Complex exon-intron marking by histone modifications is not determined solely by nucleosome distribution

It has recently been shown that nucleosome distribution, histone modifications and RNA polymerase II (Pol II) occupancy show preferential association with exons ("exon-intron marking"), linking chromatin structure and function to co-transcriptional splicing in a variety of eukaryotes. Prev...

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Published in:PloS one 2010-08, Vol.5 (8), p.e12339-e12339
Main Authors: Dhami, Pawandeep, Saffrey, Peter, Bruce, Alexander W, Dillon, Shane C, Chiang, Kelly, Bonhoure, Nicolas, Koch, Christoph M, Bye, Jackie, James, Keith, Foad, Nicola S, Ellis, Peter, Watkins, Nicholas A, Ouwehand, Willem H, Langford, Cordelia, Andrews, Robert M, Dunham, Ian, Vetrie, David
Format: Article
Language:English
Subjects:
Analysis
Cancer
Chromatin
College campuses
Deoxyribonucleic acid
DNA
DNA methylation
DNA-directed RNA polymerase
Epigenetics
Eukaryotes
Exons
Exons - genetics
Fibroblasts
Gene expression
Gene Expression Regulation
Genes
Genomes
Genomics
Growth factors
Hematology
Histones - metabolism
Humans
Introns
Introns - genetics
K562 Cells
Leukemia
Marking systems
Molecular Biology/Chromatin Structure
Molecular Biology/Chromosome Structure
Molecular Biology/Histone Modification
Molecular Biology/RNA Splicing
Molecular Biology/Translation Mechanisms
Molecular Biology/Translational Regulation
Nucleosomes - genetics
Nucleosomes - metabolism
Ribonucleic acid
RNA
RNA polymerase
RNA polymerase II
RNA Polymerase II - metabolism
Sequences
Splicing
Structure-function relationships
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Transcription (Genetics)
Transcription, Genetic
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Summary:It has recently been shown that nucleosome distribution, histone modifications and RNA polymerase II (Pol II) occupancy show preferential association with exons ("exon-intron marking"), linking chromatin structure and function to co-transcriptional splicing in a variety of eukaryotes. Previous ChIP-sequencing studies suggested that these marking patterns reflect the nucleosomal landscape. By analyzing ChIP-chip datasets across the human genome in three cell types, we have found that this marking system is far more complex than previously observed. We show here that a range of histone modifications and Pol II are preferentially associated with exons. However, there is noticeable cell-type specificity in the degree of exon marking by histone modifications and, surprisingly, this is also reflected in some histone modifications patterns showing biases towards introns. Exon-intron marking is laid down in the absence of transcription on silent genes, with some marking biases changing or becoming reversed for genes expressed at different levels. Furthermore, the relationship of this marking system with splicing is not simple, with only some histone modifications reflecting exon usage/inclusion, while others mirror patterns of exon exclusion. By examining nucleosomal distributions in all three cell types, we demonstrate that these histone modification patterns cannot solely be accounted for by differences in nucleosome levels between exons and introns. In addition, because of inherent differences between ChIP-chip array and ChIP-sequencing approaches, these platforms report different nucleosome distribution patterns across the human genome. Our findings confound existing views and point to active cellular mechanisms which dynamically regulate histone modification levels and account for exon-intron marking. We believe that these histone modification patterns provide links between chromatin accessibility, Pol II movement and co-transcriptional splicing.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0012339