Abstract
BackgroundThis paper introduces a new constrained model and the corresponding algorithm, called unsupervised Bayesian linear unmixing (uBLU), to identify biological signatures from high dimensional assays like gene expression microarrays. The basis for uBLU is a Bayesian model for the data samples which are represented as an additive mixture of random positive gene signatures, called factors, with random positive mixing coefficients, called factor scores, that specify the relative contribution of each signature to a specific sample. The particularity of the proposed method is that uBLU constrains the factor loadings to be non-negative and the factor scores to be probability distributions over the factors. Furthermore, it also provides estimates of the number of factors. A Gibbs sampling strategy is adopted here to generate random samples according to the posterior distribution of the factors, factor scores, and number of factors. These samples are then used to estimate all the unknown parameters.ResultsFirstly, the proposed uBLU method is applied to several simulated datasets with known ground truth and compared with previous factor decomposition methods, such as principal component analysis (PCA), non negative matrix factorization (NMF), Bayesian factor regression modeling (BFRM), and the gradient-based algorithm for general matrix factorization (GB-GMF). Secondly, we illustrate the application of uBLU on a real time-evolving gene expression dataset from a recent viral challenge study in which individuals have been inoculated with influenza A/H3N2/Wisconsin. We show that the uBLU method significantly outperforms the other methods on the simulated and real data sets considered here.ConclusionsThe results obtained on synthetic and real data illustrate the accuracy of the proposed uBLU method when compared to other factor decomposition methods from the literature (PCA, NMF, BFRM, and GB-GMF). The uBLU method identifies an inflammatory component closely associated with clinical symptom scores collected during the study. Using a constrained model allows recovery of all the inflammatory genes in a single factor.
Highlights
This paper introduces a new constrained model and the corresponding algorithm, called unsupervised Bayesian linear unmixing, to identify biological signatures from high dimensional assays like gene expression microarrays
This paper presents a new Bayesian factor analysis method called unsupervised Bayesian linear unmixing, that estimates the number of factors and incorporates non-negativity constraints on the factors and factor scores, as well as a sum-to-one constraint for the factor scores
In this paper we provide comparative studies that establish quantitative performance advantages of the proposed constrained model and its corresponding unsupervised Bayesian linear unmixing (uBLU) algorithm with respect to principal component analysis (PCA), negative matrix factorization (NMF), Bayesian factor regression modeling (BFRM) and gradient-based algorithm for general matrix factorization (GB-GMF) for timevarying gene expression analysis, using synthetic data with known ground truth
Summary
This paper introduces a new constrained model and the corresponding algorithm, called unsupervised Bayesian linear unmixing (uBLU), to identify biological signatures from high dimensional assays like gene expression microarrays. These samples are used to estimate all the unknown parameters Factor analysis methods such as principal component analysis (PCA) have been widely studied and can be used for discovering the patterns of differential expression in time course and/or multiple treatment biological experiments using gene or protein microarray samples. These methods aim at finding a decomposition of the observation matrix Y ∈ RG×N whose rows (respectively columns) are indexed by gene index (respectively sample index). Some recent Bayesian factor analysis methods are totally unsupervised in the sense that the number of factors is directly estimated from the data [1,2,3]
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