Self-assembly of amyloid polypeptides (1) imparts biological effects depending on the size in over 20 amyloid diseases and (2) produces useful yet relatively untapped biomaterials. Unfortunately, our understanding of amyloid polypeptides, as related to biomedical implications and biomaterial applications, is limited by their self-assembling nature. In this study, we report the creation of a dual peptide system, where a pair of β-amyloid (Aβ) variants are not self-assembled but hetero-assembled in the presence of their assembly partners. We provide evidence that the resulting hetero-assemblies share molecular, structural and morphological similarities with typical amyloid self-assemblies formed by a single polypeptide (e.g., Aβ). We anticipate that our dual peptide system may readily be adapted for precise control of amyloid assembly, for the study of size-dependent neurotoxicity and precise fabrication of amyloid biomaterials.
Aggregation of β-amyloid (Aβ) is central to the pathogenesis of Alzheimer's disease (AD). Aβ aggregation produces amyloid assemblies, such as oligomers and fibrils. In contrast to non-toxic Aβ monomers, Aβ oligomers and fibrils can act directly as major toxic agents and indirectly as pools of the toxic entities, respectively. Thus, the detection of Aβ aggregates is of diagnostic interest and should benefit enhanced molecular understanding of AD. Among many molecular platforms, peptide-based ligands hold promise as Aβ probes due to their relative simplicity, ease of optimization and facile conjugation to other molecular contexts. In this regard, Aβ hydrophobic segments (critical in Aβ self-assembly) or variants thereof can serve as lead molecules for Aβ probe development. Unfortunately, the resulting peptides are either highly self-aggregation-prone or their probe potential has not been thoroughly examined. In the present study, we characterized a novel peptide ligand, KLVFWAK, which was created by simple point mutations of an Aβ hydrophobic segment ((16)KLVFFAE(22)). We found that KLVFWAK displayed low self-aggregation propensity and was preferentially bound to Aβ oligomers and fibrils relative to Aβ monomers. Interestingly, binding of KLVFWAK to Aβ aggregates occurred at a non-homologous Aβ segment (e.g., Aβ C-terminal domain) rather than the homologous (16)KLVFFAE(22). We also show that detection of Aβ aggregates during incubation of fresh Aβ was possible with KLVFWAK, further supporting KLVFWAK's high probe potential for Aβ aggregates. In short, this study presents creation of a non-self-aggregating peptide ligand for Aβ aggregates through simple point mutation of an Aβ-derived segment.
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