Your search keyword '"Love MI"' showing total 4 results

1. DeCompress: tissue compartment deconvolution of targeted mRNA expression panels using compressed sensing.

Author

Bhattacharya A, Hamilton AM, Troester MA, and Love MI

Subjects

Algorithms, Animals, Breast Neoplasms genetics, Breast Neoplasms metabolism, Databases, Genetic, Female, Genomics, Humans, Lung Neoplasms genetics, Lung Neoplasms metabolism, Male, Neoplasms metabolism, Prostatic Neoplasms genetics, Prostatic Neoplasms metabolism, Quantitative Trait Loci, RNA, Messenger genetics, RNA-Seq, Receptors, CCR3 genetics, Receptors, CCR3 metabolism, Single-Cell Analysis, Benchmarking methods, Computational Biology methods, Gene Expression Profiling methods, Neoplasms genetics, RNA, Messenger metabolism

Abstract

Targeted mRNA expression panels, measuring up to 800 genes, are used in academic and clinical settings due to low cost and high sensitivity for archived samples. Most samples assayed on targeted panels originate from bulk tissue comprised of many cell types, and cell-type heterogeneity confounds biological signals. Reference-free methods are used when cell-type-specific expression references are unavailable, but limited feature spaces render implementation challenging in targeted panels. Here, we present DeCompress, a semi-reference-free deconvolution method for targeted panels. DeCompress leverages a reference RNA-seq or microarray dataset from similar tissue to expand the feature space of targeted panels using compressed sensing. Ensemble reference-free deconvolution is performed on this artificially expanded dataset to estimate cell-type proportions and gene signatures. In simulated mixtures, four public cell line mixtures, and a targeted panel (1199 samples; 406 genes) from the Carolina Breast Cancer Study, DeCompress recapitulates cell-type proportions with less error than reference-free methods and finds biologically relevant compartments. We integrate compartment estimates into cis-eQTL mapping in breast cancer, identifying a tumor-specific cis-eQTL for CCR3 (C-C Motif Chemokine Receptor 3) at a risk locus. DeCompress improves upon reference-free methods without requiring expression profiles from pure cell populations, with applications in genomic analyses and clinical settings., (© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2021

2. Nonparametric expression analysis using inferential replicate counts.

Author

Zhu A, Srivastava A, Ibrahim JG, Patro R, and Love MI

Subjects

Algorithms, Cell Lineage genetics, Gene Expression genetics, Humans, RNA genetics, Software, Gene Expression Profiling methods, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, RNA methods, Single-Cell Analysis methods

Abstract

A primary challenge in the analysis of RNA-seq data is to identify differentially expressed genes or transcripts while controlling for technical biases. Ideally, a statistical testing procedure should incorporate the inherent uncertainty of the abundance estimates arising from the quantification step. Most popular methods for RNA-seq differential expression analysis fit a parametric model to the counts for each gene or transcript, and a subset of methods can incorporate uncertainty. Previous work has shown that nonparametric models for RNA-seq differential expression may have better control of the false discovery rate, and adapt well to new data types without requiring reformulation of a parametric model. Existing nonparametric models do not take into account inferential uncertainty, leading to an inflated false discovery rate, in particular at the transcript level. We propose a nonparametric model for differential expression analysis using inferential replicate counts, extending the existing SAMseq method to account for inferential uncertainty. We compare our method, Swish, with popular differential expression analysis methods. Swish has improved control of the false discovery rate, in particular for transcripts with high inferential uncertainty. We apply Swish to a single-cell RNA-seq dataset, assessing differential expression between sub-populations of cells, and compare its performance to the Wilcoxon test., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2019

3. Role of the chromatin landscape and sequence in determining cell type-specific genomic glucocorticoid receptor binding and gene regulation.

Author

Love MI, Huska MR, Jurk M, Schöpflin R, Starick SR, Schwahn K, Cooper SB, Yamamoto KR, Thomas-Chollier M, Vingron M, and Meijsing SH

Subjects

Animals, Base Sequence, Bayes Theorem, Binding Sites, Cell Line, Chromatin Immunoprecipitation, Computational Biology methods, Genome-Wide Association Study, Genomics, High-Throughput Nucleotide Sequencing, Mice, Nucleotide Motifs, Organ Specificity genetics, Promoter Regions, Genetic, Protein Binding, p300-CBP Transcription Factors genetics, p300-CBP Transcription Factors metabolism, Chromatin genetics, Chromatin metabolism, Chromatin Assembly and Disassembly, Gene Expression Regulation, Receptors, Glucocorticoid metabolism

Abstract

The genomic loci bound by the glucocorticoid receptor (GR), a hormone-activated transcription factor, show little overlap between cell types. To study the role of chromatin and sequence in specifying where GR binds, we used Bayesian modeling within the universe of accessible chromatin. Taken together, our results uncovered that although GR preferentially binds accessible chromatin, its binding is biased against accessible chromatin located at promoter regions. This bias can only be explained partially by the presence of fewer GR recognition sequences, arguing for the existence of additional mechanisms that interfere with GR binding at promoters. Therefore, we tested the role of H3K9ac, the chromatin feature with the strongest negative association with GR binding, but found that this correlation does not reflect a causative link. Finally, we find a higher percentage of promoter-proximal GR binding for genes regulated by GR across cell types than for cell type-specific target genes. Given that GR almost exclusively binds accessible chromatin, we propose that cell type-specific regulation by GR preferentially occurs via distal enhancers, whose chromatin accessibility is typically cell type-specific, whereas ubiquitous target gene regulation is more likely to result from binding to promoter regions, which are often accessible regardless of cell type examined., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2017

4. Flexible expressed region analysis for RNA-seq with derfinder.

Author

Collado-Torres L, Nellore A, Frazee AC, Wilks C, Love MI, Langmead B, Irizarry RA, Leek JT, and Jaffe AE

Subjects

Gene Expression Regulation, Genomics methods, High-Throughput Nucleotide Sequencing, Molecular Sequence Annotation, Organ Specificity genetics, Transcriptome, Web Browser, Gene Expression Profiling methods, Software

Abstract

Differential expression analysis of RNA sequencing (RNA-seq) data typically relies on reconstructing transcripts or counting reads that overlap known gene structures. We previously introduced an intermediate statistical approach called differentially expressed region (DER) finder that seeks to identify contiguous regions of the genome showing differential expression signal at single base resolution without relying on existing annotation or potentially inaccurate transcript assembly.We present the derfinder software that improves our annotation-agnostic approach to RNA-seq analysis by: (i) implementing a computationally efficient bump-hunting approach to identify DERs that permits genome-scale analyses in a large number of samples, (ii) introducing a flexible statistical modeling framework, including multi-group and time-course analyses and (iii) introducing a new set of data visualizations for expressed region analysis. We apply this approach to public RNA-seq data from the Genotype-Tissue Expression (GTEx) project and BrainSpan project to show that derfinder permits the analysis of hundreds of samples at base resolution in R, identifies expression outside of known gene boundaries and can be used to visualize expressed regions at base-resolution. In simulations, our base resolution approaches enable discovery in the presence of incomplete annotation and is nearly as powerful as feature-level methods when the annotation is complete.derfinder analysis using expressed region-level and single base-level approaches provides a compromise between full transcript reconstruction and feature-level analysis. The package is available from Bioconductor at www.bioconductor.org/packages/derfinder., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2017