Publications by authors named "Alex M Yoshikawa"
Aptamer-based molecular switches that undergo a binding-induced conformational change have proven valuable for a wide range of applications, such as imaging metabolites in cells, targeted drug delivery, and real-time detection of biomolecules. Since conventional aptamer selection methods do not typically produce aptamers with inherent structure-switching functionality, the aptamers must be converted to molecular switches in a post-selection process. Efforts to engineer such aptamer switches often use rational design approaches based on in silico secondary structure predictions.
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- Aptamers are effective in identifying small molecules by distinguishing between similar structures, but traditional selection methods are inefficient due to trial-and-error approaches for counterselection.
- A new high-throughput screening method is introduced, allowing for the simultaneous identification of highly specific aptamers for multiple targets in one experiment, eliminating the need for counterselection.
- This innovative process successfully selected aptamers with strong affinity for closely related kynurenine metabolites, showcasing its adaptability for other small molecules and its potential to fast-track aptamer development.
Glycosylation is one of the most abundant forms of post-translational modification, and can have a profound impact on a wide range of biological processes and diseases. Unfortunately, efforts to characterize the biological function of such modifications have been greatly hampered by the lack of affinity reagents that can differentiate protein glycoforms with robust affinity and specificity. In this work, we use a fluorescence-activated cell sorting (FACS)-based approach to generate and screen aptamers with indole-modified bases, which are capable of recognizing and differentiating between specific protein glycoforms.
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