@ARTICLE{TreeBASE2Ref16092,
author = {Martyn Kennedy and Barbara R. Holland and Russell D. Gray and Hamish G. Spencer},
title = {Untangling long branches: Identifying conflicting phylogenetic signals using spectral analysis, Neighbor-Net, and consensus networks.},
year = {2005},
keywords = {},
doi = {10.1080/106351591007462},
url = {},
pmid = {},
journal = {Systematic Biology},
volume = {54},
number = {4},
pages = {620--633},
abstract = {Long-branch attraction is a well known source of systematic error that can mislead phylogenetic methods, it is frequently invoked posthoc, upon recovering a different tree to the one expected based on prior evidence. We demonstrate that methods that do not force the data onto a single tree, such as spectral analysis, Neighbor-Net, and consensus networks, can be used to detect conflicting signals within the data, including those caused by long-branch attraction. We illustrate this approach using a set of taxa from three unambiguously monophyletic families within the Pelecaniformes: the darters, the cormorants and shags, and the gannets and boobies. These three families are universally acknowledged as forming a monophyletic group, but the relationship between the families remains contentious. Using sequence data from three mitochondrial genes (12S, ATPase 6, and ATPase 8) we demonstrate that the relationship between these three families is difficult to resolve because they are separated by a short internal branch and there are conflicting signals due to long-branch attraction that are confounded with non-homogeneous sequence evolution across the different genes. Spectral analysis, Neighbor-Net, and consensus networks reveal conflicting signals regarding the placement of one of the darters, with support found for darter monophyly, but also support for a conflicting grouping with the outgroup, pelicans. Furthermore, parsimony and maximum-likelihood analyses produced different trees, with one of the two most parsimonious trees not supporting the monophyly of the darters. Monte-Carlo simulations, however, were not sensitive enough to reveal long-branch attraction unless the branches are longer than those actually observed. These results indicate that spectral analysis, Neighbor-Net, and consensus networks offer a powerful approach to detecting, and understanding the source of, conflicting signals within phylogenetic data.}
}
Citation for Study 1332
Citation title:
"Untangling long branches: Identifying conflicting phylogenetic signals using spectral analysis, Neighbor-Net, and consensus networks.".
This study was previously identified under the legacy study ID S1257
(Status: Published).
Citation
Kennedy M., Holland B., Gray R., & Spencer H. 2005. Untangling long branches: Identifying conflicting phylogenetic signals using spectral analysis, Neighbor-Net, and consensus networks. Systematic Biology, 54(4): 620-633.
Authors
-
Kennedy M.
-
Holland B.
-
Gray R.
-
Spencer H.
Abstract
Long-branch attraction is a well known source of systematic error that can mislead phylogenetic methods, it is frequently invoked posthoc, upon recovering a different tree to the one expected based on prior evidence. We demonstrate that methods that do not force the data onto a single tree, such as spectral analysis, Neighbor-Net, and consensus networks, can be used to detect conflicting signals within the data, including those caused by long-branch attraction. We illustrate this approach using a set of taxa from three unambiguously monophyletic families within the Pelecaniformes: the darters, the cormorants and shags, and the gannets and boobies. These three families are universally acknowledged as forming a monophyletic group, but the relationship between the families remains contentious. Using sequence data from three mitochondrial genes (12S, ATPase 6, and ATPase 8) we demonstrate that the relationship between these three families is difficult to resolve because they are separated by a short internal branch and there are conflicting signals due to long-branch attraction that are confounded with non-homogeneous sequence evolution across the different genes. Spectral analysis, Neighbor-Net, and consensus networks reveal conflicting signals regarding the placement of one of the darters, with support found for darter monophyly, but also support for a conflicting grouping with the outgroup, pelicans. Furthermore, parsimony and maximum-likelihood analyses produced different trees, with one of the two most parsimonious trees not supporting the monophyly of the darters. Monte-Carlo simulations, however, were not sensitive enough to reveal long-branch attraction unless the branches are longer than those actually observed. These results indicate that spectral analysis, Neighbor-Net, and consensus networks offer a powerful approach to detecting, and understanding the source of, conflicting signals within phylogenetic data.
External links
About this resource
- Canonical resource URI:
http://purl.org/phylo/treebase/phylows/study/TB2:S1332
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- Show BibTeX reference
@ARTICLE{TreeBASE2Ref16092,
author = {Martyn Kennedy and Barbara R. Holland and Russell D. Gray and Hamish G. Spencer},
title = {Untangling long branches: Identifying conflicting phylogenetic signals using spectral analysis, Neighbor-Net, and consensus networks.},
year = {2005},
keywords = {},
doi = {10.1080/106351591007462},
url = {},
pmid = {},
journal = {Systematic Biology},
volume = {54},
number = {4},
pages = {620--633},
abstract = {Long-branch attraction is a well known source of systematic error that can mislead phylogenetic methods, it is frequently invoked posthoc, upon recovering a different tree to the one expected based on prior evidence. We demonstrate that methods that do not force the data onto a single tree, such as spectral analysis, Neighbor-Net, and consensus networks, can be used to detect conflicting signals within the data, including those caused by long-branch attraction. We illustrate this approach using a set of taxa from three unambiguously monophyletic families within the Pelecaniformes: the darters, the cormorants and shags, and the gannets and boobies. These three families are universally acknowledged as forming a monophyletic group, but the relationship between the families remains contentious. Using sequence data from three mitochondrial genes (12S, ATPase 6, and ATPase 8) we demonstrate that the relationship between these three families is difficult to resolve because they are separated by a short internal branch and there are conflicting signals due to long-branch attraction that are confounded with non-homogeneous sequence evolution across the different genes. Spectral analysis, Neighbor-Net, and consensus networks reveal conflicting signals regarding the placement of one of the darters, with support found for darter monophyly, but also support for a conflicting grouping with the outgroup, pelicans. Furthermore, parsimony and maximum-likelihood analyses produced different trees, with one of the two most parsimonious trees not supporting the monophyly of the darters. Monte-Carlo simulations, however, were not sensitive enough to reveal long-branch attraction unless the branches are longer than those actually observed. These results indicate that spectral analysis, Neighbor-Net, and consensus networks offer a powerful approach to detecting, and understanding the source of, conflicting signals within phylogenetic data.}
}
- Show RIS reference
TY - JOUR
ID - 16092
AU - Kennedy,Martyn
AU - Holland,Barbara R.
AU - Gray,Russell D.
AU - Spencer,Hamish G.
T1 - Untangling long branches: Identifying conflicting phylogenetic signals using spectral analysis, Neighbor-Net, and consensus networks.
PY - 2005
KW -
UR - http://dx.doi.org/10.1080/106351591007462
N2 - Long-branch attraction is a well known source of systematic error that can mislead phylogenetic methods, it is frequently invoked posthoc, upon recovering a different tree to the one expected based on prior evidence. We demonstrate that methods that do not force the data onto a single tree, such as spectral analysis, Neighbor-Net, and consensus networks, can be used to detect conflicting signals within the data, including those caused by long-branch attraction. We illustrate this approach using a set of taxa from three unambiguously monophyletic families within the Pelecaniformes: the darters, the cormorants and shags, and the gannets and boobies. These three families are universally acknowledged as forming a monophyletic group, but the relationship between the families remains contentious. Using sequence data from three mitochondrial genes (12S, ATPase 6, and ATPase 8) we demonstrate that the relationship between these three families is difficult to resolve because they are separated by a short internal branch and there are conflicting signals due to long-branch attraction that are confounded with non-homogeneous sequence evolution across the different genes. Spectral analysis, Neighbor-Net, and consensus networks reveal conflicting signals regarding the placement of one of the darters, with support found for darter monophyly, but also support for a conflicting grouping with the outgroup, pelicans. Furthermore, parsimony and maximum-likelihood analyses produced different trees, with one of the two most parsimonious trees not supporting the monophyly of the darters. Monte-Carlo simulations, however, were not sensitive enough to reveal long-branch attraction unless the branches are longer than those actually observed. These results indicate that spectral analysis, Neighbor-Net, and consensus networks offer a powerful approach to detecting, and understanding the source of, conflicting signals within phylogenetic data.
L3 - 10.1080/106351591007462
JF - Systematic Biology
VL - 54
IS - 4
SP - 620
EP - 633
ER -