Characterization of enhanced monovalent and bivalent thrombin DNA aptamer binding using single molecule force spectroscopy |
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| Authors: | Neundlinger Isabel Poturnayova Alexandra Karpisova Ivana Rankl Christian Hinterdorfer Peter Snejdarkova Maja Hianik Tibor Ebner Andreas |
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| Affiliation: | †Biophysics Institute, Johannes Kepler University Linz, Linz, Austria;‡Institute of Biochemistry and Animal Genetics, Slovak Academy of Sciences, Ivanka pri Dunaji, Slovakia;§Faculty of Mathematics, Physics and Informatics, Comenius University, Bratislava, Slovakia;¶Agilent Technologies, Austria GmbH, Linz, Austria;‖Center for Advanced Bioanalysis, Linz, Austria;∗∗Christian Doppler Laboratory for Nanoscopic Methods in Biophysics, Biophysics Institute JKU, Linz, Austria |
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| Abstract: | ![]()
Thrombin aptamer binding strength and stability is dependent on sterical parameters when used for atomic force microscopy sensing applications. Sterical improvements on the linker chemistry were developed for high-affinity binding. For this we applied single molecule force spectroscopy using two enhanced biotinylated thrombin aptamers, BFF and BFA immobilized on the atomic force microscopy tip via streptavidin. BFF is a dimer composed of two single-stranded aptamers (aptabody) connected to each other by a complementary sequence close to the biotinylated end. In contrast, BFA consists of a single DNA strand and a complementary strand in the supporting biotinylated part. By varying the pulling velocity in force-distance cycles the formed thrombin-aptamer complexes were ruptured at different force loadings allowing determination of the energy landscape. As a result, BFA aptamer showed a higher binding force at the investigated loading rates and a significantly lower dissociation rate constant, koff, compared to BFF. Moreover, the potential of the aptabody BFF to form a bivalent complex could clearly be demonstrated. |
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