Zinc
binding to β-amyloid structure could promote amyloid-β
aggregation, as well as reactive oxygen species (ROS) production,
as suggested in many experimental and theoretical studies. Therefore,
the introduction of multifunctional drugs capable of chelating zinc
metal ion and inhibiting Aβ aggregation is a promising strategy
in the development of AD treatment. The present study has evaluated
the efficacy of a new bifunctional peptide drug using molecular docking
and molecular dynamics (MD) simulations. This drug comprises two different
domains, an inhibitor domain, obtained from the C-terminal hydrophobic
region of Aβ, and a Zn2+ chelating domain, derived
from rapeseed meal, merge with a linker. The multifunctionality of
the ligand was evaluated using a comprehensive set of MD simulations
spanning up to 3.2 μs including Aβ relaxation, ligand–Zn2+ bilateral interaction, and, more importantly, ligand–Zn2+–Aβ42 trilateral interactions. Analysis
of the results strongly indicated that the bifunctional ligand can
chelate zinc metal ion and avoid Aβ aggregation simultaneously.
The present study illustrated that the proposed ligand has considerable
hydrophobic interactions and hydrogen bonding with monomeric Aβ
in the presence of zinc metal ion. Therefore, in light of these considerable
interactions and contacts, the α-helical structure of Aβ
has been enhanced, while the β-sheet formation is prevented
and the α-helix native structure is protected. Furthermore,
the analysis of interactions between Aβ and ligand–zinc
complex revealed that the zinc metal ion is coordinated to Met13,
the ending residue of the ligand and merely one residue in Aβ.
The results have proven the previous experimental and theoretical
findings in the literature about Aβ interactions with zinc metal
ion and also Aβ interactions with the first domain of the proposed
ligand. Moreover, the current research has evaluated the chelation
using MD simulation and linear interaction energy (LIE) methods, and
the result has been satisfactorily verified with previous experimental
and theoretical (DFT) studies.
The high concentration of zinc metal ions in Aβ aggregations is one of the most cited hallmarks of Alzheimer's disease (AD), and several substantial pieces of evidence emphasize the key role of zinc metal ions in the pathogenesis of AD. In this study, while designing a multifunctional peptide for simultaneous targeting Aβ aggregation and chelating the zinc metal ion, a novel and comprehensive approach is introduced for evaluating the multifunctionality of a multifunctional drugs based on computational methods. The multifunctional peptide consists of inhibitor and chelator domains, which are included in the C-terminal hydrophobic region of Aβ, and the first four amino acids of human albumin. The ability of the multifunctional peptide in zinc ion chelation has been investigated using molecular dynamics (MD) simulations of the peptide−zinc interaction for 300 ns, and Bennett's acceptance ratio (BAR) method has been used to accurately calculate the chelation free energy. Data analysis demonstrates that the peptide chelating domain can be stably linked to the zinc ion. Besides, the introduced method used for evaluating chelation and calculating the free energy of peptide binding to zinc ions was successfully validated by comparison with previous experimental and theoretical published data. The results indicate that the multifunctional peptide, coordinating with the zinc metal ion, can be effective in Aβ inhibition by preserving the native helical structure of the Aβ 42 monomer as well as disrupting the β-sheet structure of Aβ 42 aggregates. Detailed assessments of the Aβ 42 −peptide interactions elucidate that the inhibition of Aβ is achieved by considerable hydrophobic interactions and hydrogen bonding between the multifunctional peptide and the hydrophobic Aβ regions, along with interfering in stable bridges formed inside the Aβ aggregate.
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