confidence: 80%

“…However, shared polymorphism is a common characteristic in white pines, and represents a challenge for multilocus genetic studies, as patterns are not clear cut (DeGiorgio et al 2014). Therefore, it becomes important to explore the role of divergent selection in genes reinforcing postzygotic reproductive barriers by reducing the fitness of hybrids, and thus promoting speciation even if the rest of the genome is not affected in the same fashion (Smadja and Butlin 2011).…”

Section: Genetic Structure and Isolation Testsmentioning

confidence: 98%

Mosaic genetic differentiation along environmental and geographic gradients indicate divergent selection in a white pine species complex

Moreno‐Letelier

Barraclough

2015

Evol Ecol

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We explored the role of isolation by environment in a white pine species complex: Pinus flexilis, Pinus strobiformis and Pinus ayacahuite distributed from Canada to Central America. We predict that species differentiation would match genetic structure of candidate genes associated with significant differences in climatic niche in the species complex. To test this prediction, we sequenced five candidate genes for drought tolerance and three housekeeping genes, in individuals from across the entire range of each species. We performed neutrality tests, estimated genetic differentiation and performed partial mantel correlations, to test for isolation by environment in the species complex. Our results show that different loci vary in degrees of genetic differentiation within species and contrast in patterns of differentiation among species. This is considered to be a mosaic pattern of genetic differentiation. There was also significant isolation by environment in candidate genes. P. flexilis was genetically differentiated for candidate genes and P. ayacahuite for housekeeping genes. There was also an overall pattern of shared ancestral polymorphism followed by independent evolution. Nonetheless, all loci together recovered groups that correspond to the recognized taxonomy. In conclusion, the pattern of isolation by environment in candidate genes support the idea of ecologically driven differentiation of this species complex, especially in the case of P. flexilis. The observed difference in housekeeping genes between P. strobiformis and P. ayacahuite can be due to limited gene Electronic supplementary material The online version of this article (flow. The mosaic pattern of differentiation suggests that speciation is recent and ecological differences could be a factor in the diversification of pines in North America.

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An empirical evaluation of two-stage species tree inference strategies using a multilocus dataset from North American pines

Cited by 21 publications

References 87 publications

Inferring rooted species trees from unrooted gene trees using approximate Bayesian computation

Inferring rooted species trees from unrooted gene trees using approximate Bayesian computation

Phylogenomic subsampling: a brief review

Mosaic genetic differentiation along environmental and geographic gradients indicate divergent selection in a white pine species complex

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