Global ETD Search

1	Synthesis of novel sialidase inhibitors to target influenza A virus and Chagas' disease Resende, Ricardo January 2010 (has links) No description available. 547.02
2	Design and synthesis of inhibitors for the human neuraminidase 3 enzyme Zou, Yao Unknown Date No description available. human neuraminidase neuraminidase inhibitors DANA derivatives
3	The search for allosteric inhibitors Brear, Paul January 2013 (has links) This thesis describes the development of chemical tools that inhibit the sialidases NanA and NanB from Streptococcus pneumonia. The primary focus was on the discovery of allosteric inhibitors of NanA and NanB, however, promising inhibitors that act by binding at the active site of these enzymes were also investigated. Chapter 1 gives an overview of the use of chemical tools in the field of chemical biology. It focuses in particular on chemical tools that function by the allosteric regulation of their target proteins. The uses, advantages and methods of discovery of allosteric tools are discussed. Finally this chapter introduces the use of serendipitous binders for the discovery of allosteric sites. In particular, the use of CHES to identify novel allosteric sites on the sialidase NanB is proposed. Chapter 2 describes how the ‘hits' from a series of high throughput screens were reanalysed using a wide range of secondary assays to eliminate any false positives that were contaminating the results. This process removed eight of the eleven ‘hits'. Two of the remaining three compounds were then analysed further in an attempt to characterise their binding mode to NanA and/or NanB using modelling and X-ray crystallographic studies. Whilst, it was not possible to confirm the binding mode by X-ray crystallography modelling studies using the modelling software GOLD generated possible binding modes for these inhibitors. A structure activity relationship study was conducted for both compounds in an attempt to generate more potent inhibitors. Chapter 3 moves from the use of high throughput screens to identify hits against NanA and NanB to the use of the serendipitous binding of N-cyclohexyl-2-aminoethanesulfonic acid in the active site of NanB for the development of selective NanB inhibitors. First taurine was identified as the minimum unit of N-cyclohexyl-2-aminoethanesulfonic acid required to bind to the active site of NanB. Taurine was then used as the basis of an optimisation study. This chapter concludes with the identification of 2-(benzylammonio)ethanesulfonate as the next key intermediate in the development of N-cyclohexyl-2-aminoethanesulfonic acid based active site inhibitors of NanB. Chapter 4 follows on from Chapter 3 with the optimisation of 2-(benzylammonio)ethanesulfonate describing the design and synthesis of a wide range of analogues. From these compounds 2-[(3-chlorobenzyl)ammonio]ethanesulfonate was identified as the most potent and selective inhibitor. Detailed analysis of the binding of 2-[(3-chlorobenzyl)ammonio]ethanesulfonate to NanB gave a rationale for its improved inhibitory activity. The increase in inhibition occurred because on binding of 2-[(3-chlorobenzyl)ammonio]ethanesulfonate to the active site of NanB a well coordinated water molecule was displaced. The displacement of this water caused an increase in the flexibility of the enzyme's 352 loop. A detailed study of the flexibility of this loop in response to various N-cyclohexyl-2-aminoethanesulfonic acid based chemical tools was then conducted. The research in chapters 2 and 3 has recently been published. In Chapter 5 a molecule of N-cyclohexyl-2-aminoethanesulfonic acid that binds serendipitously in a previously unmentioned secondary site is elaborated into a ligand, known as Optactin, that binds strongly and selectively at this secondary site. It was then shown that Optactin inhibited NanB by binding at this secondary site. It was therefore concluded that this secondary site was in fact an allosteric site that could be used for the regulation of NanB. Chapter 6 describes the development of a rationalisation for the inhibition of NanB by Optactin. This study included the X-ray crystallographic analysis of the apo-NanB structure and the NanB-Optactin complex under a range of conditions. This was followed by mechanistic studies that identified the point in the catalytic cycle at which Optactin was inhibiting NanB. This chapter concludes with a hypothesis for the mechanism of inhibition of NanB by Optactin. 572
4	Synthesis of sialyl mimetics as biological probes Phan, Tho Van January 2004 (has links) Abstract not available Sialic acids -- Synthesis Mimicry (Chemistry) Neuraminidase -- Inhibitors Fructose -- Derivatives
5	The development of sialidase inhibitors using structure-based drug design Rogers, Graeme W. January 2017 (has links) The sialidases/neuraminidases represent a family of enzymes whose function is important in the pathogenicity of bacteria and the virulence of influenza. Relenza and Tamiflu represent two drugs that were developed using structure-based drug design (SBDD) and computational-assisted drug design (CADD). These drugs target the active site of the influenza neuraminidase A and B (GH-34 family). Sialidases in the GH-33 family could represent novel drug targets for the treatment of bacterial or parasitic infection. SBDD was employed to develop chemical tools of two GH-33 sialidases, NanB and TcTS. NanB is a potential drug target for S. pneumoniae. The chemical tool developed for NanB follows on from work within the Taylor and Westwood research groups, in which a molecule of CHES and a glycerol were found serendipitously bound within a water channel at an allosteric site. Using this information as a basis for SBDD an allosteric inhibitor of NanB, Optactin was developed. Within this work, synthesis of this inhibitor was achieved and optimised. Optactin was then modified to improve potency. This proceeded through an amide analogue and addition of an arene resulting in a mid- micromolar inhibitor (IC50: 55.4±2.5 μM). Addition of polar substituents improved potency further resulting in a low micromolar inhibitor of NanB, Optactamide (IC50: 3.0±1.7 μM). Application of this tool in vitro demonstrated that NanB and NanA have a role in invasion of S. pneumoniae into lung epithelial cells. TcTS is a potential drug target for the treatment of Chagas disease. A CADD approach using a fragment library was unsuccessful at identifying an allosteric inhibitor of TcTS despite structural similarity with NanB. A re-task of the CADD approach towards the active site was successful in identifying an inhibitor of TcTS and a fragment useful for further development. This work sets the groundwork for the development of a chemical tool targeting TcTS.
6	Tamiflu in the Water : Resistance Dynamics of Influenza A Virus in Mallards Exposed to Oseltamivir Gillman, Anna January 2016 (has links) The natural reservoir of influenza A virus (IAV) is wild waterfowl, and all human IAVs have their genetic origins from avian viruses. Neuraminidase inhibitors (NAIs) are currently the best drugs for treatment of human influenza; therefore, the orally available NAI oseltamivir (Tamiflu®) has been stockpiled worldwide as part of pandemic preparedness planning. Re-sistance to NAIs is related to worse clinical outcomes and if a new pandemic influenza virus would be oseltamivir-resistant its public health impact would be substantially worsened. The active metabolite oseltamivir carboxylate (OC) is not removed by sewage treatment and ends up in river water, where OC-concentrations up to 0.86µg/L have been detected. We hypothesize that occasional OC exposure of wild waterfowl carrying IAVs may result in circulation of resistant variants that may potentially evolve to become human-pathogenic. We tested the hypothesis in an in vivo Mallard (Anas platyrhynchos) model in which birds were infected with avian IAVs and exposed to OC. Excreted viruses were analyzed regarding genotypic and phenotypic resistance by neuraminidase (NA) sequencing and a functional NA inhibition assay. Two viruses with NAs of the phylogenetic N2-group, H6N2 and H7N9, acquired the NA substitutions R292K and I222T when host ducks were exposed to 12µg/L and 2.5µg/L of OC, respectively. Drug susceptibilities were at previously described levels for the substitutions. To test persistence of resistance, an OC resistant avian H1N1/H274Y virus (with a group N1 NA-protein) from a previous study, and three resistant H6N2/R292K variants were allowed to replicate in Mallards without drug pressure. Resistance was entirely maintained in the H1N1/H274Y virus, but the H6N2/R292K variants were outcompeted by wild type virus, indicating retained fitness of the resistant H1N1 but not the H6N2 variants. We conclude that OC in the environment may generate resistant IAVs in wild birds. Resistant avian IAVs may become a problem to humans, should the resistance trait become part of a new human pathogenic virus. It implies a need for prudent use of available NAIs, optimized sewage treatment and resistance surveillance of avian IAVs of wild birds. Influenza A virus avian influenza oseltamivir neuraminidase inhibitors resistance environmental Mallard waterfowl
7	Computational antiviral drug design Liu, Lishan 24 July 2010 (has links) This study designed and computational docked a group of ligands intended to find potent inhibitors for Neuraminidase 4 which would have strong interactions with 8 conserved amino acids in the active site. Several trials of ligands were designed based on derivatives of neuraminic acid and evaluated as inhibitors of influenza neuraminidase. Optimized geometries of those ligands were determined using HF/B3LYP/6-311++G** techniques. Binding energies of the ligands bound to the N4 subtype of the neuraminidase protein were determined using AutoDock 4.0. Currently used inhibitors for influenza viruses will also be analyzed in the exactly same way. Comparing the binding information of those candidates and current ligands can provide a useful data about the potential of these species as antiviral drugs. / Department of Chemistry Neuraminidase--Inhibitors Influenza A virus Influenza--Treatment
8	Variations génomiques et antigéniques du virus de la grippe porcine (Influenzavirus porcin) sur le territoire québécois Mhamdi, Zeineb 10 1900 (has links) A ce jour, les données génétiques et moléculaires se rapportant aux virus influenza de type A (VIs) présents dans la population porcine au Québec sont relativement rares. Pourtant, ces informations sont essentielles pour la compréhension de de l'évolution des VIs à grande échelle de 2011 à 2015. Afin de remédier à ce manque de données, différents échantillons (pulmonaires, salivaires et nasaux) ont été prélevés à partir de 24 foyers dans lesquelles les animaux présentaient des signes cliniques. Ensuite, les souches virales ont été isolées en culture cellulaire (MDCK) ou sur oeufs embryonnés. Les 8 segments génomiques des VIs de 18 souches virales ont par la suite été séquencés et analysés intégralement. La résistance aux drogues antivirales telles que l’oseltamivir (GS4071) carboxylate, le zanamivir (GS167) et l’amantadine hydrochloride a également été évaluée par des tests d'inhibition de la neuraminidase (INAs) ainsi que par un test de réduction sur plaque. Deux sous-types viraux H3N2 et H1N1 ont été identifiés dans la population porcine au Québec. Douze souches des VIs de sous-type trH3N2 ont été génétiquement liées au Cluster IV, avec au moins 6 profils de réassortiment différents. D'autre part, 6 souches virales ont été trouvées génétiquement liées au virus pandémique A(H1N1)pdm09 avec au moins trois profils de réassortiment génétique différents. Le sous-type trH3N2 des VIs est le plus répandu dans la population porcine au Québec (66,7%). La cartographie d'épitope de la protéine HA de sous-type H3 a présenté la plus forte variabilité avec 21 substitutions d’acides aminés sur 5 sites antigéniques A (5), B (8), C (5), D (1), et E (2). Toutefois, la protéine HA du sous-type H1 avait seulement 5 substitutions d'aa sur les 3 sites antigéniques Sb (1), Ca1 (2) et Ca2 (2). Un isolat H1N1 (1/6 = 16,7%) et 1 autre trH3N2 (1/12 = 8,3%) ont été trouvés comme étant résistants à l'oseltamivir. En revanche, 2 isolats du H1N1 (2/6 = 33,3%) et 2 autres du trH3N2 (2/12 = 16,7%) ont révélé être résistants au zanamivir. Dans l'ensemble, le taux de résistance aux INAs et à l’amantadine était compris entre 33,3% et 100%. La présence des VIs résistants aux drogues antivirales chez les porcs ainsi que l'émergence possible de nouvelles souches virales constituent des préoccupations majeures en la santé publique et animale justifiant ainsi la surveillance continue des VIs dans la population porcine au Québec. / Data about genomic variability of swine influenza A viruses (SIV) in Quebec herds are scarce. Yet, this information is important for understanding virus evolution in Quebec from until 2015. Different clinical samples were obtained from 24 outbreaks of swine flu in which animals were experiencing respiratory disease. Samples including lung tissues, saliva and nasal swabs were collected and virus isolation was attempted in MDCK cells and embryonated eggs. All eight gene segments of the 18 isolated SIV strains were sequenced and analysed. Antiviral drugs resistance against oseltamivir carboxylate (GS4071), zanamivir (GS167) and amantadine hydrochloride was evaluated by neuraminidase inhibition assays (NAIs) and plaque reduction assay. Two subtypes of SIV, H3N2 and H1N1, were identified in Quebec pig herds. Twelve SIV strains were genetically related to trH3N2 Cluster IV and at least 6 different reassortment profiles were identified. On the other hand, 6 Quebec SIV strains were found to be genetically related to the pandemic virus A(H1N1)pdm09 and from which three reassortment profiles were identified. Overall, the trH3N2 was the most prevalent subtype (66.7%) found in Quebec swine herds. The epitope mapping of HA indicated that the H3 subtype was the most variable with a possibility of 21 amino acids (aa) substitutions within the 5 antigenic sites A(5), B(8), C(5), D(1) and E(2). However, the HA protein of the H1 subtype had only 5 aa substitutions within 3 antigenic sites Sb(1), Ca1(2) and Ca2(2). One H1N1 (1/6 = 16.7%) and one trH3N2 (1/12 = 8.3%) were identified as strains resistant against oseltamivir. In contrast, two H1N1 (2/6 = 33.3%) and two trH3N2 (2/12 = 16.7%) strains were found to be resistant against zanamivir. Overall, the SIV resistance against antiviral neuraminidase inhibitor drugs was (33.3%). All strains were resistant against the M2 inhibitor antiviral drug, amantadine. The presence of antiviral drug resistance in Quebec swine herds and the possible emergence of new SIVs strains are public health concerns supporting the surveillance of SIVs. Porcs Virus Influenza A H1N1 H3N2 Réassortiment Résistance antivirale Inhibiteurs de la neuraminidase (INAs) Influenza A virus Swine Reassortment Antiviral resistance Neuraminidase inhibitors

Search results