Star-shaped flexible arm multivalent aptamers for largely improved virus binding affinity.

Here we explore the click chemistry-based synthesis of high affinity multivalent aptamers and their application for virus detection. In contrast to attempts based on rigid constructs, such as aptamer-modified nanoparticles or hybridization-connected constructs, we propose highly flexible "star-shaped" multivalent aptamers to facilitate the cooperative binding to randomly distributed viral proteins on the surface of pleomorphic viruses such as the respiratory syncytial virus (RSV). Polyethylene glycols (PEGs) with 4 azide terminated flexible arms spanning from a pentaerythritol core were conjugated to aptamer strands with dibenzocyclooctyne and a fluorescent label at their, 3' and 5' terminus, respectively. By controlling the aptamer - PEG ratio and following electrophoretic separation all the different valency aptamer conjugates could be prepared. For proof of concept, we used an aptamer selected for the G protein of RSV. We show that significantly higher apparent affinities can be obtained by using multivalent aptamers for both the G protein and RSV virus than with the single stranded aptamer, i.e. with up to ca. 2 orders of magnitude. The inherent convenience of synthesizing fluorescently labelled multivalent aptamers leads to a versatile class of affinity ligands for sensing as demonstrated through the improved detection sensitivity of tetravalent aptamer tagged RSV by fluorescence nanoparticle tracking analysis. [Display omitted] • Star-shaped flexible PEG arm multivalent aptamers can be synthesized by click chemistry. • Different valency PEG core aptamers can be electrophoretically separated. • Flexible tetravalent aptamers showed increased affinity for the pleomorphic RSV. • Multivalent aptamers resist well to displacement from their RSV target. • Multivalent fluorescent aptamers improved the detectability of RSV in F-NTA. [ABSTRACT FROM AUTHOR]