Abstract
G-quadruplex (G4) is a DNA/RNA conformation that consists of two or more G-tetrads resulting from four-guanine bases connected by Hoogsteen-type hydrogen bonds, which is often found in the telomeres of chromatin, as well as in the promoter regions of genes. The function of G4 in the genomic DNA is being elucidated and some G4-protein interactions have been reported; these are believed to play a role in vital cellular functions. In this study, we focused on CpG methylation, a well-known epigenetic modification of the genomic DNA, especially found in the promoter regions. Although many G4-forming sequences within the genomic DNA harbor CpG sites, the relationship between CpG methylation and the binding properties of associated proteins remains unclear. We demonstrated that the binding ability of vascular endothelial growth factor (VEGF) G4 DNA to VEGF165 protein was significantly decreased by CpG methylation. We identified the binding activity of G4 DNA oligonucleotides derived from gene promoter regions to SP1, a transcription factor that interacts with a G4-forming DNA and is also altered by CpG methylation. The effect of methylation on binding affinity was accompanied by changes in G4 structure and/or topology. Therefore, this study suggested that CpG methylation might be involved in protein binding to G4-forming DNA segments for purposes of transcriptional regulation.
Highlights
G-quadruplex (G4) is a non-canonical nucleic acid structure formed in G-rich sequences [1]
We previously reported that the vascular endothelial growth factor 165 (VEGF165) protein binds to G4 DNA formed in the VEGF promoter [22] and G4 RNA formed in VEGF pre-mRNA [23]
We demonstrated that CpG methylation in G4 DNA structures was involved in mediating the binding ability of VEGF165 and specificity protein 1 (SP1) to G4 DNAs
Summary
G-quadruplex (G4) is a non-canonical nucleic acid structure formed in G-rich sequences [1]. G4 is formed by stacking of G-tetrads to form a planar array of four guanine bases connected by Hoogsteen bonding. It is well-known that the thermostability of G4 structures depends on the concentration and type of monovalent cations [2]. The topology of human telomeric DNA depends on the type of cations: G4 folds into a basket-type mixed antiparallel/parallel -stranded G4 structure or hybrid-type mixed antiparallel/parallel-stranded. G4 structure in the presence of Na+ or K+ , respectively [4,5]. These results suggest that the topology and stability are related to the biological function of G4. Genome-wide G4-forming DNA identification analysis revealed that
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