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Direct Observation of Seeded Conformational Conversion of hIAPP <i>In Silico</i> Reveals the Mechanisms for Morphological Dependence and Asymmetry of Fibril Growth

Gangtong Huang, Huayuan Tang, Yuying Liu, Chi Zhang, Pu Chun Ke, Yunxiang Sun, Feng Ding

2023Journal of Chemical Information and Modeling11 citationsDOIOpen Access PDF

Abstract

a seeded conformational conversion of monomers is a critical step of fibrillization and important for disease transmission and progression. Amyloid fibrils often display diverse morphologies with distinct populations, and yet the molecular mechanisms of fibril elongation and their corresponding morphological dependence remain poorly understood. Here, we computationally investigated the single-molecular growth of two experimentally resolved human islet amyloid polypeptide fibrils of different morphologies. In both cases, the incorporation of monomers into preformed fibrils was observed. The conformational conversion dynamics was characterized by a small number of fibril growth intermediates. Fibril morphology affected monomer binding at fibril elongation and lateral surfaces as well as the seeded conformational conversion dynamics at the fibril ends, resulting in different fibril elongation rates and populations. We also observed an asymmetric fibril growth as in our prior experiments, attributing to differences of two fibril ends in terms of their local surface curvatures and exposed hydrogen-bond donors and acceptors. Together, our mechanistic findings afforded a theoretical basis for delineating different amyloid strains-entailed divergent disease progression.

Topics & Concepts

FibrilIn silicoAsymmetryBiophysicsChemistryBiologyBiochemistryPhysicsQuantum mechanicsGeneEnzyme Structure and FunctionProtein Structure and DynamicsSkin and Cellular Biology Research
Direct Observation of Seeded Conformational Conversion of hIAPP <i>In Silico</i> Reveals the Mechanisms for Morphological Dependence and Asymmetry of Fibril Growth | Litcius