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A phylogenomic supermatrix of Galliformes (Landfowl) reveals biased branch lengths.

Authors :
Kimball, Rebecca T.
Hosner, Peter A.
Braun, Edward L.
Source :
Molecular Phylogenetics & Evolution. May2021, Vol. 158, pN.PAG-N.PAG. 1p.
Publication Year :
2021

Abstract

• A supermatrix including next-generation sequences resulted in a taxon-rich phylogeny. • Taxa with very little data typically had very long branches. • Re-estimating branch lengths using mitochondrial data reduced this problem. • Re-estimating branches may improve downstream comparative studies. Building taxon-rich phylogenies is foundational for macroevolutionary studies. One approach to improve taxon sampling beyond individual studies is to build supermatricies of publicly available data, incorporating taxa sampled across different studies and utilizing different loci. Most existing supermatrix studies have focused on loci commonly sequenced with Sanger technology ("legacy" markers, such as mitochondrial data and small numbers of nuclear loci). However, incorporating phylogenomic studies into supermatrices allows problem nodes to be targeted and resolved with considerable amounts of data, while improving taxon sampling with legacy data. Here we estimate phylogeny from a galliform supermatrix which includes well-known model and agricultural species such as the chicken and turkey. We assembled a supermatrix comprising 4500 ultra-conserved elements (UCEs) collected as part of recent phylogenomic studies in this group and legacy mitochondrial and nuclear (intron and exon) sequences. Our resulting phylogeny included 88% of extant species and recovered well-accepted relationships with strong support. However, branch lengths, which are particularly important in down-stream macroevolutionary studies, appeared vastly skewed. Taxa represented only by rapidly evolving mitochondrial data had high proportions of missing data and exhibited long terminal branches. Conversely, taxa sampled for slowly evolving UCEs with low proportions of missing data exhibited substantially shorter terminal branches. We explored several branch length re-estimation methods with particular attention to terminal branches and conclude that re-estimation using well-sampled mitochondrial sequences may be a pragmatic approach to obtain trees suitable for macroevolutionary analysis. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
10557903
Volume :
158
Database :
Academic Search Index
Journal :
Molecular Phylogenetics & Evolution
Publication Type :
Academic Journal
Accession number :
149125972
Full Text :
https://doi.org/10.1016/j.ympev.2021.107091