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Design, Synthesis, Applications of Polymers and DendrimersNimmagadda, Alekhya 16 November 2017 (has links)
WHO has reported that antibiotic resistance is the third major cause of human death all over the globe. Recent study, has focused on the development of new antibacterial resistance drugs. Herein, we tried to synthesis a series of polymers that can mimic the HDPs. HDPs can target the bacterial cell membrane and they have less chances to develop bacterial resistance. We synthesized the amphiphilic polycarbonates that are highly selective to Gram-positive bacteria, including multidrug resistant pathogens. The membrane disruption activity of these polymers was proved by fluorescence and TEM studies and the drug resistance study showed that the polymers don’t develop bacterial resistance. In order to further design the molecules that can target a broad spectrum of bacteria, we have designed a series of lipidated dendrimers that can target the Gram-positive and Gram-negative bacteria. These dendrimers mimic the HDPs and target the bacterial cell membrane. Dendrimers are reported to inhibit the formation of bacterial biofilm which makes them promising for their future development of antibiotic agents.
Apart from the synthesis of polymers and dendrimers as antibacterial agents, we have designed a series of small molecular antibacterial agents that are based on the acylated reduced amide scaffold and small dimeric cyclic guanidine derivatives. These molecules display good potency against a panel of multidrug-resistant Gram-positive and Gram-negative bacterial strains. Meanwhile, they also effectively inhibit the biofilm formation. Mechanistic studies suggest that these compounds kill bacteria by compromising bacterial membranes, a mechanism analogous to that of host-defense peptides (HDPs). Lastly, we also demonstrate that these molecules have excellent in vivo activity against MRSA in a rat model. This class of compounds could lead to an appealing class of antibiotic agents combating drug-resistant bacterial strains.
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Host and pathogen sensory systems as targets for therapeutic interventionKindrachuk, K. Jason 31 July 2007
A new paradigm for the treatment of infectious disease is through the modulation of innate immune responses. In this capacity, host defense peptides (HDPs) and synthetic Toll-like receptor 9 (TLR9) ligands have the greatest demonstrated potentials. The work presented here considers mechanisms for the improvement of these treatments through optimization, or in the case of HDPs the minimization, of the interactions of these ligands with sensory receptors.<p>Toll-like Receptor 9 activates the innate immune system in response to microbial DNA or immune-modulating oligodeoxynucleotides. While cell stimulation experiments demonstrate the preferential activating ability of CpG-containing nucleic acids, direct binding investigations have reached contradictory conclusions regarding the sequence-specificity of TLR9 ligand binding. To address this discrepancy the characterization of human TLR9 ligand binding properties is reported. TLR9 has a high degree of ligand specificity in being able to discriminate not only CpG dinucleotides, but also higher order six nucleotide motifs that mediate species-specific activation. However, TLR9 ligand binding is also functionally influenced by nucleic acids in a sequence-independent manner both in vitro and in cell proliferation experiments. A model is proposed in which TLR9 activation is mediated specifically by CpG-containing ligands while sensitivity of the receptor is modulated by the absolute concentration of nucleic acids in a sequence-independent fashion. <p>Host defense peptides are among the leading candidates to combat antibiotic resistant bacterial strains. Recently, HDPs have been demonstrated to function as ligands for the bacterial sensory kinase PhoQ resulting in the induction of virulence and adaptive responses. Thus, concerns have been raised regarding therapeutic applications of HDPs. Here a methodology is described that permits discrimination and quantification of the distinct, but related, peptide behaviors of direct antimicrobial activity and PhoQ ligand potential. Utilizing peptide derivatives of the model HDP Bac2A it is demonstrated that antimicrobial efficiency is significantly, and inversely, related to PhoQ ligand efficacy. This provides a rational basis for HDP selection with greater therapeutic potential and minimized potential for initiation of bacterial resistance.
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Host and pathogen sensory systems as targets for therapeutic interventionKindrachuk, K. Jason 31 July 2007 (has links)
A new paradigm for the treatment of infectious disease is through the modulation of innate immune responses. In this capacity, host defense peptides (HDPs) and synthetic Toll-like receptor 9 (TLR9) ligands have the greatest demonstrated potentials. The work presented here considers mechanisms for the improvement of these treatments through optimization, or in the case of HDPs the minimization, of the interactions of these ligands with sensory receptors.<p>Toll-like Receptor 9 activates the innate immune system in response to microbial DNA or immune-modulating oligodeoxynucleotides. While cell stimulation experiments demonstrate the preferential activating ability of CpG-containing nucleic acids, direct binding investigations have reached contradictory conclusions regarding the sequence-specificity of TLR9 ligand binding. To address this discrepancy the characterization of human TLR9 ligand binding properties is reported. TLR9 has a high degree of ligand specificity in being able to discriminate not only CpG dinucleotides, but also higher order six nucleotide motifs that mediate species-specific activation. However, TLR9 ligand binding is also functionally influenced by nucleic acids in a sequence-independent manner both in vitro and in cell proliferation experiments. A model is proposed in which TLR9 activation is mediated specifically by CpG-containing ligands while sensitivity of the receptor is modulated by the absolute concentration of nucleic acids in a sequence-independent fashion. <p>Host defense peptides are among the leading candidates to combat antibiotic resistant bacterial strains. Recently, HDPs have been demonstrated to function as ligands for the bacterial sensory kinase PhoQ resulting in the induction of virulence and adaptive responses. Thus, concerns have been raised regarding therapeutic applications of HDPs. Here a methodology is described that permits discrimination and quantification of the distinct, but related, peptide behaviors of direct antimicrobial activity and PhoQ ligand potential. Utilizing peptide derivatives of the model HDP Bac2A it is demonstrated that antimicrobial efficiency is significantly, and inversely, related to PhoQ ligand efficacy. This provides a rational basis for HDP selection with greater therapeutic potential and minimized potential for initiation of bacterial resistance.
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Design, Synthesis, Application of Biodegradable PolymersGide, Mussie 22 March 2018 (has links)
Bacterial infections have posed a serious threat to the public health due to the significant rise of the infections caused by antibiotic-resistant bacteria. There has been considerable interest in the development of antimicrobial agents which mimic the natural HDPs, and among them biodegradable polymers are newly discovered drug candidates with ease of synthesis and low manufacture cost compared to synthetic host defense peptides. Herein, we present the synthesis of biocompatible and biodegradable polymers including polycarbonate polymers, unimolecular micelle hyperbranched polymers and dendrimers that mimic the antibacterial mechanism of HDPs by compromising bacterial cell membranes. The developed amphiphilic polycarbonates are highly selective to Gram-positive bacteria, including multidrug-resistant pathogens and the unimolecular micelle hyperbranched polymers showed promising broad-spectrum activity. However, lipidated amphiphilic dendrimers with low molecular weight display potent and selective antimicrobial activity against both Gram-positive and Gram-negative bacteria, including multidrug-resistant strains. In addition to antibacterial activity against planktonic bacteria, these dendrimers were also shown to inhibit bacterial biofilms effectively. These class of polymers may lead to a useful generation of antibiotic agents with practical applications.
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Gamma AApeptides as Host Defense Peptide MimicsLi, Yaqiong 16 May 2016 (has links)
There has been increasing concern regarding the emergence of multi-drug resistant pathogens. The resistance develops when pathogens, especially bacteria, are frequently exposed to conventional antibiotics, as they are heavily used in both human and livestock. This is due to the high target specificity of conventional antibiotics, which places pathogens in high selective pressures and eventually results in drug resistant by mutations. To address this issue, global actions and cooperation are needed. At the same time, new technologies and strategies need to be developed. Host defense peptides (HDPs) are widely found in the innate immune system. They show both direct antimicrobial properties and immunomodulatory activities. The multifaceted functions of HPDs make them less likely to promote antimicrobial resistance. Thus, they are promising as new therapeutics to treat multi-drug resistant infections. In fact, several drug candidates derived from HDPs have entered the clinical trial, but none of them got into the clinic. This is due to several challenges associated with HDPs, such as low in vivo stability, high cost of manufacturing, and toxicity to mammalian cells. In this dissertation, we explored the ability of a new type of unnatural scaffolds (γ-AApeptides) to mimic the functions of HDPs, including both broad spectrum antimicrobial properties and immunomodulatory activities. Furthermore, the efforts to identify simpler and more drug like γ-AApeptide based antimicrobial agents were also discussed. The findings in this dissertation may lead to the development of potential drug candidates to treat multi-drug resistant infections.
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Contribution à l'analyse post-génomique de l'interaction entre le peuplier et Melampsora larici-populina, le champignon biotrophe responsable de la maladie de la rouille foliaire / Post-genomic analysis of the poplar-poplar rust fungus Melampsora larici-populina interactionPêtre, Benjamin 12 November 2012 (has links)
Melampsora larici-Populina est un champignon biotrophe qui infecte le peuplier et cause la maladie de la rouille foliaire, entraînant d'importants dégâts dans les peupleraies. Un des objectifs de l'UMR Interactions Arbres/Microorganismes est de caractériser les déterminants moléculaires de ce pathosystème. Au cours de cette thèse, des approches post-Génomiques ont permis de mener à bien quatre projets de recherche. Premièrement, l'analyse du transcriptome des temps précoces de l'interaction peuplier/M. larici-Populina a révélé un transporteur de sulfate de peuplier fortement induit par l'infection (chapitre II). Deuxièmement, l'analyse phylogénomique de la famille des thaumatin-Like proteins (TLP) a entre autres mis en évidence certains clades spécifiquement associés aux réponses aux stress chez le peuplier (chapitre III). Troisièmement, le gène codant la petite protéine sécrétée Risp de fonction inconnue est fortement induit lors des réponses de défense du peuplier et n'a pas d'homologue chez les autres plantes. La protéine recombinante est intrinsèquement désordonnée et présente une double activité de protéine antifongique envers M. larici-Populina et d'éliciteur endogène des réponses de défense chez le peuplier (chapitre IV et V). La combinaison de ces deux propriétés n'a jamais été rapportée chez une protéine de plante. Enfin, les gènes MlpP4.1 et MlpH1.1 de M. larici-Populina codent des petites protéines sécrétées riches en cystéines et de fonction inconnue, considérées comme des effecteurs candidats (chapitre VI). L'expression de MlpP4.1 et MlpH1.1 est très fortement induite lors de l'infection des feuilles de peupliers et des activités de virulence ont été observées chez Arabidopsis thaliana. Les analyses biochimique et structurale des protéines recombinantes sont en cours et ont déjà permis de démontrer la forte stabilité de MlpP4.1, probablement liée à la présence de plusieurs ponts disulfures. A l'aide des protéines recombinantes, plusieurs partenaires protéiques ont été identifiés chez les plantes permettant d'établir des hypothèses quant à leur rôle / Melampsora larici-Populina is a biotrophic fungus that infects poplar and causes the foliar rust disease, leading to severe damages in plantations. A major aim of the Tree- Microbe Interactions department is to characterize molecular determinants of the pathosystem. During this thesis, four research projects were achieved through post-Genomic approaches. First, transcriptome analysis of the early interaction between poplar and M. larici-Populina revealed a fungal-Induced host sulfate transporter (chapter II). Secondly, the phylogenomic analysis of the thaumatin-Like protein (TLP) family uncovered some clades specifically associated with stress responses in poplar (chapterIII). Thirdly, the gene encoding the small secreted protein of unknown function Risp is strongly induced during poplar defense reponses and has no homolog in other plants. The recombinant protein is intrinsically disordered and presents a dual activity as an antifungal protein against M. larici-Populina and as an endogenous elicitor of defense responses in poplar (chapter IV and V). The combination of both properties in a single protein has never been reported in plants. Finally, M. larici-Populina MlpP4.1 and MlpH1.1 genes encode cysteine-Rich small-Secreted proteins of unknown fonction, considered as candidate effectors (chapter VI). MlpP4.1 and MlpH1.1 expression is strongly induced during poplar leaf colonization, and virulence activities were observed in Arabidopsis thaliana. Biochemical and structural analyses of recombinant proteins are ongoing and already revealed the strong stability of MlpP4.1, likely due to the presence of several disulfide bridges. Several plant partners of the recombinant proteins were identified and have allowed for setting hypotheses about their role
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Diversité génétique et fonctionnelle des molécules homologues de PA1b chez Medicago truncatula Gaertn. ainsi qu’au sein de légumineuses originaires du Liban / Genetic and functional diversity of homologous of PA1b in Medicago truncatula Gaertn. and within legumes from LebanonKaraki, Lamis 12 December 2013 (has links)
Les peptides Albumines 1 b sont des membres de la famille structurale des knottines et présentent un potentiel intéressant en tant que composés insecticides. À ce jour, leur diversité parmi les Fabacées a été essentiellement étudiée en utilisant des approches biochimiques et moléculaires. Les ressources bioinformatiques (le séquençage complet du génome, les bases de données transcriptomiques (EST…), les atlas d’expression...) de l’espèce modèle des légumineuses, Medicago truncatula Gaertn. (Mtr), nous a permis de développer une approche génomique de cette biodiversité. Deux objectifs principaux nous ont guidé à : 1) déchiffrer l'histoire évolutive de la famille A1 dans cette espèce et 2) explorer la biodiversité naturelle afin de découvrir de nouvelles molécules bioactives. L'exploration du génome de Mtr a révélé une remarquable expansion, à travers des duplications en tandem, des loci A1 qui retiennent presque toutes la même structure génique canonique (2 exons et 1 intron). L'analyse phylogénétique nous a permis de comprendre l’évolution des gènes A1 intraspécifique et l’analyse de leur expression (EST, puces à ADN) a révélé la distribution de la famille des gènes A1 dans les organes de la plante (tissus) : Cette dernière s’est révélée bien plus diverse que celle connue chez les autres espèces examinées de légumineuses, où la famille était jusque-là principalement graine-spécifique. Selon plusieurs critères, certains peptides ont été sélectionnés puis chimiquement synthétisés et repliés in vitro et testés pour leur activité biologique. Parmi eux, un peptide, nommé AG41, isoforme MtrA1013 et issu de l’EST orpheline TA24778_3880, a révélé un pouvoir insecticide élevé et inattendu. L’analyse à grande échelle en présence d’homologues d’A1 des légumineuses a montré l’ancestralité de la fonction insecticide et l’âge de la famille est estimé à plus de 58 million d’années. Notre étude s’est aussi orientée vers l’analyse de cette famille peptidique chez des légumineuses originaires du Liban. Cette approche par biologie moléculaire nous a permis de caractériser 9 nouveaux gènes chez 6 espèces de Papilionoideae. L’étude plus approfondie de ces gènes au niveau structural et fonctionnel est envisagée. Afin de relier les variations de structure et d'activité, un système d'expression hétérologue (baculovirus/cellules d’insectes Sf9) a été mis au point. Le peptide recombinant de référence PA1b (Pea Albumin 1 sub-unit b), même exprimé en faible quantité, présente une activité biologique et une masse bien conforme ainsi qu’une structure bien repliée. Ce système a permis, de même, de produire la proprotéine PA1, forme intermédiaire entre la préproprotéine et le peptide PA1b mature. Cette proprotéine, identifiée pour la première fois, ne présente aucune toxicité envers les cellules Sf9. / Albumin 1 b peptides are members of the knottin structural family and display an interesting potential as insecticidal compounds. To date their diversity among Fabaceae was essentially investigated using biochemical and molecular approaches. The bioinformatic resources (full-genome sequencing, EST database, gene expression atlas…) of the Legume model, Medicago truncatula Gaertn. (Mtr), prompted us to develop a large-scale approach in two ways: 1) to decipher the evolutionary history of A1 family in this species and 2) to explore the natural biodiversity to uncover new bioactive molecules. Exploring Mtr genome revealed a remarkable expansion, through tandem duplications, of A1 loci that retain nearly all the primary structure (2 exons and 1 intron) . Phylogenetic analysis has allowed us to understand the evolution of intraspecific A1 genes and the analysis of their expression (EST, microarrays), and revealed the distribution of the A1 gene family in plant organs (tissue): the latter proved to be much more diverse than that seen in other examined legumes species, where the family until then was mainly seed-specific. Selected upon several criteria some peptides were chemically synthezised, folded in vitro and assayed for their biological activity. Among them one peptide, named AG41: isoform MtrA1013 (orphan EST : TA24778_3880), revealed a high and unexpected insecticidal power. The large-scale analysis in the presence of legumes A1 homologous showed the ancestry of the isecticidal function and the age of this family is estimated to be more than 58 million years. Our study is also directed towards the analysis of this family of peptide in legumes from Lebanon. This approach based on molecular biology has allowed us to characterize nine new genes in six species of Papilionoideae. The further study of these genes at the structural and functional level is considered. To link changes in structure and activity, a heterologous expression system (baculovirus / insect Sf9 cells) was developed. The reference recombinant peptide PA1b (Pea Albumin 1 sub-unit b), even expressed in small quantities, was biologicaly active and harbouring the expected mass as well as a well-folded structure. This system has enabled also to produce the proprotein PA1, intermediate form between the preproprotein and the mature peptide PA1b. This proprotein, identified for the first time, has no toxicity towards Sf9 cells.
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