Macroscopic-scale surface properties of streptavidin and their influence on aspecific interactions between streptavidin and dissolved biopolymers

Abstract

To avoid aspecific attractions between carrier surfaces for either ligand or receptor molecules in, e.g., immunoassays, or kinetic rate constant measurements, it has long been established that a background consisting of an aspecific, very hydrophilic carrier surface is generally quite effective. However, it is not often realized that one achieves such a non-reactive background, even with electrostatically neutral materials, at the price of creating a strong (polar) hydrophilic repulsion between dissolved biopolymer (e.g., protein) molecules and the non-adsorbing carrier surface. To investigate the quantitative effects of this type of repulsion in systems involving streptavidin, the surface properties of a streptavidin-coated glass plate were determined by contact angle measurements, from which the aspecific, macroscopic-scale free energies of repulsion between a streptavidin-coated surface and dissolved proteins such as immunoglobulin-G (IgG), and human serum albumin (HSA), could be derived. Streptavidin, even at neutral pH (at which it has virtually no electric surface charge as determined by electrophoresis) is very hydrophilic and strongly repels both IgG and HSA molecules. At neutral pH, molecules such as IgG and HSA, in aqueous solution, cannot approach a streptavidin layer more closely than to approximately 3.0 nm, which suffices to prevent IgG or HSA from any aspecific adherence to the streptavidin layer (as determined by extended DLVO analysis). This aspecific repulsion however also has the (usually unsuspected) effect of causing a decreased specific attachment between ligand and receptor molecules. In addition, it decreases the measured kinetic on-rate constants, often by about two decimal orders of magnitude. However, once the surface-thermodynamic properties of all the aspecific (macroscopic-scale) and specific (microscopic-scale) entities, as well as the specific equilibrium binding constant are known, the real kinetic on-rate constant between just the ligand and the receptor determinants can be determined, yielding the value it would have if the measurement of that constant were unhindered by the repulsive interactions exerted by the background of hydrophilic carrier molecules.