Natural oligomers of the amyloid-β protein specifically disrupt cognitive function

Cleary, J.; Walsh, Dominic M.; Hofmeister, J.; Shankar, Ganesh M.; Kuskowski, Michael A.; Selkoe, Dennis J.; Ashe, Karen H.

doi:10.1038/nn1372

Cited by 1,579 publications

(1,378 citation statements)

References 45 publications

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“…The present observations suggest that prefibrillar A␤ 1-40 aggregates are more toxic than the mature fibrils, and have a dose-dependent effect. Our data are consistent with increasing evidence that small soluble oligomers, compared to mature fibrils, are likely the more toxic species of the peptides [10,11,19,35,38,42,69]. The moderate increase in toxicity with the higher amount of A␤ 1-40 mature fibrils is likely to be the result of minute amounts of residual prefibrillar aggregates in cell media, although a specific toxicity of the fibrils cannot be ruled out.…”

Section: Discussionsupporting

confidence: 90%

Increased susceptibility to amyloid toxicity in familial Alzheimer's fibroblasts

Cecchi

Fiorillo

Baglioni

et al. 2007

Neurobiology of Aging

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Much experimental evidence suggests that an imbalance in cellular redox status is a major factor in the pathogenesis of Alzheimer's disease (AD). Our previous data showed a marked increase in membrane lipoperoxidation in primary fibroblasts from familial AD (FAD) patients. In the present study, we demonstrate that when oligomeric structures of A␤ 1-40 and A␤ 1-42 are added to the culture media, they accumulate quicker near the plasma membrane, and are internalized faster and mostly in APPV717I fibroblasts than in age-matched healthy cells; this results in an earlier and sharper increase in the production of reactive oxygen species (ROS). Higher ROS production leads in turn to an increase in membrane oxidative-injury and significant impairment of cellular antioxidant capacity, giving rise to apoptotic cascade activation and finally to a necrotic outcome. In contrast, healthy fibroblasts appear more resistant to amyloid oxidative-attack, possibly as a result of their plasma membrane integrity and powerful antioxidant capacity. Our data are consistent with increasing evidence that prefibrillar aggregates, compared to mature fibrils, are likely the more toxic species of the peptides. These findings provide compelling evidence that cells bearing increased membrane lipoperoxidation are more susceptible to aggregate toxicity as a result of their reduced ability to counteract amyloid oligomeric attack.

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Section: Discussionsupporting

confidence: 90%

Increased susceptibility to amyloid toxicity in familial Alzheimer's fibroblasts

Cecchi

Fiorillo

Baglioni

et al. 2007

Neurobiology of Aging

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“…However, increased Aβ oligomers after hCG treatment may have contributed to spatial memory deficits in rats as high concentrations of Aβ40 and Aβ42, particularly Aβ42, are considered to be neurotoxic and are correlated with cognitive deficits in AD (Naslund et al, 2000). Aβ oligomers are reported to disrupt long term potentiation (LTP) in vitro (Wang et al, 2002(Wang et al, , 2004 and in vivo (Walsh et al, 2002), and, appear to introduce memory impairment in AD mouse models (Cleary et al, 2004). In vitro research indicates that LH may increase Aβ by driving amyloid-β precursor protein (AβPP) processing to the amyoidogenic pathway (Bowen et al, 2004).…”

Section: Discussionmentioning

confidence: 99%

Human chorionic gonadotropin (a luteinizing hormone homologue) decreases spatial memory and increases brain amyloid-β levels in female rats

Berry

Tomidokoro

Ghiso

et al. 2008

Hormones and Behavior

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Numerous studies have suggested that estradiol (E) improves spatial memory as female rats with E perform better than those without E. However there is an inverse relationship between E and luteinizing hormone (LH) levels and LH could play a role. We examined whether treatment with the LH homologue human chorionic gonadotropin (hCG), would impair spatial memory of adult Etreated female rats. In the Object Location Memory Task, ovariectomized (ovxed) rats treated with E and either a single high dose (400IU/kg) or a lower repeated dose of hCG (75 IU/kg hourly for 8 hours) showed spatial memory disruption compared to ovxed rats treated with estradiol alone. Impairment was attributed to memory disruption as performance improved with shortened delay between task exposure and testing. Tests on another spatial memory task, the Barnes maze, confirmed that hCG (400IU/kg) can impair memory: although E + veh treated animals made significantly fewer hole errors across time, E + hCG treated did not. In humans, high LH levels have been correlated with Alzheimer's Disease (AD). Because brain amyloid-beta (Aβ) species have been implicated as a toxic factor thought to cause memory loss in AD, we analyzed whether hCG-treated animals had increased Aβ levels. Levels of Aβ from whole brains or hippocampi were assessed by Western Blot. hCG treatment to E-implanted females significantly increased soluble Aβ40 and Aβ42 levels. These results indicate that high levels of LH/hCG can impair spatial memory, and an increase in brain Aβ species may account for the memory impairment in hCG-treated rats.

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“…A higher molecular weight Aβ oligomer (about 56 kDa) was purified from Tg2576 mice (an APP mutant mouse model of AD) and demonstrated to be toxic [34]. It was then found that naturally secreted oligomers (a mixture of trimers and dimers) can inhibit LTP in vivo [35] and disturb cognitive function in mice [35,36]. The toxic species of these "naturally secreted oligomers" was narrowed down to the "Aβ dimer" (based on its 8-kDa molecular weight), as that "Aβ dimer" isolated from AD brains is capable of impairing memory in mice [37].…”

Section: Challenges In Targeting Amyloidmentioning

confidence: 99%

Biometals and Their Therapeutic Implications in Alzheimer's Disease

2015

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No disease modifying therapy exists for Alzheimer's disease (AD). The growing burden of this disease to our society necessitates continued investment in drug development. Over the last decade, multiple phase 3 clinical trials testing drugs that were designed to target established disease mechanisms of AD have all failed to benefit patients. There is, therefore, a need for new treatment strategies. Changes to the transition metals, zinc, copper, and iron, in AD impact on the molecular mechanisms of disease, and targeting these metals might be an alternative approach to treat the disease. Here we review how metals feature in molecular mechanisms of AD, and we describe preclinical and clinical data that demonstrate the potential for metal-based drug therapy.

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Natural oligomers of the amyloid-β protein specifically disrupt cognitive function

Cited by 1,579 publications

References 45 publications

Increased susceptibility to amyloid toxicity in familial Alzheimer's fibroblasts

Increased susceptibility to amyloid toxicity in familial Alzheimer's fibroblasts

Human chorionic gonadotropin (a luteinizing hormone homologue) decreases spatial memory and increases brain amyloid-β levels in female rats

Biometals and Their Therapeutic Implications in Alzheimer's Disease

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