Litcius/Paper detail

Distinguishing Felsenstein Zone from Farris Zone Using Neural Networks

Alina F. Leuchtenberger, Stephen Crotty, Tamara Drucks, Heiko A. Schmidt, Sebastian Burgstaller-Muehlbacher, Arndt von Haeseler

2020Molecular Biology and Evolution27 citationsDOIOpen Access PDF

Abstract

Maximum likelihood and maximum parsimony are two key methods for phylogenetic tree reconstruction. Under certain conditions, each of these two methods can perform more or less efficiently, resulting in unresolved or disputed phylogenies. We show that a neural network can distinguish between four-taxon alignments that were evolved under conditions susceptible to either long-branch attraction or long-branch repulsion. When likelihood and parsimony methods are discordant, the neural network can provide insight as to which tree reconstruction method is best suited to the alignment. When applied to the contentious case of Strepsiptera evolution, our method shows robust support for the current scientific view, that is, it places Strepsiptera with beetles, distant from flies.

Topics & Concepts

BiologyPhylogenetic treeMaximum parsimonyMaximum likelihoodTree (set theory)Artificial neural networkTaxonEvolutionary biologyAttractionPhylogeneticsPaleontologyArtificial intelligenceStatisticsCladeComputer scienceMathematicsCombinatoricsBiochemistryGeneLinguisticsPhilosophyFossil Insects in AmberPaleontology and Stratigraphy of FossilsEvolution and Paleontology Studies