Project description:DNA methylation (mC) on CpG sites is the most common epigenetic modification. Recently methylation on non-CpG context was found to widely occur on genomic DNA. However, how non-CpG methylation influences DNA/protein interaction and regulates transcription is unknown. Using single-molecule assays, we studied the interactions of transcription factors (TFs) GR, ER and BMAL1-CLOCK with methylated or unmethylated cognate DNA binding sequences. The results demonstrated that these TFs interact with methylated DNA discriminatively. We then performed BisChIP-seq with GR and BMAL1-CLOCK in HEK-293T cells and showed that they can recognize and bind to the methylated sites within chromatin. The effects of non-CpG methylation on transcriptional regulation were validated by in vitro transcription assays with correlated RNA level, and further studied mechanistically by crystallographic analyses and molecular dynamics simulations. We conclude that the non-CpG methylation of DNA provides another general mechanism for regulating gene expression through affecting TFs binding affinity.

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Project description:The majority of CpG dinucleotides in the human genome are methylated at cytosine bases. The methylation is heritable across cell divisions, and contributes to the epigenetic memory that maintains the differentiated state of distinct cell types. Active gene regulatory elements are generally undermethylated relative to their flanking regions, and the undermethylation is thought to be important for their activity. Consistently with this model, the binding of some transcription factors (TFs) is diminished by methylation of their target sequences. By systematic analysis of 542 human TFs using methylation sensitive SELEX, we find here that a large number of TFs also prefer to bind to CpG methylated sequences. Most of these represent the extended homeodomain family. Structural analysis of HOXB13, CDX1, CDX2 and LHX4 revealed that the specificity of homeodomain proteins towards methylcytosine depends on amino-acids that form direct hydrophobic interactions with the 5-methyl group of methylcytosine. Our results provide a systematic examination of the effect of an epigenetic DNA modification on human TF binding specificity, and reveal that many developmentally important homeodomain proteins display strong preference for binding to mCpG containing sequences. Genome-scale analysis reveals that binding of most transcription factors is affected by CpG methylation, and that many developmentally important homeodomain TFs directly recognize the 5-methyl group of methylcytosine.

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