Using Spectroscopy to Guide the Adaptation of Aptamers into Electrochemical Aptamer-Based Sensors

Electrochemical aptamer-based (EAB) sensors utilize the binding-induced conformational change of an electrode-attached, redox-reporter-modified aptamer to transduce target recognition into an easily measurable electrochemical output. Because this signal transduction mechanism is single-step and rapidly reversible, EAB sensors support high-frequency, real-time molecular measurements, and because it recapitulates the reagentless, conformation-linked signaling seen in vivo among naturally occurring receptors, EAB sensors are selective enough to work in the complex, time-varying environments found in the living body. The fabrication of EAB sensors, however, requires that their target-recognizing aptamer be modified such that (1) it undergoes the necessary binding-induced conformational change and (2) that the thermodynamics of this conformational switch are tuned to ensure that they reflect an acceptable trade-offbetween affinity and signal gain. That is, even if an as-selected aptamer achieves useful affinity and specificity, it may fail when adapted to the EAB platform because it lacks the binding-induced conformational change required to support EAB signaling. In this paper we reveal the spectroscopy-guided approaches we use to modify aptamers such that they support the necessary binding-induced conformational change. Specifically, using newly reported aptamers, we demonstrate the systematic design of EAB sensors achieving clinically and physiologically relevant specificity, limits of detection, and dynamic range against the targets methotrexate and tryptophan.

Automated summary

Electrochemical aptamer-based (EAB) sensors utilize conformational changes to transduce target recognition into electrochemical output, supporting high-frequency molecular measurements and working in complex environments. However, modification of the aptamer is required to achieve the necessary conformational change and balance affinity and signal gain.