Amyloid ß-derived switch-peptides as tool to study conformational changes relevant in degenerative diseases

The rapid growing number of patients diagnosed with a neurodegenerative disease and more particularly with Alzheimer's disease (AD) has stimulated intensive research in determining and understanding biological phenomena causing such devastating diseases and hence allowing for the elaboration of adapted therapeutic treatments. These diseases are also commonly called "conformational" diseases because they result from the misfolding of a protein leading to the formation of self-associated β-sheets, which in turn give rise to the formation of oligomers, protofibrils as well as insoluble fibrils characterizing the plaques found in the brain of affected patients. Consequently, the investigation of such proteins, in particular of Amyloid β (Aβ) in the case of AD, is a limited and difficult task to achieve, which often leads to contradictory results. To overcome these difficulties and to be able to study the key steps of conformational transitions and misfolding of such peptides and proteins, our research group has developed a new tool, called switch-peptides, enabling to block (Soff state) and trigger (Son state) peptide folding at will (Figure). The introduction of a switch element S built from Ser, Thr or Cys residues disrupts the regular polypeptide chain by the insertion of an ester and a flexible C-C bond resulting in a conformational disconnection of P1 and P2 (Figure), i.e. in an unordered (random coil), non-folded conformation. Each S element is protected by a protecting group Y (Soff state) that can be cleaved independently by adding a base, an enzyme or by light, depending on the chemical nature of Y. The cleavage of the different protecting groups Y triggers a spontaneous O to N acyl migration, re-establishing the regular amide backbone of the peptide chain, hence enabling the peptide to fold "in statu nascendi" and to adopt a well-defined secondary structure. The present thesis explores the potential of this novel concept for the example of conformational transitions relevant in amyloid β misfolding. In the first part we investigate the chemical stability of the S element in aqueous media, exposing a number of switch-peptides to various experimental conditions. Most notably, the ester bond proved to be stable at acidic as well as physiological conditions for several hours, opening a broad range of biological applications. The second part of the work is dedicated to the study of conformational transitions of switch-peptides derived from Aβ(1-42). By incorporating one or several switch elements disposing orthogonal protecting groups Y, the impact of different fragments of the peptide as nucleation site for the process of β-sheet formation, self-assembly and aggregation has been revealed as monitored by CD, TEM studies and ThT (pathway B, Figure). For the first time, the orthogonal triggering of the two switch elements, i.e. S26 and S37 allowed to delineate the important role of the C-terminal part of Aβ in the early step of misfolding. Subsequ