Global ETD Search

41	Design and Synthesis of Inhibitors Targeting the Hepatitis C Virus NS3 Protease : Focus on C-Terminal Acyl Sulfonamides Rönn, Robert January 2007 (has links) Hepatitis C is a global health problem that affects approximately 120–180 million people. This viral infection causes serious liver diseases and the therapy available suffers from low efficiency and severe side effects. Consequently, there is a huge unmet medical need for new therapeutic agents to combat the hepatitis C virus (HCV). Inhibition of the viral NS3 protease has recently emerged as a promising approach to defeat this infection, and the first HCV NS3 protease inhibitors have now entered clinical trials. In this project, several novel HCV NS3 protease inhibitors have been designed, synthesized and biochemically evaluated. Inhibitors with various P1 C-terminal functional groups intended as potential bioisosteres to the carboxylic acid found in product-based inhibitors have been revealed. Special focus has been placed on establishing structure–activity relationships of inhibitors containing the promising P1 C-terminal acyl sulfonamide group. The properties of the acyl sulfonamide functionality that are important for producing potent inhibitors have been identified. In addition, the advantages of the acyl sulfonamide group compared to the carboxylic acid have been demonstrated in both enzymatic and cell-based assays. Besides the acyl sulfonamide functionality, the acyl cyanamide and the acyl sulfinamide groups have been identified as new carboxylic acid bioisosteres in HCV NS3 protease inhibitors. The synthetic work included the development of a fast and convenient methodology for the preparation of aryl acyl sulfonamides. The use of microwave heating and Mo(CO)6 as a solid carbon monoxide source provided aryl acyl sulfonamides from aryl halides in excellent yields. This method was subsequently used in the decoration of novel HCV NS3 protease inhibitors comprising a non-natural P1 moiety. This new class of compounds can be used as lead structures in a future optimization process aimed at producing more drug-like HCV NS3 protease inhibitors. Pharmaceutical chemistry hepatitis C virus HCV NS3 protease inhibitor acyl sulfonamide bioisostere palladium carbonylation microwave molybdenum hexacarbonyl Farmaceutisk kemi
42	Improved CoMFA Modeling by Optimization of Settings : Toward the Design of Inhibitors of the HCV NS3 Protease Peterson, Shane January 2007 (has links) The hepatitis C virus (HCV), with a global prevalence of roughly 2%, is among the most serious diseases today. Among the more promising HCV targets is the NS3 protease, for which several drug candidates have entered clinical trials. In this work, computational methods have been developed and applied to the design of inhibitors of the HCV NS3 protease. Comparative molecular field analysis (CoMFA) modeling and molecular docking are the two main computational tools used in this work. CoMFA is currently the most widely used 3D-QSAR method. Methodology for improving its predictive performance by evaluating 6120 combinations of non-default parameters has been developed. This methodology was tested on 9 data sets for various targets and found to consistently provide models of enhanced predictive accuracy. Validation was performed using q2, r2pred and response variable randomization. Molecular docking was used to develop SARs in two series of inhibitors of the HCV NS3 protease. In the first series, preliminary investigations indicated that replacement of P2 proline with phenylglycine would improve potency. Docking suggested that phenylglycine-based inhibitors may participate in two additional interactions but that the larger, more flexible phenylglycine group may result in worse ligand fit, explaining the loss in potency. In the second series, β-amino acids were explored as α-amino acid substitutes. Although β-amino acid substitution may reduce the negative attributes of peptide-like compounds, this study showed that β-amino acid substitution resulted in reduced potency. The P3 position was least sensitive to substitution and the study highlighted the importance of interactions in the oxyanion hole. Finally, docking was used to provide the conformations and alignment necessary for a CoMFA model. This CoMFA model, derived using default settings, had q2 = 0.31 and r2pred = 0.56. Application of the optimization methodology provided a more predictive model with q2 = 0.48 and r2pred = 0.68. Pharmaceutical chemistry CoMFA 3D-QSAR model validation Docking SAR hepatitis C virus HCV NS3 protease inhibitor Farmaceutisk kemi
43	On the Design and Synthesis of Hepatitis C Virus NS3 Protease Inhibitors : From Tripeptides to Achiral Compounds Örtqvist, Pernilla January 2010 (has links) Infection by the hepatitis C virus (HCV) leads to inflammation of the liver, i.e. hepatitis. The acute infection often progresses to a chronic phase during which the liver function is gradually impaired. Approximately 20% of these chronic cases develop liver cirrhosis, with an ensuing increased risk of liver cancer. Global estimates of the total number of chronic cases range from 123–170 million. Yet, neither specific anti-HCV drugs nor vaccines are available. When drugs become available for daily clinical use, rapid development of drug-resistant strains is expected, making resistance an important issue. One of the most studied targets for specific anti-HCV drugs is the NS3 protease. The main objectives of the work presented in this thesis were to design and synthesise peptidomimetic inhibitors of this enzyme, and to establish the structure–activity relationships (SARs) regarding the inhibition of the wild type as well as of the known resistant variants A156T and D168V. Substituted prolines are common P2 residues in HCV NS3 protease inhibitors. To decrease the peptide character of the inhibitors, the non-coded phenylglycine was evaluated as a proline replacement in combination with known and novel P3 and P1 residues and P2 substituents. The results confirmed that phenylglycine is a promising P2 scaffold, with a possible π-stacking interaction with histidine 57 of the active site. However, to benefit from its full potential, additional optimisation is required. A 2(1H)-pyrazinone-based scaffold was introduced as P3 residue. Utilising the scope of the method developed for the pyrazinone scaffold synthesis, the phenylglycine side-chain was transferred to the scaffold. In combination with an aromatic P1 building-block, this design yielded achiral, peptidomimetic inhibitors, three times more potent than the tripeptide lead. The SARs for the inhibition of the resistant variants A156T and D168V were investigated for compounds based on either P2 proline or phenylglycine. It was concluded that the vulnerability of the inhibitors to alterations in the enzyme depends on the P2 and the P1 residue, not only on the P2 as previously suggested. These results provide important information for the design of a new generation of inhibitors with improved properties. hepatitis C virus NS3 protease inhibitor structure-activity relationship resistance 2(1H)-pyrazinone phenylglycine Pharmaceutical chemistry Farmaceutisk kemi
44	Peptidomimetic Enzyme Inhibitors : Targeting M. tuberculosis Ribonucleotide Reductase and Hepatitis C Virus NS3 Protease Nurbo, Johanna January 2010 (has links) This thesis focuses on the design and synthesis of inhibitors targeting Mycobacterium tuberculosis ribonucleotide reductase (RNR) and hepatitis C virus (HCV) NS3 protease; enzymes that have been identified as potential drug targets for the treatment of tuberculosis and hepatitis C, respectively. Small peptides have been recognized as inhibitors of these enzymes. However, the use of peptides as drugs is limited due to their unfavorable properties. These can be circumvented by the development of less peptidic molecules, often referred to as peptidomimetics. When this work was initiated, only a few inhibitors targeting M. tuberculosis RNR had been identified, whereas the HCV NS3 protease was an established drug target. Therefore, early peptidomimetic design strategies were applied to inhibitors of RNR while the NS3 protease inhibitors were subjected to modifications in a later stage of development. It has previously been shown that peptides derived from the C-terminus of the small subunit of M. tuberculosis RNR can compete for binding to the large subunit, and thus inhibit enzyme activity. To investigate the structural requirements of these inhibitors, different series of peptides were evaluated. First, peptides from an N-terminal truncation, an alanine scan and a designed library were synthesized and evaluated to examine the importance of the individual amino acid residues. Then, a set of N-terminally Fmoc-protected peptides was evaluated, and it was found that the N-terminal group improved the affinity of the peptides even when the length of the compounds was reduced. Furthermore, potential inhibitors of less peptidic character were generated by the introduction of a benzodiazepine-based scaffold. To further reduce the peptidic character and investigate the binding properties of HCV NS3 protease inhibitors, a series of tripeptides incorporating a β-amino acid was synthesized. Inhibition was evaluated and docking studies were performed to understand how the structural changes affected inhibitory potency. The results illustrated the importance of preserving the hydrogen bonding network and retaining electrostatic interactions in the oxyanion hole between inhibitor and protein. enzyme inhibitor peptidomimetics structure-activity relationship tuberculosis ribonucleotide reductase hepatitis C virus NS3 protease Pharmaceutical chemistry Farmaceutisk kemi
45	Microarrays fonctionnels de gouttes : de la synthèse chimique combinatoire au criblage de molécules bioactives. Mugherli, Laurent 08 December 2006 (has links) (PDF) Les microarrays, assemblages organisés d'entités chimiques, biologiques ou cellulaires sont en pleine expansion, car ils présentent un potentiel élevé en recherche fondamentale et appliquée. La mise en œuvre de la technologie microarray repose sur trois méthodes essentielles : la chimie de surface pour la fonctionnalisation des supports, l'utilisation de technologies de précision micrométrique pour fabriquer les microarrays et la détection. Parmi toutes les applications, les microarrays visant à détecter l'activité enzymatique ont connus un développement rapide car ils permettent de tester l'efficacité d'un grand nombre de substrats ou d'inhibiteurs en parallèle. Les protéases, enzymes indispensables aux organismes vivants, et cibles thérapeutiques reconnues, sont des modèles biologiques de choix pour les études d'activité enzymatique sur microarray. La synthèse chimique sur puce n'est en revanche pas très développée.<br />La technologie développée au sein du laboratoire nous permet de former sur quelques cm2 des microarrays de centaines de microgouttes constituant chacune un microréacteur indépendant. Le but de cette thèse est d'appliquer pour la première fois cette technologie à la synthèse chimique et à l'étude de l'activité protéolytique, avant de combiner de manière novatrice les deux approches pour réaliser un criblage.<br />L'application de ces microarrays en synthèse chimique a été utilisée avec succès pour la synthèse d'une banque de molécules chimiques et pour la recherche combinatoire de nouveaux fluorophores. En ce qui concerne l'enzymologie, l'observation de la protéolyse a été validée en utilisant trois types de substrats fluorogènes, dans un premier temps avec la papaïne, puis avec une métalloprotéase, et enfin avec la protéase virale NS3 du virus de l'hépatite C. Finalement, l'utilisation séquentielle de la synthèse chimique et de la biochimie sur un même microarray, qui constitue une approche inédite, a été dédiée à la recherche de nouveaux inhibiteurs de la protéase virale NS3. Ce criblage a conduit à la découverte de molécules potentiellement intéressantes comme agents antiviraux. [SDV] Life Sciences Microarray puce technologie synthèse chimique combinatoire molécules bioactives substrats fluorogènes protéases NS3 VHC antiviraux
46	Design and Synthesis of Hepatitis C Virus NS3 Protease Inhibitors : Targeting Different Genotypes and Drug-Resistant Variants Belfrage, Anna Karin January 2015 (has links) Since the first approved hepatitis C virus (HCV) NS3 protease inhibitors in 2011, numerous direct acting antivirals (DAAs) have reached late stages of clinical trials. Today, several combination therapies, based on different DAAs, with or without the need of pegylated interferon-α injection, are available for chronic HCV infections. The chemical foundation of the approved and late-stage HCV NS3 protease inhibitors is markedly similar. This could partly explain the cross-resistance that have emerged under the pressure of NS3 protease inhibitors. The first-generation NS3 protease inhibitors were developed to efficiently inhibit genotype 1 of the virus and were less potent against other genotypes. The main focus in this thesis was to design and synthesize a new class of 2(1H)-pyrazinone based HCV NS3 protease inhibitors, structurally dissimilar to the inhibitors evaluated in clinical trials or approved, potentially with a unique resistance profile and with a broad genotypic coverage. Successive modifications were performed around the pyrazinone core structure to clarify the structure-activity relationship; a P3 urea capping group was found valuable for inhibitory potency, as were elongated R6 residues possibly directed towards the S2 pocket. Dissimilar to previously developed inhibitors, the P1’ aryl acyl sulfonamide was not essential for inhibition as shown by equally good inhibitory potency for P1’ truncated inhibitors. In vitro pharmacokinetic (PK) evaluations disclosed a marked influence from the R6 moiety on the overall drug-properties and biochemical evaluation of the inhibitors against drug resistant enzyme variants showed retained inhibitory potency as compared to the wild-type enzyme. Initial evaluation against genotype 3a displayed micro-molar potencies. Lead optimization, with respect to improved PK properties, were also performed on an advanced class of HCV NS3 protease inhibitors, containing a P2 quinazoline substituent in combination with a macro-cyclic proline urea scaffold with nano-molar cell based activities. Moreover, an efficient Pd-catalyzed C-N urea arylation protocol, enabling high yielding introductions of advanced urea substituents to the C3 position of the pyrazinone, and a Pd-catalyzed carbonylation procedure, to obtain acyl sulfinamides, were developed. These methods can be generally applicable in the synthesis of bioactive compounds containing peptidomimetic scaffolds and carboxylic acid bioisosteres. hepatitis C virus HCV NS3 protease inhibitors structure-activity relationship 2(1H)-pyrazinone quinazoline resistance Pd catalysis
47	Estudo in silico das intera??es da protease NS3-NS2B de DENV-2 com o inibidor pept?dico Bz-nKRR-H com finalidades terap?uticas Ourique, Gabriela Salvador 18 July 2014 (has links) Submitted by Automa??o e Estat?stica (sst@bczm.ufrn.br) on 2015-12-15T17:40:31Z No. of bitstreams: 1 GabrielaSalvadorOurique_DISSERT.pdf: 9103307 bytes, checksum: d30f3a32f57ad778a4352a7ac2b010f0 (MD5) / Approved for entry into archive by Arlan Eloi Leite Silva (eloihistoriador@yahoo.com.br) on 2015-12-28T21:29:28Z (GMT) No. of bitstreams: 1 GabrielaSalvadorOurique_DISSERT.pdf: 9103307 bytes, checksum: d30f3a32f57ad778a4352a7ac2b010f0 (MD5) / Made available in DSpace on 2015-12-28T21:29:28Z (GMT). No. of bitstreams: 1 GabrielaSalvadorOurique_DISSERT.pdf: 9103307 bytes, checksum: d30f3a32f57ad778a4352a7ac2b010f0 (MD5) Previous issue date: 2014-07-18 / Dengue (DENVE) ? um importante v?rus pat?geno pertencente ao g?nero Flavivirus. O genoma do v?rus da Dengue, ? constitu?do de RNA envelopado de fita simples e sentido ?nico (+), possui aproximadamente 10.7-11 Kb. O RNA de DENV ? traduzido como uma ?nica poliprote?na. Esta poliprote?na, ? traduzida em 3 prote?nas estruturais (C, prM e E) e 7 n?o estruturais (NS1, NS2A, NS2B, NS3, NS4A, NS4B e NS5). A prote?na NS3 ? uma prote?na multifuncional que al?m de promover o processamento da poliprote?na do genoma viral, tamb?m possui atividade helic?sica, NTP?sica e RTP?sica. A NS3 precisa de cerca de 40 res?duos da prote?na NS2B (que age como cofator) para realizar suas atividades. Os tratamentos de DV atuais s?o principalmente sintom?ticos, n?o existem vacinas eficazes aprovadas e comercializadas, nem drogas antivirais dispon?veis para proteger ou curar a doen?a da dengue. O inibidor tetrapept?dico Bz-Nle-Lys-Arg-Arg-H, (com Ki de 5,8-7,0 ?M) tem sido apresentado na literatura como um potente inibidor da protease NS3 em DV. Sendo uma estrat?gia inteligente para o tratamento da Dengue. O presente trabalho objetivou estudar as intera??es do ligante junto ao s?tio ativo para fornecer uma vis?o mais clara e aprofundada dessas intera??es. Para tal desenvolveu-se um estudo in silico, com utiliza??o de c?lculos de mec?nica qu?ntica, baseada na Teoria do Funcional da Densidade (DFT), com aproxima??es do Gradiente Generalizado (GGA) para descri??o dos efeitos de correla??o e troca. A energia de intera??o de cada amino?cido do s?tio de liga??o, com o ligante foi calculada com base no m?todo de fragmenta??o molecular com capas conjugadas (MFCC). Al?m da energia, foram calculadas as dist?ncias, tipos de intera??es moleculares e grupos at?micos envolvidos. Os modelos te?ricos utilizados foram satisfat?rios e demonstraram uma descri??o mais precisa com a utiliza??o da constante diel?trica ?=20 e 80. Os resultados demonstram que a energia de intera??o do sistema atingiu a converg?ncia em 13,5A. Dentro desse raio de intera??o os res?duos mais importantes foram identificados. Met49, Met84 e Asp81 realizam intera??es de hidrog?nio. Os res?duos Asp79 e Asp75 apresentam elevada energia de atra??o. J? res?duos como Arg54, Arg85 e Lys 131 realizam intera??es de hidrog?nio pr?ximas com o ligante, por?m, aparecem no gr?fico do BIRD possuindo elevada energia de repuls?o com o inibidor. Os resultados tamb?m destacam a import?ncia do res?duo Tyr161 e o envolvimento da tr?ade catal?tica constitu?da por Asp75, Ser135 e His51. / Dengue virus is an important patogen that causes Dengue desease in all world, and belongs to Flavivirus gender. The virus consists of enveloped RNA with a single strand positive sense, 11Kb genome. The RNA is translated into a polyprotein precursor, wich is cleaved into 3 structural proteins (C, prM e E) and 7 non-structural proteins (NS1, NS2A, NS2B, NS3, NS4A, NS4B e NS5). The NS3 is a multifunctional protein, that besides to promote the polyprotein precursor cleavage, also have NTPase, helicase and RTPase activity. The NS3 needs a hydrophilic segment of 40 residues from the transmembrane NS2B protein (who acts like cofator) to realize this functions. Actually, there's no vacines available on the market, and the treatment are just symptomatic. The tetrapeptide inhibitor Bz-Nle-Lys-Arg-Arg-H (Ki de 5,8-7,0 M) was showed as a potent inhibitor ? for NS3prot in Dengue virus. That is a inteligent alternative to treat the dengue desease. The present work aimed analyse the interactions of the ligand bounded to the activity site to provid a clear and depth vision of that interaction. For this purpouse, it was conducted an in silico study, by using quantum mechanical calculations based on Density Functional Theory (DFT), with Generalized Gradient approximation (GGA) to describe the effects of exchange and correlation. The interaction energy of each amino acid belonging to the binding site to the ligand was calculated the using the method of molecular fragmentation with conjugated caps (MFCC). Besides energy, we calculated the distances, types of molecular interactions and atomic groups involved. The theoretical models used were satisfactory and show a more accurate description when the dielectric constant = 20 ? and 80 was used. The results demonstrate that the interaction energy of the system reached convergence at 13.5 A. Within a radius of 13,5A the most important residues were identified. Met49, Met84 and Asp81 perform interactions of hydrogen with the ligant. The Asp79 and Asp75 residues present high energy of attraction. Arg54, Arg85 and Lys 131 perform hydrogen interactions with the ligand, however, appear in BIRD graph having high repulsion energy with the inhibitor. The data also emphasizes the importance of residue Tyr161 and the involvement of the catalytic triad composed by Asp75, His51 and Ser135 CNPQ::CIENCIAS BIOLOGICAS Dengue NS3 Inibidor pept?dico Bz-Nle-Lys-Arg-Arg-H Teoria do funcional da densidade
48	Design and Synthesis of Serine and Aspartic Protease Inhibitors Wångsell, Fredrik January 2006 (has links) This thesis describes the design and synthesis of compounds that are intended to inhibit serine and aspartic proteases. The first part of the text deals with preparation of inhibitors of the hepatitis C virus (HCV) NS3 serine protease. Hepatitis C is predominantly a chronic disease that afflicts about 170 million people worldwide. The NS3 protease, encoded by HCV, is essential for replication of the virus and has become one of the main targets when developing drugs to fight HCV. The inhibitors discussed here constitute surrogates for the widely used N-acyl-hydroxyproline isostere designated 4-hydroxy-cyclopentene. The stereochemistry of the 4-hydroxy-cyclopentene scaffold was determined by nuclear overhauser effect spectroscopy (NOESY) and the regiochemistry by heteronuclear multiple bond correlation (HMBC). The scaffold was decorated with different substituents to obtain both linear and macrocyclic HCV NS3 protease inhibitors that display low nanomolar activity. The second part of the thesis describes the design and synthesis of potential aspartic protease inhibitors. The hydroxyethylene motif was used as a noncleavable transition state isostere. The synthetic route yielded a pivotal intermediate with excellent stereochemical control, which was corroborated by NOESY experiments. This intermediate can be diversified with different substituents to furnish novel aspartic protease inhibitors. / <p>Report code: LIU-TEK-LIC-2006:45</p> organic chemistry organic synthesis metathesis HCV NS3 protease proline isosteres inhibitor aspartic protease inhibitors hydroxyethylene Organic Chemistry Organisk kemi
49	Modelování mechanizmů vícenásobného přístupu do mobilní sítě / Modelling of Mechanisms for Multiple Access to Mobile Network Tinka, Zdeněk January 2014 (has links) The diploma thesis „Mechanisms modelling of multi access into mobile wireless network“ is focusing the wireless network. The diploma thesis contains basic network topology of wireless standard 802.11g and utilizes key identificators of mobile node in dependency on the distance and collision controlling function for simulation purposes. In the next part of this thesis is created LTE mobile network topology, which serves for finding key identificators. In the last part is created offload topology containing both - 802.11g and LTE network. As the result are implemented offloading algorithms, which ensure data traffic switching based on comparing 802.11g and LTE key identificators. Automatically generated and shown figures providing the key statistics are the main output of this thesis.
50	Targeting Drug Resistance In HCV NS3/4A Protease: Mechanisms And Inhibitor Design Strategies Matthew, Ashley N. 10 April 2018 (has links) The Hepatitis C virus (HCV) NS3/4A protease inhibitors (PIs) have become a mainstay of newer all-oral combination therapies. Despite improvements in potency of this inhibitor class, drug resistance remains a problem with the rapid emergence of resistance-associated substitutions (RASs). In this thesis I elucidate the molecular mechanisms of drug resistance for PIs against a resistant variant and apply insights toward the design of inhibitors with improved resistance profiles using structural, biochemical and computational techniques. Newer generation PIs retain high potency against most single substitutions in the protease active site by stacking on the catalytic triad. I investigated the molecular mechanisms of resistance against the Y56H/D168A variant. My analysis revealed that the Y56H substitution disrupts these inhibitors’ favorable stacking interactions with the catalytic residue His57. To further address the impact of drug resistance, I designed new inhibitors that minimize contact with known drug resistance residues that are unessential in substrate recognition. The initially designed inhibitors exhibited flatter resistance profiles than the newer generation PIs but lost potency against the D168A variant. Finally, I designed inhibitors to extend into the substrate envelope (SE) and successfully regained potency against RAS variants maintaining a flat profile. These inhibitors both pack well in the enzyme and fit within the SE. Together these studies elucidate the molecular mechanisms of PI resistance and highlight the importance of substrate recognition in inhibitor design. The insights from this thesis provide strategies toward the development of diverse NS3/4A PIs that may one day lead to the eradication of HCV. Hepacivirus NS3/4A Protease Viral Nonstructural Proteins Protease Inhibitors Hepatitis C virus Drug Resistance Biochemistry Biophysics Structural Biology

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