Bayesian Random Segmentation Models to Identify Shared Copy Number Aberrations for Array CGH Data

Overview

Journal J Am Stat Assoc

Specialty Public Health

Date 2011 Apr 23

PMID 21512611

Citations 23

Authors

Veerabhadran Baladandayuthapani

Yuan Ji

Rajesh Talluri

Luis E Nieto-Barajas

Jeffrey S Morris

Affiliations

Soon will be listed here.

Abstract

Array-based comparative genomic hybridization (aCGH) is a high-resolution high-throughput technique for studying the genetic basis of cancer. The resulting data consists of log fluorescence ratios as a function of the genomic DNA location and provides a cytogenetic representation of the relative DNA copy number variation. Analysis of such data typically involves estimation of the underlying copy number state at each location and segmenting regions of DNA with similar copy number states. Most current methods proceed by modeling a single sample/array at a time, and thus fail to borrow strength across multiple samples to infer shared regions of copy number aberrations. We propose a hierarchical Bayesian random segmentation approach for modeling aCGH data that utilizes information across arrays from a common population to yield segments of shared copy number changes. These changes characterize the underlying population and allow us to compare different population aCGH profiles to assess which regions of the genome have differential alterations. Our method, referred to as BDSAcgh (Bayesian Detection of Shared Aberrations in aCGH), is based on a unified Bayesian hierarchical model that allows us to obtain probabilities of alteration states as well as probabilities of differential alteration that correspond to local false discovery rates. We evaluate the operating characteristics of our method via simulations and an application using a lung cancer aCGH data set.

Citing Articles

A semiparametric Bayesian model for comparing DNA copy numbers.

Nieto-Barajas L, Ji Y, Baladandayuthapani V Braz J Probab Stat. 2023; 30(3):345-365.

PMID: 37799327 PMC: 10552905. DOI: 10.1214/15-bjps283.

BAYESIAN INFERENCE AND DYNAMIC PREDICTION FOR MULTIVARIATE LONGITUDINAL AND SURVIVAL DATA.

Zou H, Zeng D, Xiao L, Luo S Ann Appl Stat. 2023; 17(3):2574-2595.

PMID: 37719893 PMC: 10500582. DOI: 10.1214/23-aoas1733.

Integrative Sparse Bayesian Analysis of High-dimensional Multi-platform Genomic Data in Glioblastoma.

Bhadra A, Baladandayuthapani V IEEE Int Workshop Genomic Signal Process Stat. 2023; 2013:1-4.

PMID: 37016713 PMC: 10068898. DOI: 10.1109/GENSIPS.2013.6735913.

BaySyn: Bayesian Evidence Synthesis for Multi-system Multiomic Integration.

Bhattacharyya R, Henderson N, Baladandayuthapani V Pac Symp Biocomput. 2022; 28:275-286.

PMID: 36540984 PMC: 10652956.

Bayesian hierarchical quantile regression with application to characterizing the immune architecture of lung cancer.

Das P, Peterson C, Ni Y, Reuben A, Zhang J, Zhang J Biometrics. 2022; 79(3):2474-2488.

PMID: 36239535 PMC: 10102253. DOI: 10.1111/biom.13774.

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