Switch-peptides as folding precursors in self-assembling peptides and amyloid fibrillogenesis

The study of conformational transitions of peptides has obtained considerable attention recently because of their importance as a mol. key event in a variety of degenerative diseases. However, the study of peptide self-assembly into beta-sheets and amyloid beta (Abeta) fibrils is strongly hampered by their difficult synthetic access and low soly. We have recently developed a new concept termed "switch-peptides" that allows the controlled onset of polypeptide folding and misfolding at physiol. conditions. As a major feature, the folding process is initiated by chem. or enzyme triggered O,N-acyl migration in flexible and sol. folding precursors contg. Ser- or Thr-derived switch (S)-elements. The elaborated methodologies are exemplified for the in situ conversion of NPY- and Cyclosporine A-derived prodrugs, as well as for the onset and reversal of alpha and beta conformational transitions in Abeta peptides. In combining orthogonally addressable switch-elements, the consecutive switching on of S-elements gives new insights into the role of individual peptide segments ("hot spots") in early processes of polypeptide self-assembly and fibrillogenesis. Finally, the well-known secondary structure disrupting effect of pseudoprolines (Psi Pro) is explored for its use as a building block (S-element) in switch-peptides. To this end, synthetic strategies are described, allowing for the prepn. of Psi Pro-contg. folding precursors, exhibiting flexible random-coil conformations devoid of fibril forming propensity. The onset of beta-sheet and fibril formation by restoring the native peptide chain in a single step classify Psi Pro-units as the most powerful tool for inhibiting peptide self-assembly, and complement the present methodologies of the switch-concept for the study of fibrillogenesis.

"Switch peptides"

Lydiane Jeanine Saucède

Despite of considerable progress in the research at the interface of Chemistry, Biology and Medicine, neurodegenerative diseases affect more and more seriously our ageing population and remain a real therapeutic challenge for researcher. Nevertheless, advances made in this field allow us to better understand the molecular mechanisms responsible for these disorders and to stress the involvement and the key-role of conformational changes of some proteins. Thought to be at the origin of Alzheimer's disease, amyloid-β peptide undergoes structural modifications leading to β-sheet structures, which further aggregate into toxic fibrils and plaques. However, intrinsic properties of these structures result in problems such as insolubility and self-aggregation limiting their experimental access. Among the main research lines to find an efficient therapeutic agent to fight against Alzheimer's disease, fibrillar inhibition is considered as promising strategy. It requires the use of a molecule, called β-breaker, which would be able to block the misfolding triggered by conformational transitions. Consequently, the present thesis is focusing on the design and chemical synthesis of potential inhibitors of amyloid-β fibrillogenesis. As a specific common feature, the designed compounds integrate in their chemical structure a short sequence ("nucleation site") derived from the central part of Aβ(1-42), allowing to specifically interact with the pathogenic peptide. We first envisaged to design cyclic peptides as potential inhibitors containing proline residues, known for its destabilizing effect upon secondary structures (way A). In collaboration with C. Soto et al., Univ. Galveston, the biological activity of the prototype cyclo(Lys-Leu-Pro-Phe-Phe-Glu) was tested. Most notably, electron microscopy, in collaboration with J. Dubochet and M. Adrian, UNIL, Congo red and thioflavin T staining, and CD studies pointed to the potential of cyclic peptides as Aβ inhibitors. Subsequently, conjugate peptides, assembling the recognition sequence of amyloid-β and organic molecules with potential to block fibrillogenesis were synthesized specifically. (+/-)-Trans-4-cotininecarboxylic acid, 3-indolebutyric acid and a tripeptide β-strand mimic were chosen. The biological assessment of these molecules allowed us to highlight their potential in this therapeutic strategy as well as the advantage given by the intercalation of a proline between the two components of these conjugates. In an effort to introduce in the structure of β-breakers a dynamization element, comparable to the cis/trans isomerization of proline, we designed a new type of β-breaking molecules according to strategy B (Figure). The elaboration of this innovating concept termed "switch-peptides" allows to controll the function of a polypeptide by using intramolecular acyl migration as switch-element for the in situ induction of structure and function. By combining an conformational induction unit σ, a switch element S (cysteine or serine) and an amyloid recognition sequence, we obtained a new generation of dynamic β-breakers. At the Soff state, the σ part was linked to the switch element S via an ester bond, deactivating the structural influence of the conformational induction unit on the target peptide, resulting in the absence of biological activity. By removing the protecting group Y from the amino function of the switch element, intramolecular acyl migration was triggered, restoring the native amide bond, setting off the impact of σ (Son state). In applying pseudo-prolines as β-breaking σ-elements (resulting in a "kink" conformation), the corresponding switch-peptide can adopt a recognition state (Soff) and a β-sheet disrupting state (Son), triggered by controlled acyl migration. We explored the use of cysteine as switch element, with special attention to the chemoselective synthesis, kinetics of acyl migration and potential for β-breaking. Interestingly, the S→N acyl migration proceeded very fast at physiological pH, in comparison to serine derived O→N migrations. Of utmost importance for further extensions of the switch-concept, the design of non peptidic S-elements such as trifunctionalized aromatic compounds would allow us to generate the β-breaking element in situ. As a first step, the intramolecular acyl migration O→N via an intermediate of 5, 6, 7 or 9 membered rings, as well as the reversibility of this reaction, was successfully demonstrated. In addition, enzymatically cleavable protecting groups Y for triggering acyl migrations were established. In conclusion, the present thesis presents some promising concepts in the design of fibril disrupting compounds of considerable therapeutical potential.

EPFL2006

Switch-peptides: controlling biological function and self-assembly of amyloid ß-derived peptides using enzyme-triggered acyl migrations

Sonia Dos Santos

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 Ang II and IC50 = 5 nM for NPY). In the case of NPY, a conformational transition from a random coil to an α-helix as bioactive conformation is observed by CD. The second part of the work is dedicated to conformational transitions of type random coil → β-sheet in different model peptides or peptides derived from Aβ(1-42). All peptides studied show high potential for self-association and subsequent precipitation. However, in the Soff state, the switch-peptides display a high degree of stability and strongly enhanced aqueous solubility. After enzymatic triggering of the acyl migration, a conformational transition to a β-sheet accompanied by the formation of fibrils and spontaneous precipitation are observed by CD and EM studies. Based on the elaborated systems, the introduction of several orthogonal S-elements in Aβ derived peptides was realized. The incorporation of two different S-elements into the Aβ(1-42) sequence was found to greatly facilitate the normally difficult synthesis, and enabled the study of the influence of the individual peptide segments on the overall folding process. It was shown for the first time that the hexamer Aβ(37-42) is essential for the formation of β-sheets and subsequent fibrillization. As a final aspect, the elaboration of switch-peptides exhibiting β-breaking properties was investigated. Preliminary results indicate that one of the designed switch-peptides substantially slows down the formation of fibrils, representing a significant step in the development of therapeutically relevant compounds for the treatment of Alzheimer's disease. In conclusion, the elaborated methodologies allow for a general application of the switch concept as diagnostic tool in the study of fibrillogenesis.

EPFL2005

Self-Assembly of ß-Amyloid Peptides in Cells and on Solid Supports

Enrico Condemi

Neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and Huntington's disease share common mechanisms characterized by protein misfolding and aggregation, including formation of plaques or inclusion bodies. The rapid growing number of patients has motivated intensive research to understand biological phenomena involved in the pathology and hence developing therapeutic strategies. Here, we will focus on β-amyloid peptide (Aβ) involved in Alzheimer's disease. In the first part of this thesis, tissue transglutaminase (tTGase) has been investigated due to its implication in a number of cellular processes and disease states, where the enzymatic actions of tTGase may serve in both, cell survival and apoptosis. To date, the precise functional properties of tTGase in cell survival or cell death mechanisms still remain elusive. tTGase mediated cross-linking has been reported to account for the formation of insoluble lesions in conformational diseases. We report here that, tTGase induces intramolecular cross-linking of Aβ peptide, resulting in structural changes of monomeric Aβ. Using high resolution mass spectrometry (MS) of cross-linked Aβ peptides, we observed a shift in mass, which is, presumably associated with the loss of NH3 due to enzymatic transamidation activity and hence intramolecular peptide cross-linking. We have observed that, a large population of Aβ monomers contained an increase in mass of 0.984 Da at a glutamine residue, indicating that glutamine Q15 serves as an indispensable substrate in TGase mediated deamidation to glutamate E15. We provide strong analytical evidence on tTGase mediated Aβ peptide dimerization, through covalent intermolecular cross-linking and hence the formation of Aβ1-40 dimers. Our in depth analyses indicate that, tTGase induced post-translational modifications of Aβ peptide may serve as an important seed for aggregation. In the second part of this work, we explore the idea of using synthetic peptides that can switch conformation in a controlled way as a sensor for β-breakers of Aβ. The concept of switch-peptides allows the controlled onset of polypeptides folding and misfolding at physiological pH by in situ O,N-acyl migration. The synthesized sequence consisted in the core sequence responsible for Aβ aggregation, flanked by two β-sheet-inducing template through ester bonds. The triggering of the acyl migration allows the native sequence to be recovered from the ester bonds and structural change from flexible unordered conformation to β-sheets and subsequently fibrils formation were observed in solution. In a more biological environment made of lipid vesicles, the conformation of the peptide has been shown to act comparably to wild type Aβ peptide by circular dichroism (CD), namely increased negative charges over the surface led to increased helical propensity followed by a transition to β-sheets and accelerated fibrils formation. Thereafter, the conformation of the cysteine analogue of the switch-peptide covalently linked to gold surface was characterized by Fourier-transform infrared spectroscopy (FTIR). In monolayer of switch-peptide tethered to a planar gold surface, the peptide already adopts most likely β-turn conformation and no changes in the infrared spectra were detected after the triggering of the switch. On gold nanoparticles, the switch-peptide folds spontaneously into β-sheet conformation. These unwanted foldings limit the efficiency of the sensor and has driven us to an alternative configuration, where gold nanoparticles were coated with a 95:5 mixture of two peptide sequences able to stabilize the nanoparticles and to act as recognition sequence, respectively. In this configuration, the switch-peptide is added in the gold nanoparticles solution and the aggregation triggered. Here, we want to take advantage of a particular feature of gold nanoparticles that consists in a change of solution color from red to blue as the nanoparticles come closer to each other during aggregation. Preliminary results have shown that a discrimination between aggregated and soluble samples is possible. However, further improvements are necessary before a potential biosensor could be expected.

EPFL2011