Publication
Conformational transitions of peptides and proteins have recently moved to the center of interest in various domains of research at the interface of chemistry, biology, and medicine due to their implication in an increasing number of diseases in which the pathogenesis is causally linked to the misfolding of a protein. For example, the amyloid β protein linked to Alzheimer's disease undergoes various conformational transitions, eventually leading to the formation of self-associating β-sheets, which in turn give rise to insoluble, fibrillar aggregates. Consequently, studies of such proteins are hampered by problems of solubility and often yield contradictory results. With the aim of surmounting these difficulties in the study of conformational transitions of peptides and proteins, a novel tool based on the concept of "Switch-Peptides" enabling the in situ induction of peptide folding will be elaborated in the present thesis. As shown in the Scheme, N(Y)-protected switch-peptides serve as stable, self-contained precursor molecules, in which folding and self-assembly is blocked by the presence of Ser or Thr derived switch-elements S, dissecting the regular peptide backbone by an ester and a flexible C-C bond. Removal of the protecting group Y triggers a spontaneous acyl migration that restores the native polypeptide chain ("statu nascendi") setting off the folding process. The body of work presented herein consists of two main themes: With the goal of developing a system amenable to physiological conditions, the introduction and evaluation of different, enzymatically cleavable Y groups was conceived. For proof of concept, the biologically active peptides angiotensin and neuropeptide Y were used, allowing the study of the impact of the S-element on their biological activities. Investigations of the analogue [Thr]5-Ang II containing a pH-triggered switch (Y = H+) reveal that the acyl migrations are very fast, exhibiting half-lives of less than one minute. With the introduction of enzymatically labile Y groups, specifically an Arg-Pro dipeptide (cleavable by dipeptidyl aminopeptidase) or the amino acid pGlu (cleavable by pyroglutamate aminopeptidase), rates of conversion ranging from minutes to hours are observed as monitored by HPLC, NMR and CD. Problems of steric interference associated with the action of enzymes such as esterases and penicillin amidase were overcome by developing linkers of different structural features. D-aminopeptidase (Y = D-Ala) was shown to extend the rates of enzymatic cleavage to half-lives of several days. The enzymes studied display high specificity for the switch-peptide substrates and a quantitative conversion from the Soff to the Son state. We took advantage of the affinity of Ang II and NPY for their respective receptors (AT2 and Y1) to show that their switch-peptide analogs are inactive in the Soff state where as after enzymatically triggered acyl migration, the peptides display high receptor affinity (IC50 = 45 nM for