The immune response to yellow fever vaccination in aged individuals

Schulz, Axel

19 July 2016

Mit zunehmendem Alter verringert sich die Fähigkeit des menschlichen Organismus Infektionen erfolgreich zu bekämpfen und, z.B. nach Impfung, einen protektiven Schutz aufzubauen. Es wird vermutet, dass die Alterung des Immunsystems eine Rolle dabei spielt. Wichtige Ergebnisse liefern dazu vor allem tierexperimentelle Studien, welche jedoch die Komplexität menschlicher Immunität nur bedingt abbilden. Nur ansatzweise erforscht ist der Einfluss immunologischer Alterungsprozesse auf die primäre Immunantwort im Menschen. Um ein besseres Verständnis über primäre Immunantworten im Alter zu erlangen, haben wir junge (n=11, Med=26 Jahre) und ältere (n=12, Med=60 Jahre) Erwachsene mit einem viralen Erreger experimentell infiziert und die akute Immunreaktion und Entwicklung langlebiger Protektion eingehend untersucht. Dafür verwendeten wir den attenuierten Lebendimpfstoff gegen Gelbfieber, der ein hervorragendes Modelsystem darstellt um anti-virale Primärantworten im Menschen zu erforschen. Wir konnten zeigen, dass ältere Impflinge weniger Gelbfiebervirus-(GFV)-neutralisierende Antikörper produzierten, schwächere GFV-spezifische CD8+ T-Zellantworten erzeugten und quantitativ als auch qualitativ veränderte GFV-spezifische CD4+ T-Zellantworten generierten. Zudem wiesen ältere Impflinge häufiger eine vergleichsweise späte Virämie auf. Unsere systembiologische Untersuchungen zeigten, dass die niedrige Zahl von frisch aus dem Thymus ausgewanderten naiven CD4+ T Zellen, sogenannten CD4+ Recent thymic emigrants, sowie der Mangel an dendritischen Zellen vor bzw. am Beginn der Infektion ausschlaggebend für die schlechtere Immunreaktion und niedrigere Langzeit-Immunität bei Älteren war. Daraus schließen wir, dass in älteren Menschen die Verfügbarkeit eines breiten Repertoires naiver CD4+ T-Zellen und eine effektive Induktion des angeborenen Immunsystems in der frühen Phase einer primären Infektion kritisch für die akute Abwehr viraler Erreger und die Ausbildung protektiver Immunität ist. / The immunological competence to fight infections and to generate protective immunity, for example upon vaccination, progressively declines with advancing age. Although the aged immune system has been extensively studied at steady state and in aged animal models, there is only rudimentary understanding on how aging affects the immune response to a primary infection in humans. Involving complex individual systemic immune properties, such investigations have been very challenging particularly with the given restrictions of experimental infections in humans. In our study, we explored age-related changes in human immunity during experimental, primary immunization with live-attenuated yellow fever (YF) vaccine. In 11 young (median age: 26 years) and 12 elderly (median age: 60 years) vaccinees, we assessed individual viral burden and compared humoral and cellular immunity by advanced flow cytometric analysis over the entire course of the acute infection and up to 3 years after it. We discovered that aged subjects developed fewer neutralizing antibodies, mounted diminished YF-specific CD8+ T-cell responses and showed quantitatively and qualitatively altered YF-specific CD4+ T-cell immunity. A comparatively late peak in YF viremia suggested impaired infection control and viral clearance in the elderly. Among numerous immune signatures, low in vivo numbers of naive CD4+ recent thymic emigrants (CD4+ RTE) prior immunization and peripheral dendritic cells (DCs) in the early phase of the innate response phase were indicative for reduced acute responsiveness and altered long-term persistence of human cellular immunity to YF vaccination in the elderly. Thus, we reveal by this study that essential elements of immune responses such as CD4+ RTEs and DCs affect productive immunity in the elderly, explaining conclusively diminished responsiveness to vaccination with neo-antigens and infection with de novo pathogens in aged people.

Alterung

Dendritische Zellen

Immunseneszenz

Thymus

Primäre Immunantwort

Lebendimpfung

Gelbfiebervirus

Thymusemmigranten

aging

dendritic cells

immune senescence

thymus

primary immune response

live viral vaccination

yellow fever virus

recent thymic emigrants

570 Biowissenschaften, Biologie

32 Biologie

WF 9821

ddc:570

Desenvolvimento de um Teste Imunoenzimático (ELISA) para a Detecção do Antígeno do Vírus da Febre Amarela (17DD) Inativado

Silva, Mauro França da

January 2007

Submitted by Priscila Nascimento (pnascimento@icict.fiocruz.br) on 2012-11-16T11:43:38Z No. of bitstreams: 1 mauro-franca-da-silva.pdf: 1113117 bytes, checksum: 4721a993f32ab60140b4d0cf8c0f704f (MD5) / Made available in DSpace on 2012-11-16T11:43:39Z (GMT). No. of bitstreams: 1 mauro-franca-da-silva.pdf: 1113117 bytes, checksum: 4721a993f32ab60140b4d0cf8c0f704f (MD5) Previous issue date: 2007 / Fundação Oswaldo Cruz. Instituto de Tecnologia em Imunobiológicos. Rio de Janeiro, RJ, Brasil / Fundação Oswaldo Cruz. Instituto Oswaldo Cruz. Rio de Janeiro, RJ, Brasil. / O vírus atenuado da febre amarela, subcepa 17DD, é utilizado por Bio-Manguinhos para a produção da vacina contra a febre amarela. Esta vacina tem sido utilizada para a imunização humana com um excelente histórico de eficácia e segurança. Entretanto, nos últimos anos, devido à ocorrência de alguns casos de eventos adversos associados ao vírus vacinal cepa 17D e subcepa 17DD, apontou-se a necessidade de desenvolvimento de uma vacina inativada. Para a implementação desta nova vacina torna-se necessário o desenvolvimento de métodos de quantificação de antígenos virais. Diferentes metodologias de quantificação podem ser utilizadas na produção de vacinas inativadas, sendo as mais comuns o teste imunoenzimático (ELISA) e o teste de dose-resposta. O presente estudo teve como objetivo o estabelecimento de um ELISA visando à detecção do antígeno do vírus da febre amarela inativado. Para este propósito, foram obtidos estoques de partículas virais da subcepa 17DD, a partir de culturas de células Vero, os quais foram purificados e quantificados por métodos bioquímicos e virológicos clássicos, respectivamente. Para o desenvolvimento do teste utilizamos diferentes anticorpos como capturana fase sólida. Os resultados obtidos para os testes utilizando o anticorpo 2D12 como captura mostraram um limite de detecção do antígeno no ELISA foi de 2,21 log 10 PFU/0,1mL e (1,55 µg/0,1mL). A partir deste valor, foi estabelecido um controle positivo contendo o vírus 17DD atenuado com título de 3,06 log10 PFU/mL e (29µg/0,1mL). Os resultados mostram, também, que o ELISA foi capaz de detectar o vírus 17DD inativado por formaldeído até a diluição 1:16 (52,9 µg/0,1mL). Baseado nos resultados obtidos acredita-se que o desenvolvimento de um teste de ELISA para detecção e quantificação do antígeno 17DD possa representar umimportante avanço tecnológico no controle da produção de uma vacina inativada contraa febre amarela. / The attenuated 17DD substrain of yellow fever virus is used in Bio-Manguinhos for yellow fever vaccine production. This vaccine has been used for human immunization with an excellent history of efficacy and safety. However, in the latest years, the occurrence of adverse events associated with 17D and 17DD substrain pointed to the necessity of developing technologies for the production of an inactivated vaccine. The implementation of this new vaccine will require methods for antigen quantification. Different methodologies of quantification can be used, being the most commonlyused the Enzyme-Linked Immunosorbent Assay (ELISA) and dose response test.The aim of this study was the establishment of an ELISA for the detection of inactivated yellow fever virus antigen. For this purpose, 17DD virus was obtained from Vero cell cultures, purified and quantified by biochemical and virological classical methods, respectively. The results showed that ELISA test using the 2D12 capture antibody presented a limit of 2,21 log10PFU/0.1mL of viral titer and (1,55 µg viral protein/0.1mL). Based on this value, a positive control was established which contained the attenuated 17DD substrain of yellow fever virus with a titer of 2,95log 10 PFU/mL and (29 µg/0.1mL). The results also showed that the ELISA was able to detect 17DD virus inactivated by formaldehyde up the dilution 1:16 (52,9 µg protein/0,1mL). The development of an ELISA test for the detection and quantification of 17DD antigen can represent an important step in the production control of the inactivated vaccine against of yellow fever.

Febre Amarela

Ensaio de Imunoadsorção Enzimática

Vírus da Febre Amarela

Vacina de vírus Inativado

Yellow Fever

Enzyme-Linked Immunosorbent Assay

Yellow fever virus

Virus vaccine inactivated

Febre Amarela

Ensaio de Imunoadsorção Enzimática

Vírus da Febre Amarela

Avaliação em modelos animais de uma vacina para malária utilizando como vetor de expressão o vírus de febre amarela vacinal 17D

Cajaraville, Ana Carolina dos Reis Albuquerque

January 2012

Submitted by Priscila Nascimento (pnascimento@icict.fiocruz.br) on 2013-03-19T16:07:54Z No. of bitstreams: 1 Ana_Carolina.pdf: 2560132 bytes, checksum: 663a398860ff953a4b1de21a209ee151 (MD5) / Made available in DSpace on 2013-03-19T16:07:54Z (GMT). No. of bitstreams: 1 Ana_Carolina.pdf: 2560132 bytes, checksum: 663a398860ff953a4b1de21a209ee151 (MD5) Previous issue date: 2012 / Fundação Oswaldo Cruz. Instituto Oswaldo Cruz. Rio de Janeiro, RJ, Brasil. / O desenvolvimento de uma vacina para malária é considerado atualmente uma prioridade em saúde pública pelo impacto socioeconômico e morbidade da doença com 250 milhões de novos casos por ano. A vacina de febre amarela é considerada uma das vacinas mais bem sucedidas por sua imunogenicidade duradora obtida após uma única dose. Frente a elucidação das respostas polivalentes dirigidas ao vírus vacinal 17D, a utilização do mesmo como vetor de expressão para antígenos heterólogos têm sido encorajada. Tendo em vista que febre amarela e malária compartilham grandes zonas endêmicas nos continentes americano e africano, a construção de uma vacina para malária baseada no vetor de febre amarela 17D se tornou uma abordagem interessante. Foram construídos dois vírus recombinantes contendo a proteína heteróloga MSP-119de P. falciparum (FA17D/MSP-119fal) e P. vivax (FA17D/MSP-119vivax) entre os genes E/NS1 de FA. Esta proteína é constituída de um fragmento de 19 kDa obtido após o processamento proteolítico da proteína de superfície do merozoíta 1 (MSP-1) durante a invasão do eritrócito e é descrita como alvo de anticorpos protetores em animais e pessoas imunes. Os vírus recombinantes foram caracterizados in vitro quanto à capacidade proliferativa em células Vero, estabilidade genética e expressão da proteína heteróloga por microscopia confocal de imunofluorescência e western blotting. A imunização de camundongos BALB/c e primatas não-humanos da espécie Saimiri sciureus foi usada para avaliar as construções quanto à imunogenicidade. Ambos os vírus foram capazes de induzir a produção de anticorpos neutralizantes contra a FA, porém em menores títulos do que os induzidos pelo vírus vacinal 17DD. A indução de anticorpos específicos para a proteína heteróloga após a imunização com os diferentes vírus recombinantes, também foi demonstrada e resultou em baixos títulos de IgG.em ambos os modelos. Os anticorpos induzidos no modelo com macacos Saimiri reconheceram a proteína nativa do parasita em hemácias infectadas por P. falciparum. No entanto, o desafio realizado neste modelo de primata não-esplenectomizado após a imunização com FA17D/MSP-119fal não gerou resultados conclusivos. Estes resultados sugerem a necessidade de aprimoramento da plataforma de expressão em busca de maior imunogenicidade. / The development of a vaccine for malaria is currently considered a priority in public health due to the socioeconomic impact and morbidity of the disease with 250 million new cases registered every year. The yellow fever vaccine is considered one of the most successful vaccines for its longlasting immunogenicity obtained after a single dose. As a result of the elucidation of the polyvalent responses directed to YF17D vaccine virus, the use of this virus as an expression vector of heterologous antigens has been encouraged. Considering that yellow fever and malaria share the major endemic areas in American and African continents, the construction of a vaccine for malaria based on the yellow fever 17D vector became an interesting approach. Two recombinant viruses containing the heterologous protein MSP-119 from P. falciparum (YF17D/MSP-119fal) and P. vivax (YF17D/MSP-119vivax) inserted between the E/NS1 genes have been constructed. This protein consists of a 19 kDa fragment obtained after proteolytic processing of the merozoite surface protein 1 (MSP-1) during invasion of erythrocytes and is described as a target for protective antibodies in animals and immune people. Recombinant viruses were characterized in vitro for their proliferative capacity in Vero cells and genetic stability and expression of heterologous protein were assessed by confocal immunofluorescence and Western blotting. Immunization of BALB/c mice and non-human primate species Saimiri sciureus allowed the evaluation of the constructions in terms of immunogenicity. Both viruses were capable of inducing neutralizing antibodies to YF, but in lower titers than those induced by the vaccine virus 17DD.The induction of specific antibodies for the heterologous protein by the different recombinant viruses was also demonstrated by low levels of IgG in both models. The antibodies induced in this monkey model bound to the native protein in parasite-infected red blood cells by immunofluorescence. The challenge carried out in after immunization of Saimiri monkeys with FA17D/MSP-119fal did not generate conclusive results. These data suggest the need to improve the platform of expression towards higher viral immunogenicity.

Flavivirus

Vírus FA 17D

Malária

Flavivirus

Virus FA 17D

Malaria

Yellow fever virus

Flavivirus

Malária

Vírus da Febre Amarela

Investigação epidemiológica de epizootia de febre amarela em primatas não-humanos em Goiás, no período de 2007 a 2010 / Epidemiological investigation of yellow fever in nonhuman primates in Aparecida de Goiânia, Goiás, from 2007 to 2010

DELFINO, Denizard André de Abreu

30 March 2011

Made available in DSpace on 2014-07-29T15:07:32Z (GMT). No. of bitstreams: 1 Dissertacao Denizard Andre de Abreu Delfino.pdf: 922702 bytes, checksum: f27146bc0b024ae0d79c5f4cfec679f6 (MD5) Previous issue date: 2011-03-30 / The objective of this study was to carry out and analyze the actions taken to control the yellow fever epizootic in non-human primates, recorded in November 2007 to March 2010 in Aparecida de Goiania, Goias Brazil. The primary epidemiological information on the disease was obtained from the Municipal Health Secretariat, by the local Center for Zoonosis Control. Data were analyzed from the outbreak reports. In A descriptive study, the control actions, such as blocking vaccine against yellow fever by the municipal health department and the evaluation of physical barriers to contain the virus, were verified. The inspection of 58 dead nonhuman primates, representing 100% of the animals found in the period previously mentioned, was used. From these, 34.48% (20/58) were able to have samples collected, according to the specifications of the Epizooty Handbook Of this amount (58), 27.59% (16/58) of monkeys were collected and3.45% (2/58) presented positivity for yellow fever virus. By evaluating the actions that contributed to the epidemiological assessment at the city, it is emphasized the occurrence of three deaths among genera and species of nonhuman primates, Alouatta caraya, Cebus apella and Callithrix spp, with the circulation of yellow fever virus in two cities with epidemiological distinct characteristics. The areas which showed the highest incidence of deaths of monkeys had also the greatest degree of urban growth, characterized by recent environmental changes and residual maintenance of natural areas. / O presente estudo constituiu na condução e análises de ações desenvolvidas no controle da epizootia de febre amarela em primatas não-humanos, registrada nos meses de novembro 2007 a março de 2010 em Aparecida de Goiânia, Goiás. As informações epidemiológicas primárias relativas à enfermidade foram obtidas junto à Secretaria Municipal de Saúde, pelo Centro de Controle de Zoonoses local. A partir das fichas de notificação para epizootia os dados foram analisados. Foi realizado estudo descritivo, que estudou as ações de controle, como bloqueio vacinal contra a FA pela secretaria municipal de saúde do município e a avaliação das barreiras físicas na contenção do vírus amarílico. Foi utilizada a inspeção de 58 primatas não-humanos mortos, que representaram 100% dos animais encontrados no período acima citado, sendo que destes 34,48% (20/58) estavam aptos para colheita de amostras, segundo as especificações do com o Manual de Epizootia. Deste montante, foram coletados 27,59% (16/58) de macacos, com uma positividade para o vírus amarílico de 3,45% (2/58). Avaliando as ações que contribuíram para realização da investigação epidemiológica no município, destaca-se que ocorreram mortes entre três gêneros e espécies de primatas não-humanos, Alouatta caraya, Cebus spp. e Callithrix spp., com a circulação do vírus da FA em duas localidades com características epidemiológicas distintas. As áreas de maior ocorrência de mortes de macacos foram aquelas com maior grau de antropização, caracterizadas por alterações ambientais recentes e manutenção residual de áreas naturais.

Diagnóstico

Epidemiologia

Macacos

Vírus amarílico

Diagnosis

Epidemiology

Monkey

Yellow fever virus

Etude du neurotropisme des Flavivirus neuropathogènes / Study of the neurotropism of neuropathogenic Flaviviruses

Khou, Cécile

30 October 2017

Les Flavivirus neuropathogènes, tels que le virus de l’encéphalite japonaise (JEV), le virus West Nile (WNV), le virus de la fièvre jaune (YFV) et le virus Zika (ZIKV) causent des maladies neurologiques. Ces maladies sont dues à une infection des cellules du système nerveux central (CNS) par ces virus. Le CNS est un organe privilégié, isolé des agents pathogènes par une barrière entre le sang et le cerveau, appelée barrière hémato-encéphalique (BBB). Les Flavivirus neuropathogènes capables de traverser cette BBB afin d’atteindre leurs cellules cibles, localisées dans le CNS, sont neuroinvasifs. Le but de cette étude est de comprendre les mécanismes cellulaires permettant aux Flavivirus de traverser la BBB et les effets de l’infection par les virus ZIKV et WNV des cellules du CNS sur le développement de celles-ci.Le YFV est un virus hépatotrope, infectant majoritairement le foie et les reins. Deux vaccins vivants atténués dirigés contre le YFV, le vaccin FNV (pour French Neurotropic Virus) et le vaccin 17D, ont été obtenus empiriquement par passages successifs de souches virulentes de YFV sur cerveaux de souriceaux. Ces vaccins ne causent plus de maladies touchant les reins et le foie, mais peuvent parfois causer des encéphalites post-vaccinales. Ces cas d’encéphalites démontrent que ces souches vaccinales sont devenues neurovirulentes mais aussi neuroinvasives car les virus ont pu franchir la BBB. A cause d’une incidence trop élevée d’encéphalites post-vaccinales par rapport au vaccin 17D, le vaccin FNV a été retiré du marché dans les années 1980.Le JEV est un virus neurotrope, causant des encéphalites graves en Asie du Sud-Est. A ce jour, il existe un vaccin vivant atténué, le JEV SA14-14-2, obtenu empiriquement par passages successifs d’une souche virulente sur cellules de hamster. Ce vaccin est moins neurovirulent et moins neuroinvasif que les souches virulentes de JEV en modèle de souris, et protège contre des infections humaines par le JEV. Cependant, des cas d’encéphalites ont été rapportés après injection de ce vaccin. Il apparait donc que, dans certains cas, la souche vaccinale JEV SA14-14-2 est capable de traverser la BBB et d’infecter les cellules neuronales. Les dernières épidémies à virus ZIKV en Polynésie Française et en Amérique du Sud ont induit une augmentation de cas de malformations congénitales dans les zones touchées. Cela a soulevé de nouvelles questions quant à la capacité d’un Flavivirus à provoquer des malformations congénitales du CNS. Dans cette étude, nous avons identifié les mécanismes cellulaires permettant aux Flavivirus de traverser la BBB et les effets de l’infection par les virus ZIKV et WNV des cellules du CNS sur le développement de celles-ci.Nous avons utilisé deux systèmes in vitro permettant d’étudier le développement du CNS et la neuroinvasion des Flavivirus. Un premier système consiste en l’infection de coupes de cerveaux d’embryon de souris. En utilisant ce système, nous avons montré que le ZIKV a un tropisme préférentiel pour les cellules progénitrices de neurones, alors que le WNV a un tropisme préférentiel pour les neurones. Nous avons également montré que l’infection des progéniteurs neuronaux par le ZIKV induit un arrêt de la mitose cellulaire, alors que l’infection par le WNV n’a aucun effet sur la mitose. L’étude sur l’effet apoptotique de l’infection par les deux virus WNV et ZIKV n’a montré aucune différence entre les deux virus à des temps précoces d’infection.Un deuxième système a été mis au point pour l’étude de la neuroinvasion par les Flavivirus neuropathogènes. Ce système est composé de cellules endothéliales hCMEC/D3 pouvant former des jonctions serrées. Ces cellules ont été cultivées sur filtres d’insert de puits de culture cellulaire Transwell, placés au-dessus de cellules neuronales humaines. A l’aide de ce système, nous avons comparé la capacité à traverser la BBB de plusieurs Flavivirus. / Neuropathogenic Flaviviruses, such as Japanese encephalitis virus (JEV), West Nile virus (WNV), yellow fever virus (YFV) and Zika virus (ZIKV), cause neurological diseases. These diseases are due to viral infection of central nervous system (CNS) cells. The CNS is a privileged organ, isolated from pathogenic agents by a barrier between the blood and the barrier, called the blood-brain barrier (BBB). Neuropathogenic Flaviviruses which can cross this BBB in order to reach their target cells in the CNS, are neuroinvasive. This study aims at understanding the cellular mechanisms by which YFV and JEV Flaviviruses cross the BBB and the effects of viral infection by WNV and ZIKV of the CNS cells during neocortex development.YFV is a hepatrotopic virus, which mostly infects the liver and the kidneys. The two live-attenuated vaccines against YFV, the FNV (for French Neurotropic Virus) vaccine and the 17D vaccine, were obtained empirically by several passages in suckling mouse brain of YFV virulent strains. These vaccines do not cause any disease targeting the liver or the kidneys, but can sometimes cause post-vaccine encephalitis. These encephalitis cases suggest that the vaccine strains have become neurovirulent and neuroinvasive. Due to high risks of post-vaccine encephalitis, the FNV vaccine use was discontinued in the 1980s.JEV is a neurotropic virus, causing acute encephalitis in South East Asia. To date, there is a live-attenuated vaccine against JEV, the JEV SA14-14-2 vaccine, which was obtained empirically by several passages in primary hamster kidney cells. This vaccine is less neurovirulent and less neuroinvasive than JEV virulent strains in mouse model, and it protects against JEV infections. However, some cases of post-vaccine encephalitis were reported. It thus seems that, in some cases, the vaccine strain JEV SA14-14-2 is able to cross the BBB and infect neuronal cells.The recent ZIKV epidemics in French Polynesia and South America were linked to an increase in the number of congenital malformations, rising questions regarding the capacity of a Flavivirus to induce CNS congenital malformations.In this study, we have identified cellular mechanisms involved in Flavivirus neuroinvasion and studied the effect of ZIKV and WNV infection of neuronal cells under development.To study CNS development, we have infected mouse embryos brain slices. We were able to show that ZIKV has a preferential tropism for neuronal progenitors, whereas WNV has a preferential tropism for neuronal cells. We also show that infection of neuronal progenitors by ZIKV impairs the cell life cycle, whereas no effect on the cell life cycle was observed for WNV-infected cells. Studies on apoptosis induction did not show any difference between both viruses at early time points of infection.To study Flavivirus neuroinvasion, we have used an in vitro model of BBB composed of human endothelial hCMEC/D3 cells that can form tight junctions. These cells were cultivated on Transwell inserts and placed above human neuronal cells. Using this system, we show that YFV FNV cross the BBB more efficiently than YFV 17D, suggesting that YFV FNV is more neuroinvasive than YFV 17D. This observation can explain the higher post-vaccine encephalitis risks associated with YFV FNV vaccine compared to YFV 17D vaccine. We also confirmed that JEV SA14-14-2 vaccine strain is less neuroinvasive than JEV RP9.We also examined how JEV crosses the BBB and the endothelial cell response following JEV treatment. We show that both JEV RP9 and SA14-14-2 are able to cross the BBB without infecting its endothelial cells and without disrupting the BBB. Preliminary results suggest that JEV RP9, but not JEV SA14-14-2, crosses the BBB by dynamin-dependant transcytosis. Transcriptomic analysis of endothelial cells treated by either virus show slight, but significant, differences in regulation of genes implicated in several pathways associated with CNS diseases.

Maladies du système nerveux

Barrière hémato-encéphalique

Virus du Nil occidental

Virus de la fièvre jaune

Virus Zika

Nervous system diseases

Blood-brain barrier

Encephalitis virus, japanese

West nile virus

Yellow fever virus

Zika Virus