Differential sensitivity to methylated DNA by ETS-family transcription factors is intrinsically encoded in their DNA-binding domains

Transactivation by the ETS family of transcription factors, whose members share structurally conserved DNA-binding domains, is variably sensitive to methylation of their target genes. The mechanism by which DNA methylation controls ETS proteins remains poorly understood. Uncertainly also pervades th...

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Bibliographic Details
Published in:Nucleic acids research 2016-10, Vol.44 (18), p.8671-8681
Main Authors: Stephens, Dominique C, Poon, Gregory M K
Format: Article
Language:English
Subjects:
5-Methylcytosine - metabolism
Animals
Binding Sites
CpG Islands - genetics
DNA - chemistry
DNA - metabolism
DNA Methylation - genetics
Gene regulation, Chromatin and Epigenetics
Mice
Nucleic Acid Conformation
Principal Component Analysis
Protein Binding - genetics
Protein Domains
Proto-Oncogene Proteins - chemistry
Proto-Oncogene Proteins - metabolism
Proto-Oncogene Proteins c-ets - chemistry
Proto-Oncogene Proteins c-ets - metabolism
Thermodynamics
Trans-Activators - chemistry
Trans-Activators - metabolism
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Summary:Transactivation by the ETS family of transcription factors, whose members share structurally conserved DNA-binding domains, is variably sensitive to methylation of their target genes. The mechanism by which DNA methylation controls ETS proteins remains poorly understood. Uncertainly also pervades the effects of hemi-methylated DNA, which occurs following DNA replication and in response to hypomethylating agents, on site recognition by ETS proteins. To address these questions, we measured the affinities of two sequence-divergent ETS homologs, PU.1 and Ets-1, to DNA sites harboring a hemi- and fully methylated CpG dinucleotide. While the two proteins bound unmethylated DNA with indistinguishable affinity, their affinities to methylated DNA are markedly heterogeneous and exhibit major energetic coupling between the two CpG methylcytosines. Analysis of simulated DNA and existing co-crystal structures revealed that hemi-methylation induced non-local backbone and groove geometries that were not conserved in the fully methylated state. Indirect readout of these perturbations was differentially achieved by the two ETS homologs, with the distinctive interfacial hydration in PU.1/DNA binding moderating the inhibitory effects of DNA methylation on binding. This data established a biophysical basis for the pioneering properties associated with PU.1, which robustly bound fully methylated DNA, but not Ets-1, which was substantially inhibited.
ISSN:0305-1048
1362-4962
DOI:10.1093/nar/gkw528