Molecular Mechanisms of Alzheimer’s Biomarker FDDNP Binding to Aβ Amyloid Fibril

Parikh, Niyati; Klimov, Dmitri K.

doi:10.1021/acs.jpcb.5b06112

Cited by 14 publications

(16 citation statements)

References 52 publications

(141 reference statements)

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“…The dye Congo red has been used to stain amyloid plaques in tissue for nearly a century, while thioflavin T and thioflavin S have been used for several decades as both probes of amyloid plaques and tools to monitor the aggregation of amyloid-forming proteins into fibrils. − New life has been breathed into these chemical probes through the creative application of their selectivity for amyloid plaques. For example, homologues of Congo red have been used to block amyloid fibril formation, radio-labeled homologues of thioflavin T are currently used in PET imaging diagnostic tests of Alzheimer’s disease, and combinatorial fluorescent molecular sensors based around thioflavin T have enabled differentiation among aggregates of Aβ. − High-resolution structures of fibrils and fibril–dye complexes, coupled with molecular dynamics simulations, have revealed structural bases of this molecular recognition, wherein planar aromatic dyes lie parallel to the fibril axis and pack against hydrophobic residues displayed on the fibril surface. − These structures have guided the design of other small molecules that bind to amyloid fibrils …”

Section: Introductionmentioning

confidence: 99%

Repurposing Triphenylmethane Dyes to Bind to Trimers Derived from Aβ

et al. 2018

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Soluble oligomers of the β-amyloid peptide, Aβ, are associated with the progression of Alzheimer's disease. Although many small molecules bind to these assemblies, the details of how these molecules interact with Aβ oligomers remain unknown. This paper reports that crystal violet, and other C3 symmetric triphenylmethane dyes, bind to C3 symmetric trimers derived from Aβ. Binding changes the color of the dyes from purple to blue, and causes them to fluoresce red when irradiated with green light. Job plot and analytical ultracentrifugation experiments reveal that two trimers complex with one dye molecule. Studies with several triphenylmethane dyes reveal that three N, N-dialkylamino substituents are required for complexation. Several mutant trimers, in which Phe, Phe, and Ile were mutated to cyclohexylalanine, valine, and cyclohexylglycine, were prepared to probe the triphenylmethane dye binding site. Size exclusion chromatography, SDS-PAGE, and X-ray crystallographic studies demonstrate that these mutations do not impact the structure or assembly of the triangular trimer. Fluorescence spectroscopy and analytical ultracentrifugation experiments reveal that the dye packs against an aromatic surface formed by the Phe side chains and is clasped by the Ile side chains. Docking and molecular modeling provide a working model of the complex in which the triphenylmethane dye is sandwiched between two triangular trimers. Collectively, these findings demonstrate that the X-ray crystallographic structures of triangular trimers derived from Aβ can be used to guide the discovery of ligands that bind to soluble oligomers derived from Aβ.

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Section: Introductionmentioning

confidence: 99%

Repurposing Triphenylmethane Dyes to Bind to Trimers Derived from Aβ

et al. 2018

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“…To identify cholesterol binding sites in the Aβ peptide, we applied the method developed previously by our group . Briefly, we define a binding site as a set of Aβ amino acids i that satisfy two conditions.…”

Section: Methodsmentioning

confidence: 99%

Cholesterol Changes the Mechanisms of Aβ Peptide Binding to the DMPC Bilayer

Lockhart

Klimov

2017

J. Chem. Inf. Model.

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Using isobaric-isothermal all-atom replica-exchange molecular dynamics (REMD) simulations, we investigated the equilibrium binding of Aβ10-40 monomers to the zwitterionic dimyristoylphosphatidylcholine (DMPC) bilayer containing cholesterol. Our previous REMD simulations, which studied binding of the same peptide to the cholesterol-free DMPC bilayer, served as a control, against which we measured the impact of cholesterol. Our findings are as follows. First, addition of cholesterol to the DMPC bilayer partially expels the Aβ peptide from the hydrophobic core and promotes its binding to bilayer polar headgroups. Using thermodynamic and energetics analyses, we argued that Aβ partial expulsion is not related to cholesterol-induced changes in lateral pressure within the bilayer but is caused by binding energetics, which favors Aβ binding to the surface of the densely packed cholesterol-rich bilayer. Second, cholesterol has a protective effect on the DMPC bilayer structure against perturbations caused by Aβ binding. More specifically, cholesterol reduces bilayer thinning and overall depletion of bilayer density beneath the Aβ binding footprint. Third, we found that the Aβ peptide contains a single cholesterol binding site, which involves hydrophobic C-terminal amino acids (Ile31-Val36), Phe19, and Phe20 from the central hydrophobic cluster, and cationic Lys28 from the turn region. This binding site accounts for about 76% of all Aβ-cholesterol interactions. Because cholesterol binding site in the Aβ10-40 peptide does not contain the GXXXG motif featured in cholesterol interactions with the transmembrane domain C99 of the β-amyloid precursor protein, we argued that the binding mechanisms for Aβ and C99 are distinct reflecting their different conformations and positions in the lipid bilayer. Fourth, cholesterol sharply reduces the helical propensity in the bound Aβ peptide. As a result, cholesterol largely eliminates the emergence of helical structure observed upon Aβ transition from a water environment to the cholesterol-free DMPC bilayer. We explain this effect by the formation of hydrogen bonds between cholesterol and the Aβ backbone, which prevent helix formation. Taken together, we expect that our simulations will advance understanding of a molecular-level mechanism behind the role of cholesterol in Alzheimer's disease.

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“…However, because the association of such PET tracers to core sites may involve very large time scales, it is difficult to model them using traditional force field-based computational approaches. We recollect that there indeed exist some studies that have focused on the amyloid binding mechanism of various PET tracers using the molecular dynamics approach, but due to the limited time scale, it was only possible to address surface binding sites in these studies. , In an earlier study, the present authors carried out integrated molecular docking and molecular dynamics followed by molecular mechanics generalized Born surface area (MM/GBSA) based free energy calculations, where all possible binding sites (which include two core sites, one entry cleft, and two surface sites) were identified for the THT and AZD-2184 molecules . It was possible to explain the binding profiles for these two molecules, and in addition, larger binding affinity of the latter molecule was explained.…”

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confidence: 99%

The Culprit Is in the Cave: The Core Sites Explain the Binding Profiles of Amyloid-Specific Tracers

Murugan

Halldin

Nordberg

et al. 2016

J. Phys. Chem. Lett.

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The design of molecular probes and tracer molecules with specificity toward amyloid beta (Aβ) fibrils is of paramount importance for the selective diagnosis of Alzheimer's disease. This requires a detailed understanding of the binding sites in amyloid targets, their number, and their binding mechanism for various tracer molecules. We adopt an integrated approach including molecular docking, molecular dynamics, and generalized Born-based free energy calculations to investigate site-specific interactions of different amyloid binding molecules. Our study reproduces the experimental results on the relative binding affinity of the tracers and amyloid binders and explains the feature of "multiple binding sites" in amyloid targets as probed by competition binding experiments. A major outcome of this study is that it is the core sites of the Aβ fibrils that are responsible for the experimentally reported binding profiles of tracers in amyloid targets rather than the surface sites that received much focus in earlier investigations.

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Molecular Mechanisms of Alzheimer’s Biomarker FDDNP Binding to Aβ Amyloid Fibril

Cited by 14 publications

References 52 publications

Repurposing Triphenylmethane Dyes to Bind to Trimers Derived from Aβ

Repurposing Triphenylmethane Dyes to Bind to Trimers Derived from Aβ

Cholesterol Changes the Mechanisms of Aβ Peptide Binding to the DMPC Bilayer

The Culprit Is in the Cave: The Core Sites Explain the Binding Profiles of Amyloid-Specific Tracers

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