Influenza A virus environmental stability : influence of viral proteins
Identifieur interne : 000160 ( Hal/Curation ); précédent : 000159; suivant : 000161Influenza A virus environmental stability : influence of viral proteins
Auteurs : Thomas Labadie [France]Source :
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Abstract
The transmission of Influenza A viruses (IAV), either airborne in mammals or oro-faecal in aquatic birds, submits viral particle to a wide range of environmental conditions. These environmental conditions modulate IAV survival outside the host, which is also dependent on the viral subtype or strains. To date, the molecular drivers of IAV environmental persistence remain to be identified. In order to identify IAV molecular drivers of the environmental persistence, we generated different reassortant viruses between two H1N1 viruses that do not have the same stability outside the host. To this purpose, we performed survival kinetic and compared the inactivation slope of generated reassortant viruses in our controlledenvironment, using a real time cell analysis system. Our results demonstrate that the hemagglutinin (HA) and the neuraminidase (NA) are the main viral segments driving IAV environmental persistence. In addition, mutations driving viral stability in the environment were identified in the HA and NA amino-acid sequences. We also demonstrated that synonymous mutations introduced in the HA, using a codon-optimization strategy, drive the environmental persistence of IAV. The HA stability at low pH, HA surface expression levels in infected cells and the number of calcium binding sites of the NA were alternately changed by the mutations described in our study, indicating that these are stability determinants of IAV survival outside the host. Then, the sequential events of viral entry were analysed with fluorescence microscopy assays, showing that viral particles being exposed for a long period in saline water at 35°C are still able to bind their cellular receptor whereas the HA-mediated fusion within the endosome is not possible anymore. These two steps of the viral cycle are mainly mediated by the HA protein. Altogether, these result highlight the importance of the HA and the NA proteins, driving the environmental persistence of IAV. Given the known diversity of these two proteins in nature, this arouses interest in studying IAV environmental persistence at a more global scale. Such study could improve our knowledge on IAV ecology and epidemiology. Epidemiologic and climatic data analyse of human seasonal influenza viruses during 5 years and from 13 countries revealed that H1N1 virus and H3N2 virus distribution differs according to the mean weekly temperature in these countries. We then compared the H1N1 virus and H3N2 virus persistence on stainless steel surface at 4 °C and 20 °C, and the preliminary results suggest that IAV seasonal subtypes distribution might be partly regulated by their stability according to the temperature
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These environmental conditions modulate IAV survival outside the host, which is also dependent on the viral subtype or strains. To date, the molecular drivers of IAV environmental persistence remain to be identified. In order to identify IAV molecular drivers of the environmental persistence, we generated different reassortant viruses between two H1N1 viruses that do not have the same stability outside the host. To this purpose, we performed survival kinetic and compared the inactivation slope of generated reassortant viruses in our controlledenvironment, using a real time cell analysis system. Our results demonstrate that the hemagglutinin (HA) and the neuraminidase (NA) are the main viral segments driving IAV environmental persistence. In addition, mutations driving viral stability in the environment were identified in the HA and NA amino-acid sequences. We also demonstrated that synonymous mutations introduced in the HA, using a codon-optimization strategy, drive the environmental persistence of IAV. The HA stability at low pH, HA surface expression levels in infected cells and the number of calcium binding sites of the NA were alternately changed by the mutations described in our study, indicating that these are stability determinants of IAV survival outside the host. Then, the sequential events of viral entry were analysed with fluorescence microscopy assays, showing that viral particles being exposed for a long period in saline water at 35°C are still able to bind their cellular receptor whereas the HA-mediated fusion within the endosome is not possible anymore. These two steps of the viral cycle are mainly mediated by the HA protein. Altogether, these result highlight the importance of the HA and the NA proteins, driving the environmental persistence of IAV. Given the known diversity of these two proteins in nature, this arouses interest in studying IAV environmental persistence at a more global scale. Such study could improve our knowledge on IAV ecology and epidemiology. Epidemiologic and climatic data analyse of human seasonal influenza viruses during 5 years and from 13 countries revealed that H1N1 virus and H3N2 virus distribution differs according to the mean weekly temperature in these countries. We then compared the H1N1 virus and H3N2 virus persistence on stainless steel surface at 4 °C and 20 °C, and the preliminary results suggest that IAV seasonal subtypes distribution might be partly regulated by their stability according to the temperature</p> </div></front></TEI><hal api="V3"> <titleStmt> <title xml:lang="en">Influenza A virus environmental stability : influence of viral proteins</title> <title xml:lang="fr">Stabilité du virus de la grippe dans l'environnement : influence des protéines virales</title> <author role="aut"> <persName> <forename type="first">Thomas</forename> <surname>Labadie</surname> </persName> <idno type="halauthorid">11525225</idno> <affiliation ref="#struct-237998"></affiliation> </author> <editor role="depositor"> <persName> <forename>ABES</forename> <surname>STAR</surname> </persName> <email type="md5">f5aa7f563b02bb6adbba7496989af39a</email> <email type="domain">abes.fr</email> </editor> </titleStmt> <editionStmt> <edition n="v1"> <date type="whenSubmitted">2019-07-04 14:05:30</date> </edition> <edition n="v2" type="current"> <date type="whenSubmitted">2019-07-04 16:23:56</date> <date type="whenModified">2020-01-15 15:36:02</date> <date type="whenReleased">2019-07-04 16:23:59</date> <date type="whenProduced">2017-12-20</date> <date type="whenEndEmbargoed">2019-07-04</date> <ref type="file" target="https://tel.archives-ouvertes.fr/tel-02173339v2/document"> <date notBefore="2019-07-04"></date> </ref> <ref type="file" subtype="author" n="1" target="https://tel.archives-ouvertes.fr/tel-02173339/file/LABADIE_Thomas_2_va_20171220.pdf"> <date notBefore="2019-07-04"></date> </ref> </edition> <respStmt> <resp>contributor</resp> <name key="131274"> <persName> <forename>ABES</forename> <surname>STAR</surname> </persName> <email type="md5">f5aa7f563b02bb6adbba7496989af39a</email> <email type="domain">abes.fr</email> </name> </respStmt> </editionStmt> <publicationStmt> <distributor>CCSD</distributor> <idno type="halId">tel-02173339</idno> <idno type="halUri">https://tel.archives-ouvertes.fr/tel-02173339</idno> <idno type="halBibtex">labadie:tel-02173339</idno> <idno type="halRefHtml">Médecine humaine et pathologie. Université Sorbonne Paris Cité, 2017. Français. ⟨NNT : 2017USPCC274⟩</idno> <idno type="halRef">Médecine humaine et pathologie. Université Sorbonne Paris Cité, 2017. Français. ⟨NNT : 2017USPCC274⟩</idno> </publicationStmt> <seriesStmt> <idno type="stamp" n="STAR">STAR - Dépôt national des thèses électroniques</idno> <idno type="stamp" n="PASTEUR">Institut Pasteur</idno> </seriesStmt> <notesStmt></notesStmt> <sourceDesc> <biblStruct> <analytic> <title xml:lang="en">Influenza A virus environmental stability : influence of viral proteins</title> <title xml:lang="fr">Stabilité du virus de la grippe dans l'environnement : influence des protéines virales</title> <author role="aut"> <persName> <forename type="first">Thomas</forename> <surname>Labadie</surname> </persName> <idno type="halauthorid">11525225</idno> <affiliation ref="#struct-237998"></affiliation> </author> </analytic> <monogr> <idno type="nnt">2017USPCC274</idno> <imprint> <date type="dateDefended">2017-12-20</date> </imprint> <authority type="institution">Université Sorbonne Paris Cité</authority> <authority type="school">École doctorale Bio Sorbonne Paris Cité (Paris)</authority> <authority type="supervisor">India Leclercq</authority> <authority type="jury">Sylvie Van der Werf [Président]</authority> <authority type="jury">Daniel Marc [Rapporteur]</authority> <authority type="jury">Mariette Ducatez [Rapporteur]</authority> <authority type="jury">Jean-Claude Manuguerra</authority> <authority type="jury">Stéphan Zientara</authority> </monogr> </biblStruct> </sourceDesc> <profileDesc> <langUsage> <language ident="fr">French</language> </langUsage> <textClass> <keywords scheme="author"> <term xml:lang="en">Reverse genetic</term> <term xml:lang="en">Reassortment</term> <term xml:lang="en">Neuraminidase</term> <term xml:lang="en">Hemagglutinin</term> <term xml:lang="en">Molecular biology</term> <term xml:lang="en">Persistence</term> <term xml:lang="en">Stability</term> <term xml:lang="en">Virus</term> <term xml:lang="en">Influenza</term> <term xml:lang="fr">Grippe</term> <term xml:lang="fr">Stabilité</term> <term xml:lang="fr">Persistence</term> <term xml:lang="fr">Réassortiment</term> </keywords> <classCode scheme="halDomain" n="sdv.mhep">Life Sciences [q-bio]/Human health and pathology</classCode> <classCode scheme="halDomain" n="sdv.mp.vir">Life Sciences [q-bio]/Microbiology and Parasitology/Virology</classCode> <classCode scheme="halDomain" n="sdv.mhep.mi">Life Sciences [q-bio]/Human health and pathology/Infectious diseases</classCode> <classCode scheme="halTypology" n="THESE">Theses</classCode> </textClass> <abstract xml:lang="en"> <p>The transmission of Influenza A viruses (IAV), either airborne in mammals or oro-faecal in aquatic birds, submits viral particle to a wide range of environmental conditions. These environmental conditions modulate IAV survival outside the host, which is also dependent on the viral subtype or strains. To date, the molecular drivers of IAV environmental persistence remain to be identified. In order to identify IAV molecular drivers of the environmental persistence, we generated different reassortant viruses between two H1N1 viruses that do not have the same stability outside the host. To this purpose, we performed survival kinetic and compared the inactivation slope of generated reassortant viruses in our controlledenvironment, using a real time cell analysis system. Our results demonstrate that the hemagglutinin (HA) and the neuraminidase (NA) are the main viral segments driving IAV environmental persistence. In addition, mutations driving viral stability in the environment were identified in the HA and NA amino-acid sequences. We also demonstrated that synonymous mutations introduced in the HA, using a codon-optimization strategy, drive the environmental persistence of IAV. The HA stability at low pH, HA surface expression levels in infected cells and the number of calcium binding sites of the NA were alternately changed by the mutations described in our study, indicating that these are stability determinants of IAV survival outside the host. Then, the sequential events of viral entry were analysed with fluorescence microscopy assays, showing that viral particles being exposed for a long period in saline water at 35°C are still able to bind their cellular receptor whereas the HA-mediated fusion within the endosome is not possible anymore. These two steps of the viral cycle are mainly mediated by the HA protein. Altogether, these result highlight the importance of the HA and the NA proteins, driving the environmental persistence of IAV. Given the known diversity of these two proteins in nature, this arouses interest in studying IAV environmental persistence at a more global scale. Such study could improve our knowledge on IAV ecology and epidemiology. Epidemiologic and climatic data analyse of human seasonal influenza viruses during 5 years and from 13 countries revealed that H1N1 virus and H3N2 virus distribution differs according to the mean weekly temperature in these countries. We then compared the H1N1 virus and H3N2 virus persistence on stainless steel surface at 4 °C and 20 °C, and the preliminary results suggest that IAV seasonal subtypes distribution might be partly regulated by their stability according to the temperature</p> </abstract> <abstract xml:lang="fr"> <p>La transmission des virus grippaux de type A s’effectue via l’eau, l’air ou les surfaces. Elle implique donc toujours une étape dans l’environnement, durant laquelle les virus sont inactivés plus ou moins rapidement en fonction du sous-type ou de la souche virale analysés. Cependant, à ce jour, les facteurs moléculaires déterminant la stabilité des particules virales en dehors de l’hôte restent largement méconnus. Dans le but d’identifier ces déterminants, nous avons généré différentes combinaisons de réassortiments entre deux virus grippaux de sous-types H1N1 possédant un phénotype de stabilité différent. Les stabilités respectives de ces virus réassortants ont été évaluées dans un environnement-modèle, puis comparées entre elles. Pour cela, nous avons utilisé un système d’analyse en temps réel des cultures cellulaires, permettant de calculer, pour chacun des virus testés, une pente d’inactivation moyenne et, in fine, de mesurer l’influence respective de chacun des segments viraux sur le phénotype de stabilité des virus. D’après nos résultats, le phénotype de stabilité des virus grippaux est majoritairement déterminé par l’hémagglutinine (HA) et la neuraminidase (NA), qui sont les principales glycoprotéines de surface de ces virus. De plus, nous avons identifié des changements d’acides aminés dans la HA et dans la NA, qui ont pour effet une diminution ou une augmentation de la stabilité des particules virales dans l’environnement. Nous avons également montré qu’un virus avec un gène de la HA codons-optimisés, et donc porteur de mutations synonymes, suffit pour augmenter significativement la stabilité des particules virales dans l’environnement. La stabilité de la HA à pH acide, le taux d’expression de la HA dans les cellules infectées, et le nombre de sites de fixation aux ions calcium dans la NA sont modifiés par les mutations décrites dans cette étude, et sont donc des facteurs de stabilité des particules virales. De plus, une analyse en microscopie a permis de montrer que les virus inactivés dans l’environnement peuvent fixer leurs récepteurs cellulaires, mais sont incompétents pour induire l’étape de fusion dans l’endosome nécessaire à l’entrée des virus dans la cellule. Ces deux étapes du cycle viral sont dépendantes de la HA. Dans l’ensemble, nos résultats montrent l’importance de la HA et de la NA des virus grippaux dans la détermination du phénotype de stabilité des virus grippaux dans l’environnement. Par conséquent, la diversité connue des HA et NA dans la nature laisse supposer des variations fréquentes du phénotype de stabilité de ces virus. Leur étude pourrait permettre de mieux décrire l’écologie et l’épidémiologie de ces virus. L’analyse des données épidémiologiques et climatiques des épidémies de grippe saisonnière, sur 5 ans et dans 13 pays, a ainsi révélé une différence de distribution des virus H1N1 et H3N2, en fonction de la température hebdomadaire dans ces pays. La comparaison de la stabilité de ces virus sur des surfaces, à 4 °C et à 20 °C, suggère que la distribution des sous-types viraux au début des épidémies est en partie régulée par leur stabilité en fonction de la température</p> </abstract> </profileDesc> </hal></record>Pour manipuler ce document sous Unix (Dilib)
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