Abstract
BackgroundEukaryotic transcription is accompanied by combinatorial chromatin modifications that serve as functional epigenetic markers. Composition of chromatin modifications specifies histone codes that regulate the associated gene. Discovering novel chromatin regulatory relationships are of general interest.Methodology/Principal FindingsBased on the premise that the interaction of chromatin modifications is hypothesized to influence CpG methylation, we present a closeness measure to characterize the regulatory interactions of epigenomic features. The closeness measure is applied to genome-wide CpG methylation and histone modification datasets in human CD4+T cells to select a subset of potential features. To uncover epigenomic and genomic patterns, CpG loci are clustered into nine modules associated with distinct chromatin and genomic signatures based on terms of biological function. We then performed Bayesian network inference to uncover inherent regulatory relationships from the feature selected closeness measure profile and all nine module-specific profiles respectively. The global and module-specific network exhibits topological proximity and modularity. We found that the regulatory patterns of chromatin modifications differ significantly across modules and that distinct patterns are related to specific transcriptional levels and biological function. DNA methylation and genomic features are found to have little regulatory function. The regulatory relationships were partly validated by literature reviews. We also used partial correlation analysis in other cells to verify novel regulatory relationships.Conclusions/SignificanceThe interactions among chromatin modifications and genomic elements characterized by a closeness measure help elucidate cooperative patterns of chromatin modification in transcriptional regulation and help decipher complex histone codes.
Highlights
Complexity and specificity of transcriptional control has long been the subject of intense research
21 chromatin modifications and genomic elements are selected as informative features The closeness measure (CM) was used for linking chromatin modifications and DNA methylation to generate the CM profile
We evaluated whether features are related to CpG methylation by determining Pearson correlation coefficient (Pcc) between modeled and measured methylation
Summary
Complexity and specificity of transcriptional control has long been the subject of intense research. Histone modification and DNA methylation are the best known examples of epigenetic regulation. Data has helped shed light on the role of epigenetic modifications in transcriptional regulation [2,3,4]. Histone modifications play a significant role in epigenetics and can dynamically influence gene transcription [5]. Many types of histone modification are known to act on nucleosomes, but only a few of them have a defined function in genomic regulation. Chromatin modifications often function in a cooperative way to increase regulatory complexity. Histone modifications have been shown previously to be one mechanism of modulating transcription factors (TFs) and transcriptional control [6,7]. Eukaryotic transcription is accompanied by combinatorial chromatin modifications that serve as functional epigenetic markers. Composition of chromatin modifications specifies histone codes that regulate the associated gene.
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