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The function of yeast frataxin in iron-sulfur cluster biogenesis : a systematic mutagenesis of solvent-exposed side chains of the beta-sheet platformLeidgens, Sébastien 26 September 2008 (has links)
Friedreich's ataxia is a neurodegenerative disorder caused by the low expression of a mitochondrial protein called frataxin. Studies in the yeast Saccharomyces cerevisiae have unraveled a role for the frataxin homologue (Yfh1p) in iron-sulfur cluster (Fe/S) biosynthesis, probably by interacting with the scaffold protein, Isu1p, and providing iron to the machinery. Yfh1p possesses a large â-sheet platform that may be involved in the interaction with other proteins through conserved residues at its surface. We have used directed mutagenesis associated with polymerase chain reaction (PCR) to study conserved residues localizing either at the surface of the protein, Thr110, Thr118, Val120, Asn122, Gln124, Gln129, Trp131, Ser137 and Arg141, or buried in the core of the protein, Ile130 and Leu132.
Mutants T110A, T118A, V120A, N122A, Q124A, Q129A, I130A, W131A, L132A, S137A and R141A were generated in yeast. Growth on iron- or copper-containing medium was severely impaired for mutants Q129A, I130A, W131A and R141A. Others were roughly growing as well as the wild-type strain. We assessed the efficiency of Fe/S biosynthesis by measuring aconitase activity. The results confirmed those obtained on metal-containing medium: mutants Q129A, I130A, W131A and R141A showed a high decrease in their aconitase activity that dropped to the deleted strain level. Moreover, S137A showed also a decreased aconitase activity. We monitored the interaction between Yfh1p and Isu1p by co-immunoprecipitation and it turned out that only the W131A mutation affects directly this interaction. Even if the amount of Yfh1p determined by western blot analysis was highly decreased for several mutants, it is not sufficient to explain the phenotypes as they were poorly restored by overexpression of the mutant proteins to wild-type levels, except for W131F.
We have concluded that Gln129, Trp131, and Arg141 are important for Yfh1p function, while Ile130 and Ser137 are required for the folding of the protein. All these residues cluster to the 4th and 5th â-strand of the protein. Our work has demonstrated for the first time the importance of this area for Yfh1p function and shows that Trp131 is involved in the interaction with Isu1p.
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Criteria for Selecting PEGylation Sites on Proteins for Higher Thermodynamic StabilityLawrence, Paul B. 01 June 2016 (has links)
PEGylation of protein side-chains has been used for more than 30 years to enhance the pharmacokinetic properties of protein drugs, and has been enabled by the recent development of many chemoselective reactions for protein side-chain modification. However, there are no structure- or sequence-based guidelines for selecting sites that provide optimal PEG-based pharmacokinetic enhancement with minimal loss to biological activity. Chapter 1 is a brief introduction to protein PEGylation. In chapter 2 we use the WW domain of the human protein Pin 1 (WW) as a model system to probe the impact of PEG on protein conformational stability. Using a combination of experimental and theoretical approaches, we develop a structure-based method for predicting which sites within WW are most likely to experience PEG-based stabilization, and show that this method correctly predicts the location of a stabilizing PEGylation site within the chicken Src SH3 domain. PEG-based stabilization in WW is associated with enhanced resistance to proteolysis, is entropic in origin, and likely involves disruption by PEG of the network of hydrogen-bound solvent molecules that surround the protein. Chapter 3 shows that PEG-based stabilization of the WW domain depends strongly on the identity of the PEG-protein linker, with the most stabilizing linkers involving conjugation of PEG to an Asn side-chain amide nitrogen. Chapter 4 investigates the interplay between structure-based guidelines for PEG-base stabilization developed in chapter 2 and the different chemistries explored in chapter 3.
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SYNTHESIS AND CHARACTERIZATION OF OLIGO(¿-ALANINE) GRAFTED STYRENEBUTADIENE RUBBERFu, Lin January 2017 (has links)
No description available.
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X-Ray Scattering of BiomaterialsYang, Fei-Chi 11 1900 (has links)
Molecular structures of biomaterials have close relation to their functions. We are interested in how biological building blocks assemble into the structures of native biomaterials and the hierarchy of those structures. We tackled the problem mainly with X-ray diffraction experiments and developed a thorough analysis technique to assign the X-ray signals to protein secondary structures and chitin. Three different types of biomaterials were examined: vimentin fibres, squid pens, and human hair. In vimentin fibres, we found that the secondary protein structures play an important role in the strength of the fibres. In native squid pens, we found a self-similar, hierarchical structure from millimetres down to nanometres. In human hair, we compared the signals corresponding to keratin proteins, intermediate filaments, and lipids between different subjects, and found small deviations. The structures of these three biomaterials, which encompass different orders of length scales, were described both quantitatively and graphically. We hope that this work will eventually allow us to understand how and why nature builds biomaterials this way. / Thesis / Master of Science (MSc)
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Investigation into the Effects of PEGylation on the Thermodynamic Stability of the WW DomainMatthews, Sam S 01 December 2013 (has links) (PDF)
The covalent attachment of poly(ethylene glycol) (PEG) to a protein surface (known as PEGylation), has been demonstrated to increase the serum half-life of therapeutic proteins by reducing kidney clearance and immunogenicity and by protecting against proteolysis. Theses beneficial effects could be further enhanced if PEGylation consistently increased protein conformational stability (i.e. the difference in free energy between the folded and unfolded states). However, the effects of PEGylation on protein conformational stability are unpredictable; PEGylation has been reported to increase, decrease, or have no effect on the conformational stability of medicinal proteins.This thesis details the results of two studies aimed at discovering the structural determinants which influence the thermodynamic impact of PEGylation on the WW domain, a small model protein. Chapter 1 is a brief introduction to protein therapeutics and protein PEGylation. Chapter 2 describes a study which demonstrates that the thermodynamic impact of PEGylation is strongly dependent on the site to which PEG is conjugated. The studies described in Chapter 3 elaborate on this site dependence, and demonstrate that PEG stabilizes the WW domain through interactions with the surface of the folded peptide, and that two factors – the orientation of the PEG chain (relative to the protein surface) and the identity of nearby side chains – play a critical role in determining the thermodynamic impact of PEGylation.
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Design and Study of Novel Antimicrobial Peptides with Proline SubstitutionHe, Jing January 2009 (has links)
No description available.
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Supramolecular reinforcement of elastomers using β-sheet nanocrystalsZhao, Yihong January 2019 (has links)
No description available.
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X-Ray Crystallographic Studies Of Designed Peptides : Characterization Of Self-Assembled Peptide Nanotubes With Encapsulated Water Wires And β-Hairpins As Model Systems For β-Sheet FoldingRaghavender, U S 07 1900 (has links) (PDF)
The study of synthetic peptides aid in improving our current understanding of the fundamental principles for the de novo design of functional proteins. The investigation of designed peptides has been instrumental in providing answers to many questions ranging from the conformational preferences of amino acids to the compact folded structures and also in developing tools for understanding the growth and formation of the protein secondary structures (helices, sheets and turns). In addition, the self-assembly of peptides through non-covalent interactions is also an emerging area of growing interest. The design of peptides which can mimic the protein secondary structures relies on the use of stereochemically constrained amino acid residues at select positions in the linear peptide sequences, leading to the construction of protein secondary structural modules like helices, hairpins and turns. The use of non-coded amino acid residues with strict preferences for adopting particular conformations in the conformational space becomes the most crucial step in peptide design strategies. In addition the crystallographic characterization and analysis of the sequences provides the necessary optimization of the design strategies. The crystallographic characterization of designed peptides provides a definitive and conclusive proof of the success of a design strategy. Furthermore, the X-ray structures provide an atomic view of the interactions, both strong and weak, which govern the growth of the crystal. The information on the geometric parameters and stereochemical properties of a series of peptides, through a systematic study, provides the necessary basis for further scientific investigation, like the molecular dynamics and can also aid in improving the force field parameters meant for carrying out molecular simulations. This can be further complemented by constructing biologically active peptide sequences.
The focus of this thesis is to characterize crystallographically the conformational and structural aspects of peptide nanotubes and encapsulated water wires and the β-hairpin peptide models of β-sheets. The systematic study of a series of pentapeptide and octapeptide sequences, containing Aib and D-amino acid residues incorporated at strategic positions, establish the conformation and structural properties of designed peptides as mimics of protein secondary structures and hydrophobic tubular peptide channels and close-packed forms. The structures reported in this thesis are given below:
1 Boc-DPro-Aib-Leu-Aib-Val-OMe (DPUL5) C30H53N5O8
2 Boc-DPro-Aib-Val-Aib-Val-OMe (DPUV5a) C29H51N5O8 .(0.5) H2O
3 Boc-DPro-Aib-Val-Aib-Val-OMe (DPUV5b) C27H51N5O8 .(0.17) H2O
4 Boc-DPro-Aib-Ala-Aib-Val-OMe (DPUA5) C27H47N5O8
5 Boc-DPro-Aib-Phe-Aib-Val-OMe (DPUF5) C33H48N5O8
6 Boc-Pro-Aib-DLeu-Aib-DVal-OMe (PUDL5) C30H53N5O8
7 Boc-Pro-Aib-DVal-Aib-DVal-OMe (PUDV5a) C27H51N5O8 .(0.17) H2O
8 Boc-Pro-Aib-DVal-Aib-DVal-OMe (PUDV5b) C27H51N5O8 . 2H2O
9 Boc-Pro-Aib-DAla-Aib-DVal-OMe (PUDA5) C27H47N5O8
10 Boc-Pro-Aib-DPhe-Aib-DVal-OMe (PUDF5) C33H48N5O8
11 Ac-Phe-Pro-Trp-OMe (FPW) C28H32N4O5.(0.33)H2O
12 Boc-Leu-Phe-Val-DPro-Pro-Leu-Phe-Val-OMe (DPLP8) C56H84N8O1 1 .(0.5) H2O
13 Boc-Leu-Phe-Val-DPro-Pro-Leu-Phe-Val-OMe (YDPP8) C56H83N8O12 .(1.5) H2O
14 Boc-Leu-Val-Val-DPro-ψPro-Leu-Val-Val-OMe (PSIP8) C56H84N8O11S1 .(1.5) H2O
15 Boc-Leu-Phe-Val-DPro-Pro-Leu-Phe-Val-OMe (DPPV8) C48H84N8O11
16 Boc-Leu-Phe-Val-DPro-Aib-Leu-Phe-Val-OMe (DPUF8) C57H88N8O11.(1.5) H2O
17 Piv-Pro-ψH,CH3Pro-NHMe (PSPL3) C22H37N3O5S1
18 Boc-Leu-Val-Val-Aib-DPro-Leu-Val-Val-OMe (UDPV8) C47H84N8O11.2(C3H7NO)
19 Boc-Leu-Phe-Val-DPro-Ala-Leu-Phe-Val-OMe (BH1P8) C54H78N8O11.H2O
20 Boc-Leu-Phe-Val-DPro-Aib-Leu-Phe-Val-OMe (DPUFP8) C55H84N8O11. (0.5) H2O
21 Boc-Leu-Phe-Val-DPro-Pro-Leu-Phe-Val-OMe (YDPPP8) C56H83N8O12. (1.5) H2O
The crystal structure determination of the peptides presented in this thesis provides a wealth of information on the folding patterns of the sequences, in addition to the characterization of many structural and geometric properties. In particular, the study sheds light on the growth and formation of peptide nanotubes and the structure of encapsulated water wires, and also the structural details of Type I′ and Type II′β-turn nucleated hairpins. The study provides the backbone and side chain conformational parameters of the sequences, highlighting the varied conformational excursions possible in the peptide molecules.
The thesis is divided into 6 chapters and one appendix.
Chapter 1 gives a general introduction to the stereochemistry of the polypeptide chain, description of backbone torsion angles of α-amino acid residues and the major secondary structures of α-peptides, namely α-helix, β-sheet and β-turns. The basic structural features of
helices and sheets are given. A brief introduction to polymorphism and weak interactions is also presented, followed by a discussion on X-ray diffraction and solution to the phase problem.
Chapter 2 is divided into two parts. PART 1 describes the crystal structures of a series of eight related enantiomeric peptide sequences (Raghavender et al., 2009; Raghavender et al., 2010). The crystal structures of four sequences with the general formula Boc-DPro-Aib-Xxx-Aib-Val-OMe (Xxx = Ala/Val/Leu/Phe) and the enantiomeric sequences provided a set of crystal structures withdifferent packing arrangements. The structure of the peptide with Xxx = Leu revealed a nanotube formation with the Leu lining the inner walls of channel. The channels were found to be empty. The sequence with Xxx = Val revealed a solvent-filled water channel.Investigation of the water wire structures on the diffraction data collected on the same crystal over a period of time revealed the existence of two different kinds of water wires in thechannels. Comparison with the peptide tubular structures available in the literature and the water structure inside the aquaporin channels are contrasted. Close-packed structures are observed in the case of Xxx=Ala and Phe. The backbone conformations are essentially identical. Enantiomeric sequences also revealed similar structures. Polymorphic forms were observed in the case of DVal(3) containing sequence. One form is observed to have water-filled channels forming a nanotube, as opposed to the close-packed structure in the polymorphic form. Crystal parameters
DPUL5: C30H53N5O8; P65; a = b = 24.3673 (9) Å, c = 10.6844 (13) Å; α = β = 90°, γ = 120°; Z = 6; R = 0.0671, wR2 = 0.1446. DPUV5a: C29H51N5O8 .(0.5) H2O; P65; a = b = 24.2920 (13) Å, c = 10.4838 (11) Å; α = β = 90°, γ = 120°; Z = 6; R = 0.0554, wR2 = 0.1546. DPUV5b: C29H51N5O8 .(0.17) H2O; P65; a = b = 24.3161 (3) Å, c = 10.1805 (1) Å; α = β = 90°, γ = 120°; Z = 6; R = 0.0617, wR2 = 0.1844. DPUA5: C27H47N5O8; P212121; a = 12.2403 (8), b = 15.7531 (11) Å, c = 16.6894 (11) Å; Z =4; R = 0.0439, wR2 = 0.1249. DPUF5: C33H48N5O8; P212121; a = 10.3268 (8), b = 18.7549 (15) Å, c = 18.9682 (16) Å; Z = 4; R = 0.0472, wR2 = 0.1325.
PUDL5: C30H53N5O8; P61; a = b = 24.4102 (8) Å, c = 10.6627 (7) Å; α = β = 90°, γ = 120°; Z = 6; R = 0.0543, wR2 = 0.1495. PUDV5a: C29H51N5O8 .(0.17)H2O; P61; a = b = 24.3645 (14) Å, c = 10.4875 (14) Å; α = β = 90°, γ = 120°; Z = 6; R = 0.0745, wR2 = 0.1810. PUDV5b: C29H51N5O8. 2H2O; C2; a = 20.7278 (35), b = 9.1079 (15) Å, c = 19.5728 (33) Å; α = γ = 90°, β = 94.207°; Z = 6; R = 0.0659, wR2 = 0.1755. PUDA5: C27H47N5O8; P212121; a = 12.2528 (12), b = 15.7498 (16) Å, c = 16.6866 (16) Å; Z = 4; R = 0.0473, wR2 = 0.1278. PUDF5: C33H48N5O8; P212121; a = 10.3354 (8), b = 18.7733 (10) Å, c = 18.9820 (10) Å; Z = 4; R = 0.0510, wR2 = 0.1526.
PART 2 describes the crystallographic characterization of the tubular structure in a tripeptide Ac-Phe-Pro-Trp-OMe (FPW) sequence. The arrangement of the single-file water moleculesin the peptide nanotubes of FPW could be established by X-ray diffraction. In addition, the energetically favoured arrangement of the water wire inside the peptide channels could be modeled by understanding the construction of the peptide nanotube. In particular, the helicalmacrodipole of the peptide nanotube and the water wire dipoles prefer an antiparallel arrangement inside the peptide channels as opposed to parallel arrangements, is established by the classical dipole-dipole interaction energy calculation. In addition, the growth of thenanotubes and the arrangement of the water wires inside the channels could be correlated to the macroscopic dimensions of the crystal by the indexing of the crystal faces and contrasted with the structure of DPUV5. Crystal parameters
FPW: C28H32N4O5.(0.33)H2O; P65; a = b = 21.5674 (3) Å, c = 10.1035 (2) Å; α = β = 90°, γ = 120 °; Z = 6; R = 0.0786, wR2 = 0.1771
Chapter 3 provides the crystal structures of five octapeptide β-hairpin forming sequences and a tripeptide containing a modified amino acid, with modification in the side chain (pseudo-proline, ψH,CH3Pro). The parent peptide, Boc-Leu-Phe-Val-DPro-Pro-Leu-Phe-Val-OMe (DPLP8), was observed to form a strong Type II′β-turn at the DPro-Pro segment, and the strand segments adopting a β-sheet conformation. Two molecules were observed in the asymmetric unit, inclined to each other at approximately 70°. Modification in the strand sequence Phe(2) to Tyr(2) also resulted in a hairpin with identical conformation and similar packing arrangement. The difference was in the solvent content. In both the cases the molecules were packed orthogonal with respect to each other, resulting in the formation of ribbon-like structures in three dimensions. The replacement of Phe(2) and Phe(7) with Valine residues, with the retention of DPro-Pro β-turn segment, results in an entiely different packing arrangement (parallel). Modification of Pro(5) residue of the turn segment to Aib(5) and ψPro, also results in the molecules packing orthogonally to each other. The tripeptide with a modified form of ψPro, namely ψH,CH3Pro, resulted in a folded structure with a Type VIa β-turn, with the amide bond between the Pro-ψH,CH3Pro segment adopting a cis configuration (Kantharaju et al., 2009). Crystal parameters DPLP8: C56H84N8O11 .(0.5) H2O; P21; a = 14.4028 (8), b = 18.9623 (11) Å, c = 25.4903 (17) Å, β = 105.674 ° (4); Z = 4; R = 0.0959, wR2 = 0.2251. YDPP8: C56H84N8O12 .(1.5) H2O; P212121; a = 14.4028 (8), b = 18.9623 (11) Å, c = 25.4903
(17) Å, Z = 8; R = 0.0989, wR2 = 0.2064. PSIP8: C57H86N8O11S1.(1.5) H2O; C2; a = 34.6080 (2), b = 15.3179 (10) Å, c = 25.6025 (15) Å, β = 103.593 ° (3); Z = 4; R = 0.0931, wR2 = 0.2259. DPPV8: C48H84N8O11; P1; a = 9.922 (3), b = 11.229 (4) Å, c = 26.423 (9) Å, α = 87.146 (6), β = 89.440° (6), γ = 73.282 (7); Z = 2; R = 0.1058, wR2 = 0.2354. DPUF8: C57H88N8O11 .(1.5) H2O; P21; a = 18.410 (2), b = 23.220 (3) Å, c = 19.240 (3) Å, β = 118.036 ° (4); Z = 4; R = 0.1012, wR2 = 0.2061. PSPL3: C22H37N3O5S1; P31; a = b = 14.6323 (22), c = 10.4359 (22) Å, α = β = 90°, γ = 120°; Z = 3; R = 0.0597, wR2 = 0.1590.
Chapter 4 describes the crystal structure and molecular conformation of Type I′β-turn nucleated hairpin. The incorporation of Aib-DPro segment in the middle of Leu-Val-Val strands in the peptide sequence Boc-Leu-Val-Val-Aib-DPro-Leu-Val-Val-OMe results in an obligatory Type I′ turn containing hairpin. The molecular conformation and the packing arrangement of the molecules in the crystal are contrasted with the only Type I′β-hairpin reported in the literature and with a sequence where the turn residues are flipped and strand residues replaced with Phe(2) and Phe(7). Crystal parameters UDPV8: C47H84N8O11.2(C3H7NO); P21; a = 11.0623 (53), b = 18.7635 (89) Å, c = 16.6426
(80) Å, β = 102.369 (8); Z = 2; R = 0.0947, wR2 = 0.1730.
Chapter 5 provides the crystal structures of three polymorphic forms of β-hairpins. The structure of BH1P8 provides new insights into the packing of hairpins inclined orthogonally to each other. The two polymorphic forms differ not only in their modes of packing in crystals but also in the strong and weak interactions stabilizing the packing arrangements. The polymorphic forms of DPUFP8 differ only in the content of the solvent in the asymmetric unit and the role it plays in bridging the symmetry related pairs of molecules. The polymorphic form YDPPP8 crystallized in a completely different space group, revealing a completely different mode of packing and also the cocrystallized solvent participating in a different set of interactions. Crystal parameters
BH1P8: C54H78N8O11.H2O; P212121; a = 18.7511 (9), b = 23.3396 (11) Å, c = 28.1926 (13)Å; Z = 8; R = 0.1208, wR2 = 0.2898. DPUFP8: C55H84N8O11. (0.5) H2O; P21; a = 18.0950 (4), b = 23.0316 (5) Å, c = 18.6368 (5) Å, β = 117.471 (2); Z = 4; R = 0.0915, wR2 = 0.2096. YDPPP8: C56H83N8O12. (1.5) H2O; P21; a = 14.3184 (8), b = 18.9924 (9) Å, c = 25.1569 (14) Å, β = 105.590 (4); Z = 4; R = 0.1249, wR2 = 0.2929.
Chapter 6 provides a comprehensive overview of the β-hairpin peptide crystal structures published in the literature as well as those included in the thesis. The hairpins are classified based on the residues composing the β-strands and the mode of their packing in the crystals. In the crystal structures the hairpins are observed to adopt either a Type II′ or Type I′β-turns. The indexing of the crystal faces of a few representative hairpin peptides crystallographically characterized in this thesis, provides a rational explanation for the preferential growth of the crystals in certain directions, when correlated with the strong directional forces (hydrogen bonding) and weak interactions (van der Waals, aromatic-aromatic) observed in the crystal packing. The insights gained by these studies would be highly valuable in understanding the nucleation and growth of β-hairpin peptides and the formation of β-sheet structures.
Appendix I describes the Cambridge Structural Database (CSD) analysis of the conformational preferences of the proline residues found in the peptide crystal structures. The frequency distributions of the backbone φ, ψ and ω and side chain χ1, χ2, χ3, χ4 and θ torsion angles of the proline residues are calculated, tabulated and represented as graphical plots. The correlation between the backbone and endocyclic torsion angles provides for a clear evidence of the role of a particular torsion variable χ2 in deciding the state of puckering. In addition, the endocyclic bond angles also appear to be correlated, relatively strongly, with the χ2 torsion. This provides a geometrical explanation of the factors governing the puckering of the proline ring.
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Bayesian models and algoritms for protein secondary structure and beta-sheet predictionAydin, Zafer 17 September 2008 (has links)
In this thesis, we developed Bayesian models and machine learning algorithms for protein secondary structure and beta-sheet prediction problems. In protein secondary structure prediction, we developed hidden semi-Markov models, N-best algorithms and training set reduction procedures for proteins in the single-sequence category. We introduced three residue dependency models (both probabilistic and heuristic) incorporating the statistically significant amino acid correlation patterns at structural segment borders. We allowed dependencies to positions outside the segments to relax the condition of segment independence. Another novelty of the models is the dependency to downstream positions, which is important due to asymmetric correlation patterns observed uniformly in structural segments. Among the dataset reduction methods, we showed that the composition based reduction generated the most accurate results. To incorporate non-local interactions characteristic of beta-sheets, we developed two N-best algorithms and a Bayesian beta-sheet model. In beta-sheet prediction, we developed a Bayesian model to characterize the conformational organization of beta-sheets and efficient algorithms to compute the optimum architecture, which includes beta-strand pairings, interaction types (parallel or anti-parallel) and residue-residue interactions (contact maps). We introduced a Bayesian model for proteins with six or less beta-strands, in which we model the conformational features in a probabilistic framework by combining the amino acid pairing potentials with a priori knowledge of beta-strand organizations. To select the optimum beta-sheet architecture, we analyzed the space of possible conformations by efficient heuristics, in which we significantly reduce the search space by enforcing the amino acid pairs that have strong interaction potentials. For proteins with more than six beta-strands, we first computed beta-strand pairings using the BetaPro method. Then, we computed gapped alignments of the paired beta-strands in parallel and anti-parallel directions and chose the interaction types and beta-residue pairings with maximum alignment scores. Accurate prediction of secondary structure, beta-sheets and non-local contacts should improve the accuracy and quality of the three-dimensional structure prediction.
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Mimes synthétiques de feuillets bêta : conception, synthèse et évaluation de leur capacité à moduler l'agrégation du peptide bêta-amyloïde 1-42. / Synthetic mimics of beta-sheets : design, synthesis and evaluation of their ability to modulate the aggregation of the beta-amyloid 1-42 peptide.Tonali, Nicolo 24 November 2016 (has links)
La maladie d'Alzheimer (MA) est une maladie neurodégénérative liée à l’oligomérisation et à la fibrillation du peptide bêta amyloïde, avec Abêta 1-42 étant le plus agrégeant et neurotoxique. La cause exacte de la maladie d'Alzheimer n’est pas encore connue et donc il n'y a pas de traitement efficace contre cette maladie.Une stratégie prometteuse pourrait être l'inhibition de l'oligomérisation de monomères solubles d'Abêta;, en stabilisant la conformation non structurée native du peptide, à travers l’utilisation de composés capables d'empêcher la formation de feuillets bêta. En effet, les peu d'études structurales des espèces oligomériques et des fibrilles ont révélé que l'agrégation implique des structures en feuillet bêta.De nombreuses petites molécules ont été proposées pour leur capacité à inhiber ou moduler l'agrégation de Abêta 1-42 et sa toxicité. Cependant, le processus d'agrégation est très complexe et difficile à contrôler. Des études récentes indiquent que les oligomères solubles transitoires précédant la formation de fibrilles sont les espèces les plus toxiques. Ainsi, le développement d'inhibiteurs ciblant à la fois l’oligomérisation et la fibrillation reste difficile en dépit de son importance thérapeutique. Les peptides sont des alternatives raisonnables aux autres produits pharmaceutiques chimiques. En particulier, l'inhibition de l'agrégation de Abêta; a été ciblée en utilisant des éléments d'auto-reconnaissance (SRE), qui sont des séquences d'acides aminés clés impliqués dans les différentes espèces agrégées. À notre connaissance, l'utilisation de petites "bêta-hairpins" acycliques a été très rarement explorée comme ligands de feuillets-bêta et comme inhibiteurs de l'agrégation.Comme l’agrégation de Abêta est un processus dynamique et complexe, nous avons supposé que les "bêta-hairpins" flexibles pourraient mieux s'adapter dans l'interaction avec les différentes conformations de Abêta 1-42 présents pendant le processus d'agrégation, et en particulier dans les premiers stades de l'oligomérisation. Nous avons conçu des mimes de feuillets bêta acycliques basés sur un squelette semi-rigide de type pipéridine-pyrrolidine comme inducteur flexible de coude bêta, et sur différents SREs de Abêta 1-42. Le choix des SREs a été basée sur les structures d'oligomères et fibrilles.La capacité de tous les composés a été évaluée par spectroscopie de fluorescence à la thioflavine-T pour déterminer l'activité inhibitrice. Les résultats obtenus ont été complétés par microscopie à transmission électronique. Les composés les plus prometteurs ont également été étudiés par électrophorèse capillaire (EC) pour suivre les étapes très précoces du processus d'oligomérisation. Les meilleurs inhibiteurs ont été étudiés afin de déterminer leur capacité à réduire la toxicité de Abêta 1-42 sur des cellules de neuroblastome SH-SY5Y.Nous rapportons également dans cette thèse les études conformationnelles, effectuées par RMN et réalisées pour étudier et confirmer la capacité de composés de se structurer en solution comme des "bêta-hairpins".Enfin, nous avons développé une voie de synthèse pour obtenir de nouvelles chaînes peptidomimétiques composées par des résidus aza-aminoacides. Dans la littérature, seules des séquences peptidiques comportant un seul résidu aza-aminoacide au milieu, sont connues, mais les propriétés de liaison hydrogène d’un 2:1 [aza/alpha]-tripeptide ne sont pas encore, à notre connaissance, étudiées ni exploitées dans la conception d’inhibiteurs des interactions protéine-protéine. Nous présentons dans cette thèse les études conformationelles réalisées par RMN, cristallographie aux rayons X et modélisation moléculaire.On peut conclure que les éléments structurels décrits dans cette thèse fournissent des indications précieuses dans la compréhension du processus d'agrégation du peptide Abêta 1-42 et dans la conception de nouveaux " bêta-hairpins" acycliques ciblant des protéines amyloïdes. / Amyloidosis is the generic word to name a group of diseases that are caused by the misfolding and extracellular accumulation of various proteins. Alzheimer’s disease (AD) is a neurodegenerative disorder linked to oligomerization and fibrillization of amyloid β peptides, with Aβ 1-42 being the most aggregative and neurotoxic one. To date, the exactly cause of the Alzheimer's disease is not still known and so there is no effective treatment of the disease.An attractive strategy for treating AD could be the inhibition of the oligomerization of soluble Aβ monomers, by stabilizing the native unstructured conformation of the peptide, using compounds able to prevent the formation of β-sheets. Indeed, few structural studies of oligomeric species and fibrils revealed that the aggregation involves β-sheet structures.A large number of small molecules have been proposed for their ability to inhibit or modulate Aβ1-42 aggregation and toxicity. However, the aggregation process is highly complex, and extremely difficult to control. Recent studies indicate that soluble transient oligomers preceding fibril formation are highly toxic species. Thus, the development of inhibitors targeting both oligomerization and fibrillization remains challenging despite its therapeutic significance. Peptides are today reasonable alternatives to small molecule pharmaceuticals. In particular, inhibition of Aβ-aggregation has been targeted using self-recognition elements (SREs), which are key amino acid sequences involved in the different aggregated species. To our knowledge, the use of small acyclic β-hairpins has been very rarely explored as β-sheet binders and inhibitors of aggregation.As Aβ-aggregation is a dynamic and complex process, we hypothesized that flexible β-hairpins could adapt themselves in the interaction with the different Aβ1-42 conformations present during the aggregation process, and in particular in the early stages of oligomerization. We designed acyclic β-hairpin mimics based on a piperidine-pyrrolidine semi-rigid scaffold developed recently as a flexible β-turn inducer, and on different SREs of Aβ1-42. The choice of the SREs was based on oligomer and fibril structures.The ability of all compounds to influence the Aβ 1-42 fibrillization process was evaluated by thioflavin-T fluorescence spectroscopy, used as an evaluation tool to define the inhibitory activity. The obtained results were successively supplemented by transmission electron microscopy. The most promising compounds were also studied by Capillary Electrophoresis (CE) using a method we recently proposed to monitor the very early steps of the oligomerization process overtime. The best inhibitors were investigated to determine their ability to reduce the toxicity of aggregated Aβ1-42 to SH-SY5Y neuroblastoma cells.Together with the evaluation of these molecules, we report in this thesis the conformational studies performed by NMR. These structure investigations were performed to investigate and confirm the β-hairpin conformational preference of the compounds in solution.Finally, we performed a practical synthetic pathway to obtain new peptidomimetic chains composed by aza-amino acid residues. In the literature only peptide sequence, with just one aza-amino acid residue in the middle, are known, but the hydrogen-bonding properties of 2:1 [Aza/α]-tripeptides have not yet, to our knowledge, been exploited in the design of the inhibition of protein-protein interactions. We present in this thesis the conformational studies of the 2:1 [Aza/α]-tripeptide sequence by NMR analyses, X-ray crystallography and molecular modelling.In conclusion, the structural elements made in this thesis provide valuable insights in the understanding of the aggregation process of Aβ 1-42 peptide and to explore the design of novel acyclic β-hairpin targeting amyloid-forming proteins.
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