RESUMO
PREMISE OF THE STUDY: Pinaceae have a rich but enigmatic early fossil record, much of which is represented by permineralized seed cones. Our incomplete knowledge of morphology and anatomy in living and extinct species poses an important barrier to understanding their phylogenetic relationships and timing of diversification. METHODS: We expanded a morphology matrix to 46 fossil and 31 extant Pinaceae species, mainly adding characters from stem and leaf anatomy and seed cones. Using parsimony and Bayesian inference, we compared phylogenetic relationships for extant taxa with and without fossils from the morphology matrix combined with an alignment of plastid gene sequences. KEY RESULTS: Combined analysis of morphological and molecular characters resulted in a phylogeny of extant Pinaceae that was robust at all nodes except those relating to the interrelationships of Pinus, Picea, and Cathaya and the position of Cedrus. Simultaneous analysis of all fossil and extant species did not result in changes in the relationships among the extant species but did greatly reduce branch support. We found that the placement of most fossils was sensitive to the method of phylogenetic reconstruction when analyzing them singly with the extant species. CONCLUSIONS: A robust phylogenetic hypothesis for the main lineages of Pinaceae is emerging. Most Early Cretaceous fossils are stem or crown lineages of Pinus, but close relationships also were found between fossils and several other extant genera. The phylogenetic position of fossils broadly supports the existence of extant genera in the Lower Cretaceous.
Assuntos
Fósseis , Filogenia , Pinaceae/genética , Pinaceae/anatomia & histologiaRESUMO
PREMISE OF THE STUDY: Both incomplete lineage sorting and reticulation have been proposed as causes of phylogenetic incongruence. Disentangling these factors may be most difficult in long-lived, wind-pollinated plants with large population sizes and weak reproductive barriers. METHODS: We used solution hybridization for targeted enrichment and massive parallel sequencing to characterize low-copy-number nuclear genes and high-copy-number plastomes (Hyb-Seq) in 74 individuals of Pinus subsection Australes, a group of ~30 New World pine species of exceptional ecological and economic importance. We inferred relationships using methods that account for both incomplete lineage sorting and reticulation. KEY RESULTS: Concatenation- and coalescent-based trees inferred from nuclear genes mainly agreed with one another, but they contradicted the plastid DNA tree in recovering the Attenuatae (the California closed-cone pines) and Oocarpae (the egg-cone pines of Mexico and Central America) as monophyletic and the Australes sensu stricto (the southern yellow pines) as paraphyletic to the Oocarpae. The plastid tree featured some relationships that were discordant with morphological and geographic evidence and species limits. Incorporating gene flow into the coalescent analyses better fit the data, but evidence supporting the hypothesis that hybridization explains the non-monophyly of the Attenuatae in the plastid tree was equivocal. CONCLUSIONS: Our analyses document cytonuclear discordance in Pinus subsection Australes. We attribute this discordance to ancient and recent introgression and present a phylogenetic hypothesis in which mostly hierarchical relationships are overlain by gene flow.