THE SCALABLE BIRTH-DEATH MCMC ALGORITHM FOR MIXED GRAPHICAL MODEL LEARNING WITH APPLICATION TO GENOMIC DATA INTEGRATION.

IF 1.3 4区数学 Q2 STATISTICS & PROBABILITY

Annals of Applied Statistics Pub Date : 2023-09-01 Epub Date: 2023-10-07 DOI:10.1214/22-aoas1701

Nanwei Wang, Hélène Massam, Xin Gao, Laurent Briollais

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引用次数: 1

Abstract

Recent advances in biological research have seen the emergence of high-throughput technologies with numerous applications that allow the study of biological mechanisms at an unprecedented depth and scale. A large amount of genomic data is now distributed through consortia like The Cancer Genome Atlas (TCGA), where specific types of biological information on specific type of tissue or cell are available. In cancer research, the challenge is now to perform integrative analyses of high-dimensional multi-omic data with the goal to better understand genomic processes that correlate with cancer outcomes, e.g. elucidate gene networks that discriminate a specific cancer subgroups (cancer sub-typing) or discovering gene networks that overlap across different cancer types (pan-cancer studies). In this paper, we propose a novel mixed graphical model approach to analyze multi-omic data of different types (continuous, discrete and count) and perform model selection by extending the Birth-Death MCMC (BDMCMC) algorithm initially proposed by Stephens (2000) and later developed by Mohammadi and Wit (2015). We compare the performance of our method to the LASSO method and the standard BDMCMC method using simulations and find that our method is superior in terms of both computational efficiency and the accuracy of the model selection results. Finally, an application to the TCGA breast cancer data shows that integrating genomic information at different levels (mutation and expression data) leads to better subtyping of breast cancers.

查看原文本刊更多论文

用于混合图形模型学习的可扩展出生路径MCMC算法及其在基因组数据集成中的应用。

生物研究的最新进展见证了高通量技术的出现，这些技术具有许多应用，可以以前所未有的深度和规模研究生物机制。大量的基因组数据现在通过癌症基因组图谱（TCGA）等联盟分发，其中可以获得关于特定类型组织或细胞的特定类型生物信息。在癌症研究中，现在的挑战是对高维多组数据进行综合分析，以更好地理解与癌症结果相关的基因组过程，例如阐明区分特定癌症亚群（癌症亚型）的基因网络，或发现不同癌症类型重叠的基因网络（泛癌研究）。在本文中，我们提出了一种新的混合图形模型方法来分析不同类型（连续、离散和计数）的多组数据，并通过扩展最初由Stephens（2000）提出、后来由Mohammadi和Wit（2015）开发的出生-死亡MCMC（BDMCMC）算法来进行模型选择。我们使用仿真将我们的方法的性能与LASSO方法和标准BDMCMC方法进行了比较，发现我们的方法在计算效率和模型选择结果的准确性方面都是优越的。最后，TCGA乳腺癌症数据的应用表明，整合不同水平的基因组信息（突变和表达数据）可以更好地分型乳腺癌。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annals of Applied Statistics 社会科学-统计学与概率论

CiteScore

3.10

自引率

5.60%

发文量

131

审稿时长

6-12 weeks

期刊介绍： Statistical research spans an enormous range from direct subject-matter collaborations to pure mathematical theory. The Annals of Applied Statistics, the newest journal from the IMS, is aimed at papers in the applied half of this range. Published quarterly in both print and electronic form, our goal is to provide a timely and unified forum for all areas of applied statistics.