Drugging Disordered Proteins by Conformational Selection to Inform Therapeutic Intervention

Abstract

ABSTRACTDrugging intrinsically disordered proteins (IDPs) has historically been a major challenge due to their lack of stable binding sites, conformational heterogeneity, and rapid ability to self-associate or bind non-specific neighbors. Furthermore, it is unclear whether binders of disordered proteins i) induce entirely new conformations or ii) target transient pre-structured conformations via stabilizing existing states. To distinguish between these two mechanisms, we utilize molecular dynamics simulations to induce structured conformations in islet amyloid polypeptide (IAPP), a disordered endocrine peptide implicated in Type II Diabetes. Using umbrella sampling, we measureconformation-specificaffinities of molecules previously shown to bind IAPP to determine if they can discriminate between two distinct IAPP conformations (fixed in either ⍺-helix or β-sheet). We show our two-state model of IAPP faithfully predicts the experimentally observed selectivity of two classes of IAPP binders while revealing differences in their molecular mechanisms of binding. Specifically, the binding preferences of foldamers designed for human IAPP was not fully accounted for by conformational selection, unlike β-breaking peptides designed to mimic IAPP self-assembly sequences. Furthermore, the binding of these foldamers, but not β-breaking peptides, was disrupted by changes in the rat IAPP sequence. Taken together, our data quantifies the sequence and conformational specificity for IAPP binders and reveals conformational selection sometimes overrides sequence-level specificity. This work highlights the important role of conformational selection in stabilizing IDPs, and it reveals how fixed conformations can provide a tractable target for developing disordered protein binders.