Decoding complexity in biomolecular recognition of DNA i-motifs with microarrays.
Kamyar YazdaniSrinath SeshadriDesiree TiloMo YangChristopher D SibleyCharles VinsonJohn S SchneeklothPublished in: Nucleic acids research (2023)
DNA i-motifs (iMs) are non-canonical C-rich secondary structures implicated in numerous cellular processes. Though iMs exist throughout the genome, our understanding of iM recognition by proteins or small molecules is limited to a few examples. We designed a DNA microarray containing 10976 genomic iM sequences to examine the binding profiles of four iM-binding proteins, mitoxantrone and the iMab antibody. iMab microarray screens demonstrated that pH 6.5, 5% BSA buffer was optimal, and fluorescence was correlated with iM C-tract length. hnRNP K broadly recognizes diverse iM sequences, favoring 3-5 cytosine repeats flanked by thymine-rich loops of 1-3 nucleotides. Array binding mirrored public ChIP-Seq datasets, in which 35% of well-bound array iMs are enriched in hnRNP K peaks. In contrast, other reported iM-binding proteins had weaker binding or preferred G-quadruplex (G4) sequences instead. Mitoxantrone broadly binds both shorter iMs and G4s, consistent with an intercalation mechanism. These results suggest that hnRNP K may play a role in iM-mediated regulation of gene expression in vivo, whereas hnRNP A1 and ASF/SF2 are possibly more selective in their binding preferences. This powerful approach represents the most comprehensive investigation of how biomolecules selectively recognize genomic iMs to date.
Keyphrases
- gene expression
- high throughput
- single molecule
- genome wide
- high resolution
- dna binding
- circulating tumor
- binding protein
- dna methylation
- rna seq
- magnetic resonance
- healthcare
- cell free
- emergency department
- computed tomography
- mental health
- circulating tumor cells
- nucleic acid
- decision making
- mass spectrometry
- high density
- transcription factor
- quantum dots
- energy transfer