Amyloid aggregation inhibitory mechanism of arginine-rich D-peptides.

It is widely believed that Alzheimer's disease pathogenesis is driven by the production and deposition of the amyloid-ß peptide (Aß) in the brain. In this study, we employ a combination of in silico and in vitro approaches to investigate the inhibitory properties of selected arginine-rich D-enantiomeric peptides (D-peptides) against amyloid aggregation. The D-peptides include D3, a 12-residue peptide with anti-amyloid potencies demonstrated in vitro and in vivo, RD2, a scrambled sequence of D3, as well as truncated RD2 variants. Using a global optimization method together with binding free energy calculations followed by molecular dynamics simulations, we perform a detailed analysis of D-peptide binding to Aß monomer and a fibrillar Aß structure. Results obtained from both molecular simulations and surface plasmon resonance experiments reveal a strong binding of D3 and RD2 to Aß, leading to a significant reduction in the amount of ß structures in both monomer and fibril, which was also demonstrated in Thioflavin T assays. The binding of the D-peptides to Aß is driven by electrostatic interactions, mostly involving the D-arginine residues and Glu11, Glu22 and Asp23 of Aß. Furthermore, we show that the anti-amyloid activities of the D-peptides depend on the length and sequence of the Dpeptide, its ability to form multiple weak hydrophobic interactions with Aß, as well as the Aß oligomer size.

Inhibition of cytotoxicity and amyloid fibril formation by a D-amino acid peptide that specifically binds to Alzheimer's disease amyloid peptide.

Alzheimer's disease (AD) is a progressive neurodegenerative disorder. The 'amyloid cascade hypothesis' assigns the amyloid-beta-peptide (Abeta) a central role in the pathogenesis of AD. Although it is not yet established, whether the resulting Abeta aggregates are the causative agent or just a result of the disease progression, polymerization of Abeta has been identified as a major feature during AD pathogenesis. Inhibition of the Abeta polymer formation, thus, has emerged as a potential therapeutic approach. In this context, we identified peptides consisting of d-enantiomeric amino acid peptides (d-peptides) that bind to Abeta. D-peptides are known to be more protease resistant and less immunogenic than the respective L-enantiomers. Previously, we have shown that a 12mer D-peptide specifically binds to Abeta amyloid plaques in brain tissue sections from former AD patients. In vitro obtained binding affinities to synthetic Abeta revealed a K(d) value in the submicromolar range. The aim of the present study was to investigate the influence of this d-peptide to Abeta polymerization and toxicity. Using cell toxicity assays, thioflavin fluorescence, fluorescence correlation spectroscopy and electron microscopy, we found a significant effect of the d-peptide on both. Presence of D-peptides (dpep) reduces the average size of Abeta aggregates, but increases their number. In addition, Abeta cytotoxicity on PC12 cells is reduced in the presence of dpep.

The structural transition of the prion protein into its pathogenic conformation is induced by unmasking hydrophobic sites.

A series of structural intermediates in the putative pathway from the cellular prion protein PrP(C) to the pathogenic form PrP(Sc) was established by systematic variation of low concentrations (<0.1%) of the detergent sodium dodecyl sulfate (SDS) or by the interaction with the bacterial chaperonin GroEL. Most extended studies were carried out with recombinant PrP (90-231) corresponding to the amino acid sequence of hamster prions PrP 27-30. Similar results were obtained with full-length recombinant PrP, hamster PrP 27-30 and PrP(C) isolated from transgenic, non-infected CHO cells. Varying the incubation conditions, i.e. the concentration of SDS, the GroEL and GroEL/ES, but always at neutral pH and room temperature, different conformations could be established. The conformations were characterized with respect to secondary structure as determined by CD spectroscopy and to molecular mass, as determined by fluorescence correlation spectroscopy and analytical ultracentrifugation: alpha-helical monomers, soluble alpha-helical dimers, soluble but beta-structured oligomers of a minimal size of 12-14 PrP molecules, and insoluble multimers were observed. A high activation barrier was found between the alpha-helical dimers and beta-structured oligomers. The numbers of SDS-molecules bound to PrP in different conformations were determined: Partially denatured, alpha-helical monomers bind 31 SDS molecules per PrP molecule, alpha-helical dimers 21, beta-structured oligomers 19-20, and beta-structured multimers show very strong binding of five SDS molecules per PrP molecule. Binding of only five molecules of SDS per molecule of PrP leads to fast formation of beta-structures followed by irreversible aggregation. It is discussed that strongest binding of SDS has an effect identical with or similar to the interaction with GroEL thereby inducing identical or very similar transitions. The interaction with GroEL/ES stabilizes the soluble, alpha-helical conformation. The structure and their stabilities and particularly the induction of transitions by interaction of hydrophobic sites of PrP are discussed in respect to their biological relevance.