Global ETD Search

211	Mécanisme, catalyse et spécificité structurale des Méthionine Sulfoxyde Réductases de classe A et caractérisation de disulfure oxydoréductases de Neisseria meningitidis / Mechanism, catalysis and substrate specificity of Methionine sulfoxide reductases of class A and characterisation of disulfure oxidoreductases from Neisseria meningitidis Gand, Adeline 23 June 2008 (has links) La protéine périplasmique PilB est décrite jouer un rôle in vivo dans la résistance des bactéries pathogènes du genre Neisseria au peroxyde d’hydrogène généré par les macrophages de l’hôte. PilB est composée de trois domaines : un domaine N-terminal (N-ter) à activité disulfure oxydoréductase, un domaine central à activité méthionine sulfoxyde réductase (Msr) de classe A, et un domaine C-terminal à activité Msr de classe B. Les MsrA et MsrB catalysent la réduction des méthionine sulfoxydes (MetSO) incluses dans des protéines, en méthionines (Met). Les deux classes A et B de Msr sont structuralement distinctes et réduisent respectivement l’isomère S et R de la fonction sulfoxyde du substrat. Elles présentent un mécanisme catalytique similaire à trois étapes impliquant la formation d’un intermédiaire acide sulfénique, suivie de celle d’un pont disulfure intramoléculaire, qui est ensuite réduit par la thiorédoxine (Trx) dans le cas des Msr cytoplasmiques et par le domaine N-ter dans le cas des domaines Msr de PilB. Le domaine N-ter présente un repliement de type DsbE. Les DsbE sont des disulfure oxydoréductases périplasmiques impliquées dans la maturation des cytochromes c. Les études réalisées au cours de ma thèse ont permis de caractériser les résidus du site actif de la MsrA de N. meningitidis impliqués dans la reconnaissance du substrat sulfoxyde et la catalyse de l’étape réductase. L’étude des disulfure oxydoréductases périplasmiques de N. meningitidis a également été entreprise afin de caractériser in vitro la DsbE de N. meningitidis et de pouvoir identifier les facteurs structuraux et moléculaires impliqués dans la reconnaissance de leurs cibles et/ou partenaires. / The periplasmic protein PilB is described to be involved in vivo in the resistance of pathogens from Neisseria genus to hydrogen peroxide generated by the host macrophages. PilB is composed of three domains : the N-ter domain (N-ter) that display a disulfure oxidoreductase activity, the central and the C-terminal that display methionine sulfoxide reductase A and B activities. MsrA and MsrB catalyse the reduction of protein bound methionine sulfoxide (MetSO) back to methionine (Met). These two classes of Msr A and B are structurally unrelated and are specific for the reduction of the S and R isomer of the sulfoxide function respectively. They share a similar catalytic mechanism consisting of three steps that involve the formation of a sulfenic acid intermediate followed by the formation of an intramolecular disulfide bond that is then reduced by thioredoxin for cytoplasmic Msrs and by the N-ter domain for the Msrs domain of the PilB protein. The N-ter domain display a DsbE fold. These proteins are periplasmic disulfure oxidoreductases involved in the cytochrome c maturation pathway. The results obtained during my PhD have lead to the characterisation of residues of the actove site of Neisseria meningitidis involved in the recognition of the sulfoxide substrate and in the catalysis of the reductase step. The study of periplasmic disulfure oxidoreductases from N. meningitidis was undertaken in order to characterise in vitro the DsbE from N. meningitidis. The structural and molecular factors involved in the recognition of their targets and/or partners could then be determined. Méthionine Sulfoxyde Réductase A spécificité structurale disulfure oxydoréductase DsbE catalyse Neisseria meningitidis
212	Host-bacteria interactions : Host cell responses and bacterial pathogenesis de Klerk, Nele January 2016 (has links) Helicobacter pylori colonizes the human stomach, where it causes gastritis that may develop into peptic ulcer disease or cancer when left untreated. Neisseria gonorrhoeae colonizes the urogenital tract and causes the sexually transmitted disease gonorrhea. In contrast, Lactobacillus species are part of the human microbiota, which is the resident microbial community, and are considered to be beneficial for health. The first host cell types that bacteria encounter when they enter the body are epithelial cells, which form the border between the inside and the outside, and macrophages, which are immune cells that engulf unwanted material. The focus of this thesis has been the interaction between the host and bacteria, aiming to increase our knowledge of the molecular mechanisms that underlie the host responses and their effects on bacterial pathogenicity. Understanding the interactions between bacteria and the host will hopefully enable the development of new strategies for the treatment of infectious disease. In paper I, we investigated the effect of N. gonorrhoeae on the growth factor amphiregulin in cervical epithelial cells and found that the processing and release of amphiregulin changes upon infection. In paper II, we examined the expression of the transcription factor early growth response-1 (EGR1) in epithelial cells during bacterial colonization. We demonstrated that EGR1 is rapidly upregulated by many different bacteria. This upregulation is independent of the pathogenicity, Gram-staining type and level of adherence of the bacteria, but generally requires viable bacteria and contact with the host cell. The induction of EGR1 is mediated primarily by signaling through EGFR, ERK1/2 and β1-integrins. In paper III, we described the interactions of the uncharacterized protein JHP0290, which is secreted by H. pylori, with host cells. JHP0290 is able to bind to several cell types and induces apoptosis and TNF release in macrophages. For both of these responses, signaling through Src family kinases and ERK is essential. Apoptosis is partially mediated by TNF release. Finally, in paper IV, we showed that certain Lactobacillus strains can reduce the colonization of H. pylori on gastric epithelial cells. Lactobacilli decrease the gene expression of SabA and thereby inhibit the binding mediated by this adhesin. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 4: Manuscript.</p> Host-bacteria interaction Helicobacter pylori Neisseria gonorrhoeae Lactobacillus Epithelial cells Macrophages EGR1 Amphiregulin SabA
213	Populationsbiologische und pathogenetische Aspekte von Neisseria meningitidis / Population-based and pathogenetic aspects of Neisseria meningitidis. Weber, Martin V. R. H. January 2007 (has links) (PDF) Meningokokken sind nach wie vor eine wichtige Ursache für Gehirnhautentzündungen und Sepsen weltweit, vor allem bei Kindern und Jugendlichen. Weil viele Pathomechanismen dieses Erregers bislang noch unvollständig verstanden sind, wurden im Rahmen der vorliegenden Doktorarbeit populationsbiologische und pathogenetische Aspekte von Neisseria meningitidis untersucht. Die Kapsel ist der hauptsächliche Pathogenitätsfaktor von Meningokokken und wichtig für die Besiedelung von neuen Wirten. Isolate von symptomfreien Trägern sind allerdings häufig unbekapselt. Um Ursachen oder Mechanismen für den Verlust der Kapselexpression aufzudecken, wurden insgesamt 166 Isolate der Bayerischen Meningokokkenträgerstudie untersucht. Alle Isolate besaßen sämtliche zur Kapselsynthese notwendigen Gene, exprimierten aber keine Kapsel. Bei 39 Isolaten fanden sich Längenvariationen in homopolymeren Sequenzen (slipped strand mispairing, SSM) in den Genen siaA und siaD. 46 Isolate enthielten Insertionselemente (IS1301, IS1016 und IS1106) in den Genen der Kapselsynthese. Irreversible Mutationen (Deletionen, Insertionen, Basensubstitutionen) wurden bei 47 Isolaten gefunden. Veränderungen der Promotorregion schienen keine Rolle zu spielen. Es wurden bei insgesamt sechs Isolaten zwei nicht-synonyme Mutationen in unmittelbarer Nähe zum putativen aktiven Zentrum der UDP-N- Acetylglukosamin-2-Epimerase entdeckt, die einen Verlust der Kapselsynthese erklären könnten. Insgesamt wurden keine Akkumulationen von Mutationen in defekten Genen gefunden und es gab auch keine Korrelationen zwischen den verschieden Ursachen und bestimmten klonalen Linien. Die erhaltenen Ergebnisse legen nahe, dass die meisten der zur Blockierung der Kapselexpression führenden Ereignisse erst im aktuellen Wirt aufgetreten sind und dass zumindest bei bestimmten klonalen Linien die Verbreitung von der Expression einer Kapsel abhängig ist. Viele pathogene Bakterien nutzen zur Infektion des Menschen die ubiquitär im Körper vorkommende Protease Plasmin. Dazu binden diese Plasmin oder das Proenzym Plasminogen. Auch Meningokokken interagieren mit Plasmin und Plasminogen. Im Rahmen der vorliegenden Arbeit konnten drei Rezeptormoleküle für Plasminogen identifiziert werden. Die drei Proteine Enolase, DnaK und Peroxiredoxin konnten mit verschiedenen Methoden auf der Oberfläche der Erreger nachgewiesen werden. Die Bindung des Plasminogens ist bei Meningokokken ausschließlich über Lysinreste der Rezeptoren vermittelt, die C-terminalen Lysinreste der hier identifizierten Rezeptormoleküle spielen aber, wenn überhaupt, nur eine untergeordnete Rolle. Die Bindung von Plasminogen war durch rekombinante Rezeptorproteine konzentrationsabhängig inhibierbar. Plasminogen konnte von Meningokokken auch aus dem Serum rekrutiert werden. Gebundenes Plasminogen war mit uPA (Urokinase Plasminogen Aktivator) aktivierbar und physiologisch aktiv, was durch die Degradation von Fibrinogen nachgewiesen wurde. Das gebundene Plasmin wurde durch die Bakterien vor der Desaktivierung durch α2- Antiplasmin geschützt. Des Weiteren konnte gezeigt werden, dass Meningokokken auch mit weiteren Faktoren des Fibrinolyse-Systems (uPA) interagieren. Sie rekrutierten uPA an ihre Oberfläche und gebundenes uPA war physiologisch aktiv. Die erhaltenen Ergebnisse bestärken die These, dass Meningokokken die Faktoren des Fibrinolyse-Systems für ihre Pathogenese nutzen. / Meningococci remain to be one of the major causes for meningitis and septicaemia worldwide, especially in children and young adults. Because many of the pathogen’s pathomechanisms still remain unresolved, in the present doctoral thesis population biology and pathogenetic aspects of Neisseria meningitidis were investigated. The capsule is the major virulence-factor of meningococci and important for the dispersal to new hosts. However, isolates extracted from healthy carriers are frequently unencapsulated. To reveal the causes or mechanisms underlying this loss of encapsulation 166 strains of the Bavarian Meningococci Carriage Study were analysed. All these strains possessed all the genes responsible for capsule expression but were acapsulate. Slipped strand mispairing was demonstrated for 39 isolates in the genes siaA and siaD. The insertion elements IS1016, IS1106 and IS1301 were responsible for the loss of encapsulation in other 46 strains and 47 isolates showed irreversible mutations (deletions, insertions and base exchanges) in capsule genes. Sequence alterations in the promoter region seemed not to be responsible for the loss of encapsulation. In close vicinity to the putative active site of the UDP-N-acetylglucosamine-2-epimerase two non-synonymous mutations were detected in altogether six strains. Altogether there was no accumulation of mutations in the uncovered defective genes and no correlation between state of encapsulation and specific clonal lineages could be revealed. The obtained results portray a scenario, were the loss of encapsulation happens in the recent host and where at least some clonal lineages are dependent on the capsule for dissemination. Many bacteria use the protease plasmin for their pathogenesis. For this they recruit plasmin or its precursor plasminogen to their surface. Meningococci were shown to interact with plasminogen, too. In the present thesis three meningococcal receptors for plasminogen were identified. The three receptor proteins enolase, DnaK and peroxiredoxin were shown to be localised extracellularly on the bacterial cell surface by diverse techniques. Binding of plasminogen was demonstrated to occur exclusively to lysine residues of the receptor molecules, but the C-terminal lysine residues of the newly identified receptors were not involved in this process. Recruitment of plasminogen to the bacterial surface could be inhibited by soluble, recombinant receptor proteins in a concentration dependent manner. Furthermore, meningococci were shown to be able to recruit plasminogen from human serum. Receptor bound plasminogen could be activated by uPA (urokinase plasminogen activator) and was physiologically active as demonstrated by degradation of fibrinogen. The bound plasmin was also protected from deactivation by α2-antiplasmin. In addition, Neisseria meningitidis was shown to interact with other components of the fibrinolytic system. The bacteria attached uPA to their surface and the bound uPA was physiologically active. These data provide further evidence for recruitment and usage of factors of the fibrinolytic system in pathogenesis of meningococci. Neisseria meningitidis Bakterienkapsel Plasminogen Plasminogen-Aktivator Urokinase Epidemiologie Krankheitsübertragung Bakterielle Infek ddc:570
214	CEACAM3-mediated phagocytosis of human-specific bacterial pathogens involves the adaptor molecule Nck Peterson, Lisa January 2008 (has links) (PDF) Carcinoembryonic antigen-related cell adhesion molecules (CEACAMs) are exploited by human-specific pathogens to anchor themselves to or invade host cells. Interestingly, human granulocytes express a specific isoform, CEACAM3, that can direct efficient, opsonin-independent phagocytosis of CEACAM-binding Neisseria, Moraxella and Haemophilus species. As opsonin-independent phagocytosis of CEACAM-binding Neisseria depends on Src-family protein tyrosine kinase (PTK) phosphorylation of the CEACAM3 cytoplasmic domain, we hypothesized that an SH2-containing protein might be involved in CEACAM3-initiated, phagocytosis-promoting signals. Accordingly, we screened glutathione-S-transferase (GST) fusion proteins containing SH2 domains derived from a panel of signaling and adapter molecules for their ability to associate with CEACAM3. In vitro pull-down assays demonstrated that the SH2 domain of the adapter molecule Nck (GST-Nck SH2), but not other SH2 domains such as the Grb2 SH2 domain, interact with CEACAM3 in a phosphotyrosine-dependent manner. Either deletion of the cytoplasmic tail of CEACAM3, or point-mutation of a critical arginine residue in the SH2 domain of Nck (GST-NckSH2R308K) that disrupts phosphotyrosine binding, both abolished CEACAM3-Nck-SH2 interaction. Upon infection of human cells with CEACAM-binding Neisseria, full-length Nck comprising an SH2 and three SH3 domains co-localized with tyrosine phosphorylated CEACAM3 and associated bacteria as analyzed by immunofluorescence staining and confocal microscopy. In addition, Nck could be detected in CEACAM3 immunoprecipitates confirming the interaction in vivo. Importantly, overexpression of a GFP-fusion protein of the isolated Nck SH2 domain (GFP-Nck-SH2), but not GFP or GFP-Nck SH2 R308K reduced CEACAM3-mediated phagocytosis of CEACAM-binding Neisseria suggesting that the adaptor molecule Nck plays an important role in CEACAM3-initiated signaling leading to internalization and elimination of human-specific pathogens. Adaptorproteine Signaltransduktion Phagozytose Neisseria gonorrhoeae Carcino-embryonales Antigen Angeborene Immunität Src-Proteine Nichtrezeptor-Tyrosinkinasen ddc:610
215	Analyse des Transkriptionsprofils von Neisseria meningitidis während der Infektion von Epithel- und Endothelzellen unter Verwendung der Mikroarraytechnologie / Transcriptome analysis of Neisseria meningitidis during the infection with epithelial and endothelial cells by using microarray technology Hübner, Claudia January 2004 (has links) (PDF) Neisseria meningitidis, ein pathogenes Bakterium, das schwere Fälle von Sepsis und Meningitis verursacht, interagiert während der Infektion mit verschiedenen Oberflächen des Wirtes. Die schnellstmögliche Anpassung an die spezifischen Milieubedingungen im Wirtsorganismus ist daher ein essentieller Schritt in der Pathogenese. Durch Verwendung von DNA-Mikroarrays, die auf gespotteten Oligonukleotiden basieren, wurde das Transkriptionsprofil von N. meningitidis während der Infektion von Epithel- und Endothelzellen analysiert. Zur Analyse wurde die isogene kapseldefiziente siaD-Mutante des N. meningitidis Stammes MC58 verwendet. 72 Gene konnten nach Kontakt mit Epithelzellen und 48 Gene nach Kontakt mit Endothelzellen als differential reguliert identifiziert werden. Darunter auch eine große Anzahl von Virulenzgenen. Während ein Teil der detektierten Gene in beiden Systemen als differentiell reguliert galt, gab es doch eine Anzahl von ORF´s, die nur für ein Zellkulturmodell spezifisch reguliert waren (59 spezifische Gene für HEp-2 und 35 spezifische Gene für HBMEC). Für einige ausgewählte Gene wurde die im Mikroarray detektierte Regulierung durch Quantitative RT-PCR nochmals bestätigt. Die Funktion von den als induziert identifizierten Genen rfaF, hem und NMB1843 wurde im Anschluß durch die Konstruktion von Mutanten näher untersucht. Das rfaF-Gen, eine in der LPS Biosynthese involvierte Heptosyl-II-transferase, wurde in beiden Zellkultursystemen als differentiell reguliert identifiziert. Die Deletion des Gens führte speziell für den bekapselten Stamm MC58 zu einer signifikanten Erhöhung der Adhärenz und Invasion nach Infektion von Epithelzellen. Untersuchungen des Infektionspotential für HBMEC Zellen ergaben keine signifikant veränderte Adhärenz und Invasion. Bei zusätzlicher Deletion von rfaF in einem opc negativen Stamm konnte eine Abnahme der bakteriellen Aufnahme im Zellkulturmodell HBMEC beobachtet werden. Dagegen zeigten die opc, rfaF negativen Mutanten nach Kontakt mit HEp-2 Zellen keine verminderte Invasion. Weiterhin führte die Deletion des rfaF-Gens zu einer verstärkten Sensibilität gegenüber humanen Serum. Diese Daten deuten daraufhin, dass die LPS-Struktur eine Rolle in der bakteriellen Zellinteraktion spielt, speziell wenn eine für die Adhäsion wichtige Komponente nicht mehr exprimiert wird. Der ORF NMB1843, der für einen Transkriptionsregulator aus der MarR-Familie kodiert, ebenso wie das Hämolysin Gen konnten nur nach Kontakt mit HBMEC Zellen als differentiell reguliert identifiziert werden. In Infektionsstudien zeigten die hem-Mutanten keine veränderte Adhärenz und Invasion. Weiterhin war die Zytotoxizität der Mutanten nicht eingeschränkt. Ob der ORF NMB1646 daher als Hämolysin fungiert bleibt zu klären. Durchgeführte Mikroarraystudien mit den NMB1843-Mutanten, führten zur Identifizierung einiger ORF´s, die möglicherweise unter der Kontrolle dieses Regulators stehen. Dazu gehören die Virulenz assoziierten Gene sodC, iga und nadA sowie das für ein Hämolysin kodierende Gen NMB1779. Die Untersuchung des Expressionsprofils mittels SDS-PAGE Analyse führte zur Identifizierung einer Proteinbande bei 210 kDa, die spezifisch für die NMB1843 negativen Stämme ist. Dieses Protein wurde als nadA identifiziert. NadA induziert im Tiermodell bakterizide Antikörper und gilt daher als möglicher Impfstoffkandidat. Die in dieser Arbeit vorgelegten Daten liefern neue Einblicke in die Pathogenitätsmechanismen von N. meningitidis und belegen die Bedeutung der transkriptionellen Genregulation in den einzelnen Stadien der Meningokokkeninfektion. / Neisseria meningitidis is a major cause of septicemia and meningitis. During the course of infection, N. meningitidis encounters multiple environments within its host, which makes rapid adaptation to environmental changes a crucial factor for neisserial pathogenicity. As technology platform oligonucleotide-based DNA microarrays were employed to analyse the transcriptome profile of N. meningitidis during two key steps of meningococcal infection: the interaction with epithelial and endothelial cells. The isogenic capsule deficient siaD mutant of the N. meningitidis strain MC58 was used for this study. Seventy-two genes were differentially regulated after contact with epithelial cells, and 48 genes were differentially regulated after contact with endothelial cells, including a considerable proportion of well-known virulence genes. While several genes were in concordance between bacteria adherent to both cell types, there were a considerable number of open reading frames that were differentially regulated in only one system (59 genes specific for HEp-2 and 35 genes specific for HBMEC). Quantitative RT-PCR analyses confirmed the microarray observed regulation for several selected ORF´s. Subsequently, the function of the upregulated genes rfaF, hem and NMB1843 was investigated by construction of mutants. The rfaF gene, encoding a heptosyl-2-transferase involved in LPS biosynthesis, were detected as being differentially regulated in both cell systems. Disruption of the rfaF gene in meningococcal strain MC58 resulted in a significantly increased adhesion and invasion to epithelial cells in particular for the capsulated mutant. Investigations of the infection potential for HBMEC cells did not result in a significant change in adherence and invasion pattern. The additional deletion of the rfaF gene in an opc negative strain leads to a significantly decrease in the bacterial uptake for HBMEC cells. Compared to HBMEC, opc, rfaF mutants showed no differences in internalisation after contact with HEp-2 cells. Moreover rfaF deficient meningococci demonstrated enhanced sensitivity to normal human serum (NHS). These data provide evidence that the LPS structure plays a role in the bacterial cell interaction, particularly if an important adhaesive structure is absent. The ORF NMB1843, which encodes a transcriptional regulator of the MarR family, as well the hemolysin gene, were detected as being upregulated only after contact with endothelial cells. Using infection assays, no changes were detected in the adherence and invasion pattern for hem mutants. Furthermore the cytotoxic potential of the mutants was not different from the parental strains. Therefore it remains to be clarified whether the ORF NMB1646 actually act as a hemolysin. Microarray studies for the NMB1843 mutants showed some ORF´s, which possibly are under control of this regulator, for example the virulence genes sodC, iga and nadA as well as the hemolysin coding gene NMB1779. The analysis of the expression profile by SDS-PAGE led to the identification of a 210 kDa protein, which is specific for the NMB1843 negative strains. This unknown protein was identified as nadA. NadA evokes a strong antibactericidal antibody response in laboratory animals. For this reason NadA is regarded as a good vaccine candidate. The data represented in this study provide new insight into the pathogenicity mechanisms of N. meningitidis and could demonstrate the importance of gene regulation on the trancriptional level during different stages of meningococcal infection. Neisseria meningitidis Infektion Endothel Epithel Transkription <Genetik> ddc:570
216	Characterisation of alternative sigma factors and the heat shock rsponse in Neisseria gonorrhoeae Laskos, Lina 1973- January 2003 (has links) Abstract not available Heat shock proteins Neisseria gonorrhoeae Bacteria Genetic regulation Stress (Physiology) Transcription factors
217	A novel gold nanoparticle-based approach for the rapid diagnosis of meningococcal infection Basi Reddy, Sreenivasulu Reddy, s3046678@student.rmit.edu.au January 2008 (has links) The bacterial meningitis caused by Neisseria meningitidis is responsible for considerable morbidity and mortality throughout the world. Given the limitations of existing diagnostic tests and the severity of the illness associated with the disease, there is a clear requirement for a rapid and specific diagnostic assay. This thesis describes the development of nanoparticle based tests for the detection of Neisseria meningitidis specific cell surface markers. As an initial target antigen, a recombinant form of highly conserved outer membrane protein, OMP85 was used. Within the OMP85 protein sequence, a predicted antigenic sequence between residues 720 and 745 was identified and found to be unique to this organism. This amino acid sequence was synthesised as peptide (SR1) with a gly-gly-cysteine spacer sequence at the N-terminus using t-boc chemistry. Also, the major virulence factor, capsular polysaccharide of N. meningitidis serogroup B bacteria was purified. Polyclonal antibodies were raised against purified OMP85 antigen in rabbits and against SR1 peptide and also against formalin inactivated N. meningitidis serogroup B whole cell bacteria in sheep. This panel of different antibodies including the commercial anti-capsular monoclonal antibodies were examined for cross reactivity against a range of closely related Gram negative bacteria. Based on these cross-reactivity studies, a highly specific anti-NM antibody was developed following purification of the anti-SR1 antiserum by immuno-affinity chromatography. Purified OMP85 antigen and anti-OMP85 antibody were successfully conjugated on 13, 30, 40, 50 and 60 nm gold nanoparticles by an electrostatic adsorption method. Coupling of the gold nanoparticles results in a shift of the respective surface plasmon peak toward longer wavelengths (in the range of 600-800 nm) resulting in a change of the colour of the colloidal suspension from red to purple to blue. An attempt was made to develop a rapid diagnostic assay based on gold nanoparticle induced colour shift assay for N. meningitidis by utilising the specific interaction of OMP85 and anti-OMP85 antibody conjugated to gold nanoparticles as a model system. However, this system was not reproducible and is likely to be due to problems with stability of gold nanoparticles during the conjugation process. As an alternative approach, a highly selective quartz crystal microbalance (QCM)-based immunosensor was designed using the same OMP85/anti-OMP85 antibody system. A method was developed using polyvinylidene fluoride (PVDF) coated QCM crystals with protein A for the directional orientation of the antibodies. To further enhance the sensitivity of the test, OMP85-conjugated gold nanoparticles were used as signal amplification probes for the reproducible detection of the target down to 300 ng/mL, corresponding to a five fold increase in sensitivity compared to detection of OMP85 antigen alone. Also, this sensor has successfully been employed to detect whole cell bacteria at a concentration as low as 100 cfu/mL. Thus, in this study using the real-time QCM measurements, a novel strategy has been developed for the sensitive detection of both N. meningitidis bacteria and the protein antigen at very low concentrations, using gold nanoparticles as signal amplification probes. Neisseria meningitides OMP85 SR-1 peptide gold nanoparticles plasmon resonance QCM PVDF immunosensor
218	Phase variable methyltransferases and their role in gene regulation in pathogenic bacteria Stefanie Dowideit Unknown Date (has links) Previous work carried out in our laboratory has identified that phase variation of type III R-M systems found in Haemophilus influenzae, Neisseria meningitidis and N. gonorrhoeae is reversible, and occurs at high frequency, as seen both through mod::lacZ fusions, and by measuring changes in repeat tract length. In addition, phase variation of the methyltransferases results in coordinated switching of expression of a distinct group of genes in each of the strains studied so far. WE have termed this phenomenon the PHASEVARION, for phase variable regulon, to identify the set of genes whose expression is affected by moe phase variation. Many of the genes found to be regulated by mod phase variation are known virulence factors and even include some genes investigated as candidates for vaccine development (Srikhanta et al., 2005 and 2009. The aims of this project was to further the investigation of how these R-M systems regulated the expression of genes which hitherto had not been predicted to phase vary. The first step in the process of investigating how phase variable R-M systems influence expression of unrelated genes is to identify the DNA sequences methylated by the methyltransferases of interest. As discussed in Chapter 3, elucidation of the ModA1 methylation target site was in part facilitated by predictions that the phase variable methyltransferase found in H. influenzae strain Rd methylated the same sequence as did HinfIII, isolated from H. influenzae strain Rf. This hypothesis was confirmed by methylation dependent inhibition of digestion, revealing that ModA1 methylates the second A in its recognition sequence, 5’-CGAAT-3’. Once confirmed, the genes found to be regulated by modA1 phase variation in the initial phasevarion study could be investigated for the presence of ModA1 methylation sites within their promoters or upstream of their transcriptional regulators. Two such methylation target sites were located just upstream of the dnaK ORF. Transcriptional start site analysis of the dnaK gene revealed three transcripiotnal start sites, one of which is unduced by heat shock. Exactly 10 nucleotides upstream of this heat shock induced transcriptional start site lies one of these ModA1 methylation target sequences. Ongoing invetigations are looking into the importance of this ModA1 site located within the dnaK promoter, and whether this is the site responsible for ModA1 dependent variations in dnaK expression. Although numerous methods were investigated for their potential to identify all sites methylated by the different modA alleles, the only method which resulted in identification of any methylation target sites was methylation dependent inhibition of restriction. This method allowed us to confirm the ModA1 recongition sequence, and to discover the methylation sequence, and adenine targeted by the modA13 allele, which is found in many clinically relevant N. gonorrhoeae strains. As will be discussed in Chapter 5, ModA13 dependent inhibition of restriction was first observed when the Neisserial plasmid pCmGFP was extracted from modA13 ON and modA13::kan cells, and further investigated and confirmed using a Southern blot approach to determine whether ModA13 dependent inhibtion could be detected as differential methylation of the chromosome. It was found that ModA13 recognised the sequence 5’-AGAAA-3’, with methylation occurring on the second last A. This sequence was mapped not only to the genes found to be regulated by modA13 phase variation, but also to the entire FA1090 chromosome, and this information will be used in future studies to investigate the direct molecular mechanisms by which modA13 phase variation results in subpopulations with different phenotypes in relation to antimicrobial resistance and biofilm/cell invasion.
219	Etudes Biochimique et Structurale de DsbA1, DsbA2 et DsbA3 : les trois homologues à l'oxydoréductase de Thiol-disulfure DsbA chez Neisseria meningitidis. Lafaye, Céline 26 November 2009 (has links) (PDF) Neisseria meningitidis est le principal agent responsable de méningites bactériennes. Les interactions hôte-pathogène dépendent du repliement correct de nombreuses protéines de surface, qui nécessite souvent la formation de ponts disulfures. Chez les bactéries à Gram-négatif, la synthèse de ces ponts est catalysée par l'oxydoréductase de thiol-disulfure DsbA. N. meningitidis possède trois gènes qui codent pour trois DsbA actives : DsbA1, DsbA2 et DsbA3. DsbA1 et DsbA2 sont des lipoprotéines impliquées dans la virulence alors que DsbA3 est une enzyme soluble périplasmique non reliée à la virulence. Les travaux de cette thèse se rapportent aux caractérisations biochimiques de ces trois enzymes et structurales de DsbA1 et DsbA3. DsbA1 et DsbA3 adoptent le repliement classique de DsbA d'Escherichia coli. La caractéristique la plus étonnante partagée par ces trois enzymes est leur exceptionnel pouvoir oxydant. Avec un potentiel redox de -80 mV, les DsbA de Neisseria sont les enzymes de la famille des thiorédoxines les plus oxydantes connues à ce jour. En accord avec cela, les études de stabilité thermales indiquent que leur forme réduite est extrêmement stable. Pour chacune de ces enzymes, les études montrent que le résidu Thréonine, retrouvé dans la région du site actif, joue un rôle clé dans la détermination de cet extraordinaire pouvoir oxydant. L'ensemble de ces résultats montrent comment des résidus situés en dehors du motif actif CXXC peuvent influencer le potentiel redox de membres de la famille des thiorédoxines. Ils montrent également que le phénotype associé à DsbA3 chez N. meningitidis ne peut être expliqué par une différence d'activité redox ou de structure. Neisseria meningitidis pont disulfure oxydoréductase Thiorédoxine DsbA potentiel redox
220	Synthesis of Structures Related to the Capsular Polysaccharide of<i> Neisseria</i> <i>meningitidis</i> Serogroup A and to Mycothiol Slättegård, Rikard January 2007 (has links) <p>This thesis describes the synthesis of structures related to the capsular polysaccharide of <i>Neisseria meningitidis</i> serogroup A and the synthesis of analogues of mycothiol, a compound produced by <i>Mycobacterium</i> <i>tuberculosis</i>. The first part of the thesis describes the synthesis of structural elements present in the native capsular polysaccharide of <i>Neisseria</i> <i>meningitidis</i> serogroup A. In this part, an improved synthesis of 2-azido-2-deoxy-D-mannopyranose is included. The second part of the thesis describes the formation of stable C-phosphonate analogues related to the capsular polysaccharide. The last part outlines the formation of analogues of mycothiol, where the syntheses of a bicyclic analogue and a thioglycosidic analogue are described.</p> Neisseria meningitidis Capsular polysaccharide Mycobacterium tuberculosis Mycothiol Organic chemistry Organisk kemi

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