@ARTICLE{TreeBASE2Ref20614,
author = {Susana Magall?n and Khidir W. Hilu and Dietmar Quandt},
title = {Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates.},
year = {2013},
keywords = {angiosperms; calibrations; fossil record; model misspecification; penalized likelihood; substitution rate; uncorrelated lognormal relaxed clock},
doi = {10.3732/ajb.1200416},
url = {http://},
pmid = {},
journal = {American Journal of Botany},
volume = {100},
number = {3},
pages = {556--573},
abstract = {? Premise of the Study: Land plants play an essential role in the evolution of terrestrial life. Their time of origin and diversification is fundamental to understanding the evolution of life on land. We investigate the timing and the rate of molecular evolution of land plants, evaluating the effects of different types of molecular data, including temporal information from fossils, and using different molecular clock methods.
? Methods: Ages and absolute rates were estimated independently with two substitutionally different data sets: a highly conserved 4-gene data set, and matK, a fast-evolving gene. The vascular plant backbone and the crown nodes of all major lineages were calibrated with fossil-derived ages. Dates and absolute rates were estimated while including or excluding the calibrations, and using two relaxed clocks that differ in their implementation of temporal autocorrelation.
? Key Results: Land plants diverged from streptophyte alga 912 (870 ? 962) mya but diversified into living lineages 475 (471 ? 480) mya. Ages estimated for all major land-plant lineages agree with their fossil record, except for angiosperms. Different genes estimated very similar ages and statistically correlated absolute rates across the tree. Excluding calibrations resulted in the greatest age differences, and weakly correlated absolute rates. Different relaxed clocks provided similar ages, but different and uncorrelated absolute rates.
? Conclusions: Whole-genome rate accelerations or decelerations may underlie the similar ages and correlated absolute rates estimated with different genes. We suggest that pronounced substitution rate changes around the angiosperm crown node may represent a challenge for relaxed clocks to model adequately.
}
}
Citation for Study 12607
Citation title:
"Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates.".
Study name:
"Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates.".
This study is part of submission 12607
(Status: Published).
Citation
Magall?n S., Hilu K., & Quandt D. 2013. Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates. American Journal of Botany, 100(3): 556-573.
Authors
-
Magall?n S.
(submitter)
5255-5622-9087
-
Hilu K.
-
Quandt D.
Abstract
? Premise of the Study: Land plants play an essential role in the evolution of terrestrial life. Their time of origin and diversification is fundamental to understanding the evolution of life on land. We investigate the timing and the rate of molecular evolution of land plants, evaluating the effects of different types of molecular data, including temporal information from fossils, and using different molecular clock methods.
? Methods: Ages and absolute rates were estimated independently with two substitutionally different data sets: a highly conserved 4-gene data set, and matK, a fast-evolving gene. The vascular plant backbone and the crown nodes of all major lineages were calibrated with fossil-derived ages. Dates and absolute rates were estimated while including or excluding the calibrations, and using two relaxed clocks that differ in their implementation of temporal autocorrelation.
? Key Results: Land plants diverged from streptophyte alga 912 (870 ? 962) mya but diversified into living lineages 475 (471 ? 480) mya. Ages estimated for all major land-plant lineages agree with their fossil record, except for angiosperms. Different genes estimated very similar ages and statistically correlated absolute rates across the tree. Excluding calibrations resulted in the greatest age differences, and weakly correlated absolute rates. Different relaxed clocks provided similar ages, but different and uncorrelated absolute rates.
? Conclusions: Whole-genome rate accelerations or decelerations may underlie the similar ages and correlated absolute rates estimated with different genes. We suggest that pronounced substitution rate changes around the angiosperm crown node may represent a challenge for relaxed clocks to model adequately.
Keywords
angiosperms; calibrations; fossil record; model misspecification; penalized likelihood; substitution rate; uncorrelated lognormal relaxed clock
External links
About this resource
- Canonical resource URI:
http://purl.org/phylo/treebase/phylows/study/TB2:S12607
- Other versions:
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NeXML
- Show BibTeX reference
@ARTICLE{TreeBASE2Ref20614,
author = {Susana Magall?n and Khidir W. Hilu and Dietmar Quandt},
title = {Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates.},
year = {2013},
keywords = {angiosperms; calibrations; fossil record; model misspecification; penalized likelihood; substitution rate; uncorrelated lognormal relaxed clock},
doi = {10.3732/ajb.1200416},
url = {http://},
pmid = {},
journal = {American Journal of Botany},
volume = {100},
number = {3},
pages = {556--573},
abstract = {? Premise of the Study: Land plants play an essential role in the evolution of terrestrial life. Their time of origin and diversification is fundamental to understanding the evolution of life on land. We investigate the timing and the rate of molecular evolution of land plants, evaluating the effects of different types of molecular data, including temporal information from fossils, and using different molecular clock methods.
? Methods: Ages and absolute rates were estimated independently with two substitutionally different data sets: a highly conserved 4-gene data set, and matK, a fast-evolving gene. The vascular plant backbone and the crown nodes of all major lineages were calibrated with fossil-derived ages. Dates and absolute rates were estimated while including or excluding the calibrations, and using two relaxed clocks that differ in their implementation of temporal autocorrelation.
? Key Results: Land plants diverged from streptophyte alga 912 (870 ? 962) mya but diversified into living lineages 475 (471 ? 480) mya. Ages estimated for all major land-plant lineages agree with their fossil record, except for angiosperms. Different genes estimated very similar ages and statistically correlated absolute rates across the tree. Excluding calibrations resulted in the greatest age differences, and weakly correlated absolute rates. Different relaxed clocks provided similar ages, but different and uncorrelated absolute rates.
? Conclusions: Whole-genome rate accelerations or decelerations may underlie the similar ages and correlated absolute rates estimated with different genes. We suggest that pronounced substitution rate changes around the angiosperm crown node may represent a challenge for relaxed clocks to model adequately.
}
}
- Show RIS reference
TY - JOUR
ID - 20614
AU - Magall?n,Susana
AU - Hilu,Khidir W.
AU - Quandt,Dietmar
T1 - Land Plant Evolutionary Timeline: Gene Effects are Secondary to Fossil Constraints in Relaxed Clock Estimation of Age and Substitution Rates.
PY - 2013
KW - angiosperms; calibrations; fossil record; model misspecification; penalized likelihood; substitution rate; uncorrelated lognormal relaxed clock
UR - http://dx.doi.org/10.3732/ajb.1200416
N2 - ? Premise of the Study: Land plants play an essential role in the evolution of terrestrial life. Their time of origin and diversification is fundamental to understanding the evolution of life on land. We investigate the timing and the rate of molecular evolution of land plants, evaluating the effects of different types of molecular data, including temporal information from fossils, and using different molecular clock methods.
? Methods: Ages and absolute rates were estimated independently with two substitutionally different data sets: a highly conserved 4-gene data set, and matK, a fast-evolving gene. The vascular plant backbone and the crown nodes of all major lineages were calibrated with fossil-derived ages. Dates and absolute rates were estimated while including or excluding the calibrations, and using two relaxed clocks that differ in their implementation of temporal autocorrelation.
? Key Results: Land plants diverged from streptophyte alga 912 (870 ? 962) mya but diversified into living lineages 475 (471 ? 480) mya. Ages estimated for all major land-plant lineages agree with their fossil record, except for angiosperms. Different genes estimated very similar ages and statistically correlated absolute rates across the tree. Excluding calibrations resulted in the greatest age differences, and weakly correlated absolute rates. Different relaxed clocks provided similar ages, but different and uncorrelated absolute rates.
? Conclusions: Whole-genome rate accelerations or decelerations may underlie the similar ages and correlated absolute rates estimated with different genes. We suggest that pronounced substitution rate changes around the angiosperm crown node may represent a challenge for relaxed clocks to model adequately.
L3 - 10.3732/ajb.1200416
JF - American Journal of Botany
VL - 100
IS - 3
SP - 556
EP - 573
ER -