Global ETD Search

61	Efeito da suramina na atividade da fosfolipase A2 secretada humana do grupo IIA / Effect of the suramin in the activity of the human secreted phospholipase A2 of the group IIA Aragão, Elisângela Aparecida 19 December 2008 (has links) As fosfolipases A2 (PLA2s, ou fosfatidil-acil hidrolases EC 3.1.1.4) catalisam especificamente a hidrólise das ligações ácido-éster na posição sn-2 de glicerofosfolipídios liberando, como produto da catálise, ácidos graxos e lisofosfolipídio. São encontradas em plantas, mamíferos e em veneno de animais vertebrados e invertebrados e estão envolvidas em uma ampla variedade de processos fisiológicos. A fosfolipase A2 secretada humana do grupo IIA (hsPLA2 gIIA) é uma proteína de fase aguda da resposta imunológica, pois sua expressão é induzida por endotoxinas e citocinas via processos autócrinos e/ou parácrinos durante processos inflamatórios de relevância clínica. A hsPLA2 gIIA mostra efeito bactericida contra infecção por Staphylococcus aureus, e tem marcada preferência por fosfolipídios aniônicos tais como fosfatidilglicerol (PG) encontrados em membranas bacterianas. Uma grande variedade de inibidores de PLA2 do grupo IIA foi descrita na literatura, incluindo substâncias polianiônicas que atuam contra os efeitos inflamatórios destas enzimas. Suramina é um derivado de naftiluréia polissulfonado que recentemente mostrou ligação com os resíduos catiônicos no sítio de reconhecimento interfacial de Bothropstoxina-I (BthTX-I), uma PLA2-Lys49 isolada do veneno de Bothrops jararacussu, inibindo a atividade miotóxica da proteína. Devido ao tipo de interação diferenciada da suramina com BthTX-I em relação aos inibidores competitivos de PLA2, nós avaliamos a especificidade de ligação da suramina na hsPLA2 gIIA como um modelo para estudar este novo tipo de inibidor de PLA2s. O efeito da suramina nas atividades biológicas e de membranas artificiais da hsPLA2 gIIA foi avaliado. A suramina aboliu tanto a atividade hidrolítica da hsPLA2 gIIA quanto a atividade de danificação de membranas artificiais Ca2+ independente. Embora a suramina não tenha inibido a atividade bactericida da hsPLA2 gIIA contra a linhagem Micrococcus luteus, a ativação de macrófagos foi abolida pela mesma de maneira dependente de hidrólise. Além disso, técnicas de simulação de dinâmica molecular, calorimetria de titulação isotérmica e mutagênese sítio dirigida foram utilizadas para mapear os sítios de ligação da suramina na proteína. A interação da suramina com a hsPLA2 gIIA resultou de interações eletrostáticas entre grupos sulfonados com cadeias laterais de aminoácidos da região do sítio ativo e dos resíduos em torno das posições 15 e 116 localizados, respectivamente, na N- e Cterminal. Portanto, estes resultados permitem sugerir que a suramina pode atuar como inibidor de sPLA2s / Suramin is a polysulphonated napthylurea used as an antiprotozoal drug that presents inhibitory activity against a broad range of enzymes. We have evaluated the effect of suramin against the artificial and biological activities of the secreted human group IIA phospholipase A2 (hsPLA2 gIIA), a protein involved in inflammatory processes. To map the suramin binding sites on the hsPLA2 gIIA, proteins with mutations in the active site region and in the protein surface that makes contact with the phospholipids membrane were expressed in E. coli and refolded from inclusion bodies. The activation of macrophage cell line RAW 264.7 by hsPLA2 gIIA was monitored by nitric oxide release, and bactericidal activity of the protein against Micrococcus luteus was evaluated by colony counting and by flow cytometry. The hydrolytic activity of the hsPLA2 gIIA against lipossomes composed of a mixture of dioleoylphosphatidylcholine/dioleoylphosphatidylglycerol (DOPC/DOPG) was inhibited by a concentration of 100 nM suramin. The activation of macrophages by hsPLA2 gIIA was abolished at protein/suramin molar ratios where the hydrolytic activity of the enzyme was inhibited. In contrast, both the bactericidal activity of hsPLA2 gIIA against Micrococcus luteus and permeabilization of the bacterial inner membrane were unaffected by suramin concentrations up to 50 M. The affinity of interaction of the suramin with hsPLA2 gIIA was evaluated by suramine fluorescence and the mutants K15A, K38A, R54A and K123A presented a reduced affinity. The binding of the suramin/hsPLA2 gIIA complex was investigated by molecular dynamics simulations, which indicated two conformations of the bound inhibitor, which involve cationic amino-acid side chains in the active-site region and residues around positions 15 and 116 located in the N- and C-termini respectively in the substrate recognition surface. These results were correlated with isothermal titration calorimetry data, which demonstrated 2.7 suramin-binding sites on the hsPLA2 gIIA. These results suggested that suramin represents a novel class of phospholipase A2 inhibitor Atividade bactericida Bactericidal activity Danificação de membranas Fosfolipases A2 Membrane damage Mutagênese sítio dirigida Phospholipase A2 Site-directed mutagenesis Suramin Suramina
62	Caracterização de linhagens de saccharomyces cerevisiae deficientes na biossíntese da Coenzima Q. / Characterization of saccharomyces cerevisiae strains deficient in the biosynthesis of Coenzyme Q. Paulela, Janaina Areias 20 April 2018 (has links) Coenzima Q (CoQ) é uma molécula de função essencial na transferência de elétrons da cadeia respiratória mitocondrial. Em Saccharomyces cerevisiae , a CoQ é constituída por um anel de benzeno associado a uma cadeia poliprenil, com 6 unidades de repetição, sendo por isso também denominada CoQ6 ou Q6. Ao todo já foram identificados treze genes (COQ1 COQ11, ARH1 e YAH1) nucleares necessários para biossíntese da CoQ. A maioria dos produtos Coq estão fisicamente associados em um complexo biossintético ancorado na membrana mitocondrial interna. Neste projeto, tentamos descrever resíduos relevantes de Coq3p e Coq7p aliando análises de bioinformática com testes fenotípicos para balizamento funcional. Coq7p é uma proteína com dois centros de ferro com íons carboxilato e catalisa a hidroxilação de demetoxi-Q6 (DMQ6). Neste estudo, indicamos um grupo de resíduos que modulam a atividade e a estabilidade de Coq7p: D53, R57, V111 e S114. Enquanto R57, V111 e S114 são resíduos muito conservados, V111 e S114 estão correlacionados em comunidades de coevolução. Aqui, demonstramos também que o duplo mutante S114A, V111G e o mutante S114E apresentam deficiência respiratória em temperatura não permissiva, além de acumularem o intermediário DMQ6 e sintetizarem baixas quantidades de Q6, concluindo assim que o fosmimético S114E inibe a atividade Coq7p. Dessa forma, propomos que a fosforilação do resíduo S114 promove o deslocamento de uma alça entre as hélices 2 e 3, afetando assim a atividade do centro catalítico Coq7p. Por sua vez, Coq3p atua como uma metiltransferase, catalisando diferentes passos durante a biossíntese da CoQ. Aqui, identificamos resíduos que colaboram para a atividade funcional de Coq3p: E123, S125, C131, G133, G134, H165, D203, E219, K258 e S262. Mutantes carregando as alterações E123A, H165A, D203A, E219A, K258A e S62A apresentam discreto crescimento respiratório e expressão de Coq3p similares à da linhagem selvagem, além de acumularem baixas quantidades de Q6. Enquanto C131, G133 e G134 são resíduos altamente conservados, localizados em uma alça no espaço entre fitas beta, no provável sítio ativo da proteína, mutantes C131A, G133A e G134A se superexpressos apresentam crescimento respiratório em meio contendo fonte de carbono não fermentável, além de acumularem Q6 compatíveis com os níveis de expressão proteica. Propomos assim um modelo para Coq3p, tendo os resíduos C131, G133 e G134 como centro catalítico de Coq3p. / Coenzyme Q (CoQ) is a molecule of essential function in the transfer of electrons of the mitochondrial respiratory chain. In saccharomyces cerevisiae , CoQ is constituted by a benzene ring associated with a polyprenyl chain with 6 repetition units, being therefore also denominated CoQ6 or Q6. Thirteen nuclear genes have already been identified (COQ1 COQ11, ARH1 and YAH1) required for coenzyme Q biosynthesis. Most of Coq products are physically associated in a biosynthetic complex anchored at the mitochondrial internal membrane. In this project, we identified Coq3p and Coq7p residues relevant for their respective role in CoQ synthesis combining bioinformatics analyzes with phenotypic tests for functional mapping. Coq7p is a carboxylate-bridged di-iron protein that catalyzes the hydroxylation of demetoxy-Q6 (DMQ6), the last monooxygenase step in the synthesis of CoQ. In this study, we found a group of residues that modulate the activity and stability of Coq7p: D53, R57, V111 and S114. While R57, V111 and S114 are highly conserved residues, V111 and S114 are correlated in communities of coevolution. We also demonstrate that the double mutant S114A, V111G and the mutant S114E have respiratory deficiency at non-permissive temperature, in addition to accumulating of the intermediate DMQ6 and low amounts of Q6, thus concluding that phosmimetic S114E inhibits the activity of Coq7p. Hence, we propose that the phosphorylation of S114 is required to move a loop between helices 2 and 3, thus affecting the activity of the catalytic center Coq7p. For its part, Coq3p acts as a methyltransferase, catalyzing different steps during biosynthesis of CoQ. Here we identified residues that collaborate for functional activity of Coq3p: E123, S125, C131, G133, G134, H165, D203, E219, K258 and S262. Mutants E123A, H165A, D203A, E219A, K258A and S62A, have mild respiratory growth, and expression of Coq3p levels similar to the wild strain, in addition to accumulating low amounts of Q6. While C131, G133, and G134 are residues highly conserved, located in a loop in the space between beta sheets, the overexpression of the mutants C131A, G133A and G134A present respiratory growth in medium containing non-fermentable carbon source, in addition to accumulate Q6 compatible with the levels of protein expression. We propose a model for Coq3p, with residues C131, G133 and G134 as part of Coq3p catalytic center. Coenzima Q Coenzyme Q COQ3 COQ3. COQ7 COQ7 Mutagênese sítio-dirigida Saccharomyces cerevisiae Saccharomyces cerevisiae Site-directed mutagenesis
63	Mutational Analysis of Substrate Specificity in a Citrus Paradisi Flavonol 3- O-Glucosyltransferase Devaiah, Shivakumar P., Tolliver, Benjamin M., Zhang, Cheng, Owens, Daniel K., McIntosh, Cecilia A. 01 January 2018 (has links) Citrus paradisi 3-O-glucosyltransferase (Cp3GT, Genbank Protein ID: ACS15351) and Citrus sinensis 3-O-glucosyltransferase (Cs3GT, Genbank Protein ID: AAS00612.2) share 95% amino acid sequence identity. Cp3GT was previously established as a flavonol-specific 3-O-glucosyltransferase by direct enzymatic analysis. Cs3GT is annotated as a flavonoid-3-O-glucosyltransferase and predicted to use anthocyanidins as substrates based on gene expression analysis correlated with the accumulation of anthocyanins in C. sinensis cv. Tarocco, a blood orange variety. Mutant enzymes in which amino acids found in Cs3GT were substituted for position equivalent residues in Cp3GT were generated, heterologously expressed in yeast, and characterized for substrate specificity. Structure–function relationships were investigated for wild type and mutant glucosyltransferases by homology modelling using a crystallized Vitis viniferaanthocyanidin/flavonol 3-O-GT (PDB: 2C9Z) as template and subsequent substrate docking. All enzymes showed similar patterns for optimal temperature, pH, and UDP/metal ion inhibition with differences observed in kinetic parameters. Although changes in the activity of the mutant proteins as compared to wild type were observed, cyanidin was never efficiently accepted as a substrate. citrus paradisi citrus sinensis flavonoid glucosyltransferase site-directed mutagenesis substrate specificity Biological Sciences Biochemistry Molecular Biology Plant Biology
64	Structure, Function and Evolutionary Studies of Fasciola Cathepsin L-like Proteases Norbury, Luke James, s9806495@student.rmit.edu.au January 2008 (has links) Fasciola cause considerable monetary loss in the agriculture industry, while parasitism of humans is an emerging disease. Fasciola cathepsin L-like proteases are believed to aid parasite invasion and survival through a range of functions including feeding, immune evasion and modulation, tissue migration, egg production and excystment. As such these proteases are considered good targets for chemotherapies and vaccine development. Fasciola cathepsins are evolutionarily divided into clades that reflect function and life stage of expression. Analysis of F. gigantica genomic DNA and mRNA identified novel cathepsin L-like sequences which are incorporated into a phylogenetic analysis of the complete Fasciola cathepsin L-like protease family. Analysis of mRNA transcripts isolated in this study also points to trans-splicing occurring amongst cathepsin transcripts, the first time this has been identified in Fasciola species. S2 subsite specificity is important in determining substrate interactions with cathepsin L-like proteases. Previous work has shown that amino acid substitutions at this site can dramatically influence substrate specificity. A number of substitutions, specifically those that have been observed, or predicted to occur during the evolution of Fasciola cathepsins L-like proteases, were introduced into the S2 subsite of FhCatL5 at aa69 to determine their influence. The introduction of L69C and L69S substitutions resulted in low overall activity indicating their expression provides no functional advantage, thus explaining the absence of such variants amongst fluke. The L69F variant showed an increase in the ability to cleave substrates with P2 proline, indicating F69 variants expressed by fluke are also likely to have this ability, similar to that shown with L69Y and FhCatL2. The introduction of a L69W substitution leads to increased cleavage of substrates with P2 proline, along with a decrease in cleavage of substrates with P2 phenylalanine. FgCatL1G transcripts were isolated from F. gigantica metacercariae. This contrasts with FhCatL5 and FhCatL2 which have been isolated in adult F. hepatica. These cathepsins differ at aa69, possessing tryptophan, leucine and tyrosine respectively. The processing and substrate specificities of each recombinant enzyme was analysed and compared. While FhCatL5 and FhCatL2 process in vitro in a manner similar to that reported for FhCatL1, FgCatL1G requires different processing conditions, including neutral pH. Combined with FgCatL1G possessing increased stability at acidic pH, this reflects the different environment into which FgCatL1G is expressed by immature compared to the adult flukes. The substrate specificity of FgCatL1G also differed from previously reported cathepsins, with a preference for P2 proline and low activity against substrates with P2 phenylalanine. This is the first time recombinant expression and purification of a cathepsin L-like protease specific to the immature life stages of Fasciola has been undertaken and had enzyme specificity analysed. This work has expanded knowledge of the repertoire of cathepsin proteases expressed at various life-stages of the liver fluke. Vaccination and/or drug inhibition studies may in the future be targeted towards cathepsins that are expressed in either the adult or immature stage, or perhaps both in a multi-targeted approach. The knowledge gained in this study may allow such targets to be chosen. Fasciola cathepsin L cysteine protease S2 subsite substrate specificity site-directed mutagenesis phylogeny RNA splicing molecular modeling
65	Functional Studies of the Neuropeptide Y System : Receptor-Ligand Interaction and Regulation of Food Intake Åkerberg, Helena January 2009 (has links) The members of the mammalian neuropeptide Y family, i.e. the peptides neuropeptide Y (NPY), peptide YY (PYY) and pancreatic polypeptide (PP), are all involved in regulation of food intake. In human and most other mammals they act via receptors Y1, Y2, Y4 and Y5. NPY is released in the hypothalamus and is one of the strongest appetite-stimulating neurotransmitters whereas PP and PYY are secreted from gut endocrine cells after meals and function as appetite-reducing hormones. This thesis describes studies of the NPY system at both the molecular and the physiological level. The first part describes two investigations of receptor-ligand interactions with the human Y1 and Y2 receptors. The results clarify the importance of several amino-acid residues of the human Y1 receptor. Three amino acids previously suggested by others to form a binding pocket for the carboxy-terminus of the peptide were confirmed to be crucial for interaction with peptide ligands. However, they were found to be too distantly located from each other to be able to form a binding pocket. Further investigation of the three corresponding positions in the human Y2 receptor showed that only one of the positions was important for interaction with full-length peptides. The results indicate overlapping but, surprisingly, non-identical binding of the different peptides to human Y1 and Y2 receptors, despite the fact that the two receptors share a common ancestor. The second part of the thesis describes an investigation of the effect of PP on food intake in six beagle dogs and a test for personality characteristics in dogs (TFPC). Treatment with physiological doses of PP decreased both the appetitive and the consummatory drive but had no effect on the amount food consumed. The TFPC protocol was used to map individual behavioral differences in a population of sixteen beagle dogs. The test, which included several situations that may appear in an experimental study, revealed considerable inter-individual differences in behavioral responses despite the fact that the dogs were born and housed in the same animal facility in constant controlled conditions. These results demonstrate that PP can influence food intake in distantly related mammals and emphasize the importance of considering differences in personality in experimental animals. neuropeptide Y G-protein coupled receptor (GPCR) site-directed mutagenesis pancreatic polypeptide food intake dog Pharmacology Farmakologi
66	Modeling of transient protein-protein interactions: a structural study of the thioredoxin system Obiero, Josiah Maina 25 February 2011 ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces. fluorescence spectroscopy Deinococcus radiodurans Helicobacter pylori enzyme kinetics site-directed mutagenesis thioredoxin system x-ray crystallography Protein-protein interactions
67	Investigation of the interactions between the bacterial homologue to actin, and the chaperone GroEL/ES through a combination of protein engineering and spectroscopy / Undersökning av interaktionerna mellan MreB, den bakteriella homologen till aktin, och chaperonet GroEL/ES genom en kombination av protein engineering och spektroskopi Blom, Lillemor January 2008 (has links) Molecular chaperones help many proteins in the cell reach their native conformation. The mechanism with which they do this has been studied extensively, but has not been entirely elucidated. This work is a continuation of the study done by Laila Villebeck et al. (2007) on the conformational rearrangements in the eukaryotic protein actin in interaction with the eukaryotic chaperone TRiC. In this study the intentions were to analyze the protein MreB, a prokaryotic homologue to actin, when interacting with the prokaryotic chaperone GroEL. The purpose was to investigate if the mechanisms of GroEL and TRiC are similar. The analysis of the conformation of MreB was to be made through calculations of fluorescence resonance energy transfer (FRET) between two positions in MreB labeled with fluorescein. A MreB mutant was made through site-specific mutagenesis to enable labeling at a specific position. Another single mutant and a corresponding double mutant needed for these measurements were avaliable from earlier studies. The results from fluorescence measurements on these mutants indicated that the degree of labeling was insufficient for accurate determination of FRET. Suggestions are made on improvements of the experimental approach for future studies. Site-directed mutagenesis protein engineering fluorescence FRET chaperone Site-specifik mutagenes protein engineering fluorescens FRET chaperon NATURAL SCIENCES NATURVETENSKAP
68	Modeling of transient protein-protein interactions: a structural study of the thioredoxin system Obiero, Josiah Maina 25 February 2011 (has links) ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces. fluorescence spectroscopy Deinococcus radiodurans Helicobacter pylori enzyme kinetics site-directed mutagenesis thioredoxin system x-ray crystallography Protein-protein interactions
69	Identification of epitopes on the Dengue virus type 4 envelope glycoprotein involved in neutralisation by antibodies Howard, Christopher Bruce January 2006 (has links) Dengue virus (DENV) is the causative agent of dengue fever (DF), the most prevalent arthropod-borne viral disease in the world and therefore is considered an emerging global health threat. The four DENV serotypes (DENV-1, DENV-2, DENV-3 and DENV-4) that infect humans are distinguished from one another by unique antigenic determinants (epitopes) on the DENV envelope (E) protein. The E protein is the primary antigenic site of the DENV and is responsible for inducing neutralising antibody (Ab) and cell mediated immune response in DENV infected hosts. The DENV E protein also mediates attachment of virions to host cell receptors and entry of virions into host cells by membrane fusion. The study of epitopes on DENV E protein is necessary for understanding viral function and for the design of unique polyvalent vaccines capable of inducing a neutralising antibody response against each DENV serotype. Reverse genetics using infectious cDNA clones has enabled the construction of functional intertypic DENV, where the E protein of one DENV serotype is put in the genetic background of a different DENV serotype. In addition, observations from our laboratory indicate that chimeric E proteins, consisting of E protein structural domains from different DENV serotypes can fold into functional proteins. This suggests that there is potential to engineer viruses with intertypic DENV E proteins as potential DENV vaccine candidates, which is the long term goal of studies within our research group. However, if a chimeric E protein was to be constructed containing epitopes involved in antibody mediated neutralisation of each DENV serotype, then knowledge of the location of these epitopes on the E protein of each DENV serotype would be essential. Prior to this study, monoclonal antibodies (MAbs) had been used to identify epitopes involved in antibody mediated neutralisation on the E protein of all DENV serotypes, except DENV-4. The primary objective of this study was to identify epitopes on the DENV-4 E protein involved in neutralisation by antibodies. In order to achieve this objective, a panel of 14 MAbs was generated against DENV-4 in BALB/c mice and characterised using various serological and functional assays. The identification of DENV-4 specific neutralising MAbs in the panel was essential for subsequent experiments aimed at determining antigenic domains, structural domains or specific epitopes (peptides or amino acids) involved in the neutralisation of DENV-4. The majority of MAbs (11/14) generated against DENV-4 recognised the E protein. The remaining three MAbs reacted with the non-structural (NS) 1 protein. The majority of MAbs against the E protein were DENV or Flavivirus group reactive, but four MAbs were DENV-4 specific. All MAbs against the E protein recognised conformationally dependent epitopes and were able to capture DENV-4 in an enzyme linked immuno-adsorbent assay (ELISA). Eighty percent (9/11) of the anti-E MAbs produced for this study neutralised infection of cells by DENV-4 in vitro. Three of the neutralising MAbs (F1G2, 18F5 and 13H8) were DENV-4 specific and also demonstrated the strongest neutralisation activity of the panel, reducing DENV-4 infectivity by 100-1000 fold. The amount of virus neutralised by the MAbs was not related to the avidity of the MAbs. The DENV-4 specific MAbs F1G2, 18F5 and 13H8 were used to identify epitopes involved in neutralisation of DENV-4. The MAbs that effectively captured DENV-4 were used in competitive binding assays (CBAs) to determine spatial relationships between epitopes and therefore define antigenic domains on the DENV-4 E protein. The CBAs indicated that the epitopes recognised by the panel of MAbs segregated into two distinct domains (D4E1 and D4E2) and both contained epitopes involved in neutralisation. CBAs incorporating human serum from DENV-4 infected patients suggested that the MAbs recognised the same, or spatially related, epitopes in domain D4E2 as antibodies from humans who had experienced natural dengue infections, indicating the clinical relevance of such epitopes for the development of DENV vaccines. The reactivity of the capture MAbs with low pH treated DENV-4 was also evaluated in an attempt to identify epitopes that might be more accessible during low pH-mediated virus fusion. Only one of the MAbs (13H8) recognised an acid resistant epitope. Initial attempts to identify epitopes on the DENV-4 E protein involved in neutralisation followed the traditional epitope mapping approach of selecting subpopulations of DENV-4 which escaped neutralisation by MAbs. These attempts were unsuccessful so a variety of strategies for mapping epitopes were used including DENV-4 variant analysis and site directed mutagenesis of the DENV-4 E protein, MAb screening of chimeric DENV-3/4 E proteins and MAb screening of a bacterial peptide display library. DENV-4 variants including DENV-4 isolates from different geographical locations or chemically mutagenised DENV-4 were screened with neutralising MAbs to identify neutralisation escape mutant (n.e.m.) viruses. Site directed mutagenesis of the DENV-4 E protein confirmed whether amino acid changes identified in DENV-4 n.e.m.s were essential for the binding of neutralising MAbs to an epitope. The MAb screening of DENV-4 variants identified n.e.m.s with amino acid changes at residues E95, E96, E156, E157, E203, E329 and E402 of the DENV-4 E protein. Site directed mutagenesis of the DENV-4 E protein identified two epitopes recognised by the DENV-4 specific neutralising MAbs F1G2 and 18F5 at specific amino acid residues within domains II and III of the DENV-4 E protein. No specific epitopes were identified for the MAb 13H8; however this MAb did recognise domain I and II of the DENV-4 E protein, when screened against DENV-3/4 chimeric DENV E proteins. The first epitope, which was recognised by the MAb F1G2, contained residue E95 which was located in domain II of the DENV-4 E protein. The aspartate (Asp) to alanine (Ala) change at E95 prevented the binding of F1G2 to the DENV-4 E protein. The binding of F1G2 to the E95 residue was confirmed using the pFlitrX bacterial peptide display library, which demonstrated binding of F1G2 to a peptide homologous with residues E99-E104. No peptides recognised by 13H8 and 18F5 were identified by this method. The MAb F1G2 also bound to the domain III region (E300-E495) of the DENV-4 E protein when screened against DENV-3/4 chimeric DENV E proteins. This implied that F1G2 may be recognising a discontinuous epitope consisting of domains II and III. The second epitope, which was recognised by MAb 18F5, contained residue E329 which was located in domain III of the DENV-4 E protein. The alanine (Ala) to threonine (Thr) change at E329 prevented the binding of 18F5 to the DENV-4 E protein. MAb 18F5 also bound to the domain III region (E300-E495) of the DENV-4 E protein when screened against DENV-3/4 chimeric E proteins, thus confirming the E329 epitope. The potential mechanisms by which the DENV-4 specific MAbs neutralise virus infection were evaluated by the virus overlay protein binding assay (VOPBA). The binding of MAb 18F5 to a domain III (E329) epitope of the DENV-4 E protein and the binding of MAb F1G2 to domain II (E95, E99-E104) and domain III epitopes (chimeric E protein) of the DENV-4 E protein, prevented the attachment of DENV-4 to a 40 kDa C6/36 cell protein. In contrast the binding of MAb 13H8 to domains I and II of the DENV-4 E protein did not prevent attachment of DENV-4 to the same protein. This was preliminary evidence that the binding of domain III epitopes by the MAbs F1G2 and 18F5 may be important in preventing virus attachment. The binding of MAb 13H8 to domains I and II, and the ability of this MAb to recognise DENV-4 treated at low pH, suggested that MAb 13H8 may block epitopes exposed at low pH that are required for low pH mediated virus fusion to host cell membranes. Overall, the different methods used in this study identified epitopes involved in the neutralisation of DENV-4. The distribution of epitopes involved in neutralisation throughout the DENV-4 E protein were similar to the distribution of epitopes involved in neutralisation on the DENV-1, 2 and 3 E proteins. This suggested that it might be possible to elicit neutralising antibodies against multiple DENV serotypes using chimeric E-proteins derived from two or more DENV serotypes and therefore, facilitate the design of novel tetravalent DENV vaccines. Dengue virus envelope protein neutralisation monoclonal antibody epitope neutralisation escape mutant chimeric E protein site directed mutagenesis peptide display tetravalent vaccine
70	Probing metal and substrate binding to metallo-[beta]-lactamase ImiS from Aeromonas sobria using site-directed mutagenesis Chandrasekar, Sowmya. January 2004 (has links) Thesis (M.S.)--Miami University, Dept. of Chemistry and Biochemistry, 2004. / Title from first page of PDF document. Includes bibliographical references (p. 57-64).

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