Museum of Natural Science, Louisiana State University, Baton Rouge, Louisiana, USA.
PLoS One. 2013;8(1):e54848. doi: 10.1371/journal.pone.0054848. Epub 2013 Jan 29.
Evolutionary relationships among birds in Neoaves, the clade comprising the vast majority of avian diversity, have vexed systematists due to the ancient, rapid radiation of numerous lineages. We applied a new phylogenomic approach to resolve relationships in Neoaves using target enrichment (sequence capture) and high-throughput sequencing of ultraconserved elements (UCEs) in avian genomes. We collected sequence data from UCE loci for 32 members of Neoaves and one outgroup (chicken) and analyzed data sets that differed in their amount of missing data. An alignment of 1,541 loci that allowed missing data was 87% complete and resulted in a highly resolved phylogeny with broad agreement between the Bayesian and maximum-likelihood (ML) trees. Although results from the 100% complete matrix of 416 UCE loci were similar, the Bayesian and ML trees differed to a greater extent in this analysis, suggesting that increasing from 416 to 1,541 loci led to increased stability and resolution of the tree. Novel results of our study include surprisingly close relationships between phenotypically divergent bird families, such as tropicbirds (Phaethontidae) and the sunbittern (Eurypygidae) as well as between bustards (Otididae) and turacos (Musophagidae). This phylogeny bolsters support for monophyletic waterbird and landbird clades and also strongly supports controversial results from previous studies, including the sister relationship between passerines and parrots and the non-monophyly of raptorial birds in the hawk and falcon families. Although significant challenges remain to fully resolving some of the deep relationships in Neoaves, especially among lineages outside the waterbirds and landbirds, this study suggests that increased data will yield an increasingly resolved avian phylogeny.
新颌类鸟类(包含绝大多数鸟类多样性的进化枝)的进化关系一直困扰着系统分类学家,因为大量谱系经历了古老而迅速的辐射。我们应用了一种新的基因组学方法,通过靶向富集(序列捕获)和鸟类基因组中超保守元件(UCE)的高通量测序来解决新颌类中的关系。我们从 32 个新颌类成员和一个外群(鸡)的 UCE 基因座中收集了序列数据,并分析了具有不同缺失数据量的数据集。一个允许缺失数据的 1541 个基因座的比对完整度为 87%,产生了一个高度分辨率的系统发育树,贝叶斯树和最大似然树之间有广泛的一致性。尽管来自 416 个 UCE 基因座的 100%完整矩阵的结果相似,但在该分析中,贝叶斯树和最大似然树的差异更大,这表明从 416 个增加到 1541 个基因座增加了树的稳定性和分辨率。我们研究的新结果包括表型差异很大的鸟类家族之间非常接近的关系,例如热带鸟(管鼻鹱科)和太阳鸟(美洲鹤科),以及鸨(鸨科)和犀鸟(犀鸟科)之间的关系。这个系统发育树支持水鸟和陆鸟类群的单系性,也强烈支持以前研究的有争议的结果,包括雀形目和鹦鹉目之间的姐妹关系以及鹰科和隼科中的猛禽不是单系的。尽管要完全解决新颌类中的一些深层关系仍然存在重大挑战,特别是在水鸟和陆鸟以外的谱系中,但这项研究表明,增加数据将产生越来越清晰的鸟类系统发育树。
