Abstract
True fruit flies (Tephritidae) include several species that cause extensive damage to agriculture worldwide. Among them, species of the genus Bactrocera are widely studied to understand the traits associated to their invasiveness and ecology. Comparative approaches based on a reliable phylogenetic framework are particularly effective, but, to date, molecular phylogenies of Bactrocera are still controversial. Here, we employed a comprehensive genomic dataset to infer a robust backbone phylogeny of eleven representative Bactrocera species and two outgroups. We further provide the first genome scaled inference of their divergence using calibrated relaxed clock. The results of our analyses support a closer relationship of B. dorsalis to B. latifrons than to B. tryoni, in contrast to all mitochondrial-based phylogenies. By comparing different evolutionary models, we show that this incongruence likely derives from the fast and recent radiation of these species that occurred around 2 million years ago, which may be associated with incomplete lineage sorting and possibly (ongoing) hybridization. These results can serve as basis for future comparative analyses and highlight the utility of using large datasets and efficient phylogenetic approaches to study the evolutionary history of species of economic importance.
Competing Interest Statement
The authors have declared no competing interest.