Phylogenetic relationships, possible ancient hybridization, and biogeographic history of Abies (Pinaceae) based on data from nuclear, plastid, and mitochondrial genomes.

Abies, the second largest genus of Pinaceae, consists of approximately 48 species occurring in the north temperate region. Previous molecular phylogenetic studies improved our understanding of relationships within the genus, but were limited by relying on only DNA sequence data from single genome and low taxonomic sampling. Here we use DNA data from three genomes (sequences of internal transcribed spacer of nrITS, three chloroplast DNA intergenic spacers, and two mitochondrial intergenic spacers) from 42 species to elucidate species relationships and construct the biogeographic history of Abies. We further estimated the divergence times of intercontinental disjunction using a relaxed molecular clock calibrated with three macro-fossils. Our phylogenetic analyses recovered six robust clades largely consistent with previous classifications of sections. A sister relationship between the eastern Asian and Europe-Mediterranean clades was highly supported. The monophyly of section Balsamea, disjunct in Far East and western North America, is supported by the nrITS data but not by the cpDNA data. Discordance on placement of section Balsamea between the paternally inherited cpDNA and maternally inherited mtDNA trees was also observed. The data suggested that ancient hybridization was likely involved in the origin of sect. Balsamea. Results from biogeographic analyses and divergence time estimation suggested an origin and early diversification of Abies in an area of high latitude around the Pacific during the Eocene. The present disjunction in eastern Asia and Europe-Mediterranean area of Abies was likely the result of southward migration and isolation by the Turgai Strait in the Late Eocene. An 'out-of-America' migration, for the origin of an eastern Asian and western North American disjunct species pairs in section Amabilis was supported. The results suggested a western North American origin of the section with subsequent dispersal across the Bering Land Bridge (BLB) to Japan during the Middle Miocene.

Phylogeny and divergence times of gymnosperms inferred from single-copy nuclear genes.

Phylogenetic reconstruction is fundamental to study evolutionary biology and historical biogeography. However, there was not a molecular phylogeny of gymnosperms represented by extensive sampling at the genus level, and most published phylogenies of this group were constructed based on cytoplasmic DNA markers and/or the multi-copy nuclear ribosomal DNA. In this study, we use LFY and NLY, two single-copy nuclear genes that originated from an ancient gene duplication in the ancestor of seed plants, to reconstruct the phylogeny and estimate divergence times of gymnosperms based on a complete sampling of extant genera. The results indicate that the combined LFY and NLY coding sequences can resolve interfamilial relationships of gymnosperms and intergeneric relationships of most families. Moreover, the addition of intron sequences can improve the resolution in Podocarpaceae but not in cycads, although divergence times of the cycad genera are similar to or longer than those of the Podocarpaceae genera. Our study strongly supports cycads as the basal-most lineage of gymnosperms rather than sister to Ginkgoaceae, and a sister relationship between Podocarpaceae and Araucariaceae and between Cephalotaxaceae-Taxaceae and Cupressaceae. In addition, intergeneric relationships of some families that were controversial, and the relationships between Taxaceae and Cephalotaxaceae and between conifers and Gnetales are discussed based on the nuclear gene evidence. The molecular dating analysis suggests that drastic extinctions occurred in the early evolution of gymnosperms, and extant coniferous genera in the Northern Hemisphere are older than those in the Southern Hemisphere on average. This study provides an evolutionary framework for future studies on gymnosperms.

Three genome-based phylogeny of Cupressaceae s.l.: further evidence for the evolution of gymnosperms and Southern Hemisphere biogeography.

Phylogenetic information is essential to interpret the evolution of species. While DNA sequences from different genomes have been widely utilized in phylogenetic reconstruction, it is still difficult to use nuclear genes to reconstruct phylogenies of plant groups with large genomes and complex gene families, such as gymnosperms. Here, we use two single-copy nuclear genes, together with chloroplast and mitochondrial genes, to reconstruct the phylogeny of the ecologically-important conifer family Cupressaceae s.l., based on a complete sampling of its 32 genera. The different gene trees generated are highly congruent in topology, supporting the basal position of Cunninghamia and the seven-subfamily classification, and the estimated divergence times based on different datasets correspond well with each other and with the oldest fossil record. These results imply that we have obtained the species phylogeny of Cupressaceae s.l. In addition, possible origins of all three polyploid conifers were investigated, and a hybrid origin was suggested for Cupressus, Fitzroya and Sequoia. Moreover, we found that the biogeographic history of Cupressaceae s.l. is associated with the separation between Laurasia and Gondwana and the further break-up of the latter. Our study also provides new evidence for the gymnosperm phylogeny.

Molecular phylogeny and biogeography of Pseudotsuga (Pinaceae): insights into the floristic relationship between Taiwan and its adjacent areas.

Climatic oscillations and geological events play major roles in shaping species diversity and the distribution of plants. The mechanisms underlying the high level of plant species diversity in eastern Asia are hotly debated. In this study, five cpDNA regions, two mtDNA fragments and one nuclear gene (LEAFY) were employed to investigate species diversification and the historical biogeography of Pseudotsuga (Pinaceae), a genus with a typical eastern Asia and western North America disjunct distribution. Both the nuclear LEAFY gene and cpDNA phylogenies strongly suggest that eastern Asian and North American species are monophyletic, respectively. Within the eastern Asia clade, the cpDNA tree placed P. japonica as sister to the rest of the Asian species, but the LEAFY gene tree showed a sister relationship between P. japonica-P. sinensis-P. gaussenii and P. brevifolia-P. forrestii. Molecular dating indicated that the Asian species last shared a common ancestor 20.26+/-5.84 mya and the species diversification of Pseudotsuga was correlated with the Tertiary climatic and tectonic changes. These results, together with the fossil evidence, suggest that Pseudotsuga might have originated from North America and then migrated to eastern Asia by the Bering land bridge during the early Miocene. The Taiwanese species P. wilsoniana harbored two divergent types of LEAFY sequences, which implies that this species might have originated by hybridization between P. brevifolia or its ancestor and the ancestor of P. japonica-P. sinensis-P. gaussenii. Our study also suggests that Taiwan is closely related to both southwest and east China in flora.