Your search keyword '"Takada, Ayato"' showing total 23 results

1. Renaming of genera Ebolavirus and Marburgvirus to Orthoebolavirus and Orthomarburgvirus, respectively, and introduction of binomial species names within family Filoviridae.

Author

Biedenkopf N, Bukreyev A, Chandran K, Di Paola N, Formenty PBH, Griffiths A, Hume AJ, Mühlberger E, Netesov SV, Palacios G, Pawęska JT, Smither S, Takada A, Wahl V, and Kuhn JH

Subjects

Marburgvirus, Ebolavirus, Filoviridae, Viruses

Abstract

The International Committee on Taxonomy of Viruses (ICTV) Filoviridae Study Group continues to prospectively refine the established nomenclature for taxa included in family Filoviridae in an effort to decrease confusion of genus, species, and virus names and to adhere to amended stipulations of the International Code of Virus Classification and Nomenclature (ICVCN). Recently, the genus names Ebolavirus and Marburgvirus were changed to Orthoebolavirus and Orthomarburgvirus, respectively. Additionally, all established species names in family Filoviridae now adhere to the ICTV-mandated binomial format. Virus names remain unchanged and valid. Here, we outline the revised taxonomy of family Filoviridae as approved by the ICTV in April 2023., (© 2023. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2023

2. 2022 taxonomic update of phylum Negarnaviricota (Riboviria: Orthornavirae), including the large orders Bunyavirales and Mononegavirales.

Author

Kuhn JH, Adkins S, Alkhovsky SV, Avšič-Županc T, Ayllón MA, Bahl J, Balkema-Buschmann A, Ballinger MJ, Bandte M, Beer M, Bejerman N, Bergeron É, Biedenkopf N, Bigarré L, Blair CD, Blasdell KR, Bradfute SB, Briese T, Brown PA, Bruggmann R, Buchholz UJ, Buchmeier MJ, Bukreyev A, Burt F, Büttner C, Calisher CH, Candresse T, Carson J, Casas I, Chandran K, Charrel RN, Chiaki Y, Crane A, Crane M, Dacheux L, Bó ED, de la Torre JC, de Lamballerie X, de Souza WM, de Swart RL, Dheilly NM, Di Paola N, Di Serio F, Dietzgen RG, Digiaro M, Drexler JF, Duprex WP, Dürrwald R, Easton AJ, Elbeaino T, Ergünay K, Feng G, Feuvrier C, Firth AE, Fooks AR, Formenty PBH, Freitas-Astúa J, Gago-Zachert S, García ML, García-Sastre A, Garrison AR, Godwin SE, Gonzalez JJ, de Bellocq JG, Griffiths A, Groschup MH, Günther S, Hammond J, Hepojoki J, Hierweger MM, Hongō S, Horie M, Horikawa H, Hughes HR, Hume AJ, Hyndman TH, Jiāng D, Jonson GB, Junglen S, Kadono F, Karlin DG, Klempa B, Klingström J, Koch MC, Kondō H, Koonin EV, Krásová J, Krupovic M, Kubota K, Kuzmin IV, Laenen L, Lambert AJ, Lǐ J, Li JM, Lieffrig F, Lukashevich IS, Luo D, Maes P, Marklewitz M, Marshall SH, Marzano SL, McCauley JW, Mirazimi A, Mohr PG, Moody NJG, Morita Y, Morrison RN, Mühlberger E, Naidu R, Natsuaki T, Navarro JA, Neriya Y, Netesov SV, Neumann G, Nowotny N, Ochoa-Corona FM, Palacios G, Pallandre L, Pallás V, Papa A, Paraskevopoulou S, Parrish CR, Pauvolid-Corrêa A, Pawęska JT, Pérez DR, Pfaff F, Plemper RK, Postler TS, Pozet F, Radoshitzky SR, Ramos-González PL, Rehanek M, Resende RO, Reyes CA, Romanowski V, Rubbenstroth D, Rubino L, Rumbou A, Runstadler JA, Rupp M, Sabanadzovic S, Sasaya T, Schmidt-Posthaus H, Schwemmle M, Seuberlich T, Sharpe SR, Shi M, Sironi M, Smither S, Song JW, Spann KM, Spengler JR, Stenglein MD, Takada A, Tesh RB, Těšíková J, Thornburg NJ, Tischler ND, Tomitaka Y, Tomonaga K, Tordo N, Tsunekawa K, Turina M, Tzanetakis IE, Vaira AM, van den Hoogen B, Vanmechelen B, Vasilakis N, Verbeek M, von Bargen S, Wada J, Wahl V, Walker PJ, Whitfield AE, Williams JV, Wolf YI, Yamasaki J, Yanagisawa H, Ye G, Zhang YZ, and Økland AL

Subjects

Humans, Phylogeny, Mononegavirales genetics, Viruses

Abstract

In March 2022, following the annual International Committee on Taxonomy of Viruses (ICTV) ratification vote on newly proposed taxa, the phylum Negarnaviricota was amended and emended. The phylum was expanded by two new families (bunyaviral Discoviridae and Tulasviridae), 41 new genera, and 98 new species. Three hundred forty-nine species were renamed and/or moved. The accidentally misspelled names of seven species were corrected. This article presents the updated taxonomy of Negarnaviricota as now accepted by the ICTV., (© 2022. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2022

3. 2021 Taxonomic update of phylum Negarnaviricota (Riboviria: Orthornavirae), including the large orders Bunyavirales and Mononegavirales.

Author

Kuhn JH, Adkins S, Agwanda BR, Al Kubrusli R, Alkhovsky SV, Amarasinghe GK, Avšič-Županc T, Ayllón MA, Bahl J, Balkema-Buschmann A, Ballinger MJ, Basler CF, Bavari S, Beer M, Bejerman N, Bennett AJ, Bente DA, Bergeron É, Bird BH, Blair CD, Blasdell KR, Blystad DR, Bojko J, Borth WB, Bradfute S, Breyta R, Briese T, Brown PA, Brown JK, Buchholz UJ, Buchmeier MJ, Bukreyev A, Burt F, Büttner C, Calisher CH, Cao M, Casas I, Chandran K, Charrel RN, Cheng Q, Chiaki Y, Chiapello M, Choi IR, Ciuffo M, Clegg JCS, Crozier I, Dal Bó E, de la Torre JC, de Lamballerie X, de Swart RL, Debat H, Dheilly NM, Di Cicco E, Di Paola N, Di Serio F, Dietzgen RG, Digiaro M, Dolnik O, Drebot MA, Drexler JF, Dundon WG, Duprex WP, Dürrwald R, Dye JM, Easton AJ, Ebihara H, Elbeaino T, Ergünay K, Ferguson HW, Fooks AR, Forgia M, Formenty PBH, Fránová J, Freitas-Astúa J, Fu J, Fürl S, Gago-Zachert S, Gāo GF, García ML, García-Sastre A, Garrison AR, Gaskin T, Gonzalez JJ, Griffiths A, Goldberg TL, Groschup MH, Günther S, Hall RA, Hammond J, Han T, Hepojoki J, Hewson R, Hong J, Hong N, Hongo S, Horie M, Hu JS, Hu T, Hughes HR, Hüttner F, Hyndman TH, Ilyas M, Jalkanen R, Jiāng D, Jonson GB, Junglen S, Kadono F, Kaukinen KH, Kawate M, Klempa B, Klingström J, Kobinger G, Koloniuk I, Kondō H, Koonin EV, Krupovic M, Kubota K, Kurath G, Laenen L, Lambert AJ, Langevin SL, Lee B, Lefkowitz EJ, Leroy EM, Li S, Li L, Lǐ J, Liu H, Lukashevich IS, Maes P, de Souza WM, Marklewitz M, Marshall SH, Marzano SL, Massart S, McCauley JW, Melzer M, Mielke-Ehret N, Miller KM, Ming TJ, Mirazimi A, Mordecai GJ, Mühlbach HP, Mühlberger E, Naidu R, Natsuaki T, Navarro JA, Netesov SV, Neumann G, Nowotny N, Nunes MRT, Olmedo-Velarde A, Palacios G, Pallás V, Pályi B, Papa A, Paraskevopoulou S, Park AC, Parrish CR, Patterson DA, Pauvolid-Corrêa A, Pawęska JT, Payne S, Peracchio C, Pérez DR, Postler TS, Qi L, Radoshitzky SR, Resende RO, Reyes CA, Rima BK, Luna GR, Romanowski V, Rota P, Rubbenstroth D, Rubino L, Runstadler JA, Sabanadzovic S, Sall AA, Salvato MS, Sang R, Sasaya T, Schulze AD, Schwemmle M, Shi M, Shí X, Shí Z, Shimomoto Y, Shirako Y, Siddell SG, Simmonds P, Sironi M, Smagghe G, Smither S, Song JW, Spann K, Spengler JR, Stenglein MD, Stone DM, Sugano J, Suttle CA, Tabata A, Takada A, Takeuchi S, Tchouassi DP, Teffer A, Tesh RB, Thornburg NJ, Tomitaka Y, Tomonaga K, Tordo N, Torto B, Towner JS, Tsuda S, Tu C, Turina M, Tzanetakis IE, Uchida J, Usugi T, Vaira AM, Vallino M, van den Hoogen B, Varsani A, Vasilakis N, Verbeek M, von Bargen S, Wada J, Wahl V, Walker PJ, Wang LF, Wang G, Wang Y, Wang Y, Waqas M, Wèi T, Wen S, Whitfield AE, Williams JV, Wolf YI, Wu J, Xu L, Yanagisawa H, Yang C, Yang Z, Zerbini FM, Zhai L, Zhang YZ, Zhang S, Zhang J, Zhang Z, and Zhou X

Subjects

Humans, Mononegavirales, Viruses

Abstract

In March 2021, following the annual International Committee on Taxonomy of Viruses (ICTV) ratification vote on newly proposed taxa, the phylum Negarnaviricota was amended and emended. The phylum was expanded by four families (Aliusviridae, Crepuscuviridae, Myriaviridae, and Natareviridae), three subfamilies (Alpharhabdovirinae, Betarhabdovirinae, and Gammarhabdovirinae), 42 genera, and 200 species. Thirty-nine species were renamed and/or moved and seven species were abolished. This article presents the updated taxonomy of Negarnaviricota as now accepted by the ICTV., (© 2021. This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.)

Published

2021

4. Possibility and Challenges of Conversion of Current Virus Species Names to Linnaean Binomials.

Author

Postler TS, Clawson AN, Amarasinghe GK, Basler CF, Bavari S, Benko M, Blasdell KR, Briese T, Buchmeier MJ, Bukreyev A, Calisher CH, Chandran K, Charrel R, Clegg CS, Collins PL, Juan Carlos T, Derisi JL, Dietzgen RG, Dolnik O, Dürrwald R, Dye JM, Easton AJ, Emonet S, Formenty P, Fouchier RAM, Ghedin E, Gonzalez JP, Harrach B, Hewson R, Horie M, Jiang D, Kobinger G, Kondo H, Kropinski AM, Krupovic M, Kurath G, Lamb RA, Leroy EM, Lukashevich IS, Maisner A, Mushegian AR, Netesov SV, Nowotny N, Patterson JL, Payne SL, PaWeska JT, Peters CJ, Radoshitzky SR, Rima BK, Romanowski V, Rubbenstroth D, Sabanadzovic S, Sanfaçon H, Salvato MS, Schwemmle M, Smither SJ, Stenglein MD, Stone DM, Takada A, Tesh RB, Tomonaga K, Tordo N, Towner JS, Vasilakis N, Volchkov VE, Wahl-Jensen V, Walker PJ, Wang LF, Varsani A, Whitfield AE, Zerbini FM, and Kuhn JH

Subjects

Terminology as Topic, Classification, Viruses

Abstract

Botanical, mycological, zoological, and prokaryotic species names follow the Linnaean format, consisting of an italicized Latinized binomen with a capitalized genus name and a lower case species epithet (e.g., Homo sapiens). Virus species names, however, do not follow a uniform format, and, even when binomial, are not Linnaean in style. In this thought exercise, we attempted to convert all currently official names of species included in the virus family Arenaviridae and the virus order Mononegavirales to Linnaean binomials, and to identify and address associated challenges and concerns. Surprisingly, this endeavor was not as complicated or time-consuming as even the authors of this article expected when conceiving the experiment. [Arenaviridae; binomials; ICTV; International Committee on Taxonomy of Viruses; Mononegavirales; virus nomenclature; virus taxonomy.]., (Published by Oxford University Press on behalf of Society of Systematic Biologists 2016. This work is written by a US Government employee and is in the public domain in the US.)

Published

2017

5. Molecular Mechanisms Underlying Oseltamivir Resistance Mediated by an I117V Substitution in the Neuraminidase of Subtype H5N1 Avian Influenza A Viruses

Author

Takano, Ryo, Kiso, Maki, Igarashi, Manabu, Le, Quynh Mai, Sekijima, Masakazu, Ito, Kimihito, Takada, Ayato, and Kawaoka, Yoshihiro

Published

2013

6. Heterosubtypic antibody recognition of the influenza virus hemagglutinin receptor binding site enhanced by avidity

Author

Lee, Peter S., Yoshida, Reiko, Ekiert, Damian C., Sakai, Naoki, Suzuki, Yasuhiko, Takada, Ayato, and Wilson, Ian A.

Published

2012

7. Antibody-Dependent Enhancement of Marburg Virus Infection

Author

Nakayama, Eri, Tomabechi, Daisuke, Matsuno, Keita, Kishida, Noriko, Yoshida, Reiko, Feldmann, Heinz, and Takada, Ayato

Published

2011

8. Single Immunization With a Monovalent Vesicular Stomatitis Virus-Based Vaccine Protects Nonhuman Primates Against Heterologous Challenge With Bundtbugyo ebolavirus

Author

Falzarano, Darryl, Feldmann, Friederike, Grolla, Allen, Leung, Anders, Ebihara, Hideki, Strong, James E., Marzi, Andrea, Takada, Ayato, Jones, Shane, Gren, Jason, Geisbert, Joan, Jones, Steven M., Geisbert, Thomas W., and Feldmann, Heinz

Published

2011

9. Epitopes Required for Antibody-Dependent Enhancement of Ebola Virus Infection

Author

Takada, Ayato, Ebihara, Hideki, Feldmann, Heinz, Geisbert, Thomas W., and Kawaoka, Yoshihiro

Published

2007

10. 2021 Taxonomic update of phylum Negarnaviricota (Riboviria: Orthornavirae), including the large orders Bunyavirales and Mononegavirales

Author

Kuhn, Jens H, Adkins, Scott, Agwanda, Bernard R, Al Kubrusli, Rim, Alkhovsky, Sergey V, Amarasinghe, Gaya K, Avšič-Županc, Tatjana, Ayllón, María A, Bahl, Justin, Balkema-Buschmann, Anne, Ballinger, Matthew J, Basler, Christopher F, Bavari, Sina, Beer, Martin, Bejerman, Nicolas, Bennett, Andrew J, Bente, Dennis A, Bergeron, Éric, Bird, Brian H, Blair, Carol D, Blasdell, Kim R, Blystad, Dag-Ragnar, Bojko, Jamie, Borth, Wayne B, Bradfute, Steven, Breyta, Rachel, Briese, Thomas, Brown, Paul A, Brown, Judith K, Buchholz, Ursula J, Buchmeier, Michael J, Bukreyev, Alexander, Burt, Felicity, Büttner, Carmen, Calisher, Charles H, Cao, Mengji, Casas, Inmaculada, Chandran, Kartik, Charrel, Rémi N, Cheng, Qi, Chiaki, Yuya, Chiapello, Marco, Choi, Il-Ryong, Ciuffo, Marina, Clegg, J Christopher S, Crozier, Ian, Dal Bó, Elena, de la Torre, Juan Carlos, de Lamballerie, Xavier, de Swart, Rik L, Debat, Humberto, Dheilly, Nolwenn M, Di Cicco, Emiliano, Di Paola, Nicholas, Di Serio, Francesco, Dietzgen, Ralf G, Digiaro, Michele, Dolnik, Olga, Drebot, Michael A, Drexler, J Felix, Dundon, William G, Duprex, W Paul, Dürrwald, Ralf, Dye, John M, Easton, Andrew J, Ebihara, Hideki, Elbeaino, Toufic, Ergünay, Koray, Ferguson, Hugh W, Fooks, Anthony R, Forgia, Marco, Formenty, Pierre B H, Fránová, Jana, Freitas-Astúa, Juliana, Fu, Jingjing, Fürl, Stephanie, Gago-Zachert, Selma, Gāo, George Fú, García, María Laura, García-Sastre, Adolfo, Garrison, Aura R, Gaskin, Thomas, Gonzalez, Jean-Paul J, Griffiths, Anthony, Goldberg, Tony L, Groschup, Martin H, Günther, Stephan, Hall, Roy A, Hammond, John, Han, Tong, Hepojoki, Jussi, Hewson, Roger, Hong, Jiang, Hong, Ni, Hongo, Seiji, Horie, Masayuki, Hu, John S, Hu, Tao, Hughes, Holly R, Hüttner, Florian, Hyndman, Timothy H, Ilyas, M, Jalkanen, Risto, Jiāng, Dàohóng, Jonson, Gilda B, Junglen, Sandra, Kadono, Fujio, Kaukinen, Karia H, Kawate, Michael, Klempa, Boris, Klingström, Jonas, Kobinger, Gary, Koloniuk, Igor, Kondō, Hideki, Koonin, Eugene V, Krupovic, Mart, Kubota, Kenji, Kurath, Gael, Laenen, Lies, Lambert, Amy J, Langevin, Stanley L, Lee, Benhur, Lefkowitz, Elliot J, Leroy, Eric M, Li, Shaorong, Li, Longhui, Lǐ, Jiànróng, Liu, Huazhen, Lukashevich, Igor S, Maes, Piet, de Souza, William Marciel, Marklewitz, Marco, Marshall, Sergio H, Marzano, Shin-Yi L, Massart, Sebastien, McCauley, John W, Melzer, Michael, Mielke-Ehret, Nicole, Miller, Kristina M, Ming, Tobi J, Mirazimi, Ali, Mordecai, Gideon J, Mühlbach, Hans-Peter, Mühlberger, Elke, Naidu, Rayapati, Natsuaki, Tomohide, Navarro, José A, Netesov, Sergey V, Neumann, Gabriele, Nowotny, Norbert, Nunes, Márcio R T, Olmedo-Velarde, Alejandro, Palacios, Gustavo, Pallás, Vicente, Pályi, Bernadett, Papa, Anna, Paraskevopoulou, Sofia, Park, Adam C, Parrish, Colin R, Patterson, David A, Pauvolid-Corrêa, Alex, Pawęska, Janusz T, Payne, Susan, Peracchio, Carlotta, Pérez, Daniel R, Postler, Thomas S, Qi, Liying, Radoshitzky, Sheli R, Resende, Renato O, Reyes, Carina A, Rima, Bertus K, Luna, Gabriel Robles, Romanowski, Víctor, Rota, Paul, Rubbenstroth, Dennis, Rubino, Luisa, Runstadler, Jonathan A, Sabanadzovic, Sead, Sall, Amadou Alpha, Salvato, Maria S, Sang, Rosemary, Sasaya, Takahide, Schulze, Angela D, Schwemmle, Martin, Shi, Mang, Shí, Xiǎohóng, Shí, Zhènglì, Shimomoto, Yoshifumi, Shirako, Yukio, Siddell, Stuart G, Simmonds, Peter, Sironi, Manuela, Smagghe, Guy, Smither, Sophie, Song, Jin-Won, Spann, Kirsten, Spengler, Jessica R, Stenglein, Mark D, Stone, David M, Sugano, Jari, Suttle, Curtis A, Tabata, Amy, Takada, Ayato, Takeuchi, Shigeharu, Tchouassi, David P, Teffer, Amy, Tesh, Robert B, Thornburg, Natalie J, Tomitaka, Yasuhiro, Tomonaga, Keizō, Tordo, Noël, Torto, Baldwyn, Towner, Jonathan S, Tsuda, Shinya, Tu, Changchun, Turina, Massimo, Tzanetakis, Ioannis E, Uchida, Janice, Usugi, Tomio, Vaira, Anna Maria, Vallino, Marta, van den Hoogen, Bernadette, Varsani, Arvind, Vasilakis, Nikos, Verbeek, Martin, von Bargen, Susanne, Wada, Jiro, Wahl, Victoria, Walker, Peter J, Wang, Lin-Fa, Wang, Guoping, Wang, Yanxiang, Wang, Yaqin, Waqas, Muhammad, Wèi, Tàiyún, Wen, Shaohua, Whitfield, Anna E, Williams, John V, Wolf, Yuri I, Wu, Jiangxiang, Xu, Lei, Yanagisawa, Hironobu, Yang, Caixia, Yang, Zuokun, Zerbini, F Murilo, Zhai, Lifeng, Zhang, Yong-Zhen, Zhang, Song, Zhang, Jinguo, Zhang, Zhe, Zhou, Xueping, Kuhn, Jens H., Agwanda, Bernard R., Alkhovsky, Sergey V., Amarasinghe, Gaya K., Ayllón, María A., Ballinger, Matthew J., Basler, Christopher F., Bennett, Andrew J., Bente, Dennis A., Bird, Brian H., Blair, Carol D., Blasdell, Kim R., Borth, Wayne B., Brown, Paul A., Brown, Judith K., Buchholz, Ursula J., Buchmeier, Michael J., Calisher, Charles H., Charrel, Rémi N., Clegg, J. Christopher S., de Swart, Rik L., Dheilly, Nolwenn M., Dietzgen, Ralf G., Drebot, Michael A., Drexler, J. Felix, Dundon, William G., Duprex, W. Paul, Dye, John M., Easton, Andrew J., Ferguson, Hugh W., Fooks, Anthony R., Formenty, Pierre B. H., Garrison, Aura R., Gonzalez, Jean-Paul J., Goldberg, Tony L., Groschup, Martin H., Hall, Roy A., Hu, John S., Hughes, Holly R., Hyndman, Timothy H., Ilyas, M., Jonson, Gilda B., Kaukinen, Karia H., Koonin, Eugene V., Lambert, Amy J., Langevin, Stanley L., Lefkowitz, Elliot J., Leroy, Eric M., Lukashevich, Igor S., Marshall, Sergio H., Marzano, Shin-Yi L., McCauley, John W., Miller, Kristina M., Ming, Tobi J., Mordecai, Gideon J., Navarro, José A., Netesov, Sergey V., Nunes, Márcio R. T., Park, Adam C., Parrish, Colin R., Patterson, David A., Pawęska, Janusz T., Pérez, Daniel R., Postler, Thomas S., Radoshitzky, Sheli R., Resende, Renato O., Reyes, Carina A., Rima, Bertus K., Runstadler, Jonathan A., Salvato, Maria S., Schulze, Angela D., Siddell, Stuart G., Spengler, Jessica R., Stenglein, Mark D., Stone, David M., Suttle, Curtis A., Tchouassi, David P., Tesh, Robert B., Thornburg, Natalie J., Towner, Jonathan S., Tzanetakis, Ioannis E., Walker, Peter J., Whitfield, Anna E., Williams, John V., Wolf, Yuri I., Zerbini, F. Murilo, NIH - National Institute of Allergy and Infectious Diseases (NIAID) (Estados Unidos), NIH - National Cancer Institute (NCI) (Estados Unidos), National Institutes of Health (Estados Unidos), United States Department of Agriculture. National Institute of Food and Agriculture, Cancer Research UK (Reino Unido), Medical Research Council (Reino Unido), Wellcome Trust, Mississippi State University (Estados Unidos), Battelle National Biodefense Institute, National Biodefense Analysis and Countermeasures Center, Tunnell Government Services (Estados Unidos), National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), U.S. Horticultural Research Laboratory ( Fort Pierce, USA), United States Department of Agriculture (USDA), Jomo Kenyatta University of Agriculture and Technology (JKUAT), National Museums of Kenya, Humboldt University Of Berlin, Ministry of Health and Social Development of Russian Federation [Moscow], Washington University School of Medicine in St. Louis, Washington University in Saint Louis (WUSTL), University of Ljubljana, Universidad Politécnica de Madrid (UPM), University of Georgia [USA], Institute of Novel and Emerging Infectious Diseases (INNT), Friedrich-Loeffler-Institut (FLI), Laboratoire de Ploufragan-Plouzané-Niort [ANSES], Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES), Unité des Virus Emergents (UVE), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM), Virologie UMR1161 (VIRO), École nationale vétérinaire - Alfort (ENVA)-Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Virologie des archées - Archaeal Virology, Université Paris Cité (UPCité)-Microbiologie Intégrative et Moléculaire (UMR6047), Institut Pasteur [Paris] (IP)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut Pasteur [Paris] (IP)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Maladies infectieuses et vecteurs : écologie, génétique, évolution et contrôle (MIVEGEC), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Stratégies antivirales, Institut Pasteur [Paris] (IP), Centre collaborateur de l'OMS Arbovirus et Fièvres Hémorragiques virales - Stratégies antivirales (CC-OMS), NIAID under Contract No. HHSN272201800013C, NCI, NIH under Contract No. 75N91019D00024, NIH contract HHSN272201000040I/HHSN27200004/D04 and grant R24AI120942, US Department of Agriculture, Hatch Project 1021494, Cancer Research UK (FC001030), UK Medical Research Council (FC001030), Wellcome Trust (FC001030), Integrated Research Facility at Fort Detrick (IRF-Frederick), National Institutes of Health [Bethesda] (NIH)-National Institutes of Health [Bethesda] (NIH), ARS, Medical School, University of Ljubljana, École nationale vétérinaire d'Alfort (ENVA)-Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), and Virology

Subjects

Phylum, Identification, Alpharhabdovirinae, Strains, Field-collected mosquitos, [SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy, Article, MESH: Viruses, ICTV, 03 medical and health sciences, Biointeractions and Plant Health, MESH: Mononegavirales, Taxonomy of Viruses, Virology, Life Science, Humans, Crepuscuviridae, Myriaviridae, ComputingMilieux_MISCELLANEOUS, Taxonomy, 030304 developmental biology, Bunyavirales, 2. Zero hunger, 0303 health sciences, Virome, 030306 microbiology, Borne virus-infectons, Betarhabdovirinae, Rhabdovirus, General Medicine, Taxonomía de Virus, Merida virus, 3. Good health, Negarnaviricota, Aliusviridae, Triniti-virus, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, Viruses, Queensland, Mononegavirales, Hantavirus

Abstract

In March 2021, following the annual International Committee on Taxonomy of Viruses (ICTV) ratification vote on newly proposed taxa, the phylum Negarnaviricota was amended and emended. The phylum was expanded by four families (Aliusviridae, Crepuscuviridae, Myriaviridae, and Natareviridae), three subfamilies (Alpharhabdovirinae, Betarhabdovirinae, and Gammarhabdovirinae), 42 genera, and 200 species. Thirty-nine species were renamed and/or moved and seven species were abolished. This article presents the updated taxonomy of Negarnaviricota as now accepted by the ICTV. Instituto de Patología Vegetal Fil: Kuhn, Jens H. National Institute of Allergy and Infectious Diseases. National Institutes of Health. Integrated Research Facility at Fort Detrick; Estados Unidos Fil: Adkins, Scott. United States Department of Agriculture. Agricultural Research Service. US Horticultural Research Laboratory; Estados Unidos Fil: Agwanda, Bernard R. National Museums of Kenya. Zoology Department; Kenia Fil: Agwanda, Bernard R. Jomo Kenyatta University of Agriculture & Technology; Kenia Fil: Kubrusli, Rim Al. Humboldt-Universität zu Berlin. Faculty of Life Sciences. Division Phytomedicine; Alemania Fil: Alkhovsky, Sergey V. D.I. Ivanovsky Institute of Virology of N.F. Gamaleya National Center on Epidemiology and Microbiology of Ministry of Health of Russian Federation; Rusia Fil: Amarasinghe, Gaya K. Washington University School of Medicine. Department of Pathology and Immunology; Estados Unidos Fil: Avšič-Županc, Tatjana. University of Ljubljana. Faculty of Medicine; Eslovenia Fil: Ayllón, María A. Universidad Politécnica de Madrid—Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria. Campus de Montegancedo. Centro de Biotecnología y Genómica de Plantas; España Fil: Ayllón, María A. Universidad Politécnica de Madrid. Escuela Técnica Superior de Ingeniería Agronómica, Alimentaria y de Biosistemas. Departamento de Biotecnología-Biología Vegetal; España Fil: Bahl, Justin. University of Georgia. Center for Ecology of Infectious Diseases, Department of Infectious Diseases, Department of Epidemiology and Biostatistics, Insitute of Bioinformatics; Estados Unidos Fil: Balkema-Buschmann, Anne. Institute of Novel and Emerging Infectious Diseases. Friedrich-Loeffler-Institut. Federal Research Institute for Animal Health; Alemania Fil: Bejerman, Nicolas Esteban. Instituto Nacional de Tecnología Agropecuaria (INTA). Instituto de Patología Vegetal; Argentina Fil: Bejerman, Nicolas Esteban. Consejo Nacional de Investigaciones Científicas y Técnicas. Unidad de Fitopatología y Modelización Agrícola (UFyMA); Argentina Fil: Debat, Humberto Julio. Instituto Nacional de Tecnología Agropecuaria (INTA). Instituto de Patología Vegetal; Argentina Fil: Debat, Humberto Julio. Consejo Nacional de Investigaciones Científicas y Técnicas. Unidad de Fitopatología y Modelización Agrícola (UFyMA); Argentina Fil: Zhou, Xueping. Chinese Academy of Agricultural Sciences. Institute of Plant Protection. State Key Laboratory for Biology of Plant Diseases and Insect Pests; China

Published

2021

11. Ebola virus requires a host scramblase for externalization of phosphatidylserine on the surface of viral particles.

Author

Nanbo, Asuka, Maruyama, Junki, Imai, Masaki, Ujie, Michiko, Fujioka, Yoichiro, Nishide, Shinya, Takada, Ayato, Ohba, Yusuke, and Kawaoka, Yoshihiro

Subjects

PHOSPHATIDYLSERINES, EBOLA virus, PLASMA cell diseases, APOPTOTIC bodies, INTRACELLULAR membranes

Abstract

Cell surface receptors for phosphatidylserine contribute to the entry of Ebola virus (EBOV) particles, indicating that the presence of phosphatidylserine in the envelope of EBOV is important for the internalization of EBOV particles. Phosphatidylserine is typically distributed in the inner layer of the plasma membrane in normal cells. Progeny virions bud from the plasma membrane of infected cells, suggesting that phosphatidylserine is likely flipped to the outer leaflet of the plasma membrane in infected cells for EBOV virions to acquire it. Currently, the intracellular dynamics of phosphatidylserine during EBOV infection are poorly understood. Here, we explored the role of XK-related protein (Xkr) 8, which is a scramblase responsible for exposure of phosphatidylserine in the plasma membrane of apoptotic cells, to understand its significance in phosphatidylserine-dependent entry of EBOV. We found that Xkr8 and transiently expressed EBOV glycoprotein GP often co-localized in intracellular vesicles and the plasma membrane. We also found that co-expression of GP and viral major matrix protein VP40 promoted incorporation of Xkr8 into ebolavirus-like particles (VLPs) and exposure of phosphatidylserine on their surface, although only a limited amount of phosphatidylserine was exposed on the surface of the cells expressing GP and/or VP40. Downregulating Xkr8 or blocking caspase-mediated Xkr8 activation did not affect VLP production, but they reduced the amount of phosphatidylserine on the VLPs and their uptake in recipient cells. Taken together, our findings indicate that Xkr8 is trafficked to budding sites via GP-containing vesicles, is incorporated into VLPs, and then promote the entry of the released EBOV to cells in a phosphatidylserine-dependent manner. [ABSTRACT FROM AUTHOR]

Published

2018

12. Rapid and broad detection of H5 hemagglutinin by an immunochromatographic kit using novel monoclonal antibody against highly pathogenic avian influenza virus belonging to the genetic clade 2.3.4.4.

Author

Nguyen, Lam Thanh, Nakaishi, Kazunari, Motojima, Keiko, Ohkawara, Ayako, Minato, Erina, Maruyama, Junki, Hiono, Takahiro, Matsuno, Keita, Okamatsu, Masatoshi, Kimura, Takashi, Takada, Ayato, Kida, Hiroshi, and Sakoda, Yoshihiro

Subjects

HEMAGGLUTININ, MONOCLONAL antibodies, AVIAN influenza A virus, VIRAL antigens, CHROMATOGRAPHIC detectors

Abstract

Highly pathogenic avian influenza viruses (HPAIVs) of H5 subtype have persistently caused outbreaks in domestic poultry and wild birds worldwide and sporadically infected humans. Rapid and accurate diagnosis is one of the key strategies for the control of H5 HPAIVs. However, the sensitivity of the diagnosis of H5 HPAIVs has gradually reduced due to extensive antigenic variation during their evolution. Particularly, the previously developed immunochromatographic diagnosis kit for H5 viruses, Linjudge Flu A/H5, exhibits reduced detection of H5 HPAIVs isolated in recent years. In the present study, we established a new advanced H5 rapid immunochromatographic detection kit (New Linjudge Flu A/H5) by a combination of two anti-H5 hemagglutinin monoclonal antibodies, A64/1 previously applied in the Linjudge Flu A/H5 and A32/2, a novel monoclonal antibody generated from a clade 2.3.4.4 H5 HPAIV. The new kit broadly detected all classical and recent H5 influenza viruses and showed a higher specificity and sensitivity than the original Linjudge Flu A/H5 with recently circulating H5 HPAIVs. Furthermore, the applicability of the New Linjudge Flu A/H5 was demonstrated by detecting antigens from the swabs and tissue homogenates of naturally infected birds and experimentally infected chickens with H5N6 HPAIVs belonging to the genetic clade 2.3.4.4. Our study, therefore, can provide an effective point-of-care rapid antigen detection kit for the surveillance of H5 avian influenza viruses and as a prompt countermeasure against the current widespread of the clade 2.3.4.4 H5 HPAIVs in domestic and wild birds. [ABSTRACT FROM AUTHOR]

Published

2017

13. Fcγ-receptor IIa-mediated Src Signaling Pathway is Essential for the Antibody-Dependent Enhancement of Ebola Virus Infection.

Author

Furuyama, Wakako, Marzi, Andrea, Carmody, Aaron B., Maruyama, Junki, Kuroda, Makoto, Miyamoto, Hiroko, Nanbo, Asuka, Manzoor, Rashid, Yoshida, Reiko, Igarashi, Manabu, Feldmann, Heinz, and Takada, Ayato

Subjects

SRC gene, ANTIBODY-dependent cell cytotoxicity, TREATMENT of Ebola virus diseases, CELLULAR signal transduction, IMMUNOGLOBULINS, FC receptors, PHAGOCYTOSIS

Abstract

Antibody-dependent enhancement (ADE) of Ebola virus (EBOV) infection has been demonstrated in vitro, raising concerns about the detrimental potential of some anti-EBOV antibodies. ADE has been described for many viruses and mostly depends on the cross-linking of virus-antibody complexes to cell surface Fc receptors, leading to enhanced infection. However, little is known about the molecular mechanisms underlying this phenomenon. Here we show that Fcγ-receptor IIa (FcγRIIa)-mediated intracellular signaling through Src family protein tyrosine kinases (PTKs) is required for ADE of EBOV infection. We found that deletion of the FcγRIIa cytoplasmic tail abolished EBOV ADE due to decreased virus uptake into cellular endosomes. Furthermore, EBOV ADE, but not non-ADE infection, was significantly reduced by inhibition of the Src family protein PTK pathway, which was also found to be important to promote phagocytosis/macropinocytosis for viral uptake into endosomes. We further confirmed a significant increase of the Src phosphorylation mediated by ADE. These data suggest that antibody-EBOV complexes bound to the cell surface FcγRIIa activate the Src signaling pathway that leads to enhanced viral entry into cells, providing a novel perspective for the general understanding of ADE of virus infection. [ABSTRACT FROM AUTHOR]

Published

2016

14. Development and Evaluation of Reverse Transcription-Loop-Mediated Isothermal Amplification (RT-LAMP) Assay Coupled with a Portable Device for Rapid Diagnosis of Ebola Virus Disease in Guinea.

Author

Kurosaki, Yohei, Magassouba, N’Faly, Oloniniyi, Olamide K., Cherif, Mahamoud S., Sakabe, Saori, Takada, Ayato, Hirayama, Kenji, and Yasuda, Jiro

Subjects

EBOLA virus disease, GUINEA pigs, REVERSE transcriptase polymerase chain reaction, INFECTIOUS disease transmission, NUCLEOPROTEIN genetics, DIAGNOSIS, DISEASES

Abstract

Given the current absence of specific drugs or vaccines for Ebola virus disease (EVD), rapid, sensitive, and reliable diagnostic methods are required to stem the transmission chain of the disease. We have developed a rapid detection assay for Zaire ebolavirus based on reverse transcription-loop-mediated isothermal amplification (RT-LAMP) and coupled with a novel portable isothermal amplification and detection platform. The RT-LAMP assay is based on primer sets that target the untranscribed trailer region or nucleoprotein coding region of the viral RNA. The test could specifically detect viral RNAs of Central and West African Ebola virus strains within 15 minutes with no cross-reactivity to other hemorrhagic fever viruses and arboviruses, which cause febrile disease. The assay was evaluated using a total of 100 clinical specimens (serum, n = 44; oral swab, n = 56) collected from suspected EVD cases in Guinea. The specificity of this diagnostic test was 100% for both primer sets, while the sensitivity was 100% and 97.9% for the trailer and nucleoprotein primer sets, respectively, compared with a reference standard RT-PCR test. These observations suggest that our diagnostic assay is useful for identifying EVD cases, especially in the field or in settings with insufficient infrastructure. [ABSTRACT FROM AUTHOR]

Published

2016

15. Discussions and decisions of the 2012-2014 International Committee on Taxonomy of Viruses (ICTV) Filoviridae Study Group, January 2012-June 2013.

Author

Bukreyev, Alexander, Chandran, Kartik, Dolnik, Olga, Dye, John, Ebihara, Hideki, Leroy, Eric, Mühlberger, Elke, Netesov, Sergey, Patterson, Jean, Paweska, Janusz, Saphire, Erica, Smither, Sophie, Takada, Ayato, Towner, Jonathan, Volchkov, Viktor, Warren, Travis, and Kuhn, Jens

Subjects

CLASSIFICATION of viruses, FILOVIRIDAE, VIRUSES, VIROLOGY, EPIDEMIOLOGY, PATHOLOGY, IMMUNOLOGY

Abstract

The International Committee on Taxonomy of Viruses (ICTV) Filoviridae Study Group prepares proposals on the classification and nomenclature of filoviruses to reflect current knowledge or to correct disagreements with the International Code of Virus Classification and Nomenclature (ICVCN). In recent years, filovirus taxonomy has been corrected and updated, but parts of it remain controversial, and several topics remain to be debated. This article summarizes the decisions and discussion of the currently acting ICTV Filoviridae Study Group since its inauguration in January 2012. [ABSTRACT FROM AUTHOR]

Published

2014

16. Assembly and Budding of Ebolavirus.

Author

Noda, Takeshi, Ebihara, Hideki, Muramoto, Yukiko, Fujii, Ken, Takada, Ayato, Sagara, Hiroshi, Jin Hyun Kim, Kida, Hiroshi, Feldmann, Heinz, and Kawaoka, Yoshihiro

Subjects

EBOLA virus disease, HEMORRHAGIC fever, VIRUSES, CELLS, GENOMES

Abstract

Ebolavirus is responsible for highly lethal hemorrhagic fever. Like all viruses, it must reproduce its various components and assemble them in cells in order to reproduce infectious virions and perpetuate itself. To generate infectious Ebolavirus, a viral genome-protein complex called the nucleocapsid (NC) must be produced and transported to the cell surface, incorporated into virions, and then released from cells. To further our understanding of the Ebolavirus life cycle, we expressed the various viral proteins in mammalian cells and examined them ultrastructurally and biochemically. Expression of nucleoprotein alone led to the formation of helical tubes, which likely serve as a core for the NC. The matrix protein VP40 was found to be critical for transport of NCs to the cell surface and for the incorporation of NCs into virions, where interaction between nucleoprotein and the matrix protein VP40 is likely essential for these processes. Examination of virus-infected cells revealed that virions containing NCs mainly emerge horizontally from the cell surface, whereas empty virions mainly bud vertically, suggesting that horizontal budding is the major mode of Ebolavirus budding. These data form a foundation for the identification and development of potential antiviral agents to combat the devastating disease caused by this virus. [ABSTRACT FROM AUTHOR]

Published

2006

17. Molecular Determinants of Ebola Virus Virulence in Mice.

Author

Ebihara, Hideki, Takada, Ayato, Kobasa, Darwyn, Jones, Steven, Neumann, Gabriele, Theriault, Steven, Bray, Mike, Feldmann, Heinz, and Kawaoka, Yoshihiro

Subjects

*EBOLA virus disease, *VIRUSES, *MICROBIAL virulence, *VIRAL proteins, *NUCLEOPROTEINS, *MICE

Abstract

Zaire ebolavirus (ZEBOV) causes severe hemorrhagic fever in humans and nonhuman primates, with fatality rates in humans of up to 90%. The molecular basis for the extreme virulence of ZEBOV remains elusive. While adult mice resist ZEBOV infection, the Mayinga strain of the virus has been adapted to cause lethal infection in these animals. To understand the pathogenesis underlying the extreme virulence of Ebola virus (EBOV), here we identified the mutations responsible for the acquisition of the high virulence of the adapted Mayinga strain in mice, by using reverse genetics. We found that mutations in viral protein 24 and in the nucleoprotein were primarily responsible for the acquisition of high virulence. Moreover, the role of these proteins in virulence correlated with their ability to evade type I interferon-stimulated antiviral responses. These findings suggest a critical role for overcoming the interferon-induced antiviral state in the pathogenicity of EBOV and offer new insights into the pathogenesis of EBOV infection. [ABSTRACT FROM AUTHOR]

Published

2006

18. Enhanced virulence of influenza A viruses with the haemagglutinin of the 1918 pandemic virus.

Author

Kobasa, Darwyn, Takada, Ayato, Shinya, Kyoko, Hatta, Masato, Halfmann, Peter, Theriault, Steven, Suzuki, Hiroshi, Nishimura, Hidekazu, Mitamura, Keiko, Sugaya, Norio, Usui, Taichi, Murata, Takeomi, Maeda, Yasuko, Watanabe, Shinji, Suresh, M., Suzuki, Takashi, Suzuki, Yasuo, Feldmann, Heinz, and Kawaoka, Yoshihiro

Subjects

*INFLUENZA, *VIRUSES, *COMMUNICABLE diseases, *GENES, *GENETICS, *ANIMALS

Abstract

The‘Spanish’influenza pandemic of 1918-19 was the most devastating outbreak of infectious disease in recorded history. At least 20 million people died from their illness, which was characterized by an unusually severe and rapid clinical course. The complete sequencing of several genes of the 1918 influenza virus has made it possible to study the functions of the proteins encoded by these genes in viruses generated by reverse genetics, a technique that permits the generation of infectious viruses entirely from cloned complementary DNA. Thus, to identify properties of the 1918 pandemic influenza A strain that might be related to its extraordinary virulence, viruses were produced containing the viral haemagglutinin (HA) and neuraminidase (NA) genes of the 1918 strain. The HA of this strain supports the pathogenicity of a mouse-adapted virus in this animal. Here we demonstrate that the HA of the 1918 virus confers enhanced pathogenicity in mice to recent human viruses that are otherwise non-pathogenic in this host. Moreover, these highly virulent recombinant viruses expressing the 1918 viral HA could infect the entire lung and induce high levels of macrophage-derived chemokines and cytokines, which resulted in infiltration of inflammatory cells and severe haemorrhage, hallmarks of the illness produced during the original pandemic. [ABSTRACT FROM AUTHOR]

Published

2004

19. Architecture of ribonucleoprotein complexes in influenza A virus particles.

Author

Noda, Takeshi, Sagara, Hiroshi, Yen, Albert, Takada, Ayato, Kida, Hiroshi, Cheng, R. Holland, and Kawaoka, Yoshihiro

Subjects

NUCLEOPROTEINS, COMPLEX compounds, INFLUENZA viruses, VIRUSES, RNA, NUCLEOTIDES

Abstract

In viruses, as in eukaryotes, elaborate mechanisms have evolved to protect the genome and to ensure its timely replication and reliable transmission to progeny. Influenza A viruses are enveloped, spherical or filamentous structures, ranging from 80 to 120 nm in diameter. Inside each envelope is a viral genome consisting of eight single-stranded negative-sense RNA segments of 890 to 2,341 nucleotides each. These segments are associated with nucleoprotein and three polymerase subunits, designated PA, PB1 and PB2; the resultant ribonucleoprotein complexes (RNPs) resemble a twisted rod (10–15 nm in width and 30–120 nm in length) that is folded back and coiled on itself. Late in viral infection, newly synthesized RNPs are transported from the nucleus to the plasma membrane, where they are incorporated into progeny virions capable of infecting other cells. Here we show, by transmission electron microscopy of serially sectioned virions, that the RNPs of influenza A virus are organized in a distinct pattern (seven segments of different lengths surrounding a central segment). The individual RNPs are suspended from the interior of the viral envelope at the distal end of the budding virion and are oriented perpendicular to the budding tip. This finding argues against random incorporation of RNPs into virions, supporting instead a model in which each segment contains specific incorporation signals that enable the RNPs to be recruited and packaged as a complete set. A selective mechanism of RNP incorporation into virions and the unique organization of the eight RNP segments may be crucial to maintaining the integrity of the viral genome during repeated cycles of replication. [ABSTRACT FROM AUTHOR]

Published

2006

20. Hierarchy among Viral RNA (vRNA) Segments in Their Role in vRNA Incorporation into Influenza A Virions.

Author

Muramoto, Yukiko, Takada, Ayato, Fujii, Ken, Noda, Takeshi, Iwatsuki-Horimoto, Kiyoko, Watanabe, Shinji, Horimoto, Taisuke, Kida, Hiroshi, and Kawaoka, Yoshihiro

Subjects

*INFLUENZA, *VIRUSES, *RNA, *CELLS, *GREEN fluorescent protein

Abstract

The genome of influenza A viruses comprises eight negative-strand RNA segments. Although all eight segments must be present in cells for efficient viral replication, the mechanism(s) by which these viral RNA (vRNA) segments are incorporated into virions is not fully understood. We recently found that sequences at both ends of the coding regions of the HA, NA, and NS vRNA segments of A/WSN/33 play important roles in the incorporation of these vRNAs into virions. In order to similarly identify the regions of the PB2, PB1, and PA vRNAs of this strain that are critical for their incorporation, we generated a series of mutant vRNAs that possessed the green fluorescent protein gene flanked by portions of the coding and noncoding regions of the respective segments. For all three polymerase segments, deletions at the ends of their coding regions decreased their virion incorporation efficiencies. More importantly, these regions not only affected the incorporation of the segment in which they reside, but were also important for the incorporation of other segments. This effect was most prominent with the PB2 vRNA. These findings suggest a hierarchy among vRNA segments for virion incorporation and may imply intersegment association of vRNAs during virus assembly. [ABSTRACT FROM AUTHOR]

Published

2006

21. Ebola Virus VP40 Late Domains Are Not Essential for Viral Replication in Cell Culture.

Author

Neumann, Gabriele, Ebihara, Hideki, Takada, Ayato, Noda, Takeshi, Kobasa, Darwyn, Jasenosky, Luke D., Watanabe, Shinji, Kim, Jin H., Feldmann, Heinz, and Kawaoka, Yoshihiro

Subjects

*VIRUSES, *MICROORGANISMS, *VIRAL replication, *REPRODUCTION, *CELL culture, *CULTURES (Biology)

Abstract

Ebola virus particle formation and budding are mediated by the VP40 protein, which possesses overlapping PTAP and PPXY late domain motifs (7-PTAPPXY-13). These late domain motifs have also been found in the Gag proteins of retroviruses and the matrix proteins of rhabdo- and arenaviruses. While in vitro studies suggest a critical role for late domain motifs in the budding of these viruses, including Ebola virus, it remains unclear as to whether the VP40 late domains play a role in Ebola virus replication. Alteration of both late domain motifs drastically reduced VP40 particle formation in vitro. However, using reverse genetics, we were able to generate recombinant Ebola virus containing mutations in either or both of the late domains. Viruses containing mutations in one or both of their late domain motifs were attenuated by one log unit. Transmission and scanning electron microscopy did not reveal appreciable differences between the mutant and wild-type viruses released from infected cells. These findings indicate that the Ebola VP40 late domain motifs enhance virus replication but are not absolutely required for virus replication in cell culture. [ABSTRACT FROM AUTHOR]

Published

2005

22. C-type lectins do not act as functional receptors for filovirus entry into cells

Author

Takada, Ayato [Department of Global Epidemiology, Hokkaido University Research Center for Zoonosis Control, Sapporo (Japan)]

Published

2010

23. Characterization of a Human H5N1 Influenza A Virus Isolated in 2003.

Author

Shinya, Kyoko, Hatta, Masato, Yamada, Shinya, Takada, Ayato, Watanabe, Shinji, Halfmann, Peter, Horimoto, Taisuke, Neumann, Gabriele, Jin Hyun Kim, Lim, Wilma, Yi Guan, Peiris, Malik, Kiso, Makoto, Suzuki, Takashi, Suzuki, Yasuo, and Kawaoka, Yoshihiro

Subjects

*AVIAN influenza, *INFLUENZA, *VIRUSES, *VIRUS diseases

Abstract

In 2003, H5N1 avian influenza virus infections were diagnosed in two Hong Kong residents who had visited the Fujian province in mainland China, affording us the opportunity to characterize one of the viral isolates, A/Hong Kong/213/03 (HK213; H5N1). In contrast to H5N1 viruses isolated from humans during the 1997 outbreak in Hong Kong, HK213 retained several features of aquatic bird viruses, including the lack of a deletion in the neuraminidase stalk and the absence of additional oligosaccharide chains at the globular head of the hemagglutinin molecule. It demonstrated weak pathogenicity in mice and ferrets but caused lethal infection in chickens. The original isolate failed to produce disease in ducks but became more pathogenic after five passages. Taken together, these findings portray the HK213 isolate as an aquatic avian influenza A virus without the molecular changes associated with the replication of H5N1 avian viruses in land-based poultry such as chickens. This case challenges the view that adaptation to land-based poultry is a prerequisite for the replication of aquatic avian influenza A viruses in humans. [ABSTRACT FROM AUTHOR]

Published

2005