Affinity Chromatography with Collapsibly Tethered Ligands

Abstract

We introduce a novel affinity chromatography mode in which affinity ligands are secured to the media surface via collapsible tethers. In traditional affinity chromatography, the immobilized ligands act passively, and their local concentration is static. In collapsibly tethered affinity chromatography, the ligand can move dynamically in response to external stimuli, a design that enables marked changes in both the local concentration of the ligand and its surrounding environment without exchange of solvent. Using the thermoresponsive polymer poly(N-isopropylacrylamide) (PIPAAm) as a scaffold for ligand and hapten attachment, we were able to achieve controlled mobility and microenvironment alteration of the affinity ligand Ricinus communis agglutinin (RCA₁₂₀). The glycoprotein target, asialotransferrin, was loaded onto a column in which PIPAAm was partially substituted with both RCA₁₂₀ and lactose. At 5 °C, the column retained the glycoprotein, but released most (95%) of the asialotransferrin upon warming to 30 °C. This temperature-induced elution was much greater than can be explained by temperature dependency of sugar recognition by RCA₁₂₀. The simplest explanation is that upon thermally induced dehydration and collapse of the PIPAAm chains, coimmobilized RCA₁₂₀ ligand and lactose hapten are brought into closer proximity to each other, enabling immobilized lactose to displace affinity-bound asislotransferrin from the immobilized RCA₁₂₀ lectin.