DOCSLIB.ORG

Taxonomy of the Order Bunyavirales: Update 2019

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Taxonomy of the Order Bunyavirales: Update 2019 Archives of Virology https://doi.org/10.1007/s00705-019-04253-6 VIROLOGY DIVISION NEWS Taxonomy of the order Bunyavirales: update 2019 Abulikemu Abudurexiti1 · Scott Adkins2 · Daniela Alioto3 · Sergey V. Alkhovsky4 · Tatjana Avšič‑Županc5 · Matthew J. Ballinger6 · Dennis A. Bente7 · Martin Beer8 · Éric Bergeron9 · Carol D. Blair10 · Thomas Briese11 · Michael J. Buchmeier12 · Felicity J. Burt13 · Charles H. Calisher10 · Chénchén Cháng14 · Rémi N. Charrel15 · Il Ryong Choi16 · J. Christopher S. Clegg17 · Juan Carlos de la Torre18 · Xavier de Lamballerie15 · Fēi Dèng19 · Francesco Di Serio20 · Michele Digiaro21 · Michael A. Drebot22 · Xiaˇoméi Duàn14 · Hideki Ebihara23 · Toufc Elbeaino21 · Koray Ergünay24 · Charles F. Fulhorst7 · Aura R. Garrison25 · George Fú Gāo26 · Jean‑Paul J. Gonzalez27 · Martin H. Groschup28 · Stephan Günther29 · Anne‑Lise Haenni30 · Roy A. Hall31 · Jussi Hepojoki32,33 · Roger Hewson34 · Zhìhóng Hú19 · Holly R. Hughes35 · Miranda Gilda Jonson36 · Sandra Junglen37,38 · Boris Klempa39 · Jonas Klingström40 · Chūn Kòu14 · Lies Laenen41,42 · Amy J. Lambert35 · Stanley A. Langevin43 · Dan Liu44 · Igor S. Lukashevich45 · Tāo Luò1 · Chuánwèi Lüˇ 19 · Piet Maes41 · William Marciel de Souza46 · Marco Marklewitz37,38 · Giovanni P. Martelli47 · Keita Matsuno48,49 · Nicole Mielke‑Ehret50 · Maria Minutolo3 · Ali Mirazimi51 · Abulimiti Moming14 · Hans‑Peter Mühlbach50 · Rayapati Naidu52 · Beatriz Navarro20 · Márcio Roberto Teixeira Nunes53 · Gustavo Palacios25 · Anna Papa54 · Alex Pauvolid‑Corrêa55 · Janusz T. Pawęska56,57 · Jié Qiáo19 · Sheli R. Radoshitzky25 · Renato O. Resende58 · Víctor Romanowski59 · Amadou Alpha Sall60 · Maria S. Salvato61 · Takahide Sasaya62 · Shū Shěn19 · Xiǎohóng Shí63 · Yukio Shirako64 · Peter Simmonds65 · Manuela Sironi66 · Jin‑Won Song67 · Jessica R. Spengler9 · Mark D. Stenglein68 · Zhèngyuán Sū19 · Sùróng Sūn14 · Shuāng Táng19 · Massimo Turina69 · Bó Wáng19 · Chéng Wáng1 · Huálín Wáng19 · Jūn Wáng19 · Tàiyún Wèi70 · Anna E. Whitfeld71 · F. Murilo Zerbini72 · Jìngyuàn Zhāng14 · Lěi Zhāng19 · Yànfāng Zhāng19 · Yong‑Zhen Zhang73,74 · Yújiāng Zhāng1 · Xueping Zhou75 · Lìyǐng Zhū19 · Jens H. Kuhn76 Received: 8 March 2019 / Accepted: 16 March 2019 © This is a U.S. government work and its text is not subject to copyright protection in the United States; however, its text may be subject to foreign copyright protection 2019 Handling Editor: Sead Sabanadzovic. Amy J. Lambert, William Marciel de Souza, Marco Marklewitz, Márcio Roberto Teixeira Nunes, Xiǎohóng Shí: the members of Michael J. Buchmeier, Rémi N. Charrel, J. Christopher S. Clegg, the 2017–2020 ICTV Peribunyaviridae Study Group; Matthew Juan Carlos de la Torre, Jean-Paul J. Gonzalez, Stephan Günther, J. Ballinger, Roy A. Hall, Sandra Junglen, Stanley A. Langevin, Jussi Hepojoki, Igor S. Lukashevich, Sheli R. Radoshitzky, Alex Pauvolid-Corrêa: the members of the 2017–2020 ICTV Víctor Romanowski, Maria S. Salvato, Manuela Sironi, Mark Phasmaviridae Study Group; Thomas Briese, Rémi N. Charrel, D. Stenglein, Jens H. Kuhn: the members of the 2017–2020 Xavier de Lamballerie, Hideki Ebihara, George Fú Gāo, Martin H. International Committee on Taxonomy of Viruses (ICTV) Groschup, Roberto Teixeira Nunes, Gustavo Palacios, Takahide Arenaviridae Study Group; Scott Adkins, Juan Carlos de la Torre, Sasaya, Jin-Won Song: the members of the 2017–2020 ICTV Sandra Junglen, Amy J. Lambert, Piet Maes, Gustavo Palacios, Phenuiviridae Study Group; Il Ryong Choi, Anne-Lise Haenni, Takahide Sasaya, Yong-Zhen Zhang, Jens H. Kuhn: the members Miranda Gilda Jonson, Takahide Sasaya, Yukio Shirako, Tàiyún of the 2017–2020 ICTV Bunyavirales Study Group; Michele Wèi, Xueping Zhou: the members of the 2017–2020 ICTV Digiaro, Toufc Elbeaino, Giovanni P. Martelli, Nicole Mielke- Tenuivirus Study Group; Scott Adkins, Amy J. Lambert, Rayapati Ehret, Hans-Peter Mühlbach: the members of the 2017–2020 Naidu, Renato O. Resende, Massimo Turina, Anna E. Whitfeld: ICTV Fimoviridae Study Group; Charles H. Calisher, Charles the members of the 2017–2020 ICTV Tospovirus Study Group; F. Fulhorst, Boris Klempa, Jonas Klingström, Lies Laenen, Peter Simmonds: the 2017–2020 ICTV Chair of the Fungal and Piet Maes, Jin-Won Song, Yong-Zhen Zhang: the members Protist Viruses Subcommittee; F. Murilo Zerbini: the 2017–2020 of the 2017–2020 ICTV Hantaviridae Study Group; Sergey ICTV Chair of the Plant Viruses Subcommittee; and Jens H. V. Alkhovsky, Tatjana Avšič-Županc, Dennis A. Bente, Éric Kuhn: the 2017–2020 ICTV Chair of the Animal dsRNA and Bergeron, Felicity J. Burt, Michael A. Drebot, Koray Ergünay, ssRNA-Viruses Subcommittee. Aura R. Garrison, Roger Hewson, Ali Mirazimi, Gustavo Palacios, Anna Papa, Janusz T. Pawęska, Amadou Alpha Sall, Jessica R. Extended author information available on the last page of the article Spengler, Jens H. Kuhn: the members of the 2017–2020 ICTV Nairoviridae Study Group; Scott Adkins, Sergey V. Alkhovsky, Martin Beer, Carol D. Blair, Charles H. Calisher, Holly R. Hughes, Vol.:(0123456789)1 3 A. Abudurexiti et al. Abstract • Melon yellow spot orthotospovirus for melon yellow In February 2019, following the annual taxon ratifcation spot virus (MYSV) found in netted melon (Cucumis vote, the order Bunyavirales was amended by creation of melo) [15]; and two new families, four new subfamilies, 11 new genera and • Soybean vein necrosis orthotospovirus for soybean vein 77 new species, merging of two species, and deletion of one necrosis virus (SVNV) discovered in soybeans (Glycine species. This article presents the updated taxonomy of the max) [36]. order Bunyavirales now accepted by the International Com- mittee on Taxonomy of Viruses (ICTV). A genus unassigned to any family, Coguvirus, was established to include species Citrus coguvirus for citrus concave gum-associated virus (CCGaV) found in citrus Introduction trees [26] (TaxoProp 2018.020P.A.v1.Coguvirus). The virus order Bunyavirales was established in 2017 to accommodate related viruses with segmented, linear, single- Taxonomic changes at the family rank stranded, negative-sense or ambisense RNA genomes clas- sifed into nine families [19]. An amended/emended order Arenaviridae description was published in early 2019 [20]. Here, we pre- sent the changes that were proposed via ofcial ICTV taxo- The family Arenaviridae was expanded by one genus, nomic proposals that were accepted by the ICTV Executive Antennavirus, to include two new species, Hairy anten- Committee (EC) in February 2019. Therefore, these changes navirus and Striated antennavirus, for Wēnlǐng frogfsh are now part of the ofcial ICTV taxonomy. arenavirus 2 (WlFV-2) and Wēnlǐng frogfsh arenavirus 1 (WlFV-1), both found in striated frogfsh (Antennarius striatus) [33] (TaxoProp 2018.005M.A.v1.Antennavirus). Taxonomic changes at the order rank Cruliviridae The order was expanded by addition of two new families. Family Leishbuviridae was created to accommodate one No changes were made at the family rank. new genus, Shilevirus, including one new species, Lepto- monas shilevirus, for Leptomonas moramango leishbun- yavirus (LEPMV) discovered in a trypanosomatid protist Fimoviridae (Leptomonas moramango) [2]. Family Tospoviridae was recreated for the already established genus Tospovirus (now No changes were made at the family rank. renamed Orthotospovirus; TaxoProp 2018.017M.A.v1. Bunyavirales_2fam5gen) and expanded by seven new spe- cies (TaxoProp 2018.025P.A.v1.Orthotospovirus_7sp): Hantaviridae • Bean necrotic mosaic orthotospovirus for bean necrotic The family (TaxoProp 2018.010M.A.v2. mosaic virus (BeNMV) discovered in common beans Hantaviridae_4subfam) was reorganized into four (Phaseolus vulgaris) [8]; subfamilies: • Calla lily chlorotic spot orthotospovirus for calla lily chlorotic spot virus (CCSV) found in calla lilies (Zant- • subfamily Actantavirinae was created for the new genus edeschia sp.) [5, 18]; Actinovirus to accommodate three novel species: Bat- • Capsicum chlorosis orthotospovirus for capsicum chlo- fsh actinovirus for Wēnlǐng minipizza batfsh virus rosis virus (CaCV) found in capsicums, chillies, and (WEMV) discovered in minipizza batfsh (Halieutaea tomatoes [16, 23]; stellata); Goosefsh actinovirus for Wēnlǐng yellow • Chrysanthemum stem necrosis orthotospovirus for goosefish virus (WEYGV) found in yellow goose- chrysanthemum stem necrosis virus (CSNV) infecting fsh (Lophius litulon); and Spikefsh actinovirus for chrysanthemums [3, 10]; Wēnlǐng red spikefsh virus (WERSV) of red spikefsh • Melon severe mosaic orthotospovirus for melon severe (Triacanthodes anomalus) [33]; mosaic virus (MSMV) infecting cucurbit crops [6, 7]; • subfamily Agantavirinae was created for the new genus Agnathovirus to accommodate one new species, Hag- 1 3 Taxonomy of the order Bunyavirales: update 2019 fsh agnathovirus, for Wēnlǐng hagfsh virus (WEHV) Real orthobunyavirus was abolished, and its member, Estero of inshore hagfsh (Eptatretus burgeri) [33]; Real virus (ERV), was moved into family Nairoviridae [1] • subfamily Mammantavirinae was created to accom- (TaxoProp 2018.012M.A.v1.Bunyavirales_spmov). modate the established genera Loanvirus, Mobatvirus, and Orthohantavirus. Two new orthohantavirus spe- Phasmaviridae cies, Seewis orhtohantavirus and Tigray orthohantavi- rus, were created for Seewis virus (SWSV) of Eurasian The family was expanded by addition of one new genus, common shrews (Sorex araneus) [34] and Tigray virus Sawastrivirus, to include one new species, Sanxia sawast- (TIGV) of Ethiopian white-footed mice (Stenocephale- rivirus, for Sānxiá
Load more

Recommended publications
  • California Encephalitis Orthobunyaviruses in Northern Europe
    California encephalitis orthobunyaviruses in northern Europe NIINA PUTKURI Department of Virology Faculty of Medicine, University of Helsinki Doctoral Program in Biomedicine Doctoral School in Health Sciences Academic Dissertation To be presented for public examination with the permission of the Faculty of Medicine, University of Helsinki, in lecture hall 13 at the Main Building, Fabianinkatu 33, Helsinki, 23rd September 2016 at 12 noon. Helsinki 2016 Supervisors Professor Olli Vapalahti Department of Virology and Veterinary Biosciences, Faculty of Medicine and Veterinary Medicine, University of Helsinki and Department of Virology and Immunology, Hospital District of Helsinki and Uusimaa, Helsinki, Finland Professor Antti Vaheri Department of Virology, Faculty of Medicine, University of Helsinki, Helsinki, Finland Reviewers Docent Heli Harvala Simmonds Unit for Laboratory surveillance of vaccine preventable diseases, Public Health Agency of Sweden, Solna, Sweden and European Programme for Public Health Microbiology Training (EUPHEM), European Centre for Disease Prevention and Control (ECDC), Stockholm, Sweden Docent Pamela Österlund Viral Infections Unit, National Institute for Health and Welfare, Helsinki, Finland Offical Opponent Professor Jonas Schmidt-Chanasit Bernhard Nocht Institute for Tropical Medicine WHO Collaborating Centre for Arbovirus and Haemorrhagic Fever Reference and Research National Reference Centre for Tropical Infectious Disease Hamburg, Germany ISBN 978-951-51-2399-2 (PRINT) ISBN 978-951-51-2400-5 (PDF, available
    [Show full text]
  • Data-Driven Identification of Potential Zika Virus Vectors Michelle V Evans1,2*, Tad a Dallas1,3, Barbara a Han4, Courtney C Murdock1,2,5,6,7,8, John M Drake1,2,8
    RESEARCH ARTICLE Data-driven identification of potential Zika virus vectors Michelle V Evans1,2*, Tad A Dallas1,3, Barbara A Han4, Courtney C Murdock1,2,5,6,7,8, John M Drake1,2,8 1Odum School of Ecology, University of Georgia, Athens, United States; 2Center for the Ecology of Infectious Diseases, University of Georgia, Athens, United States; 3Department of Environmental Science and Policy, University of California-Davis, Davis, United States; 4Cary Institute of Ecosystem Studies, Millbrook, United States; 5Department of Infectious Disease, University of Georgia, Athens, United States; 6Center for Tropical Emerging Global Diseases, University of Georgia, Athens, United States; 7Center for Vaccines and Immunology, University of Georgia, Athens, United States; 8River Basin Center, University of Georgia, Athens, United States Abstract Zika is an emerging virus whose rapid spread is of great public health concern. Knowledge about transmission remains incomplete, especially concerning potential transmission in geographic areas in which it has not yet been introduced. To identify unknown vectors of Zika, we developed a data-driven model linking vector species and the Zika virus via vector-virus trait combinations that confer a propensity toward associations in an ecological network connecting flaviviruses and their mosquito vectors. Our model predicts that thirty-five species may be able to transmit the virus, seven of which are found in the continental United States, including Culex quinquefasciatus and Cx. pipiens. We suggest that empirical studies prioritize these species to confirm predictions of vector competence, enabling the correct identification of populations at risk for transmission within the United States. *For correspondence: mvevans@ DOI: 10.7554/eLife.22053.001 uga.edu Competing interests: The authors declare that no competing interests exist.
    [Show full text]
  • 2020 Taxonomic Update for Phylum Negarnaviricota (Riboviria: Orthornavirae), Including the Large Orders Bunyavirales and Mononegavirales
    Archives of Virology https://doi.org/10.1007/s00705-020-04731-2 VIROLOGY DIVISION NEWS 2020 taxonomic update for phylum Negarnaviricota (Riboviria: Orthornavirae), including the large orders Bunyavirales and Mononegavirales Jens H. Kuhn1 · Scott Adkins2 · Daniela Alioto3 · Sergey V. Alkhovsky4 · Gaya K. Amarasinghe5 · Simon J. Anthony6,7 · Tatjana Avšič‑Županc8 · María A. Ayllón9,10 · Justin Bahl11 · Anne Balkema‑Buschmann12 · Matthew J. Ballinger13 · Tomáš Bartonička14 · Christopher Basler15 · Sina Bavari16 · Martin Beer17 · Dennis A. Bente18 · Éric Bergeron19 · Brian H. Bird20 · Carol Blair21 · Kim R. Blasdell22 · Steven B. Bradfute23 · Rachel Breyta24 · Thomas Briese25 · Paul A. Brown26 · Ursula J. Buchholz27 · Michael J. Buchmeier28 · Alexander Bukreyev18,29 · Felicity Burt30 · Nihal Buzkan31 · Charles H. Calisher32 · Mengji Cao33,34 · Inmaculada Casas35 · John Chamberlain36 · Kartik Chandran37 · Rémi N. Charrel38 · Biao Chen39 · Michela Chiumenti40 · Il‑Ryong Choi41 · J. Christopher S. Clegg42 · Ian Crozier43 · John V. da Graça44 · Elena Dal Bó45 · Alberto M. R. Dávila46 · Juan Carlos de la Torre47 · Xavier de Lamballerie38 · Rik L. de Swart48 · Patrick L. Di Bello49 · Nicholas Di Paola50 · Francesco Di Serio40 · Ralf G. Dietzgen51 · Michele Digiaro52 · Valerian V. Dolja53 · Olga Dolnik54 · Michael A. Drebot55 · Jan Felix Drexler56 · Ralf Dürrwald57 · Lucie Dufkova58 · William G. Dundon59 · W. Paul Duprex60 · John M. Dye50 · Andrew J. Easton61 · Hideki Ebihara62 · Toufc Elbeaino63 · Koray Ergünay64 · Jorlan Fernandes195 · Anthony R. Fooks65 · Pierre B. H. Formenty66 · Leonie F. Forth17 · Ron A. M. Fouchier48 · Juliana Freitas‑Astúa67 · Selma Gago‑Zachert68,69 · George Fú Gāo70 · María Laura García71 · Adolfo García‑Sastre72 · Aura R. Garrison50 · Aiah Gbakima73 · Tracey Goldstein74 · Jean‑Paul J. Gonzalez75,76 · Anthony Grifths77 · Martin H. Groschup12 · Stephan Günther78 · Alexandro Guterres195 · Roy A.
    [Show full text]
  • Hantavirus Disease Were HPS Is More Common in Late Spring and Early Summer in Seropositive in One Study in the U.K
    Hantavirus Importance Hantaviruses are a large group of viruses that circulate asymptomatically in Disease rodents, insectivores and bats, but sometimes cause illnesses in humans. Some of these agents can occur in laboratory rodents or pet rats. Clinical cases in humans vary in Hantavirus Fever, severity: some hantaviruses tend to cause mild disease, typically with complete recovery; others frequently cause serious illnesses with case fatality rates of 30% or Hemorrhagic Fever with Renal higher. Hantavirus infections in people are fairly common in parts of Asia, Europe and Syndrome (HFRS), Nephropathia South America, but they seem to be less frequent in North America. Hantaviruses may Epidemica (NE), Hantavirus occasionally infect animals other than their usual hosts; however, there is currently no Pulmonary Syndrome (HPS), evidence that they cause any illnesses in these animals, with the possible exception of Hantavirus Cardiopulmonary nonhuman primates. Syndrome, Hemorrhagic Nephrosonephritis, Epidemic Etiology Hemorrhagic Fever, Korean Hantaviruses are members of the genus Orthohantavirus in the family Hantaviridae Hemorrhagic Fever and order Bunyavirales. As of 2017, 41 species of hantaviruses had officially accepted names, but there is ongoing debate about which viruses should be considered discrete species, and additional viruses have been discovered but not yet classified. Different Last Updated: September 2018 viruses tend to be associated with the two major clinical syndromes in humans, hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary (or cardiopulmonary) syndrome (HPS). However, this distinction is not absolute: viruses that are usually associated with HFRS have been infrequently linked to HPS and vice versa. A mild form of HFRS in Europe is commonly called nephropathia epidemica.
    [Show full text]
  • Zwiesel Bat Banyangvirus, a Potentially Zoonotic Huaiyangshan
    www.nature.com/scientificreports OPEN Zwiesel bat banyangvirus, a potentially zoonotic Huaiyangshan banyangvirus (Formerly known as SFTS)–like banyangvirus in Northern bats from Germany Claudia Kohl1*, Annika Brinkmann1, Aleksandar Radonić2, Piotr Wojtek Dabrowski2, Andreas Nitsche1, Kristin Mühldorfer3, Gudrun Wibbelt 3 & Andreas Kurth1 Bats are reservoir hosts for several emerging and re-emerging viral pathogens causing morbidity and mortality in wildlife, animal stocks and humans. Various viruses within the family Phenuiviridae have been detected in bats, including the highly pathogenic Rift Valley fever virus and Malsoor virus, a novel Banyangvirus with close genetic relation to Huaiyangshan banyangvirus (BHAV)(former known as Severe fever with thrombocytopenia syndrome virus, SFTSV) and Heartland virus (HRTV), both of which have caused severe disease with fatal casualties in humans. In this study we present the whole genome of a novel Banyangvirus, named Zwiesel bat banyangvirus, revealed through deep sequencing of the Eptesicus nilssonii bat virome. The detection of the novel bat banyangvirus, which is in close phylogenetic relationship with the pathogenic HRTV and BHAV, underlines the possible impact of emerging phenuiviruses on public health. Te Banyangvirus genus, currently classifed as part of the Phenuviridae family in the order Bunyavirales, is char- acterized by a tri-segmented, negative- or ambisense ssRNA genome of 11–19 kb length in total. Four structural proteins are encoded on the genome: the L protein (RNA-dependent RNA polymerase) on segment L, two gly- coproteins Gn and Gc on segment M, the nucleocapsid protein on segment N and the nonstructural protein NSs on segment S. Banyangviruses can infect vertebrates and invertebrates and have caused febrile infections, encephalitis and severe fevers with fatal outcome in humans, therefore being increasingly reported as emerging pathogens of public health importance1–3.
    [Show full text]
  • MOSQUITOES of the SOUTHEASTERN UNITED STATES
    L f ^-l R A R > ^l^ ■'■mx^ • DEC2 2 59SO , A Handbook of tnV MOSQUITOES of the SOUTHEASTERN UNITED STATES W. V. King G. H. Bradley Carroll N. Smith and W. C. MeDuffle Agriculture Handbook No. 173 Agricultural Research Service UNITED STATES DEPARTMENT OF AGRICULTURE \ I PRECAUTIONS WITH INSECTICIDES All insecticides are potentially hazardous to fish or other aqpiatic organisms, wildlife, domestic ani- mals, and man. The dosages needed for mosquito control are generally lower than for most other insect control, but caution should be exercised in their application. Do not apply amounts in excess of the dosage recommended for each specific use. In applying even small amounts of oil-insecticide sprays to water, consider that wind and wave action may shift the film with consequent damage to aquatic life at another location. Heavy applications of insec- ticides to ground areas such as in pretreatment situa- tions, may cause harm to fish and wildlife in streams, ponds, and lakes during runoff due to heavy rains. Avoid contamination of pastures and livestock with insecticides in order to prevent residues in meat and milk. Operators should avoid repeated or prolonged contact of insecticides with the skin. Insecticide con- centrates may be particularly hazardous. Wash off any insecticide spilled on the skin using soap and water. If any is spilled on clothing, change imme- diately. Store insecticides in a safe place out of reach of children or animals. Dispose of empty insecticide containers. Always read and observe instructions and precautions given on the label of the product. UNITED STATES DEPARTMENT OF AGRICULTURE Agriculture Handbook No.
    [Show full text]
  • Taxonomy of the Order Bunyavirales: Update 2019
    Archives of Virology (2019) 164:1949–1965 https://doi.org/10.1007/s00705-019-04253-6 VIROLOGY DIVISION NEWS Taxonomy of the order Bunyavirales: update 2019 Abulikemu Abudurexiti1 · Scott Adkins2 · Daniela Alioto3 · Sergey V. Alkhovsky4 · Tatjana Avšič‑Županc5 · Matthew J. Ballinger6 · Dennis A. Bente7 · Martin Beer8 · Éric Bergeron9 · Carol D. Blair10 · Thomas Briese11 · Michael J. Buchmeier12 · Felicity J. Burt13 · Charles H. Calisher10 · Chénchén Cháng14 · Rémi N. Charrel15 · Il Ryong Choi16 · J. Christopher S. Clegg17 · Juan Carlos de la Torre18 · Xavier de Lamballerie15 · Fēi Dèng19 · Francesco Di Serio20 · Michele Digiaro21 · Michael A. Drebot22 · Xiaˇoméi Duàn14 · Hideki Ebihara23 · Toufc Elbeaino21 · Koray Ergünay24 · Charles F. Fulhorst7 · Aura R. Garrison25 · George Fú Gāo26 · Jean‑Paul J. Gonzalez27 · Martin H. Groschup28 · Stephan Günther29 · Anne‑Lise Haenni30 · Roy A. Hall31 · Jussi Hepojoki32,33 · Roger Hewson34 · Zhìhóng Hú19 · Holly R. Hughes35 · Miranda Gilda Jonson36 · Sandra Junglen37,38 · Boris Klempa39 · Jonas Klingström40 · Chūn Kòu14 · Lies Laenen41,42 · Amy J. Lambert35 · Stanley A. Langevin43 · Dan Liu44 · Igor S. Lukashevich45 · Tāo Luò1 · Chuánwèi Lüˇ 19 · Piet Maes41 · William Marciel de Souza46 · Marco Marklewitz37,38 · Giovanni P. Martelli47 · Keita Matsuno48,49 · Nicole Mielke‑Ehret50 · Maria Minutolo3 · Ali Mirazimi51 · Abulimiti Moming14 · Hans‑Peter Mühlbach50 · Rayapati Naidu52 · Beatriz Navarro20 · Márcio Roberto Teixeira Nunes53 · Gustavo Palacios25 · Anna Papa54 · Alex Pauvolid‑Corrêa55 · Janusz T. Pawęska56,57 · Jié Qiáo19 · Sheli R. Radoshitzky25 · Renato O. Resende58 · Víctor Romanowski59 · Amadou Alpha Sall60 · Maria S. Salvato61 · Takahide Sasaya62 · Shū Shěn19 · Xiǎohóng Shí63 · Yukio Shirako64 · Peter Simmonds65 · Manuela Sironi66 · Jin‑Won Song67 · Jessica R. Spengler9 · Mark D. Stenglein68 · Zhèngyuán Sū19 · Sùróng Sūn14 · Shuāng Táng19 · Massimo Turina69 · Bó Wáng19 · Chéng Wáng1 · Huálín Wáng19 · Jūn Wáng19 · Tàiyún Wèi70 · Anna E.
    [Show full text]
  • Mosquitoes of Western Uganda
    HHS Public Access Author manuscript Author ManuscriptAuthor Manuscript Author J Med Entomol Manuscript Author . Author Manuscript Author manuscript; available in PMC 2019 May 26. Published in final edited form as: J Med Entomol. 2012 November ; 49(6): 1289–1306. doi:10.1603/me12111. Mosquitoes of Western Uganda J.-P. Mutebi1, M. B. Crabtree1, R. J. Kent Crockett1, A. M. Powers1, J. J. Lutwama2, and B. R. Miller1 1Centers for Disease Control and Prevention (CDC), 3150 Rampart Road, Fort Collins, Colorado 80521. 2Department of Arbovirology, Uganda Virus Research Institute (UVRI), P.O. Box 49, Entebbe, Uganda. Abstract The mosquito fauna in many areas of western Uganda has never been studied and is currently unknown. One area, Bwamba County, has been previously studied and documented but the species lists have not been updated for more than 40 years. This paucity of data makes it difficult to determine which arthropod-borne viruses pose a risk to human or animal populations. Using CO2 baited-light traps, from 2008 through 2010, 67,731 mosquitoes were captured at five locations in western Uganda including Mweya, Sempaya, Maramagambo, Bwindi (BINP), and Kibale (KNP). Overall, 88 mosquito species, 7 subspecies and 7 species groups in 10 genera were collected. The largest number of species was collected at Sempaya (65 species), followed by Maramagambo (45), Mweya (34), BINP (33), and KNP (22). However, species diversity was highest in BINP (Simpson’s Diversity Index 1-D = 0.85), followed by KNP (0.80), Maramagambo (0.79), Sempaya (0.67), and Mweya (0.56). Only six species (Aedes (Aedimorphus) cumminsii (Theobald), Aedes (Neomelaniconion) circumluteolus (Theobald), Culex (Culex) antennatus (Becker), Culex (Culex) decens group, Culex (Lutzia) tigripes De Grandpre and De Charmoy, and Culex (Oculeomyia) annulioris Theobald), were collected from all 5 sites suggesting large differences in species composition among sites.
    [Show full text]
  • A Look Into Bunyavirales Genomes: Functions of Non-Structural (NS) Proteins
    viruses Review A Look into Bunyavirales Genomes: Functions of Non-Structural (NS) Proteins Shanna S. Leventhal, Drew Wilson, Heinz Feldmann and David W. Hawman * Laboratory of Virology, Rocky Mountain Laboratories, Division of Intramural Research, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Hamilton, MT 59840, USA; [email protected] (S.S.L.); [email protected] (D.W.); [email protected] (H.F.) * Correspondence: [email protected]; Tel.: +1-406-802-6120 Abstract: In 2016, the Bunyavirales order was established by the International Committee on Taxon- omy of Viruses (ICTV) to incorporate the increasing number of related viruses across 13 viral families. While diverse, four of the families (Peribunyaviridae, Nairoviridae, Hantaviridae, and Phenuiviridae) contain known human pathogens and share a similar tri-segmented, negative-sense RNA genomic organization. In addition to the nucleoprotein and envelope glycoproteins encoded by the small and medium segments, respectively, many of the viruses in these families also encode for non-structural (NS) NSs and NSm proteins. The NSs of Phenuiviridae is the most extensively studied as a host interferon antagonist, functioning through a variety of mechanisms seen throughout the other three families. In addition, functions impacting cellular apoptosis, chromatin organization, and transcrip- tional activities, to name a few, are possessed by NSs across the families. Peribunyaviridae, Nairoviridae, and Phenuiviridae also encode an NSm, although less extensively studied than NSs, that has roles in antagonizing immune responses, promoting viral assembly and infectivity, and even maintenance of infection in host mosquito vectors. Overall, the similar and divergent roles of NS proteins of these Citation: Leventhal, S.S.; Wilson, D.; human pathogenic Bunyavirales are of particular interest in understanding disease progression, viral Feldmann, H.; Hawman, D.W.
    [Show full text]
  • Genetic and Phylogenetic Characterization Of
    Article Genetic and Phylogenetic Characterization of Tataguine and Witwatersrand Viruses and Other Orthobunyaviruses of the Anopheles A, Capim, Guamá, Koongol, Mapputta, Tete, and Turlock Serogroups Alexey M. Shchetinin 1, Dmitry K. Lvov 1, Petr G. Deriabin 1, Andrey G. Botikov 1, Asya K. Gitelman 1, Jens H. Kuhn 2 and Sergey V. Alkhovsky 1,* Received: 2 September 2015; Accepted: 7 November 2015; Published: 23 November 2015 Academic Editors: Jane Tao and Pierre-Yves Lozach 1 D.I. Ivanovsky Institute of Virology, Gamaleya Federal Research Center for Epidemiology and Microbiology, Ministry of Health of the Russian Federation, 123098, Moscow, Russia; [email protected] (A.M.S.); [email protected] (D.K.L.); [email protected] (P.G.D.); [email protected] (A.G.B.); [email protected] (A.K.G.) 2 Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Fort Detrick, Frederick, MD 21702, USA; [email protected] * Correspondence: [email protected]; Tel.: +7-499-190-3043; Fax: +7-499-190-2867 Abstract: The family Bunyaviridae has more than 530 members that are distributed among five genera or remain to be classified. The genus Orthobunyavirus is the most diverse bunyaviral genus with more than 220 viruses that have been assigned to more than 18 serogroups based on serological cross-reactions and limited molecular-biological characterization. Sequence information for all three orthobunyaviral genome segments is only available for viruses belonging to the Bunyamwera, Bwamba/Pongola, California encephalitis, Gamboa, Group C, Mapputta, Nyando, and Simbu serogroups. Here we present coding-complete sequences for all three genome segments of 15 orthobunyaviruses belonging to the Anopheles A, Capim, Guamá, Kongool, Tete, and Turlock serogroups, and of two unclassified bunyaviruses previously not known to be orthobunyaviruses (Tataguine and Witwatersrand viruses).
    [Show full text]
  • Orthobunyaviruses: from Virus Binding to Penetration Into Mammalian Host Cells
    viruses Review Orthobunyaviruses: From Virus Binding to Penetration into Mammalian Host Cells Stefan Windhaber 1 , Qilin Xin 2 and Pierre-Yves Lozach 1,2,* 1 CellNetworks—Cluster of Excellence and Center for Integrative Infectious Diseases Research (CIID), Department of Infectious Diseases, Virology, University Hospital Heidelberg, 69120 Heidelberg, Germany; [email protected] 2 Institut National de Recherche Pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Ecole Pratique des Hautes Etudes (EPHE), Viral Infections and Comparative Pathology (IVPC), UMR754-University Lyon, 69007 Lyon, France; [email protected] * Correspondence: [email protected] Abstract: With over 80 members worldwide, Orthobunyavirus is the largest genus in the Peribunyaviri- dae family. Orthobunyaviruses (OBVs) are arthropod-borne viruses that are structurally simple, with a trisegmented, negative-sense RNA genome and only four structural proteins. OBVs are potential agents of emerging and re-emerging diseases and overall represent a global threat to both public and veterinary health. The focus of this review is on the very first steps of OBV infection in mammalian hosts, from virus binding to penetration and release of the viral genome into the cytosol. Here, we address the most current knowledge and advances regarding OBV receptors, endocytosis, and fusion. Keywords: arbovirus; Bunyamwera; cell entry; emerging virus; endocytosis; fusion; La Crosse; Oropouche; receptor; Schmallenberg Citation: Windhaber, S.; Xin, Q.; Lozach, P.-Y. Orthobunyaviruses: 1. Introduction From Virus Binding to Penetration into Mammalian Host Cells. Viruses Orthobunyavirus consists of over 80 members that are globally distributed, which is a 2021, 13, 872. https://doi.org/ genus of the family Peribunyaviridae (Bunyavirales order) along with Herbevirus, Pacuvirus, 10.3390/v13050872 and Shangavirus (Table1)[ 1].
    [Show full text]
  • Characterization of Maguari Orthobunyavirus Mutants Suggests
    Virology 348 (2006) 224–232 www.elsevier.com/locate/yviro Characterization of Maguari orthobunyavirus mutants suggests the nonstructural protein NSm is not essential for growth in tissue culture ⁎ Elizabeth Pollitt, Jiangqin Zhao, Paul Muscat, Richard M. Elliott ,1 Division of Virology, Institute of Biomedical and Life Sciences, University of Glasgow, Church Street, Glasgow G11 5JR, Scotland, UK Received 9 November 2005; returned to author for revision 23 November 2005; accepted 15 December 2005 Available online 30 January 2006 Abstract Maguari virus (MAGV; genus Orthobunyavirus, family Bunyaviridae) contains a tripartite negative-sense RNA genome. Like all orthobunyaviruses, the medium (M) genome segment encodes a precursor polyprotein (NH2-Gn-NSm-Gc-COOH) for the two virion glycoproteins Gn and Gc and a nonstructural protein NSm. The nucleotide sequences of the M segment of wild-type (wt) MAGV, of a temperature-sensitive (ts) mutant, and of two non-ts revertants, R1 and R2, that show electrophoretic mobility differences in their Gc proteins were determined. Twelve amino acid differences (2 in Gn, 10 in Gc) were observed between wt and ts MAGV, of which 9 were maintained in R1 and R2. The M RNA segments of R1 and R2 contained internal deletions, resulting in the removal of the N-terminal 239 residues of Gc (R1) or the C- terminal two thirds of NSm and the N-terminal 431 amino acids of Gc (R2). The sequence data were consistent with analyses of the virion RNAs and virion glycoproteins. These results suggest that neither the N-terminal domain of Gc nor an intact NSm protein is required for the replication of MAGV in tissue culture.
    [Show full text]