Global ETD Search

121	Pesquisa sentinela da introdução do vírus do Oeste do Nilo no Brasil pela análise de doadores de sangue do Amazonas e Mato Grosso do Sul / Sentinel survey of the introduction of West Nile virus in Brazil by analyzing blood donors of Amazonas and Mato Grosso do Sul Marcelo Plaisant Geraldi 18 September 2012 (has links) O vírus do Oeste do Nilo (VON) é um Flavivírus capaz de infectar muitas espécies de vertebrados, incluindo o homem. Embora reconhecida desde 1940, esta virose nunca havia sido descrita nas Américas, onde emergiu nos Estados Unidos ao final da década de 1990, com numerosos casos de meningoencefalite em humanos. Posteriormente, sua transmissão por transfusão de sangue e órgãos foi comprovada, levando à implantação de testes moleculares (NAT) para a triagem de doadores nos EUA e Canadá a partir de 2003. Nos anos seguintes, o VON foi sendo progressivamente detectado em países como México, Panamá e áreas do Caribe, sugerindo sua iminente introdução na América do Sul. De fato, evidências sorológicas foram reveladas em cavalos e aves na Colômbia, Venezuela, Argentina e muito recentemente no pantanal mato-grossense (em cavalos). A vigilância epidemiológica para este agente é de grande importância para a saúde pública, visto o potencial de morbimortalidade deste vírus para humanos. Sendo assim este trabalho tem o objetivo de investigar a presença do RNA do VON em amostras de doadores de sangue, pacientes com meningoencefalite ou febre de origem indeterminada e soros e amostras cerebrais de equinos. Foram analisadas 2.202 doações de sangue do Amazonas (HEMOAM), 3.144 do Mato Grosso do Sul (HEMOSUL); líquido cefalorraquidiano de 51 pacientes com suspeita de meningoencefalite viral (Hospital das Clínicas/FMUSP, São Paulo) e soro de 198 pacientes com síndrome febril aguda, negativos para Dengue e Malária (Fundação de Medicina Tropical de Manaus). Além disto, 293 amostras de soros de equinos da região do Pantanal e 63 biópsias de tecido cerebral de cavalos que foram a óbito por encefalite de etiologia desconhecida. Estas amostras foram submetidas ao teste automatizado cobas TaqScreen WNV (Roche) na plataforma cobas s201 em sistema de pool de 6 unidades (doações de sangue) ou individualmente (pacientes). Todas as amostras apresentaram amplificação satisfatória do controle da reação, porém nenhuma apresentou resultado positivo para a presença do RNA do VON. Embora já exista evidência da exposição de equinos no Brasil ao VON, não parece haver até o momento, disseminação importante deste agente entre humanos e equinos, uma vez que o RNA viral não foi detectado nem em doadores de sangue e nem em equinos, incluindo os de cidades próximas aos locais onde cavalos soropositivos foram encontrados (Corumbá MS). / The West Nile Virus (WNV) is a Flavivirus able to infect many species of vertebrates, including man. Recognized since 1940, this virus had never been described in the Americas, which emerged in the United States at the end of the 1990s, with numerous cases of meningoencephalitis in humans. Later, transmission by transfusion of blood and organs was confirmed, leading to the deployment of molecular testing (NAT) for screening of donors in the U.S. and Canada since 2003. In the following years, WNV has been progressively detected in countries like Mexico, Panama and the Caribbean areas, suggesting their imminent introduction in South America In fact, serological evidence was revealed in horses and birds in Colombia, Venezuela and Argentina and most recently in Pantanal, Mato Grosso (horses). Epidemiological surveillance for this agent is of great importance to public health, given the potential morbidity and mortality of this virus to humans. Therefore this study aims to investigate the presence of WNV RNA in samples of blood donors, patients with meningoencephalitis or fever of unknown origin and serum and brain samples from horses. We analyzed 2202 blood donations from Amazon (HEMOAM), 3144 from Mato Grosso do Sul (HEMOSUL); cerebrospinal fluid of 51 patients with suspected viral encephalitis (Hospital das Clínicas / FMUSP, São Paulo) and serum samples from 198 patients with acute febrile syndrome, negative for Dengue and malaria (Foundation for Tropical Medicine in Manaus). In addition, more 293 serum samples from horses of the Pantanal and 63 biopsies of brain tissue from horses that died of encephalitis of unknown etiology. These samples were subjected to automated cobas TaqScreen WNV test (Roche) on the platform in cobas S201with a system of 6 units pool (blood donations) or individually (patients). All samples showed satisfactory control amplification, but none showed as positive for the presence of RNA VON. Although there is already evidence in horses in Brazil of exposure to WNV, there seems to be far that an important spread of this agent between humans and horses, since the viral RNA was not detected either in blood donors or in horses, including cities near the locations where seropositive horses were found (Corumbá - MS). Doação (Sangue) Equinos Flavivirus. Reação em Cadeia por Polimerase (PCR) Vírus do Oeste do Nilo Donation (Blood) Equidae. Flavivirus Polymerase chain reaction (PCR) West Nile virus
122	Caractérisation des enzymes de formation de la coiffe du virus du Nil Occidental et du métapneumovirus humain / Characterization of capping enzyme of West Nile Virus and human metapneumovirus Collet, Axelle 03 December 2015 (has links) Ma thèse a porté sur l’étude des activités enzymatiques impliquées dans la formation de la coiffe de deux virus à ARN: le virus du Nil Occidental (WNV) et le métapneumovirus humain (hMPV). Ces virus codent pour des enzymes assurant l’ajout de la coiffe de type-1 (m7GpppN2’Om) à l’extrémité 5’ de leur ARNm.Le domaine N-terminal de la protéine NS5 (NS5MTase) du WNV porte les activités N7- et 2’O-méthyltransférases (N7- et 2’O-MTases) et il a été proposé que NS5MTase puisse également porter l’activité guanylyltransférase (GTase). J’ai identifié in vitro des résidus clés impliqués dans l’interaction entre NS5MTase et des ARN substrats de chaque activité MTase. Nos résultats démontrent que le site de fixation de la coiffe est nécessaire lors de la 2’O-méthylation et ne l’est pas pour la N7-méthylation. En parallèle, j’ai recherché des résidus catalytiques de la GTase par la méthode de génétique inverse. Des résultats préliminaires indiquent que la mutation K29A induit un défaut de réplication. Ce résidu pourrait donc être impliqué dans l’activité GTase de NS5MTase.Concernant hMPV, j’ai effectué une analyse fonctionnelle du domaine CR-VI+ de la protéine L. J’ai démontré que CR-VI+ possède les activités N7- et 2’O-MTases et j’ai identifié les résidus impliqués dans le recrutement de l’ARNm. L’ordre de méthylation est non canonique avec la 2’O-méthylation qui précède la N7-méthylation. Enfin, j’ai également démontré que CR-VI+ possède une activité d’hydrolyse du GTP.Ce travail démontre que ces MTases possèdent 2 voire 3 des activités enzymatiques nécessaires à la formation de la coiffe, et représentent donc une cible de choix pour le développement d’inhibiteurs. / My PhD project is focus on the study of the enzymatic activities involved in the RNA capping pathway of two RNA viruses: the West Nile Virus (WNV) and the human metapneumovirus (hMPV). These viruses encode for enzymes allowing the addition of a cap-1 structure (m7GpppN2’Om) to their mRNA 5’ ends. The NS5 N-terminal domain (NS5MTase) of WNV harbours the N7- and 2’O-methyltransferase activities (N7- and 2’O-MTase); and it has been proposed that NS5MTase also bears a guanylyltransferase activity (GTase). I have identified residues involved in the NS5MTase interaction sites with their RNAs substrate. My assays demonstrate the importance of the cap-binding site for the 2’O-methylation but not for the N7-methylation. In parallel, I have tried to identify putative catalytic residues of the GTase activity by reverse genetics. Preliminary results suggest that NS5MTase K29 could be a catalytic residue.Concerning hMPV, I performed a functional analysis of CR-VI+ domain of the protein L. I demonstrated that the CR-VI+ domain harbours the N7- and 2’O-MTase activities and identified the residues involved in the mRNA recruitment. I showed that the methylation order is not canonical with the 2’O-methylation preceding the N7-methylation. Finally, I showed that the domain harbours an additional GTP hydrolysis activity, representing the first step of RNA cap formation for Mononegavirales.This work demonstrates that this MTase domains harbour 2 or 3 of the enzymatic activities required for viral RNA cap synthesis and represent attractive targets for the development of antivirals. Virus du Nil Occidental Métapneumovirus humain Coiffe des ARNm Méthyltransférase Guanylyltransférase Interactions protéine-ARN West Nile Virus Human metapneumovirus MRNA cap Methyltransferase Guanylyltransferase Protein-RNA interaction 570
123	Identifying Comorbid Risk Factors of West Nile Neuroinvasive Disease in the Ontario Population, 2002-2012, Using Laboratory and Health Administrative Data Sutinen, Jessica 12 June 2020 (has links) Background/Objectives: West Nile neuroinvasive disease (WNND) is a severe neurological illness that develops in approximately 1% of individuals infected with West Nile virus (WNV). Manifesting most frequently as encephalitis (WNE), meningitis (WNM), or acute flaccid paralysis (WNP), there is no cure for WNND beyond supportive care and rehabilitation, and death or permanent disability are common outcomes. As the virus arrived in North America less than 20 years ago, determinants of severe disease progression following infection are still being explored. This project is the first to examine comorbid conditions as risk factors of WNND in Ontario using a population-based study design. As prevention is the only avenue of defence against WNND, identifying comorbid risk factors of WNND would allow for public health prevention campaigns targeted to high-risk groups. The main objectives of this thesis were to explore whether pre-existing chronic diseases were associated with the development of WNND, or any of its three manifestations (i.e., encephalitis, meningitis, acute flaccid paralysis). Methods: This was a retrospective, population-based study including all Ontario residents with a confirmed diagnosis of WNV infection between January 1, 2002 and December 31, 2012. A cohort of individuals with WNV was identified from a provincial laboratory database and individually-linked to health administrative databases. In the WNV cohort, individuals with WNND and 13 comorbid conditions were identified using algorithms based on ICD-10-CA diagnostic codes. Incidence of WNND following WNV infection was then compared among individuals with and without comorbid conditions using relative risks estimated by log binomial regression. Additionally, risk ratios were calculated for associations between specific comorbid conditions and WNND neuroinvasive manifestation (i.e., encephalitis, meningitis, acute flaccid paralysis). Finally, associations between Charlson Comorbidity Index (CCI) scoring and development of WNND was examined through calculation of relative risk using log binomial regression. Results/Potential Impact: Risk factors for WNND included male sex (aRR: 1.21; 95% CI: 1.00-1.46) in addition to the combined effect of hypertension and increasing age (5-year intervals) (aRR: 1.16; 95% CI: 1.08-1.24); WNND was also associated with increasing CCI scores; individuals in low, medium, and high categories had increased risk compared to individuals with a score of zero, but the greatest risk was in the high CCI category (aRR: 3.45; 95% CI: 2.25-4.83) Male sex (aRR: 1.32; 95% CI: 1.00-1.76), increasing age (aRR: 1.02; 95% CI: 1.02-1.03), and being immunocompromised (aRR: 2.61; 95% CI: 1.23-4.53) were associated with development of WNE. No risk factors were identified for WNM and WNP. Identification of comorbid risk factors of WNND will allow public health officials to identify high-risk groups and to develop prevention strategies targeted for vulnerable individuals. West Nile virus West Nile neuroinvasive disease Risk factor Comorbidity Chronic disease Ontario Health administrative data Encephalitis Meningitis Charlson Comorbidity Index
124	Characterization of zoonotic flavi- and alphaviruses in sentinel animals in South Africa Human, Stacey 02 January 2012 (has links) In South Africa (SA), the arboviruses West Nile virus (WNV), Wesselsbron virus (WSLV), Sindbis virus (SINV) and Middelburg virus (MIDV) are considered the most important flavi- and alphaviruses. Clinical presentation and importance of these viruses as animal pathogens in SA remains ambiguous. Although widely endemic in SA, lineage 2 (L2) WNV has rarely been associated with cases of neurological disease and was therefore assumed to be non-pathogenic. However, fatal encephalitis in a foal was diagnosed as L2 WNV in SA, 1996, leading to the thought that L2 cases were possibly being missed. As the above-mentioned arboviruses have the same transmission vectors, Culex mosquitoes for WNV and SINV and Aedes mosquitoes for WSLV and MIDV, co-screening for these viruses is important. We hypothesise that horses could be used as sentinels for virus activity in SA and cases of unexplained neurological disease or fever in animals overlooked, rather than being non-existent. To this end, the study aimed to screen horses displaying unexplained neurological disease or fever with Flavivirus family-specific RT-PCR. Additionally, samples were screened with an Alphavirus family-specific RT-PCR to determine whether co-circulating viruses could be responsible for neurological symptoms in horses. The results would aid in establishing the molecular epidemiology and disease description of each virus, virus distribution and disease seasonality in SA. In total 261 clinical specimens were collected from horses displaying these symptoms (2008 - 2010). Samples were screened with Flavi- and Alphavirus differential diagnostic RT-PCR and acute serum was screened for WNV-IgM and neutralizing antibodies. Serological screening (WNV haemagglutination inhibition, WNV IgG and/or WNV neutralization) identified 62 suspected WNV cases while 34 cases could be confirmed by RT-PCR (16/34), WNV IgM and neutralization assays (18/34) and virus isolation. Neurological disease made up 91% (31/34) of the cases, mortality was calculated at 44% (15/34). Phylogenetically 12/16 RT-PCR positives grouped with L2 SA strains. The first detection of L1 WNV and horse-associated abortion in SA was reported when a pregnant mare aborted her foetus in Ceres, Western Cape. The first cases of WSLV-associated disease in horses were identified by sequencing Flavivirus RT-PCR positive products from 2 horses displaying severe neurological disease; one being fatal. This suggests missed cases in the past. To elucidate virulence factors of WSLV, a human encephalitic strain AV259, was subjected to Roche FLX454 full-genome sequencing and compared to a previously sequenced febrile strain (H177). Several structural amino acid changes occurred in proteins NS2A, NS4B and NS5 of AV259; necessary for Flavivirus replication. Phylogenetically AV259, clinical horse strains and WSLV strains previously isolated from animals, humans and arthropods were similar. Additionally and in concurrence with other studies, WSLV clusters with Sepik virus (SEPV) within the YFV group of the Flaviviridae family. Alphavirus screening identified 17 cases; 6/17 SINV and 11/17 MIDV. SINV-WNV co-infections resulted in fatal neurological disease; remaining SINV cases recovered after displaying fever and/or mild neurological disease. MIDV symptoms varied from “three-day-stiffness” to severe neurological symptoms, with 2 fatalities. Co-infections with equine encephalosis and Shuni virus were identified. MIDV strains identified in this study were phylogenetically distinct from older strains. Results highlight the use of horses as sentinels for virus activity and suggest that these arboviruses may have been previously missed as horse pathogens in Africa. These viruses should be considered as the aetiological agents in animals displaying unexplained neurological or hepatic disease, fevers or abortions. Awareness of flavi- and alphaviruses and the disease manifestation they may have in horses was illustrated. These findings suggest that a WNV vaccine may be beneficial for horses in SA. / Dissertation (MSc)--University of Pretoria, 2011. / Medical Virology / Unrestricted Wesselsbron virus (WSLV) West Nile virus (WNV) Flavivirus Encephalitis Horses South Africa (SA) Middelburg virus (MIDV) Alphavirus Sindbis virus (SINV) UCTD
125	Eine Studie zum Vorkommen des West-Nil-Virus in der Wildvogelpopulation Deutschlands Prell, Juliane 24 September 2013 (has links) In den letzten Jahren erreichten viele neue (emerging) Viren Europa, die zum Teil (z.T.) zoonotisch auf den Menschen übertragbar sind. So musste man sich mit Geflügel- und Schweinegrippe, Blauzungenkrankheit, Infektiöser Anämie der Einhufer oder auch SARS (severe acute respiratory syndrome) auseinandersetzen. Bedingt durch verschiedene Faktoren, wie Klimawandel oder zunehmende Globalisierung und damit einhergehendem Verkehr zwischen den Kontinenten verbesserten sich auch die Bedingungen für die Virusverbreitung, so dass viele für Deutschland untypische Krankheitserreger auch hier auftraten. Das West-Nil-Virus (WNV) ist in Europa bereits endemisch verbreitet und könnte somit eine besondere Gefahr für Deutschland darstellen. Es ist ein bekannter Zoonose-Erreger, und sein Eintrag und die rasche Verbreitung des Virus in Amerika 1999 zeigten wie gefährlich neue Viren in naiven Populationen sein können. Über die Verbreitung des Virus in Deutschland gibt es nur wenige Studien z.B. des Robert-Koch-Instituts (LINKE et al. 2007a) und des Friedrich-Loeffler-Instituts (SEIDOWSKI et al. 2010), wobei in keiner Studie tote Vögel als Untersuchungsmaterial genutzt wurden. Da das WNV in Amerika mit einem auffälligen Vogelsterben einherging, ist es naheliegend, den Virusnachweis zuerst bei toten Vögeln zu erbringen. info:eu-repo/classification/ddc/636.089 ddc:636.089
126	Expression diagnostisch verwendbarer Antigene zum Nachweis West-Nil-Virus-spezifischer Antikörper: Expression diagnostisch verwendbarer Antigene zum NachweisWest-Nil-Virus-spezifischer Antikörper Delker, Anna Maria 12 March 2014 (has links) Grundlage der vorliegenden Arbeit ist die Überlegung, dass eine Möglichkeit, die Spezifität der bisher angewendeten Verfahren zur West-Nil-Virus-Diagnostik zu verbessern, in der Anwendung rekombinanter WNV-spezifischer Antigene besteht. Die unter anderem auf bioinformatischen Methoden basierende Identifikation von potenziellen B-Zell-Epitopen und Auswahl entsprechender Sequenzabschnitte richtete sich dabei gezielt auf immunogene Bereiche, die innerhalb der Gruppe der Flaviviren einen ausreichenden Sequenzunterschied zu allen weiteren sequenzverwandten Erregern, zusammengefasst im Japanische Enzephalitis-Serokomplex, boten. Drei ausgewählte Bereiche innerhalb der Strukturproteinsequenz, bezeichnet als prM, Cnat und Cme, sollten mit Hilfe des Expressionssystems Pichia pastoris bzw. Escherichia coli rekombinant exprimiert werden. Nach Erarbeitung optimaler Expressionsbedingungen folgte die affinitätschromatografische Reinigung der im weiteren Verlauf zur Immunisierung von Balb/c-Mäusen eingesetzten Polypeptide. Die gewonnenen Seren der nach verschiedenen Immunisierungsprotokollen geimpften Mäuse wurden im Anschluss immunologisch untersucht. Es zeigte sich, dass die rekombinanten Derivate des Capsid-Proteins eine deutliche Serokonversion hervorriefen. Analysen der mit Cnat und MBP-Cme immunisierten Mausseren wiesen vorhandene peptidspezifische sowie virusspezifische Antikörper nach. Der Einsatz dieser gewonnenen Peptidantigene im indirekten ELISA-Testsystem zur Detektion WNV-spezifischer Antikörper unter Verwendung humaner WNV-IgG-positiver Serumproben zeigte positive Resultate. Im Gegensatz hierzu führte die Immunisierung mit prM lediglich zu einer unspezifischen murinen Antikörperbildung. Die Unterscheidung zwischen WNV-positiven und WNV negativen Humanseren war unter Verwendung des rekombinanten Antigens prM nicht möglich. Im Ergebnis zeigten zwei der drei in dieser Arbeit rekombinant erstellten Strukturproteinabschnitte ihr immunologisches Potenzial in der Generierung muriner WNV spezifischer Antikörper. Zudem konnte mit der Expression der WNV-spezifischen C Protein Antigene ein Beitrag zur Etablierung eines indirekten ELISA-Testsystems zur Detektion WNV-bedingter Humaninfektionen geleistet werden.:Inhaltsverzeichnis Bibliografische Darstellung V Abkürzungsverzeichnis VI Abbildungsverzeichnis IX Tabellenverzeichnis X Formelverzeichnis XII 1 Einleitung 1 1.1 West-Nil-Virus: Relevanz und epidemiologische Aspekte 1 1.2 Virale Struktur und Replikation 3 1.3 West-Nil-Virus-Erkrankung: Prädiktion, Pathogenese und Krankheitsbild 7 1.4 Diagnostik von West-Nil-Virus-Infektionen 9 1.5 Zielstellung 12 2 Materialien 13 2.1 Versuchstiere, Bakterien-, Hefe- und Virusstämme 13 2.2 Vektoren und Oligonukleotide 13 2.3 Reagenzsysteme, Standards und Enzyme 15 2.4 Antikörper 16 2.5 Feinchemikalien und Reagenzien 16 2.6 Puffer und Lösungen 19 2.7 Nährmedien 20 2.8 Verbrauchsmaterialien und Technische Ausstattung 21 3 Methoden 25 3.1 Molekularbiologische Methoden 25 3.1.1 Reverse Transkription 25 3.1.2 Polymerase-Kettenreaktion (PCR) 25 3.1.3 DNA-Sequenzierung 28 3.1.4 Agarose-Gelelektrophorese 28 3.1.5 DNA-Reinigung 29 3.1.6 Bestimmung der DNA-Konzentration 29 3.1.7 Restriktionsverdau 29 3.1.8 Ligation 30 3.2 Arbeiten mit E. coli 31 3.2.1 Kultivierung und Lagerung 31 3.2.2 Herstellung kompetenter E. coli-Zellen 31 3.2.3 Transformation von Plasmid-DNA in kompetente E. coli-Zellen 31 3.2.4 Plasmidpräparation aus E. coli 31 3.2.5 Expression rekombinanter Proteine in E. coli 32 3.3 Arbeiten mit P. pastoris 32 3.3.1 Kultivierung und Lagerung 32 3.3.2 Herstellung kompetenter P. pastoris-Zellen 32 3.3.3 Transformation von Plasmid-DNA in kompetente P. pastoris-Zellen 33 3.3.4 Expression rekombinanter Proteine in P. pastoris 33 3.4 Biochemische Methoden 34 3.4.1 Proteinextraktion aus Bakterienzellen 34 3.4.2 Proteinextraktion aus Hefezellen 35 3.4.3 Proteinfällung mittels Trichloressigsäure (TCA) 35 3.4.4 SDS-Polyacrylamidgelelektrophorese (SDS-PAGE) 35 3.4.5 Silberfärbung 37 3.4.6 Western Blot 37 3.4.7 Reinigung der rekombinanten Polypeptide aus Proteingemischen 38 3.4.8 Konzentrationsbestimmung von Proteinen 40 3.4.9 Spaltung von MBP-Fusionsproteinen 40 3.4.10 Indirekter Immunfluoreszenztest (IFT) 41 3.4.11 Immunisierung der Balb/c-Mäuse 42 3.4.12 Indirekter ELISA 43 3.4.13 Bestimmung des murinen Antikörpertiters 44 3.4.14 Nachweis humaner Antikörper im Testserum 45 4 Ergebnisse 46 4.1 Definition der ausgewählten Strukturproteinsequenzen 46 4.2 Expression der rekombinanten Polypeptide prM, Cnat und Cme in P. pastoris 47 4.2.1 Klonierung der Expressionsplasmide 47 4.2.2 Transformation von Pichia pastoris 49 4.2.3 Expression der Zielpeptide in P. pastoris 51 4.3 Expression von Cnat und Cme in E. coli 56 4.3.1 Klonierung der Expressionsplasmide 56 4.3.2 Transformation von E. coli 58 4.3.3 Expression der WNV-Sequenzen Cnat und Cme als Fusionsproteine 59 4.3.4 Spaltung der Fusionsproteine mittels Faktor Xa 62 4.3.5 Isolierung der Zielpeptide Cnat und Cme 63 4.4 Untersuchung der Immunogenität der rekombinanten WNV-Polypeptide 66 4.4.1 Immunisierung von Versuchstieren mit rekombinanten WNV-Polypeptiden 66 4.4.2 Analyse der murinen Seren mittels ELISA 66 4.4.3 Erweiterte Analyse des rekombinanten prM-Polypeptids mit Humanseren 67 4.4.4 Erweiterte Analyse der murinen prM-Seren im IFT 69 4.5 Prüfung der rekombinanten Peptidantigene auf ihre Verwendbarkeit in einem WNV-spezifischen Testsystem 69 4.5.1 Untersuchung der humanen Seren S2-S42 mittels ELISA 69 4.5.2 Einsatz von Cnat und MBP-Cme als Antigene zur Untersuchung der humanen Seren S2-S42 im ELISA 70 5 Diskussion 72 5.1 Expression von prM, Cnat und Cme in P. pastoris 73 5.2 Expression von Cnat und Cme in E. coli 77 5.3 Analyse der Immunogenität von prM, Cnat und MBP-Cme 79 5.4 Beitrag zur Etablierung eines indirekten ELISA für die Detektion WNV-spezifischer Antikörper in humanen Serumproben 84 6 Zusammenfassung 90 7 Literaturverzeichnis 94 8 Anhang 104 Erklärung über die eigenständige Abfassung der Arbeit XIV Danksagung XV Lebenslauf XVI info:eu-repo/classification/ddc/610 ddc:610 West-Nile-Virus
127	Primary and Secondary Immune Responses During Sequential West Nile Virus and Japanese Encephalitis Virus Infections: A Dissertation Trobaugh, Derek W. 14 February 2012 (has links) Japanese encephalitis virus (JEV) and West Nile virus (WNV) are closely related Flaviviruses that are important arthropod-borne human pathogens. Both of these viruses can cause encephalitis with significant morbidity and mortality after infection. Flaviviruses co-circulate in many areas of the world, which raises the risk for sequential infection between heterologous viruses. Sequential infection between dengue virus serotypes can lead to cross-protection, but in some cases, it leads to a severe outcome, dengue hemorrhagic fever. Previous work in hamsters and non-human primates demonstrated that prior JEV immunity protects against a lethal WNV infection. However, the ability of prior WNV immunity to protect against a lethal JEV infection has been inconclusive. WNV-immune hamsters were fully protected from JEV viremia, but in non-human primates, prior WNV-immunity only reduced disease severity, with symptoms of encephalitis still observed. These differences in cross-protection led to further investigation on the directionality as well as the underlying mechanisms for this phenomenon. Previous work in our lab found that JEV-immune C57BL/6J (B6) mice were fully protected against a lethal WNV infection, and JEV-immune CD4+ and CD8+ T cells were required for this cross-protection. In other mouse models, memory cross-reactive CD4+ and CD8+ T cell responses may induce protection or immunopathology upon secondary heterologous viral challenge. We hypothesize that JEV/WNV cross-reactive CD4+and CD8+ T cells preferentially expand upon 2o infection and contribute to cross-protection. To elucidate the potential role of T cells in sequential flavivirus infection, we identified and characterized cross-reactive CD4+ and CD8+ T cell responses between JEV and WNV. A previously reported WNV NS4b CD8+ T cell epitope and its JEV variant elicited CD8+ T cell responses in both JEV- and WNV-infected mice. Despite similarities in viral burden for pathogenic JEV and WNV viruses, CD8+ T cells from pathogenic JEV-infected mice exhibited functional and phenotypic profiles similar to those seen for the attenuated JEV strain. We believe the differences in the CD8+ T cell responses during primary JEV and WNV infection are due at least in part to the low levels of peripheral replication seen in JEV-infected mice compared to WNV-infected mice. We also found that WNV-immune B6 mice were protected against a lethal JEV infection. Cross-reactive CD8+ T cells in JEV-immune mice rapidly expanded after WNV infection. Even though WNV-immune mice had higher frequencies of memory CD8+ T cells, cross-reactive CD8+ T cells did not expand after secondary JEV infection. Neutralizing antibodies to JEV were detected in WNV-immune mice; however, cross-reactive CD8+ T cells did not expand even in the absence of these cross-reactive neutralizing antibodies. We did not detect any differences in the CD8+ T cell repertoires between JEV- and WNV-infected mice nor were WNV-immune CD8+ T cells functionally exhausted. In fact, proliferation of memory CD8+ T cells did not correlate with the ability of WNV-immune CD8+ T cells to restrict recombinant vaccinia viruses expressing the cross-reactive epitope or lyse peptide-coated targets. These data suggest that the higher frequency of memory CD8+ T cells and cross-reactive antibodies in WNV-immune mice are better able to prevent neuroinvasion following 2o JEV infection. Encephalitis Virus Japanese West Nile virus Encephalitis West Nile Fever Cross Protection CD8-Positive T-Lymphocytes Cells Hemic and Immune Systems Immunology and Infectious Disease Virology Virus Diseases Viruses
128	Seroprevalence and Risk Factors for EquineWest Nile Virus Infections in Eastern Germany, 2020 Ganzenberg, Stefanie, Sieg, Michael Sieg, Ziegler, Ute, Pfeffer, Martin, Vahlenkamp, Thomas W., Hörügel, Uwe, Groschup, Martin H., Lohmann, Katharina L. 31 August 2023 (has links) West Nile virus (WNV) infections were first detected in Germany in 2018, but information about WNV seroprevalence in horses is limited. The study’s overall goal was to gather information that would help veterinarians, horse owners, and veterinary-, and public health- authorities understand the spread of WNV in Germany and direct protective measures. For this purpose, WNV seroprevalence was determined in counties with and without previously registered WNV infections in horses, and risk factors for seropositivity were estimated. The cohort consisted of privately owned horses from nine counties in Eastern Germany. A total of 940 serum samples was tested by competitive panflavivirus ELISA (cELISA), and reactive samples were further tested by WNV IgM capture ELISA and confirmed by virus neutralization test (VNT). Information about potential risk factors was recorded by questionnaire and analyzed by logistic regression. A total of 106 serum samples showed antibodies against flaviviruses by cELISA, of which six tested positive for WNV IgM. The VNT verified a WNV infection for 54 samples (50.9%), while 35 sera neutralized tick-borne encephalitis virus (33.0%), and eight sera neutralized Usutu virus (7.5%). Hence, seroprevalence for WNV infection was 5.8% on average and was significantly higher in counties with previously registered infections (p = 0.005). The risk factor analysis showed breed type (pony), housing in counties with previously registered infections, housing type (24 h turn-out), and presence of outdoor shelter as the main significant risk factors for seropositivity. In conclusion, we estimated the extent of WNV infection in the resident horse population in Eastern Germany and showed that seroprevalence was higher in counties with previously registered equine WNV infections. info:eu-repo/classification/ddc/636 ddc:636
129	Population Dynamics and Community Structure of Mosquitoes (Diptera: Culicidae) Recorded in Denton, Texas from 2005 to 2015 Hambrick, Bethany Lynn 05 1900 (has links) A population survey was conducted on the mosquito species recorded in Denton, Texas for the years of 2005 to 2015. Data used in this project were obtained from an ongoing, long-term surveillance program led by the City of Denton and conducted through the University of North Texas. Research focused on the population dynamics and community structure of mosquitoes collected within urban areas of Denton, Texas in relation to certain environmental variables. A total of 80,837 female mosquitoes were captured and represented 38 species found under the following genera: Aedes, Anopheles, Coquillettidia, Culex, Culiseta, Mansonia, Orthopodomyia, Psorophora, Toxorhynchites, and Uranotaenia. Culex quinquefasciatus was the most abundant species followed by Aedes vexans. Seasonal patterns of the most abundant species revealed high variability throughout the study. Container breeders were most abundant in August and those that breed in floodwaters were most abundant in the months of May and September. Samples were tested for arbovirus presence through the Texas Department of State Health Services in Austin, Texas and multiple pools tested positive for West Nile virus throughout the study. Stepwise multiple regression and Spearman's rank correlation analyses were performed to examine the relationship between the mosquito community and environmental variables. Data revealed that temperature, precipitation, and dew point were the most important variables influencing the mosquito population in the City of Denton. Mosquito Mosquitoes Entomology Ecology Diptera Culicidae Virus Arbovirus West Nile virus Zika virus Culex Aedes Diversity Taxa Richness Mosquitoes -- Texas -- Denton.
130	Developing a Guide and Template to Aid the Preparation of Mosquito Surveillance Plans in Ohio Flynn, Rebecca Anne 16 July 2018 (has links) No description available. Environmental Studies Epidemiology Public Health Environmental Science Entomology mosquitoes mosquito-borne diseases mosquito surveillance plan Zika virus West Nile virus public health, zoonotic disease

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