Abstract
DNA aptamers were developed against five different peptides from the known binding regions of anti-Cytomegalovirus and anti-Herpes Simplex Virus-2 antibodies and the aptamers were ranked by relative affinity based on an ELISA-like (ELASA) microplate assay. The secondary structures of the top five highest affinity aptamers were studied for stem-loop commonalities and the most probable peptide binding sites. Two of these stem-loop structures were converted into beacons by addition of TYE 665 dye on the 5′ end and Iowa Black quencher on the 3′ end. When competed against increasing concentrations of each of the five peptides, only three of the possible ten interactions demonstrated “lights on” fluorescence beacon responses. When modeled by generation of PDB files, after passage through PATCHDOCK and YASARA, two of the aptamer beacon-peptide interactions showed no theoretical evidence of separating the G-C stem-loop region, despite clear empirical evidence of separation of the fluorophore and quencher beyond the Förster distance leading to abundant fluorescence. And in the second beacon’s case, YASARA modeling suggested that the beacon was always open despite clear empirical evidence that it was not (no fluorescence response) and only opened in the presence of one of the five peptides. These results are interpreted as a demonstration that 3-dimensional docking software such as PATCHDOCK and YASARA, which are based on rigid receptor-ligand shape complementarity may not reflect the “induced-fit” interactions between aptamers and their cognate targets. Therefore, for the most complete and accurate picture of aptamer-peptide binding, several theoretical and empirical (e.g., beacon fluorescence) analysis methods may be needed.
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Work was funded by NIH SBIR contract no. HHSN272201700075C.
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JB conceived all experiments, conducted the fluorescence experiments and 3-D modeling, and wrote the manuscript. TP developed and screened the aptamers by ELASA and edited the manuscript.
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Bruno, J.G., Phillips, T. Beacons Contribute Valuable Empirical Information to Theoretical 3-D Aptamer-Peptide Binding. J Fluoresc 29, 711–717 (2019). https://doi.org/10.1007/s10895-019-02380-6
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DOI: https://doi.org/10.1007/s10895-019-02380-6