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Insights into Structure, Stability, and Toxicity of Monomeric and Aggregated Polyglutamine Models from Molecular Dynamics Simulations

Luciana Esposito ^*, Antonella Paladino ^* , Carlo Pedone ^*  and Luigi Vitagliano ^*

^* Istituto di Biostrutture e Bioimmagini, CNR, I-80134 Naples, Italy; Laboratorio di Bioinformatica e Biologia Molecolare, Istituto di Scienze Alimentari, CNR, I-83100 Avellino, Italy; and Dipartimento delle Scienze Biologiche-Sezione di Biostrutture, Università degli Studi di Napoli "Federico II", I-80134 Naples, Italy

Correspondence: Address reprint requests to Luciana Esposito, E-mail: luciana.esposito{at}unina.it.

Nine genetically inherited neurodegenerative diseases are linked to abnormal expansions of a polyglutamine (polyQ) encoding region. Over the years, several structural models for polyQ regions have been proposed and confuted. The cross-β-spine steric zipper motif, identified recently for the GNNQQNY peptide, represents an attractive model for amyloid fibers formed by polyQ fragments. Here we report a detailed molecular dynamics investigation of polyQ models assembled by cross-β-spine steric zipper motifs. Our simulations indicate clearly that these assemblies are very stable. Glutamine side chains contribute strongly to the overall stability of the models by fitting perfectly within the zipper. In contrast to GNNQQNY zipper motifs, hydrogen bonding interactions provide a significant contribution to the overall stability of polyQ models. Molecular dynamics simulations carried out on monomeric polyQ forms (composed by 40–60 residues) show clearly that they can also assume structures stabilized by steric zipper motifs. Based on these findings, we build monomeric polyQ models that can explain recent data on the toxicity exerted by these species. In a more general context, our data suggests that polyQ models with interdigitated side chains can provide a structural rationale to several literature experiments on polyQ formation, stability, and toxicity.

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