The pathological involvement of β-amyloid (Aβ) protein variants in Alzheimer's disease (AD) progression manifests through distinct aggregation patterns, neurotoxic profiles, and spatial distributions contingent upon their polypeptide lengths. While gelsolin (GSN) has emerged as a potential regulatory factor in Aβ dynamics, the structural determinants governing its interaction with various Aβ isoforms remain poorly characterized. Building upon our previous demonstration of GSN-mediated inhibition of β-amyloid protein 1-42 (Aβ1-42) fibrillogenesis through monomer binding, we present the first systematic investigation of GSN interaction dynamics with Aβ fragments of varying lengths (Aβ1-42, Aβ1-40, Aβ9-37, Aβ1-16, and Aβ1-11) using dual polarization interferometry. Our experimental paradigm employed simultaneous real-time monitoring of three critical biophysical parameters (adsorbed mass, layer thickness, and density) for characterizing binding kinetics and conformational changes. This multiparametric analysis revealed a pronounced length-dependent mechanism underlying GSN-Aβ interactions. Through an integrated approach combining multiscale experimental dynamics with computational docking simulations, we elucidated the intricate relationship between interaction thermodynamics and structural complementarity. These findings established a theoretical framework for developing stage-specific therapeutic interventions in AD management while advancing our understanding of molecular determinants in protein chaperone systems.
Ma et al. (Mon,) studied this question.