10.1021/acs.jpcb.5b11380.s002 David Punihaole David Punihaole Riley J. Workman Riley J. Workman Zhenmin Hong Zhenmin Hong Jeffry D. Madura Jeffry D. Madura Sanford A. Asher Sanford A. Asher Polyglutamine Fibrils: New Insights into Antiparallel β‑Sheet Conformational Preference and Side Chain Structure American Chemical Society 2016 2Q fibril peptide bonds Q 10 fibrils UVRR Side Chain Structure side chain χ3 dihedral angles polyQ fibrils MD χ3 angle distributions fibril peptide backbone Ψ Gln side chains 2016-03-05 00:00:00 Dataset https://acs.figshare.com/articles/dataset/Polyglutamine_Fibrils_New_Insights_into_Antiparallel_Sheet_Conformational_Preference_and_Side_Chain_Structure/3118816 Understanding the structure of polyglutamine (polyQ) amyloid-like fibril aggregates is crucial to gaining insights into the etiology of at least ten neurodegenerative disorders, including Huntington’s disease. Here, we determine the structure of D<sub>2</sub>Q<sub>10</sub>K<sub>2</sub> (Q10) fibrils using ultraviolet resonance Raman (UVRR) spectroscopy and molecular dynamics (MD). Using UVRR, we determine the fibril peptide backbone Ψ and glutamine (Gln) side chain χ<sub>3</sub> dihedral angles. We find that most of the fibril peptide bonds adopt antiparallel β-sheet conformations; however, a small population of peptide bonds exist in parallel β-sheet structures. Using MD, we simulate three different potential fibril structural models that consist of either β-strands or β-hairpins. Comparing the experimentally measured Ψ and χ<sub>3</sub> angle distributions to those obtained from the MD simulated models, we conclude that the basic structural motif of Q10 fibrils is an extended β-strand structure. Importantly, we determine from our MD simulations that Q10 fibril antiparallel β-sheets are thermodynamically more stable than parallel β-sheets. This accounts for why polyQ fibrils preferentially adopt antiparallel β-sheet conformations instead of in-register parallel β-sheets like most amyloidogenic peptides. In addition, we directly determine, for the first time, the structures of Gln side chains. Our structural data give new insights into the role that the Gln side chains play in the stabilization of polyQ fibrils. Finally, our work demonstrates the synergistic power and utility of combining UVRR measurements and MD modeling to determine the structure of amyloid-like fibrils.