Electrostatics cause the molecular chaperone BiP to preferentially bind oligomerized states of a client protein

Hsp70-family chaperones bind short monomeric peptides with a weak characteristic affinity in the low micromolar range, but can also bind some aggregates, fibrils, and amyloids, with low nanomolar affinity. While this differential affinity enables Hsp70 to preferentially target potentially toxic aggregates, it is unknown how Hsp70s differentiate between monomeric and oligomeric states of a target protein. Here we examine the interaction of BiP (the Hsp70 paralog in the endoplasmic reticulum) with proIGF2, the pro-protein form of IGF2 that includes a long and mostly disordered E-peptide region that promotes proIGF2 oligomerization. We discover that electrostatic attraction enables the negatively charged BiP to bind positively charged E-peptide oligomers with low nanomolar affinity. We identify the specific BiP binding sites on proIGF2, and although some are positively charged, as monomers they bind BiP with characteristically low affinity in the micromolar range. We conclude that electrostatics enable BiP to preferentially recognize oligomeric states of proIGF2. Electrostatic targeting of Hsp70 to aggregates may be broadly applicable, as all the currently-documented cases in which Hsp70 binds aggregates with high-affinity involve clients that are expected to be positively charged.