Structure-activity analyses of beta-amyloid peptides: contributions of the beta 25-35 region to aggregation and neurotoxicity.

Abstract

The neurodegeneration of Alzheimer's disease has been theorized to be mediated, at least in part, by insoluble aggregates of beta-amyloid protein that are widely distributed in the form of plaques throughout brain regions affected by the disease. Previous studies by our laboratory and others have demonstrated that the neurotoxicity of beta-amyloid in vitro is dependent upon its spontaneous adoption of an aggregated structure. In this study, we report extensive structure-activity analyses of a series of peptides derived from both the proposed active fragment of beta-amyloid, beta 25-35, and the full-length protein, beta 1-42. We examine the effects of amino acid residue deletions and substitutions on the ability of beta-amyloid peptides to both form sedimentable aggregates and induce toxicity in cultured hippocampal neurons. We observe that significant levels of peptide aggregation are always associated with significant beta-amyloid-induced neurotoxicity. Further, both N- and C-terminal regions of beta 25-35 appear to contribute to these processes. In particular, significant disruption of peptide aggregation and toxicity result from alterations in the beta 33-35 region. In beta 1-42 peptides, aggregation disruption is evidenced by changes in both electrophoresis profiles and fibril morphology visualized at the light and electron microscope levels. Using circular dichroism analysis in a subset of peptides, we observed classic features of beta-sheet secondary structure in aggregating, toxic beta-amyloid peptides but not in nonaggregating, nontoxic beta-amyloid peptides. Together, these data further define the primary and secondary structures of beta-amyloid that are involved in its in vitro assembly into neurotoxic peptide aggregates and may underlie both its pathological deposition and subsequent degenerative effects in Alzheimer's disease.