Abstract
Cytonuclear discordance, commonly detected in phylogenetic studies, is often attributed to hybridization and/or incomplete lineage sorting (ILS). New sequencing technologies and analytical approaches can provide new insights into the relative importance of these processes. Hybridization has previously been reported in the Australian endemic plant genusAdenanthos(Proteaceae). Like many Australian genera,Adenanthosis of relatively ancient origin, and provides an opportunity to examine long-term evolutionary consequences of gene flow between lineages. Using a hybrid capture approach, we assembled densely sampled low-copy nuclear and plastid DNA sequences forAdenanthos, inferred its evolutionary history, and used a Bayesian posterior predictive approach and coalescent simulations to assess relative contributions of hybridization and ILS to cytonuclear discordance. Our analyses indicate that strong incongruence detected between our plastid and nuclear phylogenies is not only the result of ILS, but also results from extensive ancient introgression as well as recent chloroplast capture and introgression between extantAdenanthosspecies. The deep reticulation was also detected from long-persisting chloroplast haplotypes shared between evolutionarily distant species. These haplotypes may have persisted for over 12 Ma in localized populations across southwest Western Australia, indicating that the region is not only an important area for old endemic lineages and accumulation of species, but is also characterized by persistence of high genetic diversity. Deep introgression inAdenanthoscoincided with the rapid radiation of the genus during the Miocene, a time when many Australian temperate plant groups radiated in response to large-scale climatic change. This study suggests that ancient introgression may play an important role in the evolution of the Australian flora more broadly.
Highlights
Hybridization is important in the evolution of many plant groups (Arnold, 1992; Soltis and Soltis, 2009; Givnish, 2010)
Incongruence is significant between the plastid and nuclear Maximum Likelihood (ML) topologies, with the two datasets recovering a different number of clades and statistically well-supported conflicting relationships across species and clades (Figure 2)
The divergence time estimates from the combined internal transcribed spacer (ITS), matK, and rbcL, as well as ITS-only topologies, are closer to those obtained from our next-generation sequencing (NGS) plastid topology (Supplementary Table S8). These differences in divergence time estimates were consistent across all fossil calibration schemes, including those obtained from secondary calibration of NGS data only, when outgroups were excluded due to missing data (Supplementary Table S8).We focus on the divergence age estimates of the NGS plastid and ITS combined topologies here, as the older age estimates from the nuclear NGS data likely reflect the lack of available NGS data for outgroup taxa used for the calibration regimes as well as missing data from our NGS nuclear dataset
Summary
Hybridization is important in the evolution of many plant groups (Arnold, 1992; Soltis and Soltis, 2009; Givnish, 2010). Addressing the causes of cytonuclear incongruence is increasingly realistic using next-generation sequencing (NGS) approaches including targeted hybrid capture (Lemmon et al, 2012; Lemmon and Lemmon, 2013; Weitemier et al, 2014). These methods, which can generate sequences from multiple nuclear and organellar loci, allow rigorous exploration of causes of cytonuclear incongruence, including hybridization, using robustly supported phylogenies (Howarth and Baum, 2005; Vargas et al, 2017)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
