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Developing novel therapeutic strategies for acute lung injury and infection-peripheral blood monocyte depletion and prophylactic antimicrobial therapyDhaliwal, Kanwaldeep January 2013 (has links)
Background: Acute lung injury (ALI) and nosocomial pneumonia are major causes of morbidity and mortality. There are 200,000 cases per year of ALI in the US with a mortality of 40%. On the intensive care unit (ICU), ALI accounts for over 40% of all ventilated patients at any one time. Despite this huge burden on healthcare and the relatively high prevalence, no therapies currently exist in clinical practice that attenuate the condition. The pathophysiology and aetiology of ALI is multifactorial but neutrophilic influx and consequent damage to the endothelial-epithelial interface are regarded as central features. Alongside neutrophils, peripheral blood monocytes (PBMs) are recruited to the acutely inflamed lung. The role played by PBMs in perpetuating the pathogenic neutrophilic influx remains poorly characterised. Nosocomial pneumonia is also a major problem with drug resistant organisms. With the increasing prevalence of antibiotic resistance and the paucity of novel antimicrobials being generated by pharmaceutical companies, there is real concern that the end of the ‘antibiotic era’ may be approaching. AIMS 1) To develop murine models of lung inflammation and infection 2) To establish the role of the PBM in perpetuating the neutrophilic response in ALI 3) To develop non-invasive methodologies to study the trafficking of cells and molecular events within the inflamed lung 4) To apply a novel antimicrobial to prevent and treat nosocomial pneumonia Methods: A murine model of ALI was utilised using direct intratracheal instillation of lipopolysaccharide. To this model 3 different PBM depletion strategies were applied to study the effect on neutrophil recruitment and consequent lung injury. Non invasive optical imaging was utilised to study the effect of PBM depletion on proteolytic events within the murine lung. To understand cellular trafficking, cell labeling strategies were compared for primary murine macrophages with whole body optical imaging in mice. Murine models of Staphylococcus aureus, Pseudomonas aeruginosa and Burkholderia cepacia were established and a novel antimicrobial agent called the nonalysine like peptoid (NLLP) tested in vitro and in vivo for efficacy. Results: PBM depletion significantly attenuated neutrophil recruitment in an established model of ALI. Near infrared (NIR) optical imaging permitted the non invasive tracking of primary murine cells. A non toxic peptidomimetic agent (NLLP) possessed antimicrobial activity against gram positive and gram negative pathogens with therapeutic and prophylactic efficacy in vivo. Conclusions: PBM depletion is a potential therapeutic strategy for treating ALI. Further studies are required to determine the exact mechanism by which PBMs orchestrate neutrophil recruitment. Optical imaging is a versatile platform for molecular imaging. A novel antimicrobial agent termed NLLP has been discovered with therapeutic and prophylactic efficacy against multi-drug resistant pathogens.
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Combinatorial Synthesis, Sequencing, and Biological Applications of Peptide and Peptidomimetic LibrariesThakkar, Amit January 2009 (has links)
No description available.
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C10 semi-peptoid beta-turn peptidomimetics: syntheses, characterization and biological studiesNnanabu, Ernest 02 June 2009 (has links)
Over the years, the Burgess group has been focusing on the preparation and
testing of small molecules that mimic protein secondary structures for protein-protein
interactions. The most successful compounds made are C10 peptide macrocycles that
effectively mimic β-turns and have given promising results from biological testing. These
peptide macrocycles have also been dimerized to give even more effective ligands for
protein-protein interaction.
The successes of the peptide macrocycles have enabled us to look into increasing
the chemical diversity of our libraries. This we believe will not only improve our ability
to obtain high affinity ligands for the receptors of interest, but will also allow us to
investigate other receptors. To achieve this, peptoids were incorporated into the C10
system to replace the peptides in the i+1 and i+2 positions. With the help of Microwave
irradiation, semi-peptoid macrocycles were synthesized with a total reaction time of less
than 2 h. These compounds were characterized and found to mimic β-turn, and show
promising biological activity towards the Insulin-like growth factor 1 receptor (IGF-IR).
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Controlling gene expression with synthetic moleculesAlluri, Prasanna G. January 2006 (has links) (PDF)
Thesis (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2006. / Not embargoed. Vita. Bibliography: 262-264.
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Continuous flow synthesis of chemical building blocks for biological applicationJong, Thing Soon January 2014 (has links)
A collection of twenty three selectively mono-protected di- and triamines, masked with the Boc, Fmoc or Ddiv protecting groups, were synthesised via continuous flow synthesis in a self-assembled meso-scale PTFE flow reactor. The continuous flow strategy offered direct access to the mono-protected compounds in good yields, especially in the case of the Fmoc carbamates which circumvented the use of another sacrificial protecting group. Two of the mono-Boc-protected carbamates were used as starting materials to generate N-alkylglycine monomers; synthesised via tandem mono-alkylation and Fmoc carbamation, linked by an in-line scavenging protocol using a silica-based trisamine scavenger resin. The final step of the monomer synthesis employed catalytic transfer hydrogenolysis using 20% Pd(OH)2/C and 1,4- cyclohexadiene. The three-step flow procedure gave access to two monomers, with one of them being a novel N-alkylglycine unit bearing a triethylene glycol bridge. The monomers were used as building blocks to assemble new oligo-N-alkylglycines (peptoids) via microwave-assisted solid phase synthesis. Three different types of peptoids were synthesised: (i) oligo-N-(6-aminohexyl)glycines (“standard” peptoids), (ii) oligo-N-{2-[2-(2-aminoethoxy)ethoxy]ethyl}glycines (“triethylene glycol” [TEG] peptoids) and (iii) hetero-oligomers of alternating “standard” and “TEG” monomers (“hybrid” peptoids). The peptoids were evaluated for their cellular permeability and cytotoxicity with HeLa, HEK-293 and CHO cells. All the peptoids were shown to be non-cytotoxic at 10 μM based on cell proliferation assays. In general, it was found that the cellular uptake of the hybrid peptoids outperformed their standard and TEG analogues. Flow cytometry and confocal microscopy results revealed that the hybrid nonamer had the highest cellular uptake efficiency of all the peptoids synthesised. At a concentration of 1 μM, it outperformed the second best molecular transporter (standard nonamer) by a factor of seven.
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SYNTHESIS AND STUDIES OF POLYMERIC BIOMATERIALS FOR DRUG DELIVERY AND THERAPEUTIC DESIGNHutnick, Melanie A. January 2017 (has links)
No description available.
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Cationic amphipathic peptoid oligomers as antimicrobial peptide mimics / Peptoïdes cationiques amphiphiles comme mîmes de peptides antibactériensShyam, Radhe 18 May 2018 (has links)
Les organismes vivants produisent des peptides antimicrobiens (PAMs) pour se protéger contre les microbes. La résistance croissante aux antibiotiques nécessite le développement de nouvelles stratégies thérapeutiques et les PAMs sont des candidats prometteurs pour résoudre ce problème. Ils possèdent une activité à large spectre et leur principal mécanisme d'action par perméation de la membrane engendre peu de phénomènes de résistance. Néanmoins, leur faible biodisponibilité empêche leur utilisation. Certaines limitations peuvent être surmontées en développant des mîmes de PAMs qui conservent leur activité mais avec un potentiel thérapeutique accru. Les peptoïdes (oligomères de N-alkylglycine) structurés en hélice cationique amphiphile sont de bons mimes de PAMs. Les peptoïdes sont plus flexibles que les peptides en raison de l'isomérie cis/trans des amides N,N-disubstitués ; cependant la conformation des amides peut être contrôlée par un choix judicieux des chaînes latérales. Le but de cette thèse est d'étudier l'influence de chaînes latérales(hydrophobes ou cationiques) bloquant la conformation des amides en cis et induisant une structure hélicoïdale de type PolyProline I (PPI) robuste, sur l’activité antibactérienne et la sélectivité de peptoïdes. La conception, la synthèse et l’étude conformationnelle de nouveaux oligomères peptoïdes cationiques portant des chaînes latérales de type tert-butyle et/ou triazolium ont été réalisées. Dans un premier temps, la synthèse en solution d'oligomères à base de tert-butyle a été développée puis une stratégie de synthèse en phase solide a été mise en place pour accéder aux oligomères à base de 1,2,3-triazolium. Ensuite, ces nouveaux oligomères ont été évalués pour leur activité vis à vis d’un panel de bactéries Gram-positive et Gram-négative, leur l'activité antibiofilm et leur sélectivité cellulaire. Enfin, pour visualiser les effets des peptoïdes amphiphiles sur les bactéries, une étude de microscopie a été réalisée. / Living organisms produce antimicrobial peptides (AMPs) to protect themselves against microbes.The growing problem of antimicrobial resistance calls for new therapeutic strategies and the natural AMPs have shown ground-breaking potential to address that issue. They show broad-spectrum activity and their main mechanism of action by bacterial cell membrane disruption implies low emergence of resistance which makes them potent candidates for replacing conventional antibiotics. Nevertheless, few hurdles are impeding their use, notably poor bioavailability profile. Some of these limitations can be overcome by developing peptidomimetics of AMPs which exhibit antibacterial activities together with enhanced therapeutic potential. Peptoids (i.e. N-alkyl glycine oligomers) adopting cationic amphipathic helical structures are mostly competent AMP mimetics. From a conformational point of view, peptoids are fundamentally more flexible than peptides primarily due to the cis/trans isomerism of N,N-disubstituted amides but studies in this area have shown that cis amide conformation can be controlled by careful choice of side-chain to set a PolyProline I-type helical structure of peptoids. In this thesis, the genesis of novel amphipathic cationic peptoids carrying cis-directing tert-butyl and/or triazolium-type side-chains and their untapped potential to act against bacteria will be discussed comprehensively. First, the solutionphase synthesis of tert-butyl-based oligomers was developed. Second, novel method of solid-phase submonomer synthesis was optimised to access 1,2,3-triazolium-based oligomers. Then, the synthesised cationic oligomers were evaluated for their antibacterial potential, followed by antibiofilm activity and cell selectivity assays. In the end, to have insights on the mode of action of amphipathic peptoids, microscopy was carried out.
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Conformational Stability!? : Synthesis and Conformational Studies of Unnatural Backbone Modified PeptidesNorgren, Anna S. January 2006 (has links)
<p>The beauty of the wide functionality of proteins and peptides in Nature is determined by their ability to adopt three-dimensional structures. This thesis describes artificial molecules developed to mimic secondary structures similar to those found crucial for biological activities.</p><p>In the first part of this thesis, we focused on post-translational modifications of a class of unnatural oligomers known as <i>β</i>-peptides. Through the design and synthesis of a glycosylated <i>β</i><sup>3</sup>-peptide, the first such hybrid conjugate was reported. In this first report, a rather unstable 3<sub>14</sub>-helical structure was found. Subsequently, a collection of six new glycosylated <i>β</i><sup>3</sup>-peptides was synthesized with the aim to optimize the helical stability in water.</p><p>The ability of natural proteins, i.e. lectins, to recognize the carbohydrate residue on these unnatural peptide backbones was investigated through a biomolecular recognition study.</p><p>The second part of this thesis concerns the design of conformationally homogeneous scaffolds, which could be of importance for biomedical applications. In paper V, four- and five-membered cyclic <i>all</i>-<i>β</i><sup>3</sup>-peptides were investigated for this purpose. In a subsequent paper, a completely different strategy was employed; herein, the ability of a single <i>β</i><sup>2</sup>-amino acid to restrict the conformational freedom of a cyclic α-peptide was studied. </p><p>In the third part of this thesis, we synthesized and investigated the folding propensities of novel backbone modified oligomers, i.e. <i>β</i>-peptoids (<i>N</i>-substituted <i>β</i>-Ala) with α-chiral side chains.</p><p>The collective results of these studies have established the procedures required for synthesis of glycosylated <i>β</i>-peptides and deepened our understanding of the factors governing folding among such oligomers. Moreover, it was established that <i>β</i>-amino acids can be a useful tool to increase conformational stability of cyclic peptides.</p>
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Conformational Stability!? : Synthesis and Conformational Studies of Unnatural Backbone Modified PeptidesNorgren, Anna S. January 2006 (has links)
The beauty of the wide functionality of proteins and peptides in Nature is determined by their ability to adopt three-dimensional structures. This thesis describes artificial molecules developed to mimic secondary structures similar to those found crucial for biological activities. In the first part of this thesis, we focused on post-translational modifications of a class of unnatural oligomers known as β-peptides. Through the design and synthesis of a glycosylated β3-peptide, the first such hybrid conjugate was reported. In this first report, a rather unstable 314-helical structure was found. Subsequently, a collection of six new glycosylated β3-peptides was synthesized with the aim to optimize the helical stability in water. The ability of natural proteins, i.e. lectins, to recognize the carbohydrate residue on these unnatural peptide backbones was investigated through a biomolecular recognition study. The second part of this thesis concerns the design of conformationally homogeneous scaffolds, which could be of importance for biomedical applications. In paper V, four- and five-membered cyclic all-β3-peptides were investigated for this purpose. In a subsequent paper, a completely different strategy was employed; herein, the ability of a single β2-amino acid to restrict the conformational freedom of a cyclic α-peptide was studied. In the third part of this thesis, we synthesized and investigated the folding propensities of novel backbone modified oligomers, i.e. β-peptoids (N-substituted β-Ala) with α-chiral side chains. The collective results of these studies have established the procedures required for synthesis of glycosylated β-peptides and deepened our understanding of the factors governing folding among such oligomers. Moreover, it was established that β-amino acids can be a useful tool to increase conformational stability of cyclic peptides.
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PEPTOID FRAGMENTATION PATHWAYS BY TANDEM MASS SPECTROMETRY STUDIESMann, Yadwinder Singh 01 January 2022 (has links) (PDF)
Peptoids are versatile compounds exhibiting many applications in various fields ranging from polymeric science to drug development. Combinatorial libraries are a powerful tool for exploring various applications of peptoids. Among robust analytical tools, tandem mass spectrometry is a method of choice to decode the sequence of unknown peptoids in combinatorial libraries. In this study, we have synthesized peptoids with various side chains and found interesting fragmentation pathways. The introduction to my research and methods used for the experiments are discussed in detail in chapters one and two, respectively.In chapter three of this dissertation, a systematic study of acetylated peptoids with positioning of a basic sidechain at various locations has been conducted using a linear ion trap mass spectrometer. The fragmentation characteristics of peptoids charged with metal ions, such as Li+ and Na+, are compared with those of the protonated peptoids. The acetylated peptoids without any basic sidechain were taken as a reference. It has been found that metal ions assist in increasing the formation of N-terminal fragment ions due to chelating between the metal ions and the peptide fragments. In addition, metal ions enhances ionization efficiency of peptoids without charge trapping sites. In the fourth chapter, new fragmentation pathways of peptoids are proposed and tested. To investigate the mechanism of water loss from peptoid fragment ion, a linear ion trap mass spectrometer was used to perform tandem fragmentation experiments on selected peptoids. The absence of certain fragment ions toward the N-terminus suggests that water loss occurs through a five-membered ring intermediate instead of a six-membered ring. The fragmentation of peptoid backbone mainly yields the B- and Y-ions through an oxazolone ring intermediate. The Y-ions are formed by abstraction of a proton from the oxazolone ring, which is essentially the proton from the alpha position of the dissociating amide bond. In nonacetylated peptoids, an oxazolone ring is absent during the formation of terminal Y-ions. The mechanism behind the appearance of terminal Y-ions have been studied using deuterium labeled peptoids. Fragmentation experiments on deuterium labeled peptoids indicates that the proton is not abstracted from the alpha position. The likely proton source is the hydrogen on the amine group of the N-terminus. The comparison of fragmentation patterns between peptoids containing acidic and basic sidechains is documented in the last chapter of this dissertation. Carboxyl group on the sidechain does not appear to influence the favorable formation of C-terminal ions. Considerable abundance of low-mass B-ions is explained by a cascade secondary fragmentation of high-mass B-ions. The fragment ions formed using the linear ion trap instrument show a considerable abundance of high mass Y-ions. While fragmentation experiments using tandem quadrupole instrument show high intensity of low mass ions which are possibly formed from secondary fragmentation of high mass ions. This study will aid in understanding the nature of fragmentation behavior of peptoids and support the discovery of unknown sequences. As peptoids closely resemble peptides, the findings from this work will help to complement the fragmentation mechanism of peptides.
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