Abstract
BackgroundChromatin immunoprecipitation followed by high throughput sequencing (ChIP-seq), initially introduced more than a decade ago, is widely used by the scientific community to detect protein/DNA binding and histone modifications across the genome. Every experiment is prone to noise and bias, and ChIP-seq experiments are no exception. To alleviate bias, the incorporation of control datasets in ChIP-seq analysis is an essential step. The controls are used to account for the background signal, while the remainder of the ChIP-seq signal captures true binding or histone modification. However, a recurrent issue is different types of bias in different ChIP-seq experiments. Depending on which controls are used, different aspects of ChIP-seq bias are better or worse accounted for, and peak calling can produce different results for the same ChIP-seq experiment. Consequently, generating “smart” controls, which model the non-signal effect for a specific ChIP-seq experiment, could enhance contrast and increase the reliability and reproducibility of the results.ResultWe propose a peak calling algorithm, Weighted Analysis of ChIP-seq (WACS), which is an extension of the well-known peak caller MACS2. There are two main steps in WACS: First, weights are estimated for each control using non-negative least squares regression. The goal is to customize controls to model the noise distribution for each ChIP-seq experiment. This is then followed by peak calling. We demonstrate that WACS significantly outperforms MACS2 and AIControl, another recent algorithm for generating smart controls, in the detection of enriched regions along the genome, in terms of motif enrichment and reproducibility analyses.ConclusionsThis ultimately improves our understanding of ChIP-seq controls and their biases, and shows that WACS results in a better approximation of the noise distribution in controls.
Highlights
Chromatin immunoprecipitation followed by high throughput sequencing (ChIP-seq), initially introduced more than a decade ago, is widely used by the scientific community to detect protein/DNA binding and histone modifications across the genome
This improves our understanding of ChIP-seq controls and their biases, and shows that Weighted Analysis of ChIP-seq (WACS) results in a better approximation of the noise distribution in controls
We introduce a peak calling algorithm, Weighted Analysis of ChIP-Seq (WACS), which utilizes “smart” controls to model the non-signal effect for a specific ChIP-seq experiment
Summary
Chromatin immunoprecipitation followed by high throughput sequencing (ChIP-seq), initially introduced more than a decade ago, is widely used by the scientific community to detect protein/DNA binding and histone modifications across the genome. One widely used technology is chromatin immunoprecipitation followed by generation sequencing (ChIP-seq). It allows the genome-wide investigation of the structural and functional elements encoded in a genomic sequence, such as transcriptional regulatory. The main goal of a ChIP-seq experiment is the detection of protein-DNA binding sites and histone modifications genome-wide in various cell lines and tissues. Biased or noisy datasets (with a high number of false negative or false positive peaks) negatively impact downstream biological and computational analyses [8] Accounting for both noise and bias is important.
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