Divalent copper ion bound amyloid-β(40) and amyloid-β(42) alloforms are less preferred than divalent zinc ion bound amyloid-β(40) and amyloid-β(42) alloforms

Divalent copper and zinc ions bind to the amyloid-β(40) and amyloid-β(42) alloforms and affect their structural stability as well as their chemical and physical properties. Current literature debates the impact of copper ions on amyloid-β alloforms. Recently, we reported the structural and thermodynamic properties of apo amyloid-β and divalent zinc ion bound amyloid-β alloforms (see, Wise-Scira et al. in J Biol Inorg Chem 17:927–938, 2012 and Coskuner et al. in ACS Chem Neurosci 4: 310–320, 2013). In our search for understanding the impacts of transition metal ions on disordered amyloid-β, we also developed and reported new potential functions using quantum mechanics, which are required for high-quality molecular dynamics simulations of divalent copper ion bound amyloid-β alloforms (see, Wise and Coskuner in J Comput Chem 35:1278–1289, 2014). The structures and thermodynamic properties of the divalent copper ion bound amyloid-β(40) and amyloid-β(42) alloforms in an aqueous medium are studied. The secondary and tertiary structures of divalent copper ion bound amyloid-β(40) and amyloid-β(42) along with their thermodynamic properties including enthalpy, entropy, Gibbs free energy and potential of mean force surface are investigated. Results are compared to those for apo amyloid-β and divalent zinc ion bound amyloid-β alloforms. Results demonstrate that copper binding to Aβ alloforms is thermodynamically less preferred rather than zinc binding. Less compact structures of copper ion bound amyloid-β alloforms possess reduced stability in comparison to zinc ion bound amyloid-β alloforms. Cu(II) binding impacts the thermodynamic properties, secondary and tertiary structural properties of Aβ40 and Aβ42.