Detecting differential gene expression with a semiparametric hierarchical mixture method

Newton, Michael A.; Noueiry, Amine; Sarkar, Deepayan; Ahlquist, Paul

doi:10.1093/biostatistics/5.2.155

Cited by 543 publications

(532 citation statements)

References 28 publications

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“…As recently demonstrated at a gene-specific level (Lo and Gottardo, 2007), an accurate modeling of residual dispersion patterns allows for a more realistic fit of gene expression data, reducing the rate of false positives when differential gene expression is characterized in terms of mathematical expectations or their differences (Kendziorski et al, 2003;Newton et al, 2004;Lo and Gottardo, 2007). Moreover, the analysis of heterogeneous residual dispersion patterns opens up promising research possibilities within the gene expression framework, where heterogeneity in residual variability could be viewed as an alternative and plausible characterization of differential expression patterns.…”

Section: Resultsmentioning

confidence: 99%

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Variability-specific differential gene expression across reproductive stages in sows

Casellas

Martínez-Giner²,

Pena³

et al. 2013

Animal

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Differential gene expression analyses typically focus on departures across mathematical expectations (i.e. mean) from two or more groups of microarrays, without considering alternative patterns of departure. Nevertheless, recent studies in humans and great apes have suggested that differential gene expression could also be characterized in terms of heterogeneous dispersion patterns. This must be viewed as a very interesting genetic phenomenon clearly linked to the regulation mechanisms of gene transcription. Unfortunately, we completely lack information about the incidence and relevance of dispersion-specific differential gene expression in livestock species, although a specific Bayes factor (BF) for testing this kind of differential gene expression (i.e. within-probe heteroskedasticity) has been recently developed. Within this context, our main objective was to characterize the incidence of dispersion-specific differential gene expression in pigs and, if possible, providing the first evidence of this phenomenon in a livestock species. We evaluated dispersion-specific differential gene expression on ovary, uterus and hypophysis samples from 22 F2 Iberian × Meishan sows, where a total of 15 252 probes were interrogated. For each tissue, heteroskedasticity of probe-specific residual variances was evaluated by three pairwise comparisons involving three physiological stages, that is, heat, 15 days of pregnancy and 45 days of pregnancy. Between 2.9% and 37.4% of the analyzed probes provided statistical evidence of within-tissue across-physiological stages dispersion-specific differential gene expression (BF >1), and between 0.1% and 3.0% of them reported decisive evidence (BF >100). It is important to highlight that <8% of the heteroskedastic probes were also linked to differential gene expression in terms of departures among the probe-specific mathematical expectation of each physiological stage. This discarded the disturbance of scale effects in a high percentage of probes and suggested that probe-specific heteroskedasticity must be viewed as an independent phenomenon within the context of differential gene expression. As a whole, our results report a remarkable incidence of dispersion-specific differential gene expression across the whole genome of the pig, establishing a very interesting starting point for further studies focused on deciphering the genetic mechanisms underlying heteroskedasticity.

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Section: Resultsmentioning

confidence: 99%

“…Assuming null residual (co)variances (Kendziorski et al, 2003;Newton et al, 2004;, heteroskedasticity between physiological stages was analyzed by stating…”

Section: Methodsmentioning

confidence: 99%

Variability-specific differential gene expression across reproductive stages in sows

Casellas

Martínez-Giner²,

Pena³

et al. 2013

Animal

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“…Theoretical connection among various ranking methods, including those based on hierarchical Bayesian models (Newton et al, 2004;Noma et al, 2010), and comparison of their performances are important research areas. Recently, Storey (2007) developed the optimal discovery procedure, an optimality criterion for ordering tests in multiple testing, which can be formulated as a multiple test extension of the Neyman-Pearson optimality for testing individual genes.…”

Section: Discussionmentioning

confidence: 99%

“…Optimality of gene ranking is, hence, an important research area in statistical analysis of microarray studies. Recently, Newton et al (2004) and McLachlan et al (2006) have shown a ranking based on the local false discovery rate (local FDR; Efron et al, 2001), which represents the posterior probability of non-differential expression of each gene, is optimal for selecting differentially expressed genes from the viewpoint of the Bayesian decision theory. More recently, Noma et al (2010) developed three empirical Bayes methods for gene ranking on the basis of differential expression, using hierarchical mixture models.…”

Section: Introductionmentioning

confidence: 99%

Optimality of Gene Ranking Based on Univariate P-values for Detecting Differentially Expressed Genes

Noma

Matsui

2010

Jpn J Biomet

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“…Using this scale-free, univariate probability score, one can call peptide assignments correct if posterior probability is above a certain threshold. This posterior probability is directly related to local false discovery rate (fdr) discussed in Efron et al 12 and Newton et al, 13 and thus specifying the minimum probability threshold automatically controls global FDR to a desired degree.…”

Section: Introductionmentioning

confidence: 99%

Statistical Validation of Peptide Identifications in Large-Scale Proteomics Using the Target-Decoy Database Search Strategy and Flexible Mixture Modeling

2007

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Reliable statistical validation of peptide and protein identifications is a top priority in large-scale mass spectrometry based proteomics. PeptideProphet is one of the computational tools commonly used for assessing the statistical confidence in peptide assignments to tandem mass spectra obtained using database search programs such as SEQUEST, MASCOT, or X! TANDEM. We present two flexible methods, the variable component mixture model and the semiparametric mixture model, that remove the restrictive parametric assumptions in the mixture modeling approach of PeptideProphet. Using a control protein mixture data set generated on an linear ion trap Fourier transform (LTQ-FT) mass spectrometer, we demonstrate that both methods improve parametric models in terms of the accuracy of probability estimates and the power to detect correct identifications controlling the false discovery rate to the same degree. The statistical approaches presented here require that the data set contain a sufficient number of decoy (known to be incorrect) peptide identifications, which can be obtained using the target-decoy database search strategy.

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Detecting differential gene expression with a semiparametric hierarchical mixture method

Cited by 543 publications

References 28 publications

Variability-specific differential gene expression across reproductive stages in sows

Variability-specific differential gene expression across reproductive stages in sows

Optimality of Gene Ranking Based on Univariate P-values for Detecting Differentially Expressed Genes

Statistical Validation of Peptide Identifications in Large-Scale Proteomics Using the Target-Decoy Database Search Strategy and Flexible Mixture Modeling

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