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Flow-Cell-Based Technology for Massively Parallel Characterization of Base-Modified DNA Aptamers

Diana Wu, Trevor Feagin, Peter L. Mage, Alexandra E. Rangel, Leighton Wan, Dehui Kong, Anping Li, John A. Coller, Michael Eisenstein, H. Tom Soh

2023Analytical Chemistry33 citationsDOI

Abstract

Aptamers incorporating chemically modified bases can achieve superior affinity and specificity compared to natural aptamers, but their characterization remains a labor-intensive, low-throughput task. Here, we describe the "non-natural aptamer array" (N2A2) system, in which a minimally modified Illumina MiSeq instrument is used for the high-throughput generation and characterization of large libraries of base-modified DNA aptamer candidates based on both target binding and specificity. We first demonstrate the capability to screen multiple different base modifications to identify the optimal chemistry for high-affinity target binding. We next use N2A2 to generate aptamers that can maintain excellent specificity even in complex samples, with equally strong target affinity in both buffer and diluted human serum. For both aptamers, affinity was formally calculated with gold-standard binding assays. Given that N2A2 requires only minor mechanical modifications to the MiSeq, we believe that N2A2 offers a broadly accessible tool for generating high-quality affinity reagents for diverse applications.

Topics & Concepts

AptamerChemistryDNACharacterization (materials science)Computational biologyCombinatorial chemistryNanotechnologyMolecular biologyBiochemistryMaterials scienceBiologyAdvanced biosensing and bioanalysis techniquesBiosensors and Analytical DetectionRNA Interference and Gene Delivery
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