English

Statistical models for RNA-seq data derived from a two-condition 48-replicate experiment

Genomics 2015-07-28 v1

Abstract

High-throughput RNA sequencing (RNA-seq) is now the standard method to determine differential gene expression. Identifying differentially expressed genes crucially depends on estimates of read count variability. These estimates are typically based on statistical models such as the negative binomial distribution, which is employed by the tools edgeR, DESeq and cuffdiff. Until now, the validity of these models has usually been tested on either low-replicate RNA-seq data or simulations. A 48-replicate RNA-seq experiment in yeast was performed and data tested against theoretical models. The observed gene read counts were consistent with both log-normal and negative binomial distributions, while the mean-variance relation followed the line of constant dispersion parameter of ~0.01. The high-replicate data also allowed for strict quality control and screening of bad replicates, which can drastically affect the gene read-count distribution. RNA-seq data have been submitted to ENA archive with project ID PRJEB5348.

Keywords

Cite

@article{arxiv.1505.00588,
  title  = {Statistical models for RNA-seq data derived from a two-condition 48-replicate experiment},
  author = {Marek Gierliński and Christian Cole and Pietà Schofield and Nicholas J. Schurch and Alexander Sherstnev and Vijender Singh and Nicola Wrobel and Karim Gharbi and Gordon Simpson and Tom Owen-Hughes and Mark Blaxter and Geoffrey J. Barton},
  journal= {arXiv preprint arXiv:1505.00588},
  year   = {2015}
}

Comments

15 pages 6 figures

R2 v1 2026-06-22T09:27:33.692Z