Huiyuan Li

C-terminal peptides coassemble into Aβ42 oligomers and protect neurons against Aβ42-induced neurotoxicity

Alzheimers disease (AD) is an age-related disorder that threatens to become an epidemic as the world population ages. Neurotoxic oligomers of Aβ42 are believed to be the main cause of AD; therefore, disruption of Aβ oligomerization is a promising approach for developing therapeutics for AD. Formation of Aβ42 oligomers is mediated by intermolecular interactions in which the C terminus plays a central role. We hypothesized that peptides derived from the C terminus of Aβ42 may get incorporated into oligomers of Aβ42, disrupt their structure, and thereby inhibit their toxicity. We tested this hypothesis using Aβ fragments with the general formula Aβ(x−42) (x = 28–39). A cell viability screen identified Aβ(31–42) as the most potent inhibitor. In addition, the shortest peptide, Aβ(39–42), also had high activity. Both Aβ(31–42) and Aβ(39–42) inhibited Aβ-induced cell death and rescued disruption of synaptic activity by Aβ42 oligomers at micromolar concentrations. Biophysical characterization indicated that the action of these peptides likely involved stabilization of Aβ42 in nontoxic oligomers. Computer simulations suggested a mechanism by which the fragments coassembled with Aβ42 to form heterooligomers. Thus, Aβ(31–42) and Aβ(39–42) are leads for obtaining mechanism-based drugs for treatment of AD using a systematic structure–activity approach.

Aβ(39-42) modulates Aβ oligomerization but not fibril formation.

Recently, certain C-terminal fragments (CTFs) of Aβ42 have been shown to be effective inhibitors of Aβ42 toxicity. Here, we examine the interactions between the shortest CTF in the original series, Aβ(39-42), and full-length Aβ. Mass spectrometry results indicate that Aβ(39-42) binds directly to Aβ monomers and to the n = 2, 4, and 6 oligomers. The Aβ42:Aβ(39-42) complex is further probed using molecular dynamics simulations. Although the CTF was expected to bind to the hydrophobic C-terminus of Aβ42, the simulations show that Aβ(39-42) binds at several locations on Aβ42, including the C-terminus, other hydrophobic regions, and preferentially in the N-terminus. Ion mobility-mass spectrometry (IM-MS) and electron microscopy experiments indicate that Aβ(39-42) disrupts the early assembly of full-length Aβ. Specifically, the ion-mobility results show that Aβ(39-42) prevents the formation of large decamer/dodecamer Aβ42 species and, moreover, can remove these structures from solution. At the same time, thioflavin T fluorescence and electron microscopy results show that the CTF does not inhibit fibril formation, lending strong support to the hypothesis that oligomers and not amyloid fibrils are the Aβ form responsible for toxicity. The results emphasize the role of small, soluble assemblies in Aβ-induced toxicity and suggest that Aβ(39-42) inhibits Aβ-induced toxicity by a unique mechanism, modulating early assembly into nontoxic hetero-oligomers, without preventing fibril formation.

Structural Basis for Aβ1–42 Toxicity Inhibition by Aβ C-Terminal Fragments: Discrete Molecular Dynamics Study

Amyloid β-protein (Aβ) is central to the pathology of Alzheimers disease. Of the two predominant Aβ alloforms, Aβ(1-40) and Aβ(1-42), the latter forms more toxic oligomers. C-terminal fragments (CTFs) of Aβ were recently shown to inhibit Aβ(1-42) toxicity in vitro. Here, we studied Aβ(1-42) assembly in the presence of three effective CTF inhibitors and an ineffective fragment, Aβ(21-30). Using a discrete molecular dynamics approach that recently was shown to capture key differences between Aβ(1-40) and Aβ(1-42) oligomerization, we compared Aβ(1-42) oligomer formation in the absence and presence of CTFs or Aβ(21-30) and identified structural elements of Aβ(1-42) that correlated with Aβ(1-42) toxicity. CTFs co-assembled with Aβ(1-42) into large heterooligomers containing multiple Aβ(1-42) and inhibitor fragments. In contrast, Aβ(21-30) co-assembled with Aβ(1-42) into heterooligomers containing mostly a single Aβ(1-42) and multiple Aβ(21-30) fragments. The CTFs, but not Aβ(21-30), decreased the β-strand propensity of Aβ(1-42) in a concentration-dependent manner. CTFs and Aβ(21-30) had a high binding propensity to the hydrophobic regions of Aβ(1-42), but only CTFs were found to bind the Aβ(1-42) region A2-F4. Consequently, only CTFs but not Aβ(21-30) reduced the solvent accessibility of Aβ(1-42) in region D1-R5. The reduced solvent accessibility of Aβ(1-42) in the presence of CTFs was comparable to the solvent accessibility of Aβ(1-40) oligomers formed in the absence of Aβ fragments. These findings suggest that region D1-R5, which was more exposed to the solvent in Aβ(1-42) than in Aβ(1-40) oligomers, is involved in mediating Aβ(1-42) oligomer neurotoxicity.

Biophysical Characterization of Aβ42 C-Terminal Fragments: Inhibitors of Aβ42 Neurotoxicity

A key event in Alzheimers disease (AD) is age-dependent, brain accumulation of amyloid beta-protein (Abeta) leading to Abeta self-association into neurotoxic oligomers. Previously, we showed that Abeta oligomerization and neurotoxicity could be inhibited by C-terminal fragments (CTFs) of Abeta42. Because these CTFs are highly hydrophobic, we asked if they themselves aggregated and, if so, what parameters regulated their aggregation. To answer these questions, we investigated the dependence of CTF aqueous solubility, aggregation kinetics, and morphology on peptide length and sequence and the correlation between these characteristics and inhibition of Abeta42-induced toxicity. We found that CTFs up to 8 residues long were soluble at concentrations >100 microM and had a low propensity to aggregate. Longer CTFs were soluble at approximately 1-80 microM, and most, but not all, readily formed beta-sheet-rich fibrils. Comparison to Abeta40-derived CTFs showed that the C-terminal dipeptide I41-A42 strongly promoted aggregation. Aggregation propensity correlated with the previously reported tendency to form beta-hairpin conformation but not with inhibition of Abeta42-induced neurotoxicity. The data enhance our understanding of the physical characteristics that affect CTF activity and advance our ability to design, synthesize, and test future generations of inhibitors.

Mechanistic Investigation of the Inhibition of Aβ42 Assembly and Neurotoxicity by Aβ42 C-Terminal Fragments

Oligomeric forms of amyloid beta-protein (Abeta) are key neurotoxins in Alzheimers disease (AD). Previously, we found that C-terminal fragments (CTFs) of Abeta42 interfered with assembly of full-length Abeta42 and inhibited Abeta42-induced toxicity. To decipher the mechanism(s) by which CTFs affect Abeta42 assembly and neurotoxicity, here, we investigated the interaction between Abeta42 and CTFs using photoinduced cross-linking and dynamic light scattering. The results demonstrate that distinct parameters control CTF inhibition of Abeta42 assembly and Abeta42-induced toxicity. Inhibition of Abeta42-induced toxicity was found to correlate with stabilization of oligomers with a hydrodynamic radius (R(H)) of 8-12 nm and attenuation of formation of oligomers with an R(H) of 20-60 nm. In contrast, inhibition of Abeta42 paranucleus formation correlated with CTF solubility and the degree to which CTFs formed amyloid fibrils themselves but did not correlate with inhibition of Abeta42-induced toxicity. Our findings provide important insight into the mechanisms by which different CTFs inhibit the toxic effect of Abeta42 and suggest that stabilization of nontoxic Abeta42 oligomers is a promising strategy for designing inhibitors of Abeta42 neurotoxicity.

Zn2+-Aβ40 Complexes Form Metastable Quasi-spherical Oligomers That Are Cytotoxic to Cultured Hippocampal Neurons

Background: The mechanism by which interaction between Aβ and Zn2+ induces Aβ aggregation and cell toxicity is elusive. Results: Zn2+ and Aβ40 form metastable neurotoxic oligomers. Conclusion: Aβ40 binding to Zn2+ leads to formation of small neurotoxic oligomers that become benign upon further self-assembly. Significance: We provide a structure-function analysis of Zn2+-stabilized Aβ40, a neurotoxic species that may contribute to the pathology in AD. The roles of metal ions in promoting amyloid β-protein (Aβ) oligomerization associated with Alzheimer disease are increasingly recognized. However, the detailed structures dictating toxicity remain elusive for Aβ oligomers stabilized by metal ions. Here, we show that small Zn2+-bound Aβ1–40 (Zn2+-Aβ40) oligomers formed in cell culture medium exhibit quasi-spherical structures similar to native amylospheroids isolated recently from Alzheimer disease patients. These quasi-spherical Zn2+-Aβ40 oligomers irreversibly inhibit spontaneous neuronal activity and cause massive cell death in primary hippocampal neurons. Spectroscopic and x-ray diffraction structural analyses indicate that despite their non-fibrillar morphology, the metastable Zn2+-Aβ40 oligomers are rich in β-sheet and cross-β structures. Thus, Zn2+ promotes Aβ40 neurotoxicity by structural organization mechanisms mediated by coordination chemistry.

Mechanism of C-Terminal Fragments of Amyloid β-Protein as Aβ Inhibitors: Do C-Terminal Interactions Play a Key Role in Their Inhibitory Activity?

Targeting the early oligomerization of amyloid β protein (Aβ) is a promising therapeutic strategy for Alzheimers disease (AD). Recently, certain C-terminal fragments (CTFs) derived from Aβ42 were shown to be potent inhibitors of Aβ-induced toxicity. The shortest peptide studied, Aβ(39-42), has been shown to modulate Aβ oligomerization and inhibit Aβ toxicity. Understanding the mechanism of these CTFs, especially Aβ(39-42), is of significance for future therapeutic development of AD and peptidomimetic-based drug development. Here we used ion mobility spectrometry-mass spectrometry to investigate the interactions between two modified Aβ(39-42) derivatives, VVIA-NH2 and Ac-VVIA, and full-length Aβ42. VVIA-NH2 was previously shown to inhibit Aβ toxicity, whereas Ac-VVIA did not. Our mass spectrometry analysis revealed that VVIA-NH2 binds directly to Aβ42 monomer and small oligomers while Ac-VVIA binds only to Aβ42 monomer. Ion mobility studies showed that VVIA-NH2 modulates Aβ42 oligomerization by not only inhibiting the dodecamer formation but also disaggregating preformed Aβ42 dodecamer. Ac-VVIA also inhibits and removes preformed Aβ42 dodecamer. However, the Aβ42 sample with the addition of Ac-VVIA clogged the nanospray tip easily, indicating that larger aggregates are formed in the solution in the presence of Ac-VVIA. Molecular dynamics simulations suggested that VVIA-NH2 binds specifically to the C-terminal region of Aβ42 while Ac-VVIA binds dispersedly to multiple regions of Aβ42. This work implies that C-terminal interactions and binding to Aβ oligomers are important for C-terminal fragment inhibitors.

C-Terminal Tetrapeptides Inhibit Aβ42-Induced Neurotoxicity Primarily through Specific Interaction at the N-Terminus of Aβ42

Inhibition of amyloid β-protein (Aβ)-induced toxicity is a promising therapeutic strategy for Alzheimers disease (AD). Previously, we reported that the C-terminal tetrapeptide Aβ(39-42) is a potent inhibitor of neurotoxicity caused by Aβ42, the form of Aβ most closely associated with AD. Here, initial structure-activity relationship studies identified key structural requirements, including chirality, side-chain structure, and a free N-terminus, which control Aβ(39-42) inhibitory activity. To elucidate the binding site(s) of Aβ(39-42) on Aβ42, we used intrinsic tyrosine (Y) fluorescence and solution-state NMR. The data suggest that Aβ(39-42) binds at several sites, of which the predominant one is located in the N-terminus of Aβ42, in agreement with recent modeling predictions. Thus, despite the small size of Aβ(39-42) and the hydrophobic, aliphatic nature of all four side-chains, the interaction of Aβ(39-42) with Aβ42 is controlled by specific intermolecular contacts requiring a combination of hydrophobic and electrostatic interactions and a particular stereochemistry.

Modulation of Amyloid β-Protein (Aβ) Assembly by Homologous C-Terminal Fragments as a Strategy for Inhibiting Aβ Toxicity

Self-assembly of amyloid β-protein (Aβ) into neurotoxic oligomers and fibrillar aggregates is a key process thought to be the proximal event leading to development of Alzheimers disease (AD). Therefore, numerous attempts have been made to develop reagents that disrupt this process and prevent the formation of the toxic oligomers and aggregates. An attractive strategy for developing such reagents is to use peptides derived from Aβ based on the assumption that such peptides would bind to full-length Aβ, interfere with binding of additional full-length molecules, and thereby prevent formation of the toxic species. Guided by this rationale, most of the studies in the last two decades have focused on preventing formation of the core cross-β structure of Aβ amyloid fibrils using β-sheet-breaker peptides derived from the central hydrophobic cluster of Aβ. Though this approach is effective in inhibiting fibril formation, it is generally inefficient in preventing Aβ oligomerization. An alternative approach is to use peptides derived from the C-terminus of Aβ, which mediates both oligomerization and fibrillogenesis. This approach has been explored by several groups, including our own, and led to the discovery of several lead peptides with moderate to high inhibitory activity. Interestingly, the mechanisms of these inhibitory effects have been found to be diverse, and only in a small percentage of cases involved interference with β-sheet formation. Here, we review the strategy of using C-terminal fragments of Aβ as modulators of Aβ assembly and discuss the relevant challenges, therapeutic potential, and mechanisms of action of such fragments.

A Two-Step Strategy for Structure–Activity Relationship Studies of N-Methylated Aβ42 C-Terminal Fragments as Aβ42 Toxicity Inhibitors

Neurotoxic Aβ42 oligomers are believed to be the main cause of Alzheimer’s disease. Previously, we found that the C‐terminal fragments (CTFs), Aβ(30–42) and Aβ(31–42) were the most potent inhibitors of Aβ42 oligomerization and toxicity in a series of Aβ(x–42) peptides (x=28–39). Therefore, we chose these peptides as leads for further development. These CTFs are short (12–13 amino acids) hydrophobic peptides with limited aqueous solubility. Our first attempt to attach hydrophilic groups to the N terminus resulted in toxic peptides. Therefore, we next incorporated N‐methyl amino acids, which are known to increase the solubility of such peptides by disrupting the β‐sheet formation. Focusing on Aβ(31–42), we used a two‐step N‐methyl amino acid substitution strategy to study the structural factors controlling inhibition of Aβ42‐induced toxicity. First, each residue was substituted by N‐Me‐alanine (N‐Me‐A). In the next step, in positions where substitution produced a significant effect, we restored the original side chain. This strategy allowed exploring the role of both side chain structure and N‐Me substitution in inhibitory activity. We found that the introduction of an N‐Me amino acid was an effective way to increase both the aqueous solubility and the inhibitory activity of Aβ(31–42). In particular, N‐Me amino acid substitution at position 9 or 11 increased the inhibitory activity relative to the parent peptide. The data suggest that inhibition of Aβ42 toxicity by short peptides is highly structure‐specific, providing a basis for the design of new peptidomimetic inhibitors with improved activity, physicochemical properties, and metabolic stability.