Genome-scale Mapping of DNase I Sensitivity in Vivo Using Tiling DNA Microarrays

Overview

Journal Nat Methods

Specialties Biomedical Engineering
Pathology

Date 2006 Jun 23

PMID 16791208

Citations 213

Authors

Peter J Sabo

Michael S Kuehn

Robert Thurman

Brett E Johnson

Ericka M Johnson

Hua Cao

Man Yu

Elizabeth Rosenzweig

Jeff Goldy

Andrew Haydock

Molly Weaver

Anthony Shafer

Kristin Lee

Fidencio Neri

Richard Humbert

Michael A Singer

Todd A Richmond

Michael O Dorschner

Michael McArthur

Michael Hawrylycz

Roland D Green

Patrick A Navas

William S Noble

John A Stamatoyannopoulos

Affiliations

Soon will be listed here.

Abstract

Localized accessibility of critical DNA sequences to the regulatory machinery is a key requirement for regulation of human genes. Here we describe a high-resolution, genome-scale approach for quantifying chromatin accessibility by measuring DNase I sensitivity as a continuous function of genome position using tiling DNA microarrays (DNase-array). We demonstrate this approach across 1% ( approximately 30 Mb) of the human genome, wherein we localized 2,690 classical DNase I hypersensitive sites with high sensitivity and specificity, and also mapped larger-scale patterns of chromatin architecture. DNase I hypersensitive sites exhibit marked aggregation around transcriptional start sites (TSSs), though the majority mark nonpromoter functional elements. We also developed a computational approach for visualizing higher-order features of chromatin structure. This revealed that human chromatin organization is dominated by large (100-500 kb) 'superclusters' of DNase I hypersensitive sites, which encompass both gene-rich and gene-poor regions. DNase-array is a powerful and straightforward approach for systematic exposition of the cis-regulatory architecture of complex genomes.

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