Electrophoretic study of G-quadruplex aptamer interactions with different short single-strand complementary oligonucleotides

Abstract Aptamers are single-stranded nucleic acids, typically 20-80 nucleobases (nb) in length, which can bind different compounds with high affinity and selectively. Their ligand-binding properties can be attenuated by adding short complementary strands. These interactions open new opportunities for aptamer-based assays. Strong dependence between the length and electrophoretic mobility of short nucleic acids makes polyacrylamide gel electrophoresis a powerful tool for studying their complexes. The interactions between the 36 nb DNA G-quadruplex aptamer (5’-GAT-CGG-GTG-TGG-GTG-GCG-TAA-AGG-GAG-CAT-CGG-ACA-3’) specific to ochratoxin A and 9 complementary single-stranded DNA (ssDNA) were studied. The length of ssDNA varied from 5 to 9 nb. To maintain ligand-binding conformation of the aptamer, a high ionic strength buffer was used. The best resolution between the aptamer and its complex was provided for the gel with 15% monomer and a monomer/cross-linker ratio of 15:1. Bands of free aptamer and ssDNA were observed for all studied variants. If the ssDNA length was less than 9 nb, the position of the aptamer’s band remained unchanged, independent of the aptamer/ssDNA ratios, and additional bands did not appear. The longest ssDNA (5’-CGC-CAC-CCA-3’) did not lead to the appearance of a new band, but it slowed the aptamer’s migration depending on the ssDNA concentration. Under a 27-fold excess of the given ssDNA, the relative mobility of the aptamer band changed from 0.566 to 0.468. Thus, electrophoresis visualizes aptamer-ssDNA interactions and can be used in the development of aptamer-based analytical systems.