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DNA strand asymmetry generated by CpG hemimethylation has opposing effects on CTCF binding.

Stacey L ThomasTing-Hai XuBrittany L CarpenterSteven E PierceBradley M DicksonMinmin LiuGangning LiangPeter A Jones
Published in: Nucleic acids research (2023)
CpG methylation generally occurs on both DNA strands and is essential for mammalian development and differentiation. Until recently, hemimethylation, in which only one strand is methylated, was considered to be simply a transitory state generated during DNA synthesis. The discovery that a subset of CCCTC-binding factor (CTCF) binding sites is heritably hemimethylated suggests that hemimethylation might have an unknown biological function. Here we show that the binding of CTCF is profoundly altered by which DNA strand is methylated and by the specific CTCF binding motif. CpG methylation on the motif strand can inhibit CTCF binding by up to 7-fold, whereas methylation on the opposite strand can stimulate binding by up to 4-fold. Thus, hemimethylation can alter binding by up to 28-fold in a strand-specific manner. The mechanism for sensing methylation on the opposite strand requires two critical residues, V454 and S364, within CTCF zinc fingers 7 and 4. Similar to methylation, CpG hydroxymethylation on the motif strand can inhibit CTCF binding by up to 4-fold. However, hydroxymethylation on the opposite strand removes the stimulatory effect. Strand-specific methylation states may therefore provide a mechanism to explain the transient and dynamic nature of CTCF-mediated chromatin interactions.
Keyphrases
  • dna methylation
  • genome wide
  • dna binding
  • binding protein
  • circulating tumor
  • cell free
  • single molecule
  • gene expression
  • oxidative stress
  • transcription factor
  • small molecule
  • blood brain barrier
  • cerebral ischemia