Estudo da imunogenicidade da proteína de classe 3 (PorB) purificada da membrana externa de Neisseria miningitidis: imunização intranasal/intramuscular em camundongos adultos e neonatos utilizando Bordetella pertussis como adjuvante. / Study of the immunogenecity of the class 3 proteins (PorB) purified from the outer mebrane of Neisseria meningitidis: intranasal and intramuscular immunization in adult and neonate mice using Bordetella pertussis as adjuvant.

Mariana Lopes Teixeira Raphael

28 March 2008

As proteínas de classe 3 são candidatas na preparação de uma vacina contra a doença meningocócica. O objetivo deste estudo é determinar a imunogenicidade da proteína de classe 3 purificada da cepa de Neisseria meningitidis do sorogrupo B juntamente com a capacidade adjuvante de whole cells de Bordetella pertussis. Foram imunizados camundongos BALB/c neonatos em um intervalo de 3 a 12 dias entre 1 e 4 doses da proteína de classe 3 mais adjuvante, pela via intranasal e no 21º dia pela via intramuscular com a proteína de classe 3 emulsificada com hidróxido de alumínio. Os resultados demonstraram que após 2 doses pela via intranasal e 1 dose pela via intramuscular houve rápido estímulo das células imunes nos camundongos adultos BALB/c e neonatos BALB/c e outbred. Todos os soros foram analisados por ELISA e immunoblot. O adjuvante B. pertussis administrado pelas vias intranasal ou intramuscular, aumentou a resposta imune comparada com os controles. Anticorpos bactericidas e de alta afinidade foram produzidos. / Proteins of class 3 sound candidates in the preparation of vaccine against meningococcal illness. The aim of this study was to determine the immunogenicity of class 3 proteins purified of Neisseria meningitidis of the serogroup B along with whole cells of Bordetella pertussis as adjuvant. BALB/c and outbred neonate mice between 3 and 12 days old were immunized with 1 to 4 doses of the purified class 3 proteins with or without adjuvant given by the intranasal route, and on the 21st day the animals received an intramuscular dose of the class 3 proteins with or without aluminum hydroxide. The results demonstrated that after 2 doses by the intranasal route and 1 dose intramuscular there was a rapid stimulation of the immune cells in BALB/c adult mice as well as BALB/c and outbred neonates mice. All sera were analyzed by ELISA and immunoblot. The adjuvant B. pertussis used in the present investigation and given via the intranasal or intramuscular route increased the immune response compared with the controls. High affinity and bactericidal antibodies were produced.

Neisseria meningitidis

Adjuvantes

Camundongos neonatos e adultos

Imunização intranasal

Proteína de mebrana externa

Resposta imune humoral

Neisseria meningitidis

Adjuvants

Humoral immune response

Nasal immunization

Neonates and adults mice

Outer membrane protein

IMUNIZAÇÃO NASAL EM COELHOS COM NEISSERIA LACTAMICA: IMPORTÂNCIA DOS ANTÍGENOS DE REATIVIDADE CRUZADA / Nasal Immunization in rabbits with Neisseria lactamica: importance of cross-reactive antigens

Claudia Feriotti Tunes

09 March 2006

Neisseria lactamica, uma bactéria comensal não patogênica, predominantemente humana e usualmente encontrada no trato respiratório superior de crianças, está intimamente relacionada a Neisseria meningitidis patogênica. A colonização com N. lactamica pode ser responsável pelo envolvimento da imunidade natural contra a infecção pelos meningococos em crianças pequenas, quando as taxas de portadores de meningococos são baixas. Estas características levam a sugerir que os componentes de N. lactamica possam ser um elemento-chave para a produção de uma nova vacina para N. meningitidis. Devido ao pouco conhecimento sobre a dinâmica dos portadores e sobre a diversidade da população de N. lactamica em crianças, tem sido difícil escolher um isolado representativo para preparar um adequado produto imunogênico. Em nosso estudo, foi proposto um protocolo para estudar a imunogenicidade de whole cells de N. lactamica, N. meningitidis, N. sicca ou N. meningitidis c (isoladas de portadores), através da imunização intranasal em coelhos, considerando a via de entrada natural do patógeno. Isolados da orofaringe de N. lactamica, N. meningitidis, N. sicca ou N. meningitidis c, foram inoculados em coelhos adultos pela via intranasal, numa concentração de densidade ótica 1.0 a 650nm, num volume de 1000 ?L. Os coelhos foram imunizados por quatro vezes em intervalos de sete dias. Também foram usadas cepas como N. subflava, N. elongata, N. sicca, N. perflava, N. mucosa isoladas do líquido cérebro-espinhal ou sangue de pacientes. Os coelhos desenvolveram níveis de anticorpos IgG específicos no soro, como foi determinado por ELISA usando whole cells de cepas homólogas e heterólogas. O soro dos coelhos imunizados com N. lactamica, N. meningitidis, N.sicca ou N. meningitidis c, apresentaram anticorpos IgG que reagiram com antígenos numa faixa de 5 a 130 kDa por meio de immunoblot. Os anticorpos presentes nos soros dos coelhos imunizados com N. lactamica não induziram altos títulos de anticorpos com atividade bactericida contra as cepas de N. meningitidis, no entanto, esta atividade pode ser observada com anticorpos produzidos pelos coelhos imunizados intranasalmente com N. meningitidis. Anticorpos IgG de alta avidez foram produzidos, embora não tenha sido determinada uma significativa correlação entre atividade bactericida e a indução de anticorpos IgG de alta avidez, principalmente nos coelhos imunizados com N. lactamica. A imunização RESUMO intranasal usando whole cells de N. lactamica foi adequada para sensibilizar eficientemente o sistema imune de mucosa no modelo coelho. / Neisseria lactamica, a commensal bacterium non-pathogenic to human beings and usually found in the upper respiratory tract of children, is closely related to pathogenic Neisseria meningitides. Colonization with N. lactamica can be responsible for evolving natural immunity to meningococcal infection in childhood, when rates of meningococcus carriers are low. These features lead to suggest that N. lactamica components can be key-elements in the production of a new vaccine for N. meningitides. As little is known about dynamic carriers and N. lactamica population diversity in children, it has been difficult choosing a representative for preparing an adequate immunogenic product. A protocol was proposed to study immunogenicity of whole cells of N. lactamica, N. meningitidis, N. sicca or N. meningitides c (carrier-isolated) by i.n. immunization in rabbits considering the natural pathogen entry route. Oropharinx-isolated N. lactamica, N. meningitidis, N. sicca, or N. meningitides c were i.n. inoculated into adult rabbits, in a concentration of optical density 1.0 at 650nm in a volume of 1000 ?L. The rabbits were immunized four times at seven-day intervals. N. subflava, N. elongata, N. sicca, N. perflava, N. mucosa strains isolated from CSF and blood from patients were also used. The rabbits developed levels of specific lgG antibodies in serum, as determined by ELISA using whole cells of homologous and heterologous strains. Serum from rabbits immunized with N. lactamica, N. meningitidis, and N. sicca or N. meningitides c, presented lgG antibodies reactive to 5 to 130 kDa antigens on immunoblot. Antibodies in serum from rabbits immunized with N. lactamica failed to induce high concentration of antibodies with bactericidal activity against N. meningitidis; however, this activity could be observed with antibodies produced by rabbits i.n. immunized with N. meningitidis. High avidity lgG antibodies were produced, although a significant correlation between bactericidal activity and induction of lgG antibodies of high avidity could not be determined, mainly in rabbits immunized with N. lactamica. Intranasal immunization of N.lactamica whole cells was suitable to efficiently sensitize mucosal immune system in rabbit model.

Anticorpos monoclonais

Coelhos

Neisseria lactamica

Neisseria meningitidis

Resposta imune humoral

Vacinas

Humoral immune response

Monoclonal anti-body Vaccine

Neisseria lactamica

Neisseria meningitidis

Rabbits

Skillnad i pilE genkopieantal och genuttryck mellan Neisseria meningitidis vid invasiv sjukdom eller bärarskap / Differences in pilE gene copy number and gene expression between Neisseria meningitidis in invasive disease or carriage

Al-Haseny, Sara

January 2023

Neisseria meningitidis är en bakterie som kan leda till invasiv sjukdom eller endast orsaka bärarskap i nasopharynx. Bakterien delas in i olika serogrupper och klonala komplex. Vissa av dessa grupper och klonala komplex förekommer endast hos invasiva isolat och andra bland bärare, vilket tyder på att det finns genetiska skillnader mellan invasiva och bärarisolat. I denna studie undersöktes genen pilE som kodar för PilE proteinet och ingår i bakteriens pili. Proteinet finns i två klasser, klass 1 och klass 2. Metoden som användes för att studera eventuella skillnader i förekomst och uttryck av pilE genen var digital droplet PCR (ddPCR). Både DNA och RNA kvantifierades med ddPCR för att undersöka antalet kopior av pilE genen (DNA) samt dess uttryck (RNA) mellan invasiva isolat och bärarisolat, mellan klass 1 pilE isolat och klass 2 samt fördelning av klasserna i isolattyperna. Principen för ddPCR är att dela ett prov till tiotusentals nanodroppar där individuella droppar genomgår PCR för en senare avläsning av flourescens från prober. Resultatet visade skillnad mellan bärarisolat och invasiva isolat där de invasiva isolaten visade mindre uttryck av pilE än bärarisolat. Klass 2 isolat hade signifikant färre genuttryck än klass 1 isolat och invasiva isolat visade klass 2 i högre utsträckning än bärarisolat. / Neisseria meningitidis is a bacterium that can cause invasive disease or carriage in the nasopharynx. The bacteria are divided into different serogroups and clonal complexes. Specific serogroups and clonal complexes are more frequent or are only found among invasive isolates or in carriage isolates. This study has investigated pilE, a gene that encodes the PilE protein located in the bacteria´s pilin and the protein is found in either class 1 or class 2. digital droplet PCR was used to investigate differences in presence and expression of the gene pilE. Both DNA and RNA was quantified to study the difference in copy number of the pilE gene (DNA) and its expression (RNA) between invasive isolates and carriage isolates but also between class 1 isolates and class 2 isolates. The distribution of classes between the isolate types was also investigated. The ddPCR method divides a sample into thousands of nanodroplets and a PCR reaction occurs in each droplet followed by droplet reading where fluoroscens from probes is measured. The difference that could be seen was that the invasive isolates expressed pilE in lower copies. Class 2 isolates had a significantly lower gene expression than class 1 isolates and invasive isolates expressed class 2 in a higher frequency.

Neisseria meningitidis

invasive disease

carriage

pilE

digital droplet PCR

Neisseria meningitidis

invasiv sjukdom

bärarskap

pilE

digital droplet PCR

Biomedical Laboratory Science/Technology

Interactions of Neisseria meningitidis with the human immune system

Harding, Rachel Jane

January 2015

Neisseria meningitidis is an obligate human pathogen causing over 1000 cases of meningococcal disease within the U.K., 10 % of which result in long-term disability or fatality. 10-70 % of the population carry N. meningitidis in their nasopharynx, the natural reservoir of this bacterium, as a commensal. The host-pathogen interactions of this species are complex and a greater understanding of the molecular mechanisms involved in pathogenesis and immune evasion is required. Three aspects of N. meningitidis pathogenesis were explored in this study. One mechanism of immune evasion which promotes serum resistance of N. meningitidis is recuitment of complement factor H through domains 6 and 7 (fH₆₇) by factor H binding protein (fHbp). In this study, mouse fH₆₇ was recombinantly expressed and purified. fHbp did not bind mouse fH₆₇ at physiologically relevant protein concentrations. The structure of mouse fH₆₇ was solved, showing differences in domain orientation and surface chemistry compared to the human version of this protein, potentially accounting for the host specificity of this interaction. Type IV pili (T4P) are crucial adhesins of N. meningitidis, the fibre of which is composed of thousands of copies of PilE. A method was developed to recombinantly produce large quantities of this protein from a variety of meningococcal strains and the structure was solved of one PilE protein. Subsequent analysis was performed with the PilE proteins investigating their interaction with the putative pilus receptor CD46 and human epithelia as well as their immunogenicity. A method was also established to produce PilC, the proposed tip-assocoated adhesin of T4P. ZapE has recently been identified as an important protein in pathogen colonisation, functioning as an ATPase linked to Z-ring formation in bacterial cell fission. Both N. meningitidis and E. coli ZapE were recombinantly produced. The domain boundaries were mapped and ATPase activity was confirmed. No interaction was seen with FtsZ but DNA binding and modulation was observed by shift assays, the exact function of which remains to be elucidated in future studies.

572.8

B cell responses to conjugate and polysaccharide meningococcal vaccines

Ramasamy, Maheshi Nirmala

January 2012

The primary approach to the control of meningococcal disease remains effective vaccination programmes in susceptible populations. Vaccines against serogroups A, C, W and Y offer broad protection against meningococci and both polysaccharide and conjugate quadrivalent vaccines are licensed for use in the UK. Previous studies have assessed the antibody response to meningococcal polysaccharide and conjugate vaccines, but there is limited information on the nature of the B cell response to these antigens. As part of a clinical trial using both polysaccharide (MenACWY-PS) and conjugate (MenACWY-CRM) vaccines in adult volunteers, this DPhil reports the analysis of subsets of antigen specific B-cells produced in response to either vaccine. Prior MenACWY-PS impaired the response to a subsequent dose of MenACWY-CRM. This may be due to MenACWY-PS driving terminal differentiation of antigen specific cells into plasma cells, without replenishment of the memory B cell pool. In addition, despite prior data indicating that it may act as a thymus dependent antigen, the serogroup A polysaccharide component of MenACWY-PS appears to behave in the same way as serogroup C, W & Y polysaccharide components. Antibody molecules recognise and bind to a multitude of conformational epitopes. This variability is enabled by the complexities of immunoglobulin variable domain gene recombination which can generate a vast potential repertoire of unique antibody molecules. However, the diversity of the antibody repertoire is more restricted against specific antigens and within defined B cell subsets. In this DPhil, ‘next generation’ sequencing technologies were used to investigate the diversity of the B cell variable domain before and after vaccination of adult volunteers. Individuals at baseline were found to have distinct antibody repertoires. Vaccination with a Haemophilus influenzae type b (Hib) conjugate vaccine resulted in an oligoclonal antibody response, with enrichment for Hib specific canonical antibody sequences.

616.82

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

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

Populationsbiologische und pathogenetische Aspekte von Neisseria meningitidis / Population-based and pathogenetic aspects of Neisseria meningitidis.

Weber, Martin V. R. H.

January 2007

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

Functional and molecular characterization of FarR – a transcriptional regulator of the MarR family in Neisseria meningitidis / Funktionelle und molekulare Charakterisierung von FarR, einem Transkriptionsregulator der MarR Familie in Neisseria meningitidis

Schielke, Stephanie

January 2010

Neisseria meningitidis is a facultatively pathogenic human commensal and strictly adapted to its niche within the human host, the nasopharynx. Not much is known about the regulatory processes required for adaptation to this environment. Therefore the role of the transcriptional regulator NMB1843, one of the two predicted regulators of the MarR family in the meningococcal genome, was investigated. As this gene displayed a high sequence homology to FarR, the Fatty acid resistance Regulator in N. gonorrhoeae, we designated the meningococcal protein FarR (NmFarR). Homology modeling of this protein revealed a dimeric structure with the characteristic winged helix-turn-helix DNA binding motif of the MarR family. NmFarR is highly conserved among meningococcal strains and expression of farR during exponential growth is controlled post-transcriptionally, being highest in the late exponential phase. By means of electrophoretic mobility shift assays (EMSAs) the direct and specific binding of FarR to the farAB promoter region was shown, comparable to its homologue in gonococci. As FarR is involved in fatty acid resistance in N. gonorrhoeae, susceptibility assays with the medium chain lauric acid (C12:0), the long chain saturated palmitic acid (C16:0) and the long chain unsaturated linoleic acid (C18:2) were performed, testing a wide variety of strains of both species. In contrast to the unusually susceptible gonococci, a high intrinsic fatty acid resistance was detected in almost all meningococcal isolates. The molecular basis for this intrinsic resistance in N. meningitidis was elucidated, showing that both a functional FarAB efflux pump system as well as an intact lipopolysaccharide (LPS) are responsible for palmitic acid resistance. However, even despite circumvention of the intrinsic resistance, FarR could not be connected with fatty acid resistance in meningococci. Instead, FarR was shown to directly and specifically repress expression of the Neisseria adhesin A (nadA), a promising vaccine candidate absent in N. gonorrhoeae. Microarray analyses verified these results and disclosed no further similarly regulated genes, rendering the FarR regulon the smallest regulon in meningococci reported until now. The exact FarR binding site within the nadA promoter region was identified as a 16 bp palindromic repeat and its influence on nadA transcription was proved by reporter gene fusion assays. This repression was also shown to be relevant for infection as farR deficient mutant strains displayed an increased attachment to epithelial cells. Furthermore, farR transcription was attested to be repressed upon contact with active complement components within human serum. Concluding, it is shown that FarR adopted a role in meningococcal host niche adaptation, holding the balance between immune evasion by repressing the highly antigenic nadA and host cell attachment via this same adhesin. / Neisseria meningitidis ist ein fakultativ pathogener menschlicher Kommensale und eng an die Bedingungen seiner spezifischen Nische, den Nasopharynx, angepasst. Über die regulatorischen Mechanismen, die für diese Anpassung vonnöten sind, ist nicht viel bekannt. Daher wurde die Rolle des Transkriptionsregulators NMB1843 untersucht, eines der beiden prognostizierten Regulatoren der MarR Familie im Meningokokken-Genom. Aufgrund einer hohen Sequenzhomologie dieses Gens zu FarR, dem Fatty acid resistance Regulator in N. gonorrhoeae, nannten wir das Meningokokken-Protein ebenfalls FarR (NmFarR). Homologie-Modellierung dieses Proteins ergab eine dimere Struktur mit dem charakteristischen winged helix-turn-helix DNA-Bindemotiv der MarR Familie. Es wurde gezeigt, dass NmFarR in Meningokokken-Stämmen hochkonserviert ist. Die Expression von farR wird während des exponentiellen Wachstums posttranskriptional kontrolliert und erreicht ihren Höchststand in der spätexponentiellen Phase. Wie bei seinem Homolog in Gonokokken konnte die direkte und spezifische Bindung von FarR an die farAB Promotorregion nachgewiesen werden. Da FarR in N. gonorrhoeae an der Fettsäureresistenz beteiligt ist, wurde die Suszeptibilität einer großen Auswahl von Stämmen beider Spezies gegenüber drei unterschiedlichen Fettsäuren getestet: Laurinsäure (C12:0), Palmitinsäure (C16:0) und Linolsäure (C18:2). Im Gegensatz zu den ungewöhnlich sensitiven Gonokokken konnte eine hohe inhärente Fettsäureresistenz in fast allen Meningokokken-Isolaten beobachtet werden. Nach Analyse der molekularen Grundlage dieser Resistenz konnte gezeigt werden, dass sowohl eine funktionale FarAB Efflux-Pumpe als auch ein intaktes Lipopolysaccharid (LPS) für die Palmitinsäureresistenz verantwortlich sind. Trotz Umgehung der inhärenten Resistenz konnte keine Verbindung von FarR mit Fettsäureresistenz in Meningokokken hergestellt werden. Stattdessen reprimiert FarR direkt und spezifisch die Expression des Neisseria Adhäsins A (nadA), eines vielversprechenden Impfstoffbestandteils. Microarrays bestätigten diese Ergebnisse, zeigten aber keine weiteren ähnlich regulierten Gene auf. Somit ist das FarR-Regulon das bisher kleinste Regulon in Meningokokken. Die genaue FarR-Bindestelle innerhalb des nadA Promotors wurde als ein 16 bp Palindrom identifiziert und dessen Einfluss auf die Transkription von nadA mittels Reportergenanalysen gezeigt. Auch in Infektionsversuchen wurde die Relevanz dieser Repression deutlich, da ein farR-deletierter Stamm eine höhere Adhärenz an Epithelzellen aufwies. Die Transkription von farR sank nach Kontakt mit aktiven Komplementbestandteilen aus humanem Serum. Zusammenfassend wurde gezeigt, dass FarR eine Rolle in der Nischenadaptation von Meningokokken zukommt, indem er zwischen Immunevasion durch Repression des hoch-immunogenen nadA und Wirtszelladhäsion durch eben dieses Adhäsin vermittelt.

Transkription <Genetik>

Neisseria gonorrhoeae

Neisseria meningitidis

Adhäsine

ddc:570

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

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

Molecular changes in the topoisomerase genes, gyrA and parC, and their contribution to fluoroquinolone resistance in the pathogenic Neisseria.

Hogan, Tiffany Rose, School of Medical Science, UNSW

January 2006

This thesis examined molecular changes in the quinolone-resistance determining regions (QRDRs) of the topoisomerase genes, gyrA and parC of Neisseria gonorrhoeae and Neisseria meningitidis and their contribution to fluoroquinolone resistance (FQR). Initially models of FQR emergence were developed from analysis of resistant mutants generated in vitro. The effects of the nature and order of sequential changes in GyrA and ParC on FQR were explored by correlating QRDR changes with ciprofloxacin minimum inhibitory concentration (MIC) determinations. The in vitro models were validated by comparisons of QRDR changes and MICs in two populations of wild-type FQR N. gonorrhoeae over a wide MIC range (0.09 to 24??g/mL), and in a wild type FQR meningococcus. The in vitro activities of three newer quinolones with differential activity on GyrA and ParC were compared with that of ciprofloxacin. Key findings were that the initial QRDR changes always occurred in gyrA and were the predominant influence on phenotypic expression of FQR. QRDR alterations were acquired sequentially and two GyrA and two ParC changes represented the full complement of changes observed in gonococci and two GyrA and one ParC change those in meningococci. GyrA alterations at Ser-91 in gonococci and Thr???91 in meningococci were pivotal for the development of further resistance. ParC changes required the presence of two GyrA alterations for any major impact on FQR. ParC substitutions, Ser-87???Arg and Glu-91???Gly in gonococci and Cys- 85???Asp and Glu-91???Lys in meningococci led to the expression of the highest FQR levels. Examination of FQR in wild-type meningococci was necessarily restricted, but analyses using the broader MIC range available in in-vitro-derived FQR meningococci (0.09 to 16??g/mL) revealed the first ParC changes in N. meningitidis. The study also redefined QRDR boundaries and described novel mutations within them. The nature of sequence changes in GyrA and ParC in FQR Neisseria also affected the relative activities of the three newer quinolones. Trovafloxacin was the most active quinolone in vitro but MIC differences with ciprofloxacin were mutation-dependent. Grepafloxacin and moxifloxacin were only slightly more active than ciprofloxacin in the presence of multiple QRDR changes. This thesis provides a comprehensive analysis of the relationship between QRDR alterations and FQR in N. gonorrhoeae and offers insights into the potential for FQR development in N. meningitidis.

Neisseria gonorrhoeae

Neisseria meningitidis

Drug resistance in microorganisms