RT Journal Article
SR Electronic
T1 Interspecific plastome recombination reflects ancient reticulate evolution in <em>Picea</em> (Pinaceae)
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 097519
DO 10.1101/097519
A1 Alexis R. Sullivan
A1 Bastian Schiffthaler
A1 Stacey Lee Thompson
A1 Nathaniel R. Street
A1 Xiao-Ru Wang
YR 2017
UL http://biorxiv.org/content/early/2017/03/13/097519.abstract
AB Plastid sequences are a cornerstone in plant systematic studies and key aspects of their evolution, such as uniparental inheritance and absent recombination, are often treated as axioms. While exceptions to these assumptions can profoundly influence evolutionary inference, detecting them can require extensive sampling, abundant sequence data, and detailed testing. Using advancements in high-throughput sequencing, we analyzed the whole plastomes of 65 accessions of Picea, a genus of ~35 coniferous forest tree species, to test for deviations from canonical plastome evolution. Using complementary hypothesis and data-driven tests, we found evidence for chimeric plastomes generated by interspecific hybridization and recombination in the clade comprising Norway spruce (P. abies) and ten other species. Support for interspecific recombination remained after controlling for sequence saturation, positive selection, and potential alignment artifacts. These results reconcile previous conflicting plastid-based phylogenies and strengthen the mounting evidence of reticulate evolution in Picea. Given the relatively high frequency of hybridization and biparental plastid inheritance in plants, we suggest interspecific plastome recombination may be more widespread than currently appreciated and could underlie reported cases of discordant plastid phylogenies.