The Timing of Eukaryotic Evolution: Does a Relaxed Molecular Clock Reconcile Proteins and Fossils?

The use of nucleotide and amino acid sequences allows improved understanding of the timing of evolutionary events of life on earth. Molecular estimates of divergence times are, however, controversial and are generally much more ancient than suggested by the fossil record. The limited number of genes...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2004-10, Vol.101 (43), p.15386-15391
Main Authors: Emmanuel J. P. Douzery, Snell, Elizabeth A., Bapteste, Eric, Delsuc, Frédéric, Philippe, Hervé, Li, Wen-Hsiung
Format: Article
Language:English
Subjects:
Amino acids
Animals
Bilateria
Biodiversity and Ecology
Bioinformatics
Biological Evolution
Biological Sciences
Calibration
Computer Science
Datasets
domain_sde.be.biod
domain_sde.be.bios
domain_sde.be.evo
domain_sde.be.pal
Environmental Sciences
Eukaryotes
Eukaryotic cells
Evolution
Fossils
Fungi
Life Sciences
Likelihood Functions
Missing data
Plant roots
Quantitative Methods
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Summary:The use of nucleotide and amino acid sequences allows improved understanding of the timing of evolutionary events of life on earth. Molecular estimates of divergence times are, however, controversial and are generally much more ancient than suggested by the fossil record. The limited number of genes and species explored and pervasive variations in evolutionary rates are the most likely sources of such discrepancies. Here we compared concatenated amino acid sequences of 129 proteins from 36 eukaryotes to determine the divergence times of several major clades, including animals, fungi, plants, and various protists. Due to significant variations in their evolutionary rates, and to handle the uncertainty of the fossil record, we used a Bayesian relaxed molecular clock simultaneously calibrated by six paleontological constraints. We show that, according to 95% credibility intervals, the eukaryotic kingdoms diversified 950-1,259 million years ago (Mya), animals diverged from choanoflagellates 761-957 Mya, and the debated age of the split between protostomes and deuterostomes occurred 642-761 Mya. The divergence times appeared to be robust with respect to prior assumptions and paleontological calibrations. Interestingly, these relaxed clock time estimates are much more recent than those obtained under the assumption of a global molecular clock, yet bilaterian diversification appears to be ≈100 million years more ancient than the Cambrian boundary.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0403984101