Data from: Taxon sampling to address an ancient rapid radiation: a supermatrix phylogeny of early brachyceran flies (Diptera)
Shin, Seunggwan et al. (2018), Data from: Taxon sampling to address an ancient rapid radiation: a supermatrix phylogeny of early brachyceran flies (Diptera), Dryad, Dataset, https://doi.org/10.5061/dryad.cq63m
Early diverging brachyceran fly lineages underwent a rapid radiation approximately 180 million years ago, coincident in part with the origin of flowering plants. This region of the fly tree includes 25,000 described extant species with diverse ecological roles such as blood feeding (haematophagy), parasitoidism, predation, pollination, and wood feeding (xylophagy). Early diverging brachyceran lineages were once considered a monophyletic group of families called Orthorrhapha, based on the shared character of a longitudinal break in the pupal skin made during the emergence of the adult. Yet other morphological and molecular evidence generally supports a paraphyletic arrangement of ‘Orthorrhapha,’ with strong support for one orthorrhaphan lineage — dance flies and relatives — as the closest relative to all higher flies (Cyclorrhapha), together called Eremoneura. In order to establish a comprehensive estimate of the relationships among orthorrhaphan lineages using a thorough sample of publicly available data we compiled and analyzed a dataset including 1,217 taxa representing major lineages and 20 molecular markers. Our analyses suggest that ‘Orthorrhapha’ excluding Eremoneura is not monophyletic; instead, we recover two main lineages of early brachyceran flies— Homeodactyla and Heterodactyla. Homeodactyla includes Nemestrinoidea (uniting two parasitic families Acroceridae + Nemestrinidae) as the closest relatives to the large SXT clade, comprised of Stratiomyomorpha, Xylophagidae and Tabanomorpha. Heterodactyla includes Bombyliidae with a monophyletic Asiloidea (exclusive of Bombyliidae) as the closest relatives to Eremoneura. Reducing missing data, modifying the distribution of genes across taxa, and, in particular, removing rogue taxa significantly improved tree resolution and statistical support. Although relying on dense taxonomic sampling and substantial gene coverage, our analyses pinpoint the limited resolving power of Sanger sequencing-era molecular phylogenetic datasets in respect to ancient, hyperdiverse radiations.
National Science Foundation,