Cell labeling and proximity dependent biotinylation with engineered monomeric streptavidin

Abstract

Because streptavidin is a homotetramer, it can bind multiple biotinylated ligands and cause target aggregation. To allow biotin detection without clustering, we previously engineered monomeric streptavidin (mSA) that is structurally similar to a single streptavidin subunit. Introducing the S25H mutation near the binding site increases the biotin dissociation half-life t1/2 to 83 minutes. The slowly dissociating mutant, mSA2, is useful in imaging studies because it allows stable labeling of biotinylated targets. We show that mSA2 conjugated with Alexa 488 binds biotinylated receptors on HEK293 with high specificity, and bound mSA2–Alexa488 does not dissociate significantly during an imaging study lasting 50 minutes. As a structural monomer, mSA2 can be fused to other proteins to create bifunctional molecules. We tested the use of mSA2 in proximity dependent biotinylation, in which mSA2 is fused to a peptide or a protein that binds a protein of interest (POI) and is used to recruit photoactivatable biotin (PA-biotin) to the target molecule. Once the resulting cluster of interacting proteins is subjected to UV-initiated distance-dependent biotinylation, subsequent affinity purification of biotinylated proteins on streptavidin beads can identify protein molecules that interact with POI. In addition to proteins that directly interact with the mSA2 fusion, mSA2 also induces biotinylation of other proteins that are associated through a series of noncovalent interactions. We show that mSA2 fused to an antibody recognition domain can be recruited to the kinase Erk-2 using a commercially available antibody and induce biotinylation of a known Erk-2 substrate, GST-Elk-1. Therefore, mSA2 can be used to implement proximity dependent biotinylation and detect transient enzyme-substrate interactions.