Quartet-Based Computations of Internode Certainty Provide Robust Measures of Phylogenetic Incongruence

Zhou, Xin; Lutteropp, Sarah; Czech, Lucas; Stamatakis, Alexandros; Looz, Moritz von; Rokas, Antonis

doi:10.1093/sysbio/syz058

Cited by 45 publications

(44 citation statements)

References 65 publications

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“…Finally, the research field currently faces a challenge in that bootstrap support appears unsuited as a measure of node support for genome‐scale data (Townsend & Naylor, ; Kumar et al ., ; Salichos & Rokas, ; Freitas et al ., ). Here I opt for a conservative measure of node support in the form of IC calculated from gene tree variation, although these measures are under active development and can vary considerably based on approach used to adjust for taxon completeness (Zhou et al ., ). Other options that might allow us to move forward in node assessment could be related measures of gene tree conflict (Salichos et al ., ; Zhou et al ., ), concatenation analyses (Narechania et al ., ) and four‐cluster likelihood mapping (Bank et al ., ; Johnson et al ., ).…”

Section: Discussionmentioning

confidence: 97%

“…Here I opt for a conservative measure of node support in the form of IC calculated from gene tree variation, although these measures are under active development and can vary considerably based on approach used to adjust for taxon completeness (Zhou et al ., ). Other options that might allow us to move forward in node assessment could be related measures of gene tree conflict (Salichos et al ., ; Zhou et al ., ), concatenation analyses (Narechania et al ., ) and four‐cluster likelihood mapping (Bank et al ., ; Johnson et al ., ). At the very least, it is necessary to assess sensitivity of the phylogenetic results to the way in which the matrix is constructed (Whelan et al ., ; Garrison et al ., ; Cunha & Giribet, ), including the use of matrices containing orthologues that are more complete for taxa relevant to the study question (decisive datasets; Dell'Ampio et al ., ; Parks et al ., ).…”

Section: Discussionmentioning

confidence: 97%

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The phylogeny of insects in the data‐driven era

Chesters

2019

Systematic Entomology

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Maturation of omics and DNA barcode programs along with advances in sequence analysis tools and phyloinformatics protocols are enabling the realization of comprehensive and robust phylogenies of even the most diverse lineages. Several lineages in insects have undergone hyper‐radiations, and thus a unified picture of their evolution is ultimately required for understanding the process of diversification. In this study I further develop informatics protocols for de novo phylogenetic construction, and present the most species‐comprehensive insect phylogeny to date, constructed hierarchically using c. 440 transcriptomes, 1490 mitogenomes, DNA barcodes for 69 000 species, and several additional species‐rich markers. Even with this expanded transcriptome backbone, support is still insufficient for some historically problematic nodes, particularly in Polyneoptera and Paraneoptera. Low support (measured by internode certainty) was observed for the node separating Dictyoptera from its sister polyneopeterans; configuration of the Paraneoptera was not resolved; the recently proposed Hymenoptera grouping Eusymphyta received high support, while Parasitoida did not; and Orthorrhapha (Diptera) was not recovered. Sampling is uneven across the insects, and while highly sequenced lineages (e.g. Lepidoptera) boast greater information content, this accompanies computational burdens. The protocol and resulting tree represent an advance in the analytic and phylogenetic framework, for an objectively and consistently determined species‐comprehensive phylogeny.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 97%

The phylogeny of insects in the data‐driven era

Chesters

2019

Systematic Entomology

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“…2) Data processing: care should be taken in data cleaning, partitioning (e.g., nuclear vs. plastid), and using orthology inference methods that explicitly address paralogy issues (e.g., treebased orthology inference and synteny information). 3) Species tree inference: select species tree methods that accommodate the dataset size and data type (e.g., ASTRAL for gene tree-based inferences or SVDquartet [Chifman and Kubatko 2014] for SNP-based inferences), followed by visualization of phylogenetic conflict using tools such as the pie charts (e.g., PhyParts) and quartet-based tools (e.g., Quartet Sampling; Quadripartition Internode Certainty [Zhou et al 2020]; Concordance Factors [Minh et al 2020]). 4) Assessing hybridization: if phylogenetic conflict cannot be explained by processes like ILS, phylogenetic species network analyses (e.g., PhyloNet) reduced taxon sampling can be applied to test hybridization hypotheses given results in step 3; 5) Hypothesis testing: additional tests can be performed given the results of recommendation 3 and 4 and depending on the scenario.…”

Section: Discussionmentioning

confidence: 99%

Disentangling Sources of Gene Tree Discordance in Phylogenomic Datasets: Testing Ancient Hybridizations in Amaranthaceae s.l

Morales‐Briones

Kadereit

Tefarikis

et al. 2019

Preprint

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Phylogenomic datasets have become common and fundamental to understanding the 24 phylogenetic relationships of recalcitrant groups across the Tree of Life. At the same time, 25 working with large genomic or transcriptomic datasets requires special attention to the processes 26 that generate gene tree discordance, such as data processing and orthology inference, incomplete 27 lineage sorting, hybridization, model violation, and uninformative gene trees. Methods to 28 estimate species trees from phylogenomic datasets while accounting for all sources of conflict 29 are not available, but a combination of multiple approaches can be a powerful tool to tease apart 30 alternative sources of conflict. Here using a phylotranscriptomic analysis in combination with 31 reference genomes, we explore sources of gene tree discordance in the backbone phylogeny of 32 the plant family Amaranthaceae s.l. The dataset was analyzed using multiple phylogenetic 33 approaches, including coalescent-based species trees and network inference, gene tree 34 discordance analyses, site pattern test of introgression, topology test, synteny analyses, and 35 simulations. We found that a combination of processes might have acted, simultaneously and/or 36 cumulatively, to generate the high levels of gene tree discordance in the backbone of 37 Amaranthaceae s.l. Furthermore, other analytical shortcomings like uninformative genes as well 38 as misspecification of the model of molecular evolution seem to contribute to tree discordance 39 signal in this family. Despite the comprehensive phylogenomic dataset and detailed analyses 40 presented here, no single source can confidently be pointed out to account for the strong signal of 41 gene tree discordance, suggesting that the backbone of Amaranthaceae s.l. might be a product of 42 an ancient and rapid lineage diversification, and remains -and probably will remain-43 unresolved even with genome-scale data. Our work highlights the need to test for multiple 44 sources of conflict in phylogenomic analyses and provide a set of recommendations moving 45 forward in disentangling ancient and rapid diversification. 46 3

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“…Low phylogenetic support can be caused by poor phylogenetic signal and/or conflicting signals among the loci used for species tree inference. To test the effects of conflicting phylogenetic signal within the data set, we calculated the quadripartition internode certainty score (QP-IC; Zhou et al, 2019) of internodes within the species trees. We calculated the QP-IC scores using the program QuartetScores, a quartet-based measure for examining incongruence within a set of phylogenetic trees (available at https://github.com/lutteropp/QuartetScores).…”

Section: Internode Certaintymentioning

confidence: 99%

“…The average QP-IC score for the concatenated maximum likelihood tree of all taxa was 0.329 (File S10). Quartet-based IC scores can be open to interpretation (Zhou et al, 2019), making it difficult to objectively evaluate these scores, however, this result may be indicative of moderate levels of phylogenetic incongruence of the gene trees relative to the species tree. The only negative scores, indicating an alternative topology was more prevalent among the gene trees, corresponded to branches descended from the root and may be a technical artifact.…”

Section: Internode Certaintymentioning

confidence: 99%

A deeper meaning for shallow‐level phylogenomic studies: nested anchored hybrid enrichment offers great promise for resolving the tiger moth tree of life (Lepidoptera: Erebidae: Arctiinae)

Dowdy

Keating

Lemmon

et al. 2020

Systematic Entomology

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Anchored hybrid enrichment (AHE) has emerged as a powerful tool for uncovering the evolutionary relationships within many taxonomic groups. AHE probe sets have been developed for a variety of insect groups, though none have yet been shown to be capable of simultaneously resolving deep and very shallow (e.g., intraspecific) divergences. In this study, we present NOC1, a new AHE probe set (730 loci) for Lepidoptera specialized for tiger moths and assess its ability to deliver phylogenetic utility at all taxonomic levels. We test the NOC1 probe set with 142 individuals from 116 species sampled from all the major lineages of Arctiinae (Erebidae), one of the most diverse groups of noctuoids (>11 000 species) for which no well‐resolved, strongly supported phylogenetic hypothesis exists. Compared to previous methods, we generally recover much higher branch support (BS), resulting in the most well‐supported, well‐resolved phylogeny of Arctiinae to date. At the most shallow‐levels, NOC1 confidently resolves species‐level and intraspecific relationships and potentially uncovers cryptic species diversity within the genus Hypoprepia. We also implement a ‘sensitivity analysis’ to explore different loci combinations and site sampling strategies to determine whether a reduced probe set can yield results similar to those of the full probe set. At both deep and shallow levels, only 50–175 of the 730 loci included in the complete NOC1 probe set were necessary to resolve most relationships with high confidence, though only when the more rapidly evolving sites within each locus are included. This demonstrates that AHE probe sets can be tailored to target fewer loci without a significant reduction in BS, allowing future studies to incorporate more taxa at a lower per‐sample sequencing cost. NOC1 shows great promise for resolving long‐standing taxonomic issues and evolutionary questions within arctiine lineages, one of the most speciose clades within Lepidoptera.

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Quartet-Based Computations of Internode Certainty Provide Robust Measures of Phylogenetic Incongruence

Cited by 45 publications

References 65 publications

The phylogeny of insects in the data‐driven era

The phylogeny of insects in the data‐driven era

Disentangling Sources of Gene Tree Discordance in Phylogenomic Datasets: Testing Ancient Hybridizations in Amaranthaceae s.l

A deeper meaning for shallow‐level phylogenomic studies: nested anchored hybrid enrichment offers great promise for resolving the tiger moth tree of life (Lepidoptera: Erebidae: Arctiinae)

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