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使用具有软边界和硬边界的贝叶斯分析评估分子钟校准。

Evaluating molecular clock calibrations using Bayesian analyses with soft and hard bounds.

作者信息

Sanders Kate L, Lee Michael S Y

机构信息

School of Earth and Environmental Sciences, University of Adelaide, Darling Building, Adelaide, Australia 5005.

出版信息

Biol Lett. 2007 Jun 22;3(3):275-9. doi: 10.1098/rsbl.2007.0063.

DOI:10.1098/rsbl.2007.0063
PMID:17363358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2464697/
Abstract

A limiting factor in many molecular dating studies is shortage of reliable calibrations. Current methods for choosing calibrations (e.g. cross-validation) treat them as either correct or incorrect, whereas calibrations probably lie on a continuum from highly accurate to very poor. Bayesian relaxed clock analysis permits inclusion of numerous candidate calibrations as priors: provided most calibrations are reliable, the model appropriate and the data informative, the accuracy of each calibration prior can be evaluated. If a calibration is accurate, then the analysis will support the prior so that the posterior estimate reflects the prior; if a calibration is poor, the posterior will be forced away from the prior. We use this approach to test two fossil dates recently proposed as standard calibrations within vertebrates. The proposed bird-crocodile calibration (approx. 247Myr ago) appears to be accurate, but the proposed bird-lizard calibration (approx. 255Myr ago) is substantially too recent.

摘要

许多分子年代测定研究中的一个限制因素是缺乏可靠的校准。目前选择校准的方法(如交叉验证)将校准视为要么正确要么错误,而校准可能处于从高度准确到非常差的连续区间。贝叶斯宽松时钟分析允许纳入众多候选校准作为先验:只要大多数校准是可靠的、模型合适且数据提供信息,就可以评估每个校准先验的准确性。如果校准是准确的,那么分析将支持该先验,使得后验估计反映该先验;如果校准较差,后验将被迫偏离该先验。我们使用这种方法来检验最近被提议作为脊椎动物标准校准的两个化石年代。提议的鸟类 - 鳄鱼校准(约2.47亿年前)似乎是准确的,但提议的鸟类 - 蜥蜴校准(约2.55亿年前)则明显太近了。

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