Abstract

Adeno-associated viruses (AAVs) have emerged as promising vectors for gene therapy due to their non-pathogenic nature and ability to transduce various cell types efficiently. In recent years, there has been an increasing effort to optimize the production and purification of AAV to support clinical applications; however, challenges exist in affinity ligand design, synthesis, and characterization. Understanding the binding interactions of these viruses with functional molecules is pivotal for the development of affinity-based separation methods of AAVs. Classical methods to measure thermodynamic parameters such as Isothermal Titration Calorimetry (ITC) are challenging to employ in these scenarios, as the concentrations of the viral titers are significantly lower than those used in binding experiments with small biomolecules. Here, we present design principles that enable ITC-based determination of binding interactions between AAV2 and heparin. We observe increasing binding affinity with increasing molecular weight of heparin. We also elucidate the binding stoichiometry between AAV2 and heparins of varying molecular weights. Additionally, we report on the impact of buffer conditions and pH values on AAV2–heparin binding properties. Lastly, we also present the binding affinities and thermodynamic properties of interactions between the two species with heparin immobilized onto surfaces, namely, silica nanoparticles, as surface immobilization of the ligand is a common pathway for affinity-based separations. Overall, our results may provide key information for optimization of AAV-ligand binding protocols that are an essential step toward optimizing AAV capture and immobilization methods.

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