32 research outputs found

    Rationally Designed Cu(I) Ligand to Prevent CuAĪ²-Generated ROS Production in the Alzheimerā€™s Disease Context

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    In the context of Alzheimerā€™s disease, copper (Cu) can be loosely bound to the amyloid-Ī² (AĪ²) peptide, leading to the formation of CuAĪ², which can catalytically generate reactive oxygen species that contribute to oxidative stress. To fight against this phenomenon, the chelation therapy approach has been developed and consists of using a ligand able to remove Cu from AĪ² and to redox-silence it, thus stopping the reactive oxygen species (ROS) production. A large number of Cu(II) chelators has been studied, allowing us to define and refine the properties required to design a ā€œgoodā€ ligand, but without strong therapeutic outcomes to date. Those chelators targeted the Cu(II) redox state. Herein, we explore a parallel and relevant alternative pathway by designing a chelator able to target the Cu(I) redox state. To that end, we designed LH2 ([1N3S] binding set) and demonstrated that (i) it is perfectly able to extract Cu(I) from Cu(I)AĪ² even in the presence of an excess of Zn(II) and (ii) it redox-silences the Cu, preventing the formation of ROS. We showed that LH2 that is sensitive to oxidation can efficiently replace the [Zn(II)L] complex without losing its excellent ability to stop the ROS production while increasing its resistance to oxidation

    Modeling Copper Binding to the Amyloidā€‘Ī² Peptide at Different pH: Toward a Molecular Mechanism for Cu Reduction

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    Oxidative stress, including the production of reactive oxygen species (ROS), has been reported to be a key event in the etiology of Alzheimerā€™s disease (AD). Cu has been found in high concentrations in amyloid plaques, a hallmark of AD, where it is bound to the main constituent amyloid-Ī² (AĪ²) peptide. Whereas it has been proposed that Cu-AĪ² complexes catalyze the production of ROS via redox-cycling between the CuĀ­(I) and CuĀ­(II) state, the redox chemistry of Cu-AĪ² and the precise mechanism of redox reactions are still unclear. Because experiments indicate different coordination environments for CuĀ­(II) and CuĀ­(I), it is expected that the electron is not transferred between Cu-AĪ² and reactants in a straightforward manner but involves structural rearrangement. In this work the structures indicated by experimental data are modeled at the level of modern density-functional theory approximations. Possible pathways for CuĀ­(II) reduction in different coordination sites are investigated by means of first-principles molecular dynamics simulations in the water solvent and at room temperature. The models of the ligand reorganization around Cu allow the proposal of a preferential mechanism for Cu-AĪ² complex reduction at physiological pH. Models reveal that for efficient reduction the deprotonated amide N in the Ala 2-Glu 3 peptide bond has to be protonated and that interactions in the second coordination sphere make important contributions to the reductive pathway, in particular the interaction between COO<sup>ā€“</sup> and NH<sub>2</sub> groups of Asp 1. The proposed mechanism is an important step forward to a clear understanding of the redox chemistry of Cu-AĪ², a difficult task for spectroscopic approaches as the Cu-peptide interactions are weak and dynamical in nature

    Dynamics of Zn<sup>II</sup> Binding as a Key Feature in the Formation of Amyloid Fibrils by AĪ²11-28

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    Supramolecular assembly of peptides and proteins into amyloid fibrils is of multifold interest, going from materials science to physiopathology. The binding of metal ions to amyloidogenic peptides is associated with several amyloid diseases, and amyloids with incorporated metal ions are of interest in nanotechnology. Understanding the mechanisms of amyloid formation and the role of metal ions can improve strategies toward the prevention of this process and enable potential applications in nanotechnology. Here, studies on Zn<sup>II</sup> binding to the amyloidogenic peptide AĪ²11-28 are reported. Zn<sup>II</sup> modulates the AĪ²11-28 aggregation, in terms of kinetics and fibril structures. Structural studies suggest that AĪ²11-28 binds Zn<sup>II</sup> by amino acid residues Glu11 and His14 and that Zn<sup>II</sup> is rapidly exchanged between peptides. Structural and aggregation data indicate that Zn<sup>II</sup> binding induces the formation of the dimeric Zn<sup>II</sup><sub>1</sub>(AĪ²11-28)<sub>2</sub> species, which is the building block of fibrillar aggregates and explains why Zn<sup>II</sup> binding accelerates AĪ²11-28 aggregation. Moreover, transient Zn<sup>II</sup> binding, even briefly, was enough to promote fibril formation, but the final structure resembled that of apo-AĪ²11-28 amyloids. Also, seeding experiments, i.e., the addition of fibrillar Zn<sup>II</sup><sub>1</sub>(AĪ²11-28)<sub>2</sub> to the apo-AĪ²11-28 peptide, induced aggregation but not propagation of the Zn<sup>II</sup><sub>1</sub>(AĪ²11-28)<sub>2</sub>-type fibrils. This can be explained by the dynamic Zn<sup>II</sup> binding between soluble and aggregated AĪ²11-28. As a consequence, dynamic Zn<sup>II</sup> binding has a strong impact on the aggregation behavior of the AĪ²11-28 peptide and might be a relevant and so far little regarded parameter in other systems of metal ions and amyloidogenic peptides

    Identifying, By First-Principles Simulations, Cu[Amyloid-Ī²] Species Making Fenton-Type Reactions in Alzheimerā€™s Disease

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    According to the amyloid cascade hypothesis, amyloid-Ī² peptides (AĪ²) play a causative role in Alzheimerā€™s disease (AD), of which oligomeric forms are proposed to be the most neurotoxic by provoking oxidative stress. Copper ions seem to play an important role as they are bound to AĪ² in amyloid plaques, a hallmark of AD. Moreover, Cuā€“AĪ² complexes are able to catalyze the production of hydrogen peroxide and hydroxyl radicals, and oligomeric Cuā€“AĪ² was reported to be more reactive. The flexibility of the unstructured AĪ² peptide leads to the formation of a multitude of different forms of both CuĀ­(I) and CuĀ­(II) complexes. This raised the question of the structureā€“function relationship. We address this question for the biologically relevant Fenton-type reaction. Computational models for the Cuā€“AĪ² complex in monomeric and dimeric forms were built, and their redox behavior was analyzed together with their reactivity with peroxide. A set of 16 configurations of Cuā€“AĪ² was studied and the configurations were classified into 3 groups: (A) configurations that evolve into a linearly bound and nonreactive CuĀ­(I) coordination; (B) reactive configurations without large reorganization between the two Cu redox states; and (C) reactive configurations with an open structure in the CuĀ­(I)ā€“AĪ² coordination, which have high water accessibility to Cu. All the structures that showed high reactivity with H<sub>2</sub>O<sub>2</sub> (to form HO<sup>ā€¢</sup>) fall into class C. This means that within all the possible configurations, only some pools are able to produce efficiently the deleterious HO<sup>ā€¢</sup>, while the other pools are more inert. The characteristics of highly reactive configurations consist of a Nā€“CuĀ­(I)ā€“N coordination with an angle far from 180Ā° and high water crowding at the open side. This allows the side-on entrance of H<sub>2</sub>O<sub>2</sub> and its cleavage to form a hydroxyl radical. Interestingly, the reactive CuĀ­(I)ā€“AĪ² states originated mostly from the dimeric starting models, in agreement with the higher reactivity of oligomers. Our study gives a rationale for the Fenton-type reactivity of Cuā€“AĪ² and how dimeric Cuā€“AĪ² could lead to a higher reactivity. This opens a new therapeutic angle of attack against Cuā€“AĪ²-based reactive oxygen species production

    Insights into the Mechanisms of Amyloid Formation of Zn<sup>II</sup>-Ab11-28: pH-Dependent Zinc Coordination and Overall Charge as Key Parameters for Kinetics and the Structure of Zn<sup>II</sup>-Ab11-28 Aggregates

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    Self-assembly of amyloidogenic peptides and their metal complexes are of multiple interest including their association with several neurological diseases. Therefore, a better understanding of the role of metal ions in the aggregation process is of broad interest. We report pH-dependent structural and aggregation studies on Zn<sup>II</sup> binding to the amyloidogenic peptide Ab11-28. The results suggest that coordination of the N-terminal amine to Zn<sup>II</sup> is responsible for the inhibition of amyloid formation and the overall charge for amorphous aggregates

    Measurement of Interpeptidic Cu(II) Exchange Rate Constants by Static Fluorescence Quenching of Tryptophan

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    The interpeptidic exchange of CuĀ­(II) between biologically relevant peptides like Gly-His-Lys (GHK) was measured through proximity static fluorescence quenching of a noncoordinating tryptophan residue by CuĀ­(II). The inability to spectrally distinguish between starting and final CuĀ­(H<sub>ā€“1</sub>GHK)<sup>+</sup> complexes by the current methods was solved by the replacement of noncoordinating lysine for tryptophan in the starting complex, CuĀ­(H<sub>ā€“1</sub>GHW). Because the apoGHW is the only fluorescent species, the recovered fluorescence is directly proportional to the [CuĀ­(II)]<sub>exchanged</sub> between GHW and GHK. The apparent second-order rate constants of the exchanges from CuĀ­(H<sub>ā€“1</sub>GHW) to GHK and DAHK are 1.6 (Ā±0.2) Ɨ 10<sup>2</sup> and 5.0 (Ā±0.7) Ɨ 10<sup>1</sup> M<sup>ā€“1</sup> s<sup>ā€“1</sup>, respectively. The easy-to-implement kinetic fluorescent method described here for CuĀ­(II) interpeptidic exchange can be expanded to other biological systems

    Copper Coordination to Native Nā€‘Terminally Modified versus Full-Length Amyloid-Ī²: Second-Sphere Effects Determine the Species Present at Physiological pH

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    Alzheimerā€™s disease is characterized by senile plaques in which metallic ions (copper, zinc, and iron) are colocalized with amyloid-Ī² peptides of different sequences in aggregated forms. In addition to the full-length peptides (AĪ²1-40/42), N-terminally truncated AĪ²3-40/42 forms and their pyroglutamate counterparts, AĪ²p3-40/42, have been proposed to play key features in the aggregation process, leading to the senile plaques. Furthermore, they have been shown to be more toxic than the full-length AĪ², which made them central targets for therapeutic approaches. In order to better disentangle the possible role of metallic ions in the aggregation process, copperĀ­(II) coordination to the full-length amyloid peptides has been extensively studied in the last years. However, regarding the N-terminally modified forms at position 3, very little is known. Therefore, copperĀ­(I) and copperĀ­(II) coordination to those peptides have been investigated in the present report using a variety of complementary techniques and as a function of pH. CopperĀ­(I) coordination is not affected by the N-terminal modifications. In contrast, copperĀ­(II) coordination is different from that previously reported for the full-length peptide. In the case of the pyroglutamate form, this is due to preclusion of N-terminal amine binding. In the case of the N-terminally truncated form, alteration in copperĀ­(II) coordination is caused by second-sphere effects that impact the first binding shell and the pH-dependent repartition of the various [CuĀ­(peptide)] complexes. Such second-sphere effects are anticipated to apply to a variety of metal ions and peptides, and their importance on changing the first binding shell has not been fully recognized yet

    Cu(II) Affinity for the Alzheimerā€™s Peptide: Tyrosine Fluorescence Studies Revisited

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    CopperĀ­(II) binding to the amyloid-Ī² peptide has been proposed to be a key event in the cascade leading to Alzheimerā€™s disease. As a direct consequence, the strength of the CuĀ­(II) to AĪ² interaction, that is, the CuĀ­(II) affinity of AĪ², is a very important parameter to determine. Because AĪ² peptide contain one Tyr fluorophore in its sequence and because CuĀ­(II) does quench Tyr fluorescence, fluorescence measurements appear to be a straightforward way to obtain this parameter. However, this proved to be wrong, mainly because of data misinterpretation in some previous studies that leads to a conflicting situation. In the present paper, we have investigated in details a large set of fluorescence data that were analyzed with a new method taking into account the presence of two CuĀ­(II) sites and the inner-filter effect. This leads to reinterpretation of the published data and to the determination of a unified affinity value in the 10<sup>10</sup> M<sup>ā€“1</sup> range

    pH-Dependent Cu(II) Coordination to Amyloid-Ī² Peptide: Impact of Sequence Alterations, Including the H6R and D7N Familial Mutations.

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    Copper ions have been proposed to intervene in deleterious processes linked to the development of Alzheimerā€™s disease (AD). As a direct consequence, delineating how Cu(II) can be bound to amyloid-Ī² (AĪ²) peptide, the amyloidogenic peptide encountered in AD, is of paramount importance. Two different forms of [Cu<sup>II</sup>(AĪ²)] complexes are present near physiological pH, usually noted components <b>I</b> and <b>II</b>, the nature of which is still widely debated in the literature, especially for <b>II</b>. In the present report, the phenomenological pH-dependent study of Cu(II) coordination to AĪ² and to ten mutants by EPR, CD, and NMR techniques is described. Although only indirect insights can be obtained from the study of Cu(II) binding to mutated peptides, they reveal very useful for better defining Cu(II) coordination sites in the native AĪ² peptide. Four components were identified between pH 6 and 12, namely, components <b>I</b>, <b>II</b>, <b>III</b> and <b>IV</b>, in which the predominant Cu(II) equatorial sites are {āˆ’NH<sub>2</sub>, CO (Asp1ā€“Ala2), N<sub>im</sub> (His6), N<sub>im</sub> (His13 or His14)}, {āˆ’NH<sub>2</sub>, N<sup>ā€“</sup> (Asp1ā€“Ala2), CO (Ala2ā€“Glu3), N<sub>im</sub>}, {āˆ’NH<sub>2</sub>, N<sup>ā€“</sup> (Asp1ā€“Ala2), N<sup>ā€“</sup> (Ala2ā€“Glu3), N<sub>im</sub>} and {āˆ’NH<sub>2</sub>, N<sup>ā€“</sup> (Asp1ā€“Ala2), N<sup>ā€“</sup> (Ala2ā€“Glu3), N<sup>ā€“</sup> (Glu3ā€“Phe4)}, respectively, in line with classical pH-induced deprotonation of the peptide backbone encountered in Cu(II) peptidic complexes formation. The structure proposed for component <b>II</b> is discussed with respect to another coordination model reported in the literature, that is, {CO (Ala2ā€“Glu3), 3 N<sub>im</sub>}. Cu(II) binding to the H6R-AĪ² and D7N-AĪ² peptides, where the familial H6R and D7N mutations have been linked to early onset of AD, has also been investigated. In case of the H6R mutation, some different structural features (compared to those encountered in the native [Cu<sup>II</sup>(AĪ²)] species) have been evidenced and are anticipated to be important for the aggregating properties of the H6R-AĪ² peptide in presence of Cu(II)

    Concept for Simultaneous and Specific in Situ Monitoring of Amyloid Oligomers and Fibrils via FoĢˆrster Resonance Energy Transfer

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    Oligomeric species of amyloidogenic peptides or proteins are often considered as the most toxic species in several amyloid disorders, like Alzheimer or Parkinsonā€™s diseases, and hence came into the focus of research interest and as a therapeutic target. An easy and specific monitoring of oligomeric species would be of high utility in the field, as it is the case for thioflavin T fluorescence for the fibrillar aggregates. Here, we show proof of concept for a new sensitive method to increase specific detection of oligomers by two extrinsic fluorophores. This is achieved by exploiting a FoĢˆrster resonance energy transfer (FRET) between the two fluorophores. Thus, a mixture of two extrinsic fluorophores, bis-ANS and a styrylquinoxalin derivative, enabled one to monitor simultaneously and in situ the presence of oligomers and fibrils of amyloidogenic peptides. Thereby, the formation of oligomers and their transformation into fibrils can be followed
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