A wavelet-based method to exploit epigenomic language in the regulatory region

TY - JOUR

T1 - A wavelet-based method to exploit epigenomic language in the regulatory region

AU - Nguyen, Nha

AU - Vo, An

AU - Won, Kyoung-Jae

PY - 2014/4/1

Y1 - 2014/4/1

N2 - Motivation: Epigenetic landscapes in the regulatory regions reflect binding condition of transcription factors and their co-factors. Identifying epigenetic condition and its variation is important in understanding condition-specific gene regulation. Computational approaches to explore complex multi-dimensional landscapes are needed.Results: To study epigenomic condition for gene regulation, we developed a method, AWNFR, to classify epigenomic landscapes based on the detected epigenomic landscapes. Assuming mixture of Gaussians for a nucleosome, the proposed method captures the shape of histone modification and identifies potential regulatory regions in the wavelet domain. For accuracy estimation as well as enhanced computational speed, we developed a novel algorithm based on down-sampling operation and footprint in wavelet. We showed the algorithmic advantages of AWNFR using the simulated data. AWNFR identified regulatory regions more effectively and accurately than the previous approaches with the epigenome data in mouse embryonic stem cells and human lung fibroblast cells (IMR90). Based on the detected epigenomic landscapes, AWNFR classified epigenomic status and studied epigenomic codes. We studied co-occurring histone marks and showed that AWNFR captures the epigenomic variation across time.

AB - Motivation: Epigenetic landscapes in the regulatory regions reflect binding condition of transcription factors and their co-factors. Identifying epigenetic condition and its variation is important in understanding condition-specific gene regulation. Computational approaches to explore complex multi-dimensional landscapes are needed.Results: To study epigenomic condition for gene regulation, we developed a method, AWNFR, to classify epigenomic landscapes based on the detected epigenomic landscapes. Assuming mixture of Gaussians for a nucleosome, the proposed method captures the shape of histone modification and identifies potential regulatory regions in the wavelet domain. For accuracy estimation as well as enhanced computational speed, we developed a novel algorithm based on down-sampling operation and footprint in wavelet. We showed the algorithmic advantages of AWNFR using the simulated data. AWNFR identified regulatory regions more effectively and accurately than the previous approaches with the epigenome data in mouse embryonic stem cells and human lung fibroblast cells (IMR90). Based on the detected epigenomic landscapes, AWNFR classified epigenomic status and studied epigenomic codes. We studied co-occurring histone marks and showed that AWNFR captures the epigenomic variation across time.

KW - Algorithms

KW - Animals

KW - Cell Line

KW - Cluster Analysis

KW - Embryonic Stem Cells/metabolism

KW - Epigenomics/methods

KW - Fibroblasts/metabolism

KW - Gene Expression Regulation

KW - Histones/chemistry

KW - Humans

KW - Lung/metabolism

KW - Mice

KW - Software Design

U2 - 10.1093/bioinformatics/btt467

DO - 10.1093/bioinformatics/btt467

M3 - Journal article

C2 - 24096080

SN - 1367-4811

VL - 30

SP - 908

EP - 914

JO - Bioinformatics (Online)

JF - Bioinformatics (Online)

IS - 7

ER -