Substoichiometric Levels of Cu2+ Ions Accelerate the Kinetics of Fiber Formation and Promote Cell Toxicity of Amyloid-β from Alzheimer Disease

Sarell, Claire J.; Wilkinson, Shane R.; Viles, John H.

doi:10.1074/jbc.m110.171355

Cited by 181 publications

(235 citation statements)

References 66 publications

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“…Thus, compounds that can modulate or shift the equilibrium of the A␤-Cu(II) complex to a less stable conformation or toward a non-toxic aggregated state could be a new therapeutic strategy for treating AD. Here it should be mentioned that a recent study showed, contrary to the previous reports, that it is the substoichiometric Cu(II) concentrations that are most cytotoxic, whereas an equimolar Cu(II) concentration does not increase A␤ cytotoxicity, and supra-stoichiometric Cu(II) concentrations reduce cytotoxicity (24).…”

Section: Aβ Monomercontrasting

confidence: 47%

“…In all events elucidating the underlying molecular mechanisms of the A␤-Cu, interactions are vital for understanding the role of Cu(II) in the pathology of AD, and hence in developing new therapeutic strategies for the treatment of AD (7,22). Despite extensive studies, however, these mechanisms remain largely unsettled and conflicting effects have been reported; in some studies Cu(II) appears to be involved in amyloid oligomerization (4,23,24), other studies report that Cu(II) does enhance aggregation but only along non-amyloidogenic pathways (17,25), or even that Cu(II) inhibits the aggregation of A␤ (26). We recently showed that Cu(II) could induce both oligomerization and non-oligomerization pathways of A␤ on the millisecond-second time scale (27).…”

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confidence: 99%

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Cu(II) Mediates Kinetically Distinct, Non-amyloidogenic Aggregation of Amyloid-β Peptides

Pedersen

Østergaard

Rozlosnik

et al. 2011

Journal of Biological Chemistry

118

160

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Cu(II) ions are implicated in the pathogenesis of Alzheimer disease by influencing the aggregation of the amyloid-␤ (A␤)peptide. Elucidating the underlying Cu(II)-induced A␤ aggregation is paramount for understanding the role of Cu(II) in the pathology of Alzheimer disease. The aim of this study was to characterize the qualitative and quantitative influence of Cu(II) on the extracellular aggregation mechanism and aggregate morphology of A␤ 1-40 using spectroscopic, microelectrophoretic, mass spectrometric, and ultrastructural techniques. We found that the Cu(II):A␤ ratio in solution has a major influence on (i) the aggregation kinetics/mechanism of A␤, because three different kinetic scenarios were observed depending on the Cu(II):A␤ ratio, (ii) the metal:peptide stoichiometry in the aggregates, which increased to 1.4 at supra-equimolar Cu(II):A␤ ratio; and (iii) the morphology of the aggregates, which shifted from fibrillar to non-fibrillar at increasing Cu(II):A␤ ratios. We observed dynamic morphological changes of the aggregates, and that the formation of spherical aggregates appeared to be a common morphological end point independent on the Cu(II) concentration. Experiments with A␤ 1-42 were compatible with the conclusions for A␤ 1-40 even though the low solubility of A␤ 1-42 precluded examination under the same conditions as for the A␤ 1-40 . Experiments with A␤ 1-16 and A␤ 1-28 showed that other parts than the Cu(II)-binding His residues were important for Cu(II)-induced A␤ aggregation. Based on this study we propose three mechanistic models for the Cu(II)-induced aggregation of A␤ 1-40 depending on the Cu(II):A␤ ratio, and identify key reaction steps that may be feasible targets for preventing Cu(II)-associated aggregation or toxicity in Alzheimer disease.Extracellular cerebral plaques composed mainly of amyloid ␤-peptide (A␤) 1-40 and 1-42 fibrils are a histopathological hallmark of Alzheimer disease (AD) 3 (1, 2). These plaques contain elevated levels of metals, in particular zinc and copper (3). Also, it has been shown that these metal ions can promote the aggregation of A␤ in vitro (4, 5). This implies a key role of the metal ions in the A␤-mediated pathology of AD (6), although the subject is still under much debate (7,8), and a role of amyloid-independent pathways in AD neurodegeneration have recently been reviewed (9).Specifically regarding the role of metal ions in the amyloidmediated pathology of AD, it is believed that Zn(II) acts as a neuroprotector (10, 11), whereas Cu(II) is considered to mediate neurotoxicity (12)(13)(14). The latter effect is thought to occur through early stage soluble A␤ and A␤-Cu oligomeric intermediates (15-18) that may be involved in the formation of reactive oxygen species (6). It was discovered that Cu(II) may be released postsynaptically at glutamatergic synapses in hippocampus (19,20), the site for initial A␤ deposition in AD. This provides an explanation for how Cu(II) can interact with A␤. Seemingly in contrast to the support for the neurotoxic effects of Cu(II),...

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Section: Aβ Monomercontrasting

confidence: 47%

mentioning

confidence: 99%

Cu(II) Mediates Kinetically Distinct, Non-amyloidogenic Aggregation of Amyloid-β Peptides

Pedersen

Østergaard

Rozlosnik

et al. 2011

Journal of Biological Chemistry

118

160

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“…A␤ forms fibers much faster than A␤ and is also more toxic in vivo (61)(62)(63)(64). The heightened rate of fiber nucleation and elongation observed for A␤ (11-40/42) may be caused by the loss of negatively charged side chains, as it is known that the pI and charge of A␤ have a profound influence on its rate of fiber formation (22,65). The absence of a number of charged residues at the N terminus increases the theoretical pI from 5.1 for A␤ (1-40/42) to 6.0 for A␤ (11-40/42) .…”

Section: Discussionmentioning

confidence: 99%

Truncated Amyloid-β(11–40/42) from Alzheimer Disease Binds Cu2+ with a Femtomolar Affinity and Influences Fiber Assembly

Barritt

Viles

2015

Journal of Biological Chemistry

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Background: N-terminally truncated A␤ (11-40/42) typically constitutes 19% of plaque load in Alzheimer patients. Results: Cu 2ϩ binds to A␤ with a 34-fM dissociation constant and stabilizes very short highly amyloidogenic amyloid rods into longer A␤ fibers. Concussion: The very tight affinity explains the high levels of Cu 2ϩ in amyloid plaques. Significance: Copper, tightly bound to A␤ (11-40/42) , may influence disease pathology.

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“…Albumin is also responsible for the transport of the labile pool of Cu 2ϩ ions in blood plasma (21). Of note, the A␤-Cu 2ϩ interaction and its role in AD have received significant interest (22)(23)(24), and Cu 2ϩ may be transferred from A␤ to HSA (25), meaning that albumin could have two mechanisms by which it inhibits fiber formation.…”

Section: Discussionmentioning

confidence: 99%

Human Serum Albumin Can Regulate Amyloid-β Peptide Fiber Growth in the Brain Interstitium

Stanyon

Viles

2012

Journal of Biological Chemistry

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143

124

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Substoichiometric Levels of Cu2+ Ions Accelerate the Kinetics of Fiber Formation and Promote Cell Toxicity of Amyloid-β from Alzheimer Disease

Cited by 181 publications

References 66 publications

Cu(II) Mediates Kinetically Distinct, Non-amyloidogenic Aggregation of Amyloid-β Peptides

Cu(II) Mediates Kinetically Distinct, Non-amyloidogenic Aggregation of Amyloid-β Peptides

Truncated Amyloid-β(11–40/42) from Alzheimer Disease Binds Cu2+ with a Femtomolar Affinity and Influences Fiber Assembly

Human Serum Albumin Can Regulate Amyloid-β Peptide Fiber Growth in the Brain Interstitium

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