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Molecular dynamics simulation of aluminium binding to amyloid-? and its effect on peptide structure.


ABSTRACT: Multiple microsecond-length molecular dynamics simulations of complexes of Al(III) with amyloid-? (A?) peptides of varying length are reported, employing a non-bonded model of Al-coordination to the peptide, which is modelled using the AMBER ff14SB forcefield. Individual simulations reach equilibrium within 100 to 400 ns, as determined by root mean square deviations, leading to between 2.1 and 2.7 ?s of equilibrated data. These reveal a compact set of configurations, with radius of gyration similar to that of the metal free peptide but larger than complexes with Cu, Fe and Zn. Strong coordination through acidic residues Glu3, Asp7 and Glu11 is maintained throughout all trajectories, leading to average coordination numbers of approximately 4 to 5. Helical conformations predominate, particularly in the longer Al-A?40 and Al-A?42 peptides, while ?-strand forms are rare. Binding of the small, highly charged Al(III) ion to acidic residues in the N-terminus strongly disrupts their ability to engage in salt bridges, whereas residues outside the metal binding region engage in salt bridges to similar extent to the metal-free peptide, including the Asp23-Lys28 bridge known to be important for formation of fibrils. High helical content and disruption of salt bridges leads to characteristic tertiary structure, as shown by heat maps of contact between residues as well as representative clusters of trajectories.

SUBMITTER: Turner M 

PROVIDER: S-EPMC6559712 | biostudies-literature | 2019

REPOSITORIES: biostudies-literature

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Molecular dynamics simulation of aluminium binding to amyloid-β and its effect on peptide structure.

Turner Matthew M   Mutter Shaun T ST   Kennedy-Britten Oliver D OD   Platts James A JA  

PloS one 20190611 6


Multiple microsecond-length molecular dynamics simulations of complexes of Al(III) with amyloid-β (Aβ) peptides of varying length are reported, employing a non-bonded model of Al-coordination to the peptide, which is modelled using the AMBER ff14SB forcefield. Individual simulations reach equilibrium within 100 to 400 ns, as determined by root mean square deviations, leading to between 2.1 and 2.7 μs of equilibrated data. These reveal a compact set of configurations, with radius of gyration simi  ...[more]

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