Performance of tree-building methods using a morphological dataset and a well-supported Hexapoda phylogeny

Recently, many studies have addressed the performance of phylogenetic tree-building methods (maximum parsimony, maximum likelihood, and Bayesian inference), focusing primarily on simulated data. However, for discrete morphological data, there is no consensus yet on which methods recover the phylogen...

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Bibliographic Details
Published in:PeerJ (San Francisco, CA) CA), 2024-01, Vol.12, p.e16706-e16706, Article e16706
Main Authors: Francisco Barbosa, Felipe, Mermudes, José Ricardo M, Russo, Claudia A M
Format: Article
Language:English
Subjects:
Accuracy
Animals
Arthropods
Bayes Theorem
Bayesian analysis
Biodiversity
Datasets
Entomology
Evolutionary Studies
Hexapoda
Insecta
Insects
Likelihood Functions
Likelihood-based methods
Methods
MK model
Morphological discrete data
Morphology
Performance evaluation
Phylogenetics
Phylogeny
Precision
Simulation
Software
Statistics
Taxonomy
Zoology
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Summary:Recently, many studies have addressed the performance of phylogenetic tree-building methods (maximum parsimony, maximum likelihood, and Bayesian inference), focusing primarily on simulated data. However, for discrete morphological data, there is no consensus yet on which methods recover the phylogeny with better performance. To address this lack of consensus, we investigate the performance of different methods using an empirical dataset for hexapods as a model. As an empirical test of performance, we applied normalized indices to effectively measure accuracy (normalized Robinson-Foulds metric, nRF) and precision, which are measured resolution, one minus Colless' consensus fork index (1-CFI). Additionally, to further explore phylogenetic accuracy and support measures, we calculated other statistics, such as the true positive rate (statistical power) and the false positive rate (type I error), and constructed receiver operating characteristic plots to visualize the relationship between these statistics. We applied the normalized indices to the reconstructed trees from the reanalyses of an empirical discrete morphological dataset from extant Hexapoda using a well-supported phylogenomic tree as a reference. Maximum likelihood and Bayesian inference applying the k-state Markov (Mk) model (without or with a discrete gamma distribution) performed better, showing higher precision (resolution). Additionally, our results suggest that most available tree topology tests are reliable estimators of the performance measures applied in this study. Thus, we suggest that likelihood-based methods and tree topology tests should be used more often in phylogenetic tree studies based on discrete morphological characters. Our study provides a fair indication that morphological datasets have robust phylogenetic signal.
ISSN:2167-8359
2167-8359
DOI:10.7717/peerj.16706