Mechanism of amyloid plaque formation suggests an intracellular basis of Aβ pathogenicity

166

160

Aggregation of amyloid-␤ (A␤)2 peptides and deposition into neuritic plaques are hallmark features of Alzheimer disease (AD) neuropathology (1, 2). Therefore, research efforts during the past 3 decades have focused on elucidating the mechanisms of A␤ fibrillization, identifying toxic species, and developing strategies to inhibit and/or reverse A␤ amyloid formation and toxicity in vivo (3,4).A␤ peptides are produced as soluble monomers (5, 6) and undergo oligomerization and amyloid fibril formation via a nucleation-dependent polymerization process (7,8). During the course of in vitro A␤ fibril formation, various nonfibrillar aggregation intermediates, collectively called soluble oligomers or protofibrils, have been shown to precede the emergence of fibrils. Increasing evidence from various sources points to A␤ oligomers/protofibrils as putative toxic species in AD pathogenesis and suggests that these species are potential therapeutic targets for treating AD (reviewed in Refs. 9, 10). Although the toxic oligomer hypothesis has emerged as one of the major current working hypotheses in AD research, the development of effective diagnostic tools and therapies on the basis of this hypothesis has yet to be realized (11-13). This is partially due to the fact that identification of a single toxic A␤ species that correlates with AD progression and severity remains elusive. Furthermore, the exact mechanisms by which these species contribute to A␤ toxicity in vivo and the nature of the toxic species are not yet fully understood. Recent evidence suggests that accelerating the process of A␤ fibrillization greatly enhances A␤ toxicity in vitro (14) and the spread of amyloid pathology in vivo (15-17).Despite significant efforts by different groups to isolate specific intermediates along the amyloid formation pathway (12, 18 -22), the inherent heterogeneity of the process and metastable nature of A␤ oligomers (11-13) have precluded the isolation of a single toxic species. Unless covalently crosslinked (23), A␤ oligomers do not exist as stable entities, i.e. they evolve into higher order aggregates and, if they are onpathway intermediates, convert into fibrils (19). Therefore, it is plausible to assume that the structural dynamics of oligomers and factors that govern their interconversion and/or growth might influence some of the disease-related cytotoxic effects of A␤. In other words, an ongoing polymerization

Section: Discussionmentioning

confidence: 62%

Aβ42 Neurotoxicity Is Mediated by Ongoing Nucleated Polymerization Process Rather than by Discrete Aβ42 Species

Jan¹,

Adolfsson

Allaman

et al. 2011

166

160

“…Electron micrographs of a sample of MSP3F on the 1st day showed the presence of homogeneous spherical structures that were similar to the self-assemblies (amylospheroid) and intermediate species formed by A␤-derived diffusible ligands (32,34). At 50 h, these spherical structures were primarily transformed to short fibrillar assemblies resembling intermediate species formed during amyloidogenesis of A␤ peptide (35), whereas at 72 h clear amyloid fibrils were noticeable along with few amorphous aggregates. The role of amorphous aggregates has been studied in detail in a kinetic study of a prion protein-based peptide in which the aggregates were shown to have a dual role for releasing monomeric species as well as to act as a site for initiation of amyloid growth (36).…”

Section: Discussionmentioning

confidence: 94%

Plasmodium falciparum Merozoite Surface Protein 3

Imam

Singh

Kaushik

et al. 2014

Background: Plasmodium falciparum merozoite surface protein 3 (MSP3) oligomerizes and binds heme. Results: MSP3 forms amyloid-like structures that bind ϳ35 heme molecules, and these filamentous structures are also present on the surface of merozoites. Conclusion: Amyloid formation by MSP3 is related to heme binding. Significance: The presence of MSP3 fibrils on merozoite surface and significant heme binding suggest its functional role during erythrocytic stages of P. falciparum.

“…The aggregation of ␤-amyloid (A␤) peptide as extracellular amyloid deposits on the cholesterol-rich regions of neuronal membrane is the primary feature of AD (1,2). Recent evidences showed that A␤ peptide is generated extracellularly and intracellularly by the enzymatic breakdown of the amyloid precursor protein by ␤-and ␥-secretases.…”

mentioning

confidence: 99%

Factor V Activator from Daboia russelli russelli Venom Destabilizes β-Amyloid Aggregate, the Hallmark of Alzheimer Disease

Bhattacharjee

Bhattacharyya

2013

Background: ␤-Amyloid aggregate formation and its destabilization are addressed in Alzheimer disease. Results: Peptides synthesized using Russell's viper venom factor V activator as a template can destabilize ␤-amyloid fibril and inhibit cytotoxicity. Conclusion: These peptides dissociate ␤-amyloid fibrils to the nontoxic monomeric state. Significance: This study explores possibility of designed peptides for clinical applications in Alzheimer disease.