The correlation between neurotoxicity, aggregative ability and secondary structure studied by sequence truncated Abeta peptides.

Aggregated beta-amyloid (Abeta) peptides are neurotoxic and cause neuronal death both in vitro and in vivo. Although the formation of a beta-sheet structure is usual required to form aggregates, the relationship between neurotoxicity and the Abeta sequence remains unclear. To explore the correlation between Abeta sequence, secondary structure, aggregative ability, and neurotoxicity, we utilized both full-length and fragment-truncated Abeta peptides. Using a combination of spectroscopic and cellular techniques, we demonstrated that neurotoxicity and aggregative ability are correlated while the relationship between these characteristics and secondary structure is not significant. The hydrophobic C-terminus, particularly the amino acids of 17-21, 25-35, and 41-42, is the main region responsible for neurotoxicity and aggregation. Deleting residues 17-21, 25-35 or 41-42 significantly reduced the toxicity. On the other hand, truncation of the peptides at either residues 22-24 or residues 36-40 had little effect on toxicity and aggregative ability. While the N-terminal residues 1-16 may not play a major role in neurotoxicity and aggregation, a lack of N-terminal fragment Abeta peptide, (e.g. Abeta17-35), does not display the neurotoxicity of either full-length or 17-21, 25-35 truncated Abeta peptides.

The effect of Abeta conformation on the metal affinity and aggregation mechanism studied by circular dichroism spectroscopy.

The conformational change and associated aggregation of beta amyloid (Abeta) with or without metals is the main cause of Alzheimer's disease (AD). In order to further understand the effects of Abeta and its associated metals on the aggregation mechanism, the influence of Abeta conformation on the metal affinity and aggregation was investigated using circular dichroism (CD) spectroscopy. The Abeta conformation is dependent on pH and trifluoroethanol (TFE). The binding of metals to Abeta was found to be dependent on the Abeta conformation. The aggregation induced by Abeta itself or its associated metals is completely diminished for Abeta in 40% TFE. Only in 5% and 25% TFE can Abeta undergo an alpha-helix to beta-sheet aggregation, which involve a three-state mechanism for the metal-free state, and a two-state transition for the metal-bound state, respectively. The aggregation-inducing activity of metals is in the order, Cu2+ > Fe3+ > or = Al3+ > Zn2+.

Structure and stability of the molten globule state of guinea-pig alpha-lactalbumin: a hydrogen exchange study.

A partially folded state of guinea pig alpha-lactalbumin (the A-state or molten globule state), formed by denaturation at low pH, has been studied using hydrogen exchange methods. The overall distribution of exchange kinetics, measured by 1-D NMR, suggests that fewer than 20 amides in the structure are involved in highly persistent residual structure, although CD results suggest that many other parts of the chain are folded, for a significant proportion of the time, into less stable structural elements. The pH-jump experiments show that some amides that are strongly protected from exchange in the native state become freely accessible in the A-state but that conversely a majority, at least, of those that are slow to exchange in the A-state retain that protection in the native state. This suggests that the persistent structure in the A-state is native-like although the possibility that nonnative like structural elements persist cannot be eliminated. Resonance assignments for key residues in the NMR spectrum of the native state have enabled us to use the pH-jump method also to identify the majority of the most protected amides in the A-state: they are located in two hydrophobic segments, corresponding to the B- and C-helices of the native structure. This strongly suggests that the most persistent structure of the A-state includes these regions. A variety of lines of evidence, including fluorescence quenching data and, most remarkably, very effective protection from exchange of an indole NH in a tryptophan side chain, suggest that some form of hydrophobic core in the helical domain of the native structure persists in the A-state, although without the stereochemical rigidity of the native tertiary structure. The other domain of the native structure, including the beta-sheet, appears not to contain structural elements which persist to the same extent in the A-state, emphasizing that the molten globule is highly heterogeneous, in terms of the stability and specificity of both backbone and side chain interactions.

1H-NMR assignments and local environments of aromatic residues in bovine, human and guinea pig variants of alpha-lactalbumin.

1H-NMR assignments have been defined for the aromatic-ring protons of the bovine, guinea pig and human variants of alpha-lactalbumin. Spin-system networks were identified by means of double-quantum-filtered two-dimensional J-correlated spectroscopy and two-dimensional relayed coherence spectroscopy data. Analysis of two-dimensional nuclear-Overhauser-enhancement spectroscopy data of the proteins indicated that in each case two clusters of aromatic residues exist. The two clusters are also evident in the crystal structure of the human protein, and this evidence, in conjunction with sequence differences between the three proteins, permitted sequence-specific assignments to be made for the majority of aromatic residues. Remaining ambiguities in the assignments could be resolved by analysis of photochemically induced dynamic nuclear polarization (PCIDNP) effects. Comparison of the PCIDNP spectra of the three proteins indicated the presence of only minor differences in the surface exposure of conserved aromatic residues. Taken together, these results indicate that the environments of the conserved aromatic residues in bovine, guinea pig and human alpha-lactalbumin in solution are very similar to each other, and that the solution and the crystal forms of at least the human protein are similar.