Literature DB >> 21373371

Network-based genomic discovery: application and comparison of Markov random field models.

Peng Wei1, Wei Pan.   

Abstract

As biological knowledge accumulates rapidly, gene networks encoding genome-wide gene-gene interactions have been constructed. As an improvement over the standard mixture model that tests all the genes iid a priori, Wei and Li (2007) and Wei and Pan (2008) proposed modeling a gene network as a Discrete- or Gaussian-Markov random field (DMRF or GMRF) respectively in a mixture model to analyze genomic data. However, how these methods compare in practical applications in not well understood and this is the aim here. We also propose two novel constraints in prior specifications for the GMRF model and a fully Bayesian approach to the DMRF model. We assess the accuracy of estimating the False Discovery Rate (FDR) by posterior probabilities in the context of MRF models. Applications to a ChIP-chip data set and simulated data show that the modified GMRF models has superior performance as compared with other models, while both MRF-based mixture models, with reasonable robustness to misspecified gene networks, outperform the standard mixture model.

Entities:  

Year:  2010        PMID: 21373371      PMCID: PMC3046412          DOI: 10.1111/j.1467-9876.2009.00686.x

Source DB:  PubMed          Journal:  J R Stat Soc Ser C Appl Stat        ISSN: 0035-9254            Impact factor:   1.864


  19 in total

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  11 in total

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2.  Variable selection for discriminant analysis with Markov random field priors for the analysis of microarray data.

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3.  A hidden Markov random field-based Bayesian method for the detection of long-range chromosomal interactions in Hi-C data.

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4.  Detecting subnetwork-level dynamic correlations.

Authors:  Yan Yan; Shangzhao Qiu; Zhuxuan Jin; Sihong Gong; Yun Bai; Jianwei Lu; Tianwei Yu
Journal:  Bioinformatics       Date:  2016-09-25       Impact factor: 6.937

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8.  Incorporating biological prior knowledge for Bayesian learning via maximal knowledge-driven information priors.

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9.  An integrative framework for Bayesian variable selection with informative priors for identifying genes and pathways.

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10.  Incorporating interaction networks into the determination of functionally related hit genes in genomic experiments with Markov random fields.

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