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Symmetry breaking of fluorophore binding to a G-quadruplex generates an RNA aptamer with picomolar KD.

Xiaocen LuLuiz F M PassalacquaMatthew NodwellKristen Y S KongGuillermo Caballero-GarcíaElena V DolgosheinaAdrian R Ferre-D'AmareRobert A BrittonPeter J Unrau
Published in: Nucleic acids research (2024)
Fluorogenic RNA aptamer tags with high affinity enable RNA purification and imaging. The G-quadruplex (G4) based Mango (M) series of aptamers were selected to bind a thiazole orange based (TO1-Biotin) ligand. Using a chemical biology and reselection approach, we have produced a MII.2 aptamer-ligand complex with a remarkable set of properties: Its unprecedented KD of 45 pM, formaldehyde resistance (8% v/v), temperature stability and ligand photo-recycling properties are all unusual to find simultaneously within a small RNA tag. Crystal structures demonstrate how MII.2, which differs from MII by a single A23U mutation, and modification of the TO1-Biotin ligand to TO1-6A-Biotin achieves these results. MII binds TO1-Biotin heterogeneously via a G4 surface that is surrounded by a stadium of five adenosines. Breaking this pseudo-rotational symmetry results in a highly cooperative and homogeneous ligand binding pocket: A22 of the G4 stadium stacks on the G4 binding surface while the TO1-6A-Biotin ligand completely fills the remaining three quadrants of the G4 ligand binding face. Similar optimization attempts with MIII.1, which already binds TO1-Biotin in a homogeneous manner, did not produce such marked improvements. We use the novel features of the MII.2 complex to demonstrate a powerful optically-based RNA purification system.
Keyphrases
  • nucleic acid
  • gold nanoparticles
  • transcription factor
  • photodynamic therapy
  • room temperature
  • recombinant human
  • fluorescence imaging