利用神经网络估算系统发生树参数的性能和稳健性

bioRxiv Pub Date : 2024-08-08 DOI:10.1101/2024.08.02.606350
Tianjian Qin, Koen J. van Benthem, Luis Valente, R. Etienne
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引用次数: 0

摘要

物种多样化的特点是物种的分化和灭绝,在某些假设条件下,物种分化和灭绝的速率可以通过时间校准的系统发育来估算。然而,用于推断速率的最大似然估计方法(MLE)仅限于较简单的模型,而且会出现偏差,尤其是在小型系统发育中。利用深度学习估计多样化模型参数的无似然方法已经开始出现,但神经网络方法在处理系统发育数据的复杂性方面有多强大,仍然是一个未决问题。在这里,我们提出了一种新的集合神经网络方法,利用不同类别的神经网络(密集神经网络、图神经网络和长短期记忆递归网络),同时从系统发育的图表示、分支时间和汇总统计中学习,从而从系统发育树中估计多样化参数。我们性能最好的集合神经网络(使用递归神经网络修正图神经网络的结果)计算估计值的速度比 MLE 更快,而且受树的大小影响较小。我们的分析表明,精确参数估计的主要限制因素是系统发育所包含的信息量,具体表现为系统发育的大小和影响系统发育的强度。在无法使用 MLE 的情况下,我们的神经网络方法为系统发生树参数估计提供了一种很有前途的替代方法。如果存在可检测到的系统发生学信号,我们的方法可以得到与 MLE 相当的结果,但不会产生固有偏差。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance and Robustness of Parameter Estimation from Phylogenetic Trees Using Neural Networks
Species diversification is characterized by speciation and extinction, the rates of which can, under some assumptions, be estimated from time-calibrated phylogenies. However, maximum likelihood estimation methods (MLE) for inferring rates are limited to simpler models and can show bias, particularly in small phylogenies. Likelihood-free methods to estimate parameters of diversification models using deep learning have started to emerge, but how robust neural network methods are at handling the intricate nature of phylogenetic data remains an open question. Here we present a new ensemble neural network approach to estimate diversification parameters from phylogenetic trees that leverages different classes of neural networks (dense neural network, graph neural network, and long short-term memory recurrent network) and simultaneously learns from graph representations of phylogenies, their branching times and their summary statistics. Our best-performing ensemble neural network (which corrects graph neural network result using a recurrent neural network) can compute estimates faster than MLE and is less affected by tree size. Our analysis suggests that the primary limitation to accurate parameter estimation is the amount of information contained within a phylogeny, as indicated by its size and the strength of effects shaping it. In cases where MLE is unavailable, our neural network method provides a promising alternative for estimating phylogenetic tree parameters. If there are detectable phylogenetic signals present, our approach delivers results that are comparable to MLE but without inherent biases.
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