Divergence within the Atlantic forest clade began in the Mid-Oligocene, while the Amazonian clade underwent rapid diversification starting in the Late Miocene. These two clades showed very different diversification scenarios. The first diversification event involved a split between Amazonian and Atlantic forest clades. Amphilophium originated in the Early Oligocene, and started to diversify in the Late Oligocene. Overall, we obtained a well-resolved and strongly supported phylogeny for Amphilophium, with five main clades that are well characterized by morphological features. We further inferred ancestral ranges, migration events, and shifts in diversification rates using a branch-specific diversification model and the Dispersal-Extinction-Cladogenesis (DEC) model implemented in a Bayesian phylogenetic framework. We also used this dataset to estimate divergence times using a Bayesian relaxed-clock approach. The final dataset included 78 plastid-coding regions and was analyzed under Maximum Likelihood and Bayesian approaches to reconstruct the phylogeny of Amphilophium. We generated nearly-complete plastome sequences for 32 species of Amphilophium, representing 70% of the species diversity in the genus.
Even though Amphilophium is broadly distributed across the Neotropics, it is centered in Amazonia and the Atlantic rainforest. In this study, we used a phylogenomic approach to infer relationships and examine the role of major geological and climatic events in shaping biogeographic patterns within Amphilophium (Bignonieae, Bignoniaceae), a genus of Neotropical lianas.
Geneious convert sequencher spf file drivers#
The Neotropics is the most species-rich region in the World, representing an excellent model for studying the drivers of diversification. The mechanisms and processes underlying patterns of species distributions have intrigued ecologists and biogeographers for a long time.