Dissertations / Theses on the topic 'Acidic oligopeptides'

Les travaux décrits dans ce manuscrit concernent la synthèse, l’étude structurale et l’évaluation biologique d’oligopeptides abiotiques incorporant le gamma-aminoacide hétérocyclique nommé ATC (acide-4-Aminométhyl-1,3-Thiazole-5-Carboxylique). Les ATCs sont construits autour d’un noyau thiazole et présentent deux points de diversité structurale. De précédents travaux ont déterminé que la présence du noyau thiazole entre les positions alpha et béta bloquait l'angle zéta autour de 0°, structurant les homo-oligomères de poly-(S)-ATCs en une hélice 9 droite et les faisant ainsi entrer dans le domaine des foldamères. Dans une première partie, nous avons entrepris de développer une voie de synthèse simple, flexible et énantiosélective permettant d’obtenir les ATCs stéréochimiquement purs sur une échelle de plusieurs grammes à partir d'alpha-aminoacides commerciaux. L’introduction de la diversité chimique est réalisée via deux étapes-clés que sont la condensation croisée de Claisen et la réaction de cyclisation de Hantzsch. Puis l’identification des marqueurs de structuration RMN et IR-TF des oligomères d'ATCs a été mise à profit pour caractériser le repliement d’hétéro-oligomères combinant ATCs et alpha-aminoacides. Ainsi, une étude structurale par RMN, IR-TF, cristallographie RX et dichroïsme circulaire a démontré que l’enchaînement 1:1 (L)-alpha:(S)-ATC se structurait en un ruban, stabilisé par un réseau intramoléculaire de liaisons hydrogène bifides formant des pseudocycles à 9 et 12 chaînons. La distribution des chaînes latérales le long du squelette principal présente une forte analogie avec l’hélice alpha, ce qui pourrait constituer un atout majeur pour le développement de composés à finalité thérapeutique. La dernière partie de ce travail a porté sur la conception de pseudo-peptides amphipatiques pour des applications en temps qu'antimicrobiens
This manuscript describes the synthesis, the structural study and the biological evaluation of abiotic oligopeptides incorporating the heterocyclic gamma-amino acid ATC (4-Aminomethyl-1,3-Thiazole-5 Carboxylic acid). This original block is built around a thiazole ring and displays two lateral chains. Previous work in our laboratory highlighted that the presence of the thiazole ring between the positions alpha and beta implied that zeta angle was blocked around 0°, thus structuring poly-(S)-ATCs homo-oligomers in a right-handed 9-helix foldamer. First, development of a simple, flexible and enantioselective synthesis on a few grams scale has allowed to get access of a highly diverse ATC library from commercial alpha-amino acids. Introduction of the chemical diversity occurs via two key steps implying a cross-Claisen condensation and a Hantzsch cyclization. Then identification of NMR and FT-IR structural markers of ATC-containing oligomers was used to characterize the folding propensity of hybrid α:ATC oligomers. We demonstrated that 1:1 (L)-alpha:(S)-ATC heterochiral oligomers are structured in solution in a new ribbon-like shape stabilized by a bidentate intramolecular hydrogen bond network forming 9- and 12-membered pseudorings. The distribution of lateral chains along the main skeleton shows a high analogy with alpha-helix thus constituting a major advantage for potential medicinal applications. The last part of this work has focused on the design of amphipathic ATC-containing pseudo-peptides as antimicrobial agents

This thesis discusses two major projects. The first project focuses on understanding the effect of chirality on intrinsic acidity of oligopeptides. Gas-phase acidity (ΔacidG) and related thermochemical parameters (ΔacidH, and ΔacidS), of model N- and C-terminal cysteine polyalanine peptides in which one L-alanine was substituted by a D-alanine viz. CAADA and AADAC, were measured by the extended Cooks kinetic method. Gas-phase acidities of CAADA and AADAC were measured to be about 318 kcal/mol and 322 kcal/mol, respectively. These values are different from the gas-phase acidities of the all L-amino acid containing analogues of the above peptides, but suggest that D-alanine containing peptides show the same trend as their all L-amino acid analogues with the N-terminal cysteine peptide being more acidic than the C-terminal cysteine peptide. However, the difference in the acidities of CAADA and AADAC is about 4 kcal/mol which is about half of the difference between their all L-amino acid analogues. These results also suggest that, presumably, a single L-alanine to D-alanine substitution has a moderate effect on the conformation of the respective peptides. The aim of the second project is to understand how acidic amino acids influence peptide fragmentation during tandem mass spectrometric analysis. A series of model N- and C- terminal glutamic acid polyalanine and polyglycine (EAn, AnE (n=2,3); EGn (n=2,3), GnE (n=2-4)) and cysteine polyalanine (CAn, AnC (n=4-6)) peptides were studied. Primarily, EAn and EGn peptides formed bn ions. In contrast, while EOn peptides formed all yn ions, EAn peptides formed fewer yn ions. Similarly, AnE and GnE peptides also formed bn ions. No major differences were observed in yn ion formation. For both sets of peptides, water loss seemed to trend with the position of glutamic acid. CAn and AnC peptides also formed bn ions, just like their glutamic acid counterparts. However, yn ions were observed only for AnC peptides. For all sets of peptides, ions related to bn and yn ions were also observed.

Il existe, aujourd'hui, de nombreuses et efficaces méthodes de caractérisation structurale tridimensionnelle de composés biologiques en phase condensée (RMN, diffraction des rayons X ou dichroïsme circulaire). Depuis une dizaine d'années, ce champ d'études s'est étendu à la phase gazeuse. Ce travail s'inscrit dans ce contexte et concerne le rôle structurant de Na+ sur les acides aminés Gly et Pro et sur des oligo-peptides de Gly et Ala, en combinant approches théoriques et expérimentales de spectroscopie infrarouge d'ions gazeux par dissociation multiphotonique (IRMPD) couplée à la spectrométrie de masse. Les spectres IRMPD expérimentaux des complexes sodiés d'acide aminé, nous ont permis d'identifier la présence exclusive de la forme zwitterionique dans le cas de Pro-Na+ et la présence de la forme non-zwitterionique dans le cas de Gly-Na+, conformément aux résultats de chimie quantique. Ainsi nous avons fourni la première démonstration directe de la présence d'un zwitterion d'acide aminé en phase gazeuse. Il s'agissait des premiers spectres infrarouge d'ions biologiques en phase gazeuse. L'étude théorique des complexes Glyn-Na+ et Alan-Na+ a montré que, pour n<=5, les conformères de plus basse énergie maximisent l'interaction électrostatique du métal avec les n groupements carbonyles, avec ou sans l'amine terminale. Ce comportement a été confirmé d'une part, par des expériences de spectroscopie IRMPD pour n=2,3 et d'autre part, par la détermination des énergies de liaison de ces complexes par la méthode cinétique de Cooks (n=2-4). Pour l'étude théorique de Glyn-Na+, 5<=n<=10, nous avons couplé des recherches conformationnelles Monte-Carlo basées sur des calculs de champ de forces AMBER, à des optimisations par calculs de type ri-BLYP utilisant l'approximation "résolution de l'identité". Cette approche a permis d'explorer en détail des sur! faces de potentiel très complexes. On peut distinguer deux classes limites de conformères, celle où le peptide est globulaire et celle où il adopte une conformation en hélice alpha ou 310. Nous avons montré que les structures les plus basses en énergie présentent le plus souvent une complexation tétradentate avec une forte auto-solvatation. Ces structures sont toutes globulaires pour n<10. Dans le cas de Gly10-Na+, le conformère le plus bas en énergie a une structure globulaire autour du sodium et un domaine de cinq résidus en hélice 310.

The altered acidities of amino acid residues in folded proteins can be used as a good indication for the diverse functions, stabilities as well as folding-unfolding states of the proteins. Previously, our group has investigated the gas phase acidities of a series of cysteine containing peptides of four residues and longer. The results showed that the helix macrodipole might have a significant influence on the acidities of these peptides. In this work, the gas phase acidities of isomeric small cysteine containing di- and tri-peptides were investigated experimentally and computationally. The gas phase acidities (ΔacidG) and related thermochemical quantities (ΔacidH and ΔacidS) were determined by using the extended Cooks kinetic method. A triple-quadruple mass spectrometer interfaced with an electrospray ionization source was employed for the study. The gas phase acidities of the N-terminal cysteine peptides (CysAla1,2NH2 and CysGly1,2NH2) were determined to be in the range of 321-323 kcal/mol, and the acidities of the C-terminal cysteine peptides (Ala1,2CysNH2 and Gly1,2CysNH2) were around 327- 331 kcal/mol. The results showed that theN-cysteine peptides were more acidic than the corresponding C-cysteine peptides, tri-peptides were stronger acids than di-peptides, and the acidities of cysteine-polyglycine peptides were close to those of the cysteine-polyalanine analogues. Computational studies were performed through conformer search, geometry optimization, and energy calculations using the Spartan and the Gaussian suite of programs. The results showed that the low energy conformations of all deprotonated peptides were coils. The greater acidities of the N-cysteine peptides were likely due to the stronger hydrogen-bonding interactions in the deprotonated N-cysteine peptides, which efficiently stabilized the thiolate anions. The theoretically predicted acidities were in good agreements with the experimental results.

Cryptosporidium parvum, parasite de l'épithélium intestinal, est reconnu comme une cause majeure de diarrhée chez les jeunes enfants à l'origine d'une malnutrition et d'un retard de croissance. Afin d'explorer les mécanismes de cette malnutrution, nous avons étudié l'expression intestinale de transporteurs d'acides aminés, EAAT3 et NBAT, et d'oligopeptides PEPT1, au cours de l'infection dans un modèle de crytosporidiose aigue͏̈ chez le raton âgé de 4 à 50 jours. Nous montrons que l'implantation du parasite induit au pic de l'infection une dérégulation respectivement négative et positive de l'expression de EAAT3 et de PEPT1 tout le long de l'intestin grêle. Ces dérégulations impliquent des mécanismes transcriptionnels et post-traductionnels liés d'une part à l'implantation du parasite, et d'autre part à l'hypophagie et à la réponse immunitaire muqueuse. Ces résultats mettent en avant l'intérêt d'une prise en charge nutritionnelle précoce et prolongée des patients infectés par C. Parvum
Crytosporidium parvum is now recognized as being a major cause of diarrheal disease leading to malnutrition and growth retardation in young children. In order to assess the mechanism of C. Parvum-induced malnutrution, we investigated the intestinal expression of animo acid (EAAT3 and NBAT) and oligopeptides (PEPT1) transporters in an acute model of cryptosporidiosis in suckling rat aged from 4 to 50 days. We shown that parasite development induces a down- and up-regulation of PEPT1 and EAAT3 expression respectively along the entire small intestine at the peak of infection. Both transcriptional and post-translational mechanisms are involved in response to parasite implantation, hypophagia and mucosal immune response. .

The gas-phase hydrogen/deuterium (H/D) exchange of protonated di- and tripeptides containing a basic amino acid residue has been studied with a Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometer. Bimolecular reactions are monitored as a function of time providing exchange efficiencies and temporal distributions for the peptide ions. Results from these experiments indicated that position of the basic residue within the peptide (i.e. N-terminal, internal, or C-terminal) influences gas-phase H/D exchange, suggesting unique peptide ion conformations. The FT-ICR mass spectrometer employed for these gas-phase H/D exchange studies was modified from its original design. Instrument modifications include development of an internal matrix assisted laser desorption ionization (MALDI) source for peptide protonation. In addition, a two-section cell was utilized, allowing control of ion motion and factors affecting gas-phase ion molecule reactions. Systems investigated in these gas-phase H/D exchange studies are peptides containing the same amino acid residues but different sequences. These sequence isomers display dissimilar reaction efficiencies and temporal distributions for deuterium incorporation depending on the primary structure of the peptide ion. Specifically, [M+H]+ peptide ions containing a N-terminal basic residue demonstrate unique H/D exchange behavior when compared to their internal and C-terminal counterparts. These differences are attributed to dissimilar intramolecular bridging interactions involved with inductive stabilization of the charge site. Gas-phase H/D exchange of peptide sequence isomers was also probed with various deuterium reagents. Findings suggest that different reagents also influence H/D exchange reaction rate efficiencies and temporal distributions. These dissimilarities are ascribed to relative gas-phase basicity and proposed mechanistic exchange differences for the deuterium reagents.

Nous nous intéressons à la production de peptides bioactifs dans des laits fermentés par la bactérie lactique Streptococcus thermophilus. Pour ce faire, il est nécessaire que cette bactérie en internalise le moins possible lors de sa croissance. Il était donc important de caractériser le système protéolytique S. thermophilus. Tout d’abord, les relations phylogéniques liant 30 souches de S. thermophilus ont été recherchées par MLST. Ensuite, un système de transport de type ABC qui semble fonctionnel a été identifié chez la souche LMD-9 et appelé OTS. Une étude de la variabilité des systèmes de transport Ami et OTS des 30 souches de S. thermophilus a été réalisée. Enfin, l’hydrolyse des caséines par la protéase PrtS de S. thermophilus a été étudiée. Cette protéase habituellement ancrée à la paroi de la bactérie est retrouvée chez la souche 4F44 également sous forme libre. La séquence protéique de PrtS4F44, différente de celle de PrtS de la souche LMD 9 (PrtSLMD-9), n’est pas la cause de la libération partielle de PrtS4F44. La sortase A, acteur de l’ancrage de PrtS à la paroi de la bactérie, présente chez la souche 4F44 (srtA4F44) un allèle différent de celui de la souche LMD-9 (srtALMD-9). En effet, PrtSLMD-9 se trouve libérée lorsque srtALMD-9 est remplacée par srtA4F44 dans la souche LMD-9 montrant ainsi que SrtA4F44 est déficiente, entrainant par conséquent un défaut d’ancrage de PrtS4F44 et sa libération partielle dans le milieu extracellulaire. L’hydrolyse des caséinates bovines totales par la forme libre de PrtS4F44 a permis d’obtenir des peptides bioactifs qui pourront être utilisés pour la fonctionnalisation de produits laitiers fermentés
We are interested in the production of bioactive peptides in fermented milk by the lactic acid bacterium Streptococcus thermophilus. For this, it requires that the bacterium internalize them as few as possible during its growth. Therefore, it was important to characterize the proteolytic system of S. thermophilus. First, phylogenetic relationships linking 30 S. thermophilus strains have been searched by MLST. Secondly, an ABC-type transport system which seems to be functional was identified in the LMD-9 strain and named OTS. A study of the variability of Ami and OTS transport systems of the 30 strains of S. thermophilus was performed. Finally, the hydrolysis of caseins by proteinase PrtS of S. thermophilus was studied. This proteinase usually anchored to the wall of the bacterium was also found in a free form in strain 4F44. The protein sequence of PrtS4F44, different from the one of PrtS in the LMD-9 strain (PrtSLMD-9), is not the cause of the partial release of PrtS4F44. Sortase A, the actor of the anchoring of PrtS to the wall of the bacteria, presents different alleles between the strain 4F44 (srtA4F44) and the LMD-9 strain (srtALMD-9). Indeed, PrtSLMD-9 is released when srtALMD-9 is replaced by srtA4F44 in the strain LMD-9 showing that SrtA4F44 is deficient, causing consequently a default of PrtS4F44 anchoring and its partial release into the extracellular medium. Additionally, hydrolysis of bovine caseinates was performed using the free form PrtS4F44 and allowed the production of bioactive peptides that can be used for the functionalization of fermented dairy products

Thesis (Ph. D.)--School of Pharmacy and Dept. of Chemistry. University of Missouri--Kansas City, 2005.
"A dissertation in pharmaceutical sciences and chemistry." Advisor: Ashim K. Mitra. Typescript. Vita. Description based on contents viewed Nov. 21, 2007; title from "catalog record" of the print edition. Includes bibliographical references (leaves 238-258). Online version of the print edition.

Mesoporous silica nanoparticles (MSNPs) possess large surface areas and ample pore space that can be readily modified with specific functional groups for targeted binding of bioactive materials to be transported through cellular barriers. Engineered silica nanoparticles (ESNP) have been used extensively to deliver bio-active materials to target intracellular sites, including as non-viral vectors for nucleic acid (DNA/RNA) delivery such as for siRNA induced interference. The reverse process guided by the same principles is called “nanoharvesting”, where valuable biomolecules are carried out and separated from living and functioning organisms using nano-carriers. This dissertation focuses on ESNP design principles for both applications. To investigate the bioactive materials loading, the adsorption of antioxidant flavonoids was investigated on titania (TiO2) functionalized MSNPs (mean particle diameter ~170 nm). The amount of flavonoid adsorbed onto particle surface was a strong function of active group (TiO2) grafting and a 100-fold increase in the adsorption capacity was observed relative to nonporous particles with similar TiO2 coverage. Active flavonoid was released from the particle surface using citric acid-mediated ligand displacement. Afterwards, nanoharvesting of flavonoids from plant hairy roots is demonstrated using ESNP in which TiO2 and amine functional groups are used as specific binding sites and positive surface charge source, respectively. Isolation of therapeutics was confirmed by increased pharmacological activity of the particles. After nanoharvesting, roots are found to be viable and capable of therapeutic re-synthesis. In order to identify the underlying nanoparticle uptake mechanism, TiO2 content of the plant roots was quantified with exposure to nanoparticles. Temperature (4 or 23 °C) dependent particle recovery, in which time dependent release of ESNP from plant cells showed a similar trend, indicated an energy independent process (passive transport). To achieve the selective separation and nanoharvesting of higher value therapeutics, amine functionalized MSNPs were conjugated with specific functional oligopeptides using a hetero-bifunctional linker. Fluorescence spectroscopy was used to confirm and determine binding efficiency using fluorescently attached peptides. Binding of targeted compounds was confirmed by solution depletion using liquid chromatography–mass spectrometry. The conjugation strategy is generalizable and applicable to harvest the pharmaceuticals produced in plants by selecting a specific oligopeptide that mimic the appropriate binding sites. For related gene delivery applications, the thermodynamic interaction of amine functionalized MSNPs with double-stranded (ds) RNA was investigated by isothermal titration calorimetry (ITC). The heat of interaction was significantly different for particles with larger pore size (3.2 and 7.6 nm) compared to that of small pore particles (1.6 nm) and nonporous particles. Interaction of dsRNA also depended on molecular length, as longer RNA (282 base pair) was unable to load into 1.6 nm particles, consistent with previous confocal microscopy observations. Calculated thermodynamic parameters (enthalpy, entropy and free energy of interaction) are essential to design pore size dependent dsRNA loading, protection and delivery using MSNP carriers. While seemingly diverse, the highly tunable nature of ESNP and their interactions with cells are broadly applicable, and enable facile nano-harvesting and delivery based on a continuous uptake-expulsion mechanism.

Thesis (Ph.D.)--York University, 2003. Graduate Programme in Chemistry.
Typescript. Includes bibliographical references. Also available on the Internet. MODE OF ACCESS via web browser by entering the following URL: http://wwwlib.umi.com/cr/yorku/fullcit?pNQ99165

博士
國立臺灣科技大學
化學工程系
101
The equilibrium constants for metal ions (Fe3+, Cr3+, Cu2+, Ni2+, Co2+) with ligands (glycine, glycylglycine, glycylglycyglycine, L-norvaline, ferulic acid and gallic acid) were reported in this work. The protonation constants of these ligands along with the formation of metal-ligand complex in binary and ternary systems were studied by using pH-potentiometric titration in aqueous solution at 298.15K and an ionic strength 0.15 mol‧dm-3 of NaNO3. The complexation model for each system was refined by software program “HYPERQUAD 2008” from potentiometric titration data. Moreover, Gibbs free energy of reaction (?愉G) that obtained from Gaussian modeling program were used to verify the contributing binding site of the ligands and to predict the structure of the one metal and one ligand complexes. The phenomenon that occurred in each system was discussed. In terms of metal ion, the trend of stability constant decreases in the following order Fe3+ > Cr3+ > Cu2+ > Ni2+ > Co2+, which is affected by its electrical charge and following Irving-William rule for divalent metal ion. In terms of the ligand, the system with less bulky structure (glycine) and more negatively charged ligand (gallic acid) formed more stable complex than the other ligands. While for system with gycine oligopeptide, nitrogen in peptide backbone enhanced the complex stability while it existed in deprotonated form. In ternary system that contains gallic acid, the stability constant of the complexes are more stable than the systems with ferulic acid. The stability of mixed ligand complexes was quantitatively compared with corresponding binary complexes in term of ∆logK and logX.

Peptides have assumed considerable importance in pharmaceutical industry and vaccine research. Understanding the structural features of these peptide molecules can be effective not only in mimicking natural proteins but also in the design of new biomaterials. Polypeptide sequences consisting of twenty genetically coded amino acids possess structural flexibility, which makes the predictions difficult. However, the introduction of non-protein amino acids into the peptide chain restricts the available range of backbone conformations and acts as stereochemical directors of polypeptide chain folding. Such conformationally rigid residues allow the formation of well defined structures like helices, strands etc, which further assemble into super secondary structural motifs by flexible linkages. Crystal structure determination of the oligopeptides by X-ray diffraction gives insight into the specific conformational states, modes of aggregation, hydrogen bond interactions, solvation of peptides and various weakly polar interactions involving the side chains of aromatic residues (Phe, Trp and Tyr). In β-, γ- and higher ω-amino acids, due to the insertion of one or more methylene groups between the N- and Cα-atoms into the peptide backbone the accessible conformational space is greater than the α-amino acids. The β-, γ-, δ-…. amino acid residues belong to the family of ω-amino acids. Extensive research in the field of β-peptides, which have been experimentally verified or theoretically postulated, has assigned several helices, turns and sheets. The use of ω-amino acid residues in conjunction with α-residues permits systematic exploration of the effects of introducing additional backbone atoms into well-characterized α-peptide structures. The observation of new families of hydrogen bonded motifs in the hybrid peptides containing α- and ω-amino acids are the recent interest in this regard. This thesis reports results of X-ray crystallographic studies of eighteen designed peptides and four protected ω-amino acids listed below. Within brackets are given the abbreviations used for the sequences (Symbol U represents Aib). The ω-amino acids reported in this thesis are: (S)-β3-HAla (β3-homoalanine), (R)-β3-HVal, (S)-β3-HVal (β3-homovaline), (S)-β3-HPhe (β3-homophenylalanine), (S)-β3-HPro (β3-homoproline), βGly (β-homoglycine), γAbu (gamma aminobutyric acid) and δAva (delta aminovaleric acid). 1. Boc-Leu-Trp-Val-OMe (LWV), C28H42N4O6 2. Ac-Leu-Trp-Val-OMe (Space group P21) (LWV1), C25H36N4O5 3. Ac-Leu-Trp-Val-OMe (Space group P212121) (LWV2), C25H36N4O5 4. Boc-Leu-Phe-Val-OMe (LFV), C26H41N3O6 5. Ac-Leu-Phe-Val-OMe (LFV1), C23H35N3O5 6. Boc-Ala-Aib-Leu-Trp-Val-OMe (AULWV), C35H54N6O8 7. Boc-Trp-Trp-OMe (WW), C28H32N4O5 8. Boc-Trp-Aib-Gly-Trp-OMe. (WUGW), C34H42N6O7 9. Boc-Leu-Trp-Val-Ala-Aib-Leu-Trp-Val-OMe (H8AU), C57H84N10O11 10. Boc-(S)-β3-HAla-NHMe (BANH), C10H20N2O3 11. Boc-(R)-β3-HVal-NHMe (BVNH), C12H24N2O3 12. Boc-(S)-β3-HPhe-NHMe (BFNH), C16H24N2O3 13. Boc-(R)-β3-HVal-(R)-β3-HVal-OMe (BVBV), C18H34N2O5 14. Boc-(R)-β3-HVal-(S)-β3-HVal-OMe (LVDV), C18H34N2O5 15. Boc-(S)-β3-HPro-OH (BPOH), C11H19N1O4 16. Boc-Leu-Phe-Val-Aib-(S)-β3-HPhe-Leu-Phe-Val-OMe (UBF8), C60H88N8O11 17. Piv-Pro-Gly-NHMe (PA1), C13H23N3O3 18. Piv-Pro-βGly-NHMe (PB1), C14H25N3O3 19. Piv-Pro-βGly-OMe (PBO), C14H24N2O4 20. Piv-Pro-δAva-OMe (PDAVA), C16H28N2O4 21. Boc-Pro-γAbu-OH (BGABU), C14H24N2O5 22. Boc-Aib-γAbu-OH (UG), C13H24N2O5 23. Boc-Aib-γAbu-Aib-OMe (UGU), C18H33N3O6 The thesis is divided into seven chapters. Chapter 1 gives a general introduction to the stereochemistry of polypeptide chains and the secondary structure classification: helices, β-sheets and β-turns followed by an overview of different types of weakly polar interactions involving the side chains of aromatic amino acid residues. This section also provides a brief overview of the conformational analysis of β-, γ- and higher ω-amino acid residues in oligomeric β-peptides and in α,ω-hybrid peptides. A brief discussion on X-ray diffraction and solution to the phase problem is also presented. Chapter 2 describes the crystal structures of the peptides, Boc-Leu-Trp-Val-OMe (LWV), the two polymorphs of Ac-Leu-Trp-Val-OMe (LWV1 and LWV2), Boc-Leu-Phe-Val-OMe (LFV), Ac-Leu-Phe-Val-OMe (LFV1) and Boc-Ala-Aib-Leu-Trp-Val-OMe (AULWV), in order to explore the nature of interactions between aromatic rings, specifically the indole side chain of Trp residues [1]. Peptide LWV adopts a type I β-turn conformation, stabilized by an intramolecular 4→1 hydrogen bond. Molecules of LWV pack into helical columns stabilized by two intermolecular hydrogen bonds, Leu(1)NH…O=CTrp(2) and Indole NH…O=CLeu(1). The superhelical columns further pack into the tetragonal space group P43 by means of a continuous network of indole - indole interactions. The peptide Ac-Leu-Trp-Val-OMe crystallized in two polymorphic forms: P21 (LWV1) and P212121 (LWV2). In both forms, the peptide backbone is extended and the crystal packing shows anti-parallel β-sheet arrangement. Similarly, extended strand conformation and anti-parallel β-sheet formation are also observed in the Phe containing analogs, LFV and LFV1. The pentapeptide AULWV adopts a short stretch of 310-helix. Analysis of aromatic - aromatic and aromatic - amide interactions in the structures of peptides LWV, LWV1 and LWV2 are reported along with the examples of 12 Trp containing peptides from the Cambridge Structural Database. The results suggest that there is no dramatic preference for the orientation of two proximal indole rings. In Trp containing peptides specific orientations of the indole ring, with respect to the preceding and succeeding peptide units, appear to be preferred in β-turns and extended structures. Crystal parameters LWV: C28H42N4O6; P43; a = 14.698(1) Å, b = 14.698(1) Å, c = 13.975(2) Å; Z = 4; R = 0.0737, wR2 = 0.1641. LWV1: C25H36N4O5; P21; a =10.966(3) Å, b = 9.509(2) Å; c = 14.130(3) Å, β = 104.94(1)°; Z = 2; R = 0.0650, wR2 = 0.1821. LWV2: C25H36N4O5; P212121; a = 9.533(6) Å, b = 14.148(9) Å, c = 19.53(1) Å, Z = 4; R = 0.0480, wR2 = 0.1365. LFV: C26H41N3O6; C2; a = 31.318(8) Å, b = 10.022(3) Å, c = 9.657(3) Å, β = 107.41(1)°; Z = 4; R = 0.0536, wR2 = 0.1328. LFV1: C23H35N3O5; P212121; a = 9.514(8) Å, b = 13.56(1) Å, c = 20.04(2) Å, Z = 4; R = 0.0897, wR2 = 0.1960. AULWV: C35H54N6O8.2H2O; P21; a = 9.743(3) Å, b = 22.807(7) Å, c = 10.106(3) Å, β = 105.73(2)°; Z = 2; R = 0.0850; wR2 = 0.2061. Chapter 3 describes the crystal structures of three peptides containing Trp residues at both N- and C-termini of the peptide backbone: Boc-Trp-Trp-OMe (WW), Boc-Trp-Aib-Gly-Trp-OMe (WUGW) and Boc-Leu-Trp-Val-Ala-Aib-Leu-Trp-Val-OMe (H8AU). Peptide WW adopts an extended conformation and the molecules pack into an arrangement of parallel β-sheet in crystals, stabilized by three intermolecular N-H…O hydrogen bonds. The potential hydrogen bonding group NE1H of Trp(1), which does not take part in hydrogen bonding interaction with an oxygen acceptor participate in an intermolecular N-H…π interaction. Peptide WUGW adopts a folded structure, stabilized by a consecutive type II-I’ β-turn conformation. The crystal of WUGW contains a stoichiometric amount of chloroform in two distinct sites each with an occupancy factor of 0.5 and the structure provides examples of N-H…π, C-H…π, π…π, N-H…Cl, C-H…Cl and C-H…O interactions [2]. The molecular conformation of H8AU reveals a 310-helix. The crystal structure of H8AU reveals an interesting packing motif in which helical columns are stabilized by side chain - backbone hydrogen bond involving the indole NH of Trp(2) as donor and C=O group of Leu(6) as acceptor of a neighboring molecule, which closely resembles the hydrogen bonding pattern obtained in the tripeptide LWV [1]. Helical columns also associate laterally and strong interactions are observed between the Trp(2) and Trp(7) residues on neighboring molecules [3]. The edge-to-face aromatic interactions between the indoles suggest a potential C-H…π interaction involving the CE3H of Trp (2) Crystal parameters WW: C28H32N4O5; P212121; a = 5.146(1) Å, b = 14.039(2) Å, c = 35.960(5) Å; Z = 4; R = 0.0503, wR2 = 0.1243. WUGW: C34H42N6O7.CHCl3; P21; a = 12.951(5) Å, b = 11.368(4) Å, c = 14.800(5) Å, β = 101.41(2)°; Z = 2; R = 0.1095, wR2 = 0.2706. H8AU: C57H84N10O11; P1; a = 10.494(7) Å, b = 11.989(7) Å, c = 13.834(9) Å, α = 70.10(1)°, β = 82.74(1)°, γ = 78.96(1)°; Z = 1; R = 0.0855, wR2 = 0.1965. Chapter 4 describes the crystal structures of four protected β-amino acid residues, Boc-(S)-β3-HAla-NHMe (BANH); Boc-(R)-β3-HVal-NHMe (BVNH); Boc-(S)-β3-HPhe-NHMe (BFNH); Boc-(S)-β3-HPro-OH (BPOH) and two β-dipeptides, Boc-(R)-β3-HVal-(R)-β3-HVal-OMe (BVBV); Boc-(R)-β3-HVal-(S)-β3-HVal-OMe (LVDV). Gauche conformations about the Cβ-Cα bonds (θ ~ ± 60°) are observed for the β3-HPhe residue in BFNH and all four β3-HVal residues in the dipeptides BVBV and LVDV. Trans conformations (θ ~ 180°) are observed for β3-HAla residues in both independent molecules in BANH and for the β3-HVal and β3-HPro residues in BVNH and BPOH, respectively. In all these cases except for BPOH, molecules associate in the crystals via intermolecular backbone hydrogen bonds leading to the formation of sheets. The polar strands formed by β3-residues aggregate in both parallel (BANH, BFNH, LVDV) and anti-parallel (BVNH, BVBV) fashion. Sheet formation accommodates both the trans and gauche conformations about the Cβ - Cα bonds [4]. Crystal parameters BANH: C10H20N2O3; P1; a = 5.104(2) Å, b = 9.469(3) Å, c = 13.780(4) Å, α = 80.14(1)°, β = 86.04(1)°, γ = 89.93(1)°; Z =2; R = 0.0489, wR2 = 0.1347. BVNH: C12H24N2O3; P212121; a = 8.730(2) Å, b = 9.741(3) Å, c = 17.509(5) Å; Z = 4; R = 0.0479, wR2 = 0.1301. BFNH: C16H24N2O3; C2; a = 20.54(1) Å, b = 5.165(3) Å, c = 16.87(1) Å, β = 109.82(1)°; Z = 4; R = 0.0909, wR2 = 0.1912. BVBV: C18H34N2O5; P212121; a = 9.385(2) Å, b = 11.899(2) Å, c = 19.199(4) Å; Z = 4; R = 0.0583, wR2 = 0.1589. LVDV: C18H34N2O5; P212121; a = 5.170(4) Å, b = 10.860(8) Å, c = 37.30(3) Å; Z = 4; R = 0.0787, wR2 = 0.1588. BPOH: C11H19N1O4; P1; a = 5.989(2) Å, b = 6.651(2) Å, c = 8.661(3) Å, α = 70.75(1)°, β = 77.42(1)°, γ = 86.98(1)°; Z = 1; R = 0.0562, wR2 = 0.1605. Chapter 5 describes a new class of polypeptide helices in hybrid sequences containing α-, β- and γ-residues. The molecular conformation in crystals determined for the octapeptide Boc-Leu-Phe-Val-Aib-(S)-β3-HPhe-Leu-Phe-Val-OMe (UBF8) reveals an expanded helical turn in the hybrid sequence (ααβ)n. A repetitive helical structure composed of C14 hydrogen bonded units is observed. Using experimentally determined backbone torsion angles for the hydrogen bonded units formed by hybrid sequences, the energetically favorable hybrid helices have been generated. Conformational parameters are provided for C11, C12, C13, C14 and C15 helices in hybrid sequences [5]. Crystal parameters UBF8: C60H88N8O11; P212121; a = 12.365(1) Å, b = 18.940(2) Å, c = 27.123(3) Å; Z = 4; R = 0.0625, wR2 = 0.1274. Chapter 6 describes the crystal structures of five model peptides Piv-Pro-Gly-NHMe (PA1), Piv-Pro-βGly-NHMe (PB1), Piv-Pro-βGly-OMe (PBO), Piv-Pro-δAva-OMe (PDAVA) and Boc-Pro-γAbu-OH (BGABU). A comparison of the structures of peptides PA1 and PB1 illustrates the dramatic consequences upon backbone homologation in short sequences. The molecule PA1 adopts a type II β-turn conformation in the crystal state, while in PB1, the molecule adopts an open conformation with the β-residue being fully extended. The peptide PBO, which differs from PB1 by replacement of the C-terminal NH group by an O-atom, adopts an almost identical molecular conformation and packing arrangement in the crystal state. In peptide PDAVA, the observed conformation resembles that determined for PB1 and PBO, with the δAva residue being fully extended. In peptide BGABU, the molecule undergoes a chain reversal, revealing a β-turn mimetic structure stabilized by a C-H…O hydrogen bond [6]. Crystal parameters PA1: C13H23N3O3; P1; a = 5.843(1) Å, b = 7.966(2) Å, c = 9.173(2) Å, α = 114.83(1)°, β = 97.04(1)°, γ = 99.45(1)°; Z = 1; R = 0.0365, wR2 = 0.0979. PB1: C14H25N3O3.H2O; P212121; a = 6.297(3) Å, b = 11.589(5) Å, c = 22.503(9) Å; Z = 4; R = 0.0439, wR2 = 0.1211. PBO: C14H24N2O4.H2O; P212121; a = 6.157(2) Å, b = 11.547(4) Å, c = 23.408(8) Å; Z = 4; R = 0.050, wR2 = 0.1379. PDAVA: C16H28N2O4.H2O; P21212; a = 11.33(1) Å, b = 25.56(2) Å, c = 6.243(6) Å; Z = 4; R = 0.0919, wR2 = 0.2344. BGABU: C14H24N2O5; P61; a = 9.759(2) Å, b = 9.759(2) Å, c = 29.16(1) Å; Z = 6; R = 0.0773, wR2 = 0.1243. Chapter 7 describes the crystal structures of a dipeptide, Boc-Aib-γAbu-OH (UG) and a tripeptide, Boc-Aib-γAbu-Aib-OMe (UGU) containing a single γAbu residue in each sequence. The structure of UG forms a reverse turn stabilized by a 10-membered intramolecular C-H…O hydrogen bonded ring. The peptide UGU crystallized in the triclinic space group P⎯1 with two molecules in the asymmetric unit resulting in a parallel assembly of sheets in crystals. Notably, the insertion of a single Aib residue at the C-terminus drastically changes the overall conformation of the structures. Crystal parameters UG: C13H24N2O5; P21/c; a = 16.749(3) Å, b = 5.825(1) Å, c = 16.975(3) Å; β = 111.82(1); Z = 4; R = 0.0507; wR2 = 0.1294. UGU: C18H33N3O6; P⎯1; a = 9.576(6) Å, b = 13.98(1) Å, c = 17.83(1); α = 85.31 (1); β = 77.46 (1); γ = 71.39 (1); Z = 4; R = 0.0648; wR2 = 0.1837.

This thesis reports diverse synthetic and mechanistic studies in six chapters, as summarized below. Chapter 1. Revised mechanism and improved methodology for the perkin condensation.1 The generally accepted mechanism for the well-known Perkin condensation is unviable for at least two reasons: (1) the normally employed base, acetate ion, is too weak to deprotonate acetic anhydride (Ac2O, the substrate); and (2) even were Ac2O to be derprotonated , its anion would rapidly fragment to ketene and acetate ion at the high temperatures employed for the reaction. It has proved in this study that the Perkin condensation occurs most likely via the initial formation of a fem-diacetate (3, Scheme 1) from benzaldehyde (2) and acetic anhydride (1).1 The key nucleophile appears to be the enolate of 3 (and not of 1), which adds t the C=O group of the aldehyde 2 (present in equilibrium with 3). Thus cinnamic acid (4a) was formed in -75% yield with 3 as the substrate under the normal conditions of the Perkin reaction. The deprotonation of the diacetate appears to be electrophilically assisted by the neighbouring acetate group, the resulting enolate being also thermodynamically stabilized in form of an orthoester (I). The possibility that the diacetate 3 is the actual substrate in the Perkin reaction indicates that the reaction can be effected under far milder conditions, with a base much stronger than acetate ion. This was indeed realized with potassium t-butoxide in dioxane, which converted the gem-diacetates derived from a variety of aromatic aldehydes to the corresponding cinnamic acids (4), rapidly and in good yields at room temperature (Scheme 2). This represents a vast improvement in the synthetic protocol for the classical Perkin reaction, which remains an important carbon-carbon bond forming reaction to this day. Chapter 2. Aromaticity in azlactone anions and its sifnificance for the Erlenmeyer synthesis.2 The classical Erlenmeyer azlactone synthesis of amino acids occur via the formation of an intermediate azlactone, and its subsequent deprotonation by a relatively weak base(acetate ion),. The resulting azlactone anion (cf. II, Scheme 3) functions as a glycine enolate equilvalent, and is considered in situ with an aromatic aldehyde, subsequent dehydration leading to the 4-alkylidene oxazolone(analogously to the Perkin reaction). Interestingly, azlactone anions are possibly aromatic, as they possess 6π electrons in cyclic conjugation; this would explain their facile formation as also the overall success of the Erlenmeyer synthesis. The following studies evidence this possibility. The strategy involved studying the rates of base-catalyzed deprotonation in 2-phenyl-5(4H)-oxazolone (azlactone, 5) and its amide and ketone analogs, 3-methyl-2-phenyl-4(5H)-imidazolone (6), and 3,3-dimethyl-2-phenyl-493H)-pyrrolone (7) respectively.2 Two processes were studied, deuterium exchange and condensation with hexadeuteroacetone (Scheme3): both are presumably mediated by the anions II-IV, so their stabilities would govern the overall rates. These were followed by 1H NMR spectroscopy by monitoroing the disappearance of the resonance of the proton α to the carbonyl group. The order of deprotonation was found to be 6 > 5 > 7. However, the expected order based on pKa values would be ketone > ester > amide, i.e. 7 > 5 > 6. The inverted order observed strongly indicates the incursion of aromaticity, which would be enhanced by the electron-donor capabilities of the heteroatoms is 5 and 6. This is further substantiated by the greater reactivity in the case of the nitrogen analog 6 relative to the oxygen 5, which parallel the electronegativity order. (The aromaticity order would thus be: III > II > IV. The imidazole nucleus is indeed to be considerably more aromatic than the oxazole.) The synthesis of the analogs 6 and 7 was accomplished via an interesting intramolecular aza-Wittig reaction (Schemes 4 & 5) Chapter 3. Umpolung approach to the Erlenmeyer process in the synthesis of dehydro amino acids. These studies are based on the general observation that most of the strategies for the synthesis of α-amino acids introduce the side chain (or part was inverted in an umpolung sense. The key reaction studied was that of 2-phenyl-4-ethoxymethylne-5(4H)-oxazolone (11) with Grignard reagents: this resulted in the opening to yield a protected dehydro amino acid (12), in good to excellent yields (65-87%)(Scheme ^). As the azlactone reactant 11 is the ekectrophilic partner, this may be viewed as a partial umpolung version of the classical Erlenmeyer process. The readily available reactants, simple procedure and mild reaction conditions make this a very attractive method for the synthesis of a variety of α-dehydro amino acids. Chapter 4. The Erlenmeyer azlactone synthesis with aliphatic aldehydes under solvent-free microwave conditions. 3 A serious limitation to the classical Erlenmeyer reaction is that it generally fails in the case of aliphatic aldehydes. This chapter describes a convenient approach to this problem that extends the scope of the Erlenmeyer synthesis, via a novel microwave-induced, solvent-free process. This, it was observed that azlactones (5) react with aliphatic aldehydes (13) upon adsorption on neutral alumina and irradiation with microwaves (< 2 min), forming the corresponding Erlenmeyer products (14) in good yields (62-78%, Scheme 7). (The possible mechanistic basis of the procedure, which is presumably mediated by V , is discussed).3 Chapter 5. 2,4, 10-Trioxaadamantane as a carboxyl protecting group: application to the asymmetric synthesis of α-amino acids (umpolung approach).It is known that the 2,4,10-trioxaadamantane moiety is not only remarkably stable to nucleophilic attack, but can also be easily hydrolyzed to the corresponding carboxylic acid.4 It was of interest to apply this carboxyl protection strategy for designing a synthesis of α-amino acids, essentially by starting with a protected glyoxylic acid. The corresponding aldimine was expected to (nucleophilically) add organometallic reagents at the C=N moiety (cf. Shceme 8), the side chain of the amino acid being thus introduced in umpolung fashion. Also, a chiral aldimine would define an asymmetric synthesis of amino acids. Indeed, the chiral aldimine 17, derived from 2,4,10-troxaadamantane-3-carbaldehyde 15 and [(S)-(-)-1-phenylethylamine] 16, reacted with a variety of Grignard reagents to furnish the corresponding protected α-amino acids (18) in good yields, with moderate diastereometric excess (Scheme 8). Better yields and ‘de’ values were obtained with organolithium reagents. Chapter 6: possible one-pot oligopeptide synthesis with azlactones or amino acid N-carboxyanhydrides (NCAs). This chapter describes a novel approach to oligopeptide synthesis employing azlactones or NCA’s as amino acid equivalents which are simultaneously protected and activated (Scheme 9). Thus, the addition of the 4-substituted 2-benzyloxyazlactone (19) to an N-protected amino acid under basic conditions, was initially explored. The reaction was expected to yield a dipeptide (21) via the rearrangement of the mixed anhydride intermediate (VI) (Scheme 9). The subsequent addition of a different azlactone to the dipeptide (21) would analogously lead to the formation of a tripeptide (22). This may be performed repetitively to define a strategy for C-terminal extension of an oligopeptide chain, noting that no intervening deprotecting and activating steps are necessary. (In toto deprotection may be effected finally via the hydrogenolyis of the bvenzyloxy groups, to obtain 23.) A closely analogous strategy may also be envisaged by employing N.carboxyanhydrides (NCA’S, 24) instead of azlactones, as shown in Scheme 10 (forming dipeptide 26 and tripeptide 27). The main difference n this case is that the carbamic acid moiety of the intermediate mixed anhydride (VII) is expected to undergo decarboxylation to VIII (thus obviating the need for a deprotection step). However, this putative advantage is offset by the instability of NCA’s and their tendency toward polymerization. However, only partial success could be achieved in these attempts, although a variety of conditions were explored. The strategy and the experimental results have been analyzed in detail, as this interesting approach appears to be promising, and worth further study. (For structural formula pl refer the pdf file)