@ARTICLE{TreeBASE2Ref16456,
author = {Carlos Lopez-Vaamonde and Niklas Wikstrom and Conrad C. Labandeira and H. Charles J. Godfray and Simon J. Goodman and James M. Cook},
title = {Fossil-calibrated molecular phylogenies reveal that leaf-mining moths radiated several million years after their host plants},
year = {2006},
keywords = {},
doi = {},
url = {},
pmid = {},
journal = {Journal of Evolutionary Biology},
volume = {19},
number = {},
pages = {1314--1326},
abstract = {Coevolution has been hypothesized as the main driving force for the remarkable diversity of insect-plant associations. Dating of insect and plant phylogenies allows us to test coevolutionary hypotheses and distinguish between the contemporaneous radiation of interacting lineages versus insect host tracking of previously diversified plants. Here, we used nuclear DNA to reconstruct a molecular phylogeny for 100 species of Phyllonorycter leaf-mining moths and 36 outgroup taxa. Ages for nodes in the moth phylogeny were estimated using a combination of a penalized likelihood method and a Bayesian approach, which takes into account phylogenetic uncertainty. To convert the relative ages of the moths into dates, we used an absolute calibration point from the fossil record. The age estimates of (a selection of) moth clades were then compared with fossil-based age estimates of their host plants. Our results show that the principal radiation of Phyllonorycter leaf-mining moths occurred well after the main radiation of their host-plants and may represent the dominant associational mode in the fossil record.}
}
Trees for Study 1479

Citation title:
"Fossil-calibrated molecular phylogenies reveal that leaf-mining moths radiated several million years after their host plants".

This study was previously identified under the legacy study ID S1423
(Status: Published).
Trees