Denoising genome-wide histone ChIP-seq with convolutional neural networks

Motivation Chromatin immunoprecipitation sequencing (ChIP-seq) experiments are commonly used to obtain genome-wide profiles of histone modifications associated with different types of functional genomic elements. However, the quality of histone ChIP-seq data is affected by a myriad of experimental parameters such as the amount of input DNA, antibody specificity, ChIP enrichment, and sequencing depth. Making accurate inferences from chromatin profiling experiments that involve diverse experimental parameters is challenging. Results We introduce a convolutional denoising algorithm, Coda, that uses convolutional neural networks to learn a mapping from suboptimal to high-quality histone ChIP-seq data. This overcomes various sources of noise and variability, substantially enhancing and recovering signal when applied to low-quality chromatin profiling datasets across individuals, cell types, and species. Our method has the potential to improve data quality at reduced costs. More broadly, this approach – using a high-dimensional discriminative model to encode a generative noise process – is generally applicable to other biological domains where it is easy to generate noisy data but difficult to analytically characterize the noise or underlying data distribution. Availability https://github.com/kundajelab/coda Contact akundaje@stanford.edu

• Publication year

  2016

• Venue

  bioRxiv

• Publication date

  2016-05-07

• Fields of study

  Biology, Medicine, Computer Science

• Identifiers
  DOI 10.1093/bioinformatics/btx243PMID 28881977PMCID 5870713
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• An Integrated Encyclopedia of DNA Elements in the Human Genome

  2016cited by this paper
• DeepCpG: accurate prediction of single-cell DNA methylation states using deep learning

  2016cited by this paper
• Deep learning for computational biology

  2016cited by this paper
• Basset: learning the regulatory code of the accessible genome with deep convolutional neural networks

  2015cited by this paper
• Predicting the sequence specificities of DNA- and RNA-binding proteins by deep learning

  2015cited by this paper
• Integrative analysis of 111 reference human epigenomes

  2015cited by this paper
• Deep Speech 2 : End-to-End Speech Recognition in English and Mandarin

  2015cited by this paper
• An ultra-low-input native ChIP-seq protocol for genome-wide profiling of rare cell populations

  2015influential reference
• Predicting effects of noncoding variants with deep learning–based sequence model

  2015cited by this paper
• Conserved epigenomic signals in mice and humans reveal immune basis of Alzheimer’s disease

  2015cited by this paper
• Large-scale epigenome imputation improves data quality and disease variant enrichment

  2015influential reference
• A deep learning approach to structured signal recovery

  2015cited by this paper
• A microfluidic device for epigenomic profiling using 100 cells

  2015cited by this paper
• Dropout: a simple way to prevent neural networks from overfitting

  2014cited by this paper
• Impact of sequencing depth in ChIP-seq experiments

  2014cited by this paper
• Sequence to Sequence Learning with Neural Networks

  2014cited by this paper
• Transcription factor EBF1 is essential for the maintenance of B cell identity and prevention of alternative fates in committed cells

  2013cited by this paper
• 骨髄異形成症候群のgenome-wide analysis

  2013cited by this paper
• Transposition of native chromatin for fast and sensitive epigenomic profiling of open chromatin, DNA-binding proteins and nucleosome position

  2013cited by this paper
• Extensive Variation in Chromatin States Across Humans

  2013cited by this paper
• Using the Wash U Epigenome Browser to Examine Genome‐Wide Sequencing Data

  2012cited by this paper
• Identifying ChIP-seq enrichment using MACS

  2012cited by this paper
• ChromHMM: automating chromatin-state discovery and characterization

  2012cited by this paper
• Unsupervised pattern discovery in human chromatin structure through genomic segmentation

  2012cited by this paper
• ChIP-seq guidelines and practices of the ENCODE and modENCODE consortia

  2012cited by this paper
• Image Denoising and Inpainting with Deep Neural Networks

  2012cited by this paper
• Randomized smoothing for (parallel) stochastic optimization

  2012cited by this paper
• Recurrent Neural Networks for Noise Reduction in Robust ASR

  2012cited by this paper
• An Integrated Encyclopedia of DNA Elements in the Human Genome

  2012cited by this paper
• ImageNet classification with deep convolutional neural networks

  2012cited by this paper
• Noisy matrix decomposition via convex relaxation: Optimal rates in high dimensions

  2011cited by this paper
• Differential expression analysis for sequence count data

  2011cited by this paper
• Adaptive Subgradient Methods for Online Learning and Stochastic Optimization

  2011cited by this paper
• Genome-wide analysis of the relationships between DNaseI HS, histone modifications and gene expression reveals distinct modes of chromatin domains

  2011cited by this paper
• Differential expression analysis for sequence count data

  2010cited by this paper
• Natural Image Denoising with Convolutional Networks

  2008influential reference
• Genome-scale ChIP-chip analysis using 10,000 human cells.

  2007cited by this paper
• The relationship between Precision-Recall and ROC curves

  2006cited by this paper
• A bivalent chromatin structure marks key developmental genes in embryonic stem cells.

  2006cited by this paper
• Genome-wide mapping of DNase hypersensitive sites using massively parallel signature sequencing (MPSS).

  2005cited by this paper
• Runx1 expression marks long-term repopulating hematopoietic stem cells in the midgestation mouse embryo.

  2002cited by this paper
• Commitment to the B-lymphoid lineage depends on the transcription factor Pax5

  1999cited by this paper
• Commitment to the B-lymphoid lineage depends on the transcription factor Pax5

  1999cited by this paper

• SPSID: A single-parameter shrinkage inverse-diffusion for denoising gene-regulatory networks

  2026cites this paper
• Chrom-Sig: de-noising 1-dimensional genomic profiles by signal processing methods

  2025cites this paper
• Chrom-Sig: de-noising 1D genomic profiles by signal processing methods

  2025cites this paper
• PATTY corrects open-chromatin bias for improved bulk and single-cell CUT&Tag profiling

  2025cites this paper
• PATTY corrects open chromatin bias for improved bulk and single-cell CUT&Tag profiling

  2025cites this paper
• Discriminative histone imputation using chromatin accessibility

  2024cites this paper
• Summary of ChIP-Seq Methods and Description of an Optimized ChIP-Seq Protocol.

  2024cites this paper
• Exploring the Potential of Deep Learning in Healthcare: A perspective

  2024cites this paper
• Deep Learning-based Artificial Intelligence for Assisting Diagnosis, Assessment and Treatment in Soft Tissue Sarcomas

  2024cites this paper
• Interpretable deep learning reveals the sequence rules of Hippo signaling

  2024cites this paper
• Advances and applications of machine learning and deep learning in environmental ecology and health.

  2023cites this paper
• Deep Learning Application Pros And Cons Over Algorithm

  2022cites this paper
• Machine Learning and Deep Learning Applications in Multiple Myeloma Diagnosis, Prognosis, and Treatment Selection

  2022cites this paper
• Getting Personal with Epigenetics: Towards Machine-Learning-Assisted Precision Epigenomics

  2022cites this paper
• A hybrid deep neural network for robust single-cell genome-wide DNA methylation detection

  2021cites this paper
• Anomaly detection in genomic catalogues using unsupervised multi-view autoencoders

  2021cites this paper
• OLOGRAM-MODL: mining enriched n-wise combinations of genomic features with Monte Carlo and dictionary learning

  2021cites this paper
• Rapid, Reference-Free human genotype imputation with denoising autoencoders

  2021influential citation
• Evidence for the role of transcription factors in the co-transcriptional regulation of intron retention

  2021cites this paper
• Convolutional Motif Kernel Networks

  2021cites this paper
• AI applications in functional genomics

  2021cites this paper
• Applied machine learning in cancer research: A systematic review for patient diagnosis, classification and prognosis

  2021cites this paper
• Rescuing biologically relevant consensus regions across replicated samples

  2021cites this paper
• Deep learning-based enhancement of epigenomics data with AtacWorks

  2021cites this paper
• The Road Not Taken with Pyrrole-Imidazole Polyamides: Off-Target Effects and Genomic Binding

  2020cites this paper
• A self-attention model for inferring cooperativity between regulatory features

  2020cites this paper
• A novel deep mining model for effective knowledge discovery from omics data

  2020cites this paper
• Opportunities and obstacles for deep learning in biology and medicine [update in progress]

  2020cites this paper
• Methods for ChIP-seq analysis: A practical workflow and advanced applications.

  2020cites this paper
• CNN-Peaks: ChIP-Seq peak detection pipeline using convolutional neural networks that imitate human visual inspection

  2020cites this paper
• Tackling COVID-19 through Responsible AI Innovation: Five Steps in the Right Direction

  2020cites this paper
• A deep learning framework for characterization of genotype data

  2020cites this paper
• Machine learning and deep learning for the advancement of epigenomics

  2020cites this paper
• State of the Art and Future Direction for the Analysis of Cell-Free Circulating DNA

  2019cites this paper
• The Role of Deep Learning in Improving Healthcare

  2019cites this paper
• Deep Learning for Healthcare Biometrics

  2019cites this paper
• AtacWorks: A deep convolutional neural network toolkit for epigenomics

  2019cites this paper
• Prediction of sgRNA on-target activity in bacteria by deep learning

  2019cites this paper
• A guide to deep learning in healthcare

  2019cites this paper
• APPLES: Fast Distance-Based Phylogenetic Placement

  2019cites this paper
• Evaluating the informativeness of deep learning annotations for human complex diseases

  2019cites this paper
• Single-cell ATAC-Seq in human pancreatic islets and deep learning upscaling of rare cells reveals cell-specific type 2 diabetes regulatory signatures

  2019cites this paper
• Temporal FiLM: Capturing Long-Range Sequence Dependencies with Feature-Wise Modulations

  2019cites this paper
• DeepHealth: Deep Learning for Health Informatics

  2019cites this paper
• Fully interpretable deep learning model of transcriptional control

  2019cites this paper
• DeepHealth: Review and challenges of artificial intelligence in health informatics

  2019cites this paper
• An Inception Convolutional Autoencoder Model for Chinese Healthcare Question Clustering

  2019cites this paper
• Denoising of Aligned Genomic Data

  2019cites this paper
• Deep learning: new computational modelling techniques for genomics

  2019cites this paper
• Deep learning for healthcare: review, opportunities and challenges

  2018cites this paper
• Algorithmic Bias

  2018cites this paper
• Enhancing Hi-C data resolution with deep convolutional neural network HiCPlus

  2018cites this paper
• Artificial intelligence used in genome analysis studies

  2018cites this paper
• Computational Modelling of Human Transcriptional Regulation by an Information Theory-based Approach

  2018cites this paper
• Time Series Super Resolution withTemporal Adaptive Batch Normalization

  2018cites this paper
• PlantPAN3.0: a new and updated resource for reconstructing transcriptional regulatory networks from ChIP-seq experiments in plants

  2018cites this paper
• Deep learning in omics: a survey and guideline

  2018cites this paper
• Biological Sequence Modeling with Convolutional Kernel Networks

  2017cites this paper
• Computational biology: deep learning

  2017cites this paper
• Opportunities and obstacles for deep learning in biology and medicine

  2017cites this paper
• Artificial intelligence (AI) systems for interpreting complex medical datasets

  2017cites this paper
• Reconstruction of high read-depth signals from low-depth whole genome sequencing data using deep learning

  2017cites this paper
• Box 1 . Common neural network models Neuron

  2017cites this paper
• Deep learning for computational biology

  2016cites this paper
• TISSUE-SPECIFIC FUNCTIONAL EFFECT PREDICTION OF GENETIC VARIATION AND APPLICATIONS TO COMPLEX TRAIT GENETICS

  2016cites this paper
• FUN-LDA: A LATENT DIRICHLET ALLOCATION MODEL FOR PREDICTING TISSUE-SPECIFIC FUNCTIONAL EFFECTS OF NONCODING VARIATION

  2016cites this paper