References: Nairoviridae

Bergeron, É., Zivcec, M., Chakrabarti, A. K., Nichol, S. T., Albariño, C. G. & Spiropoulou, C. F. (2015).  Recovery of recombinant Crimean Congo hemorrhagic fever virus reveals a function for non-structural glycoproteins cleavage by furin. PLoS Pathog 11, e1004879. [PubMed]

Bishop, D. H. L., Calisher, C. H., Casals, J., Chumakov, M. P., Gaidamovich, S. Y., Hannoun, C., Lvov, D. K., Marshall, I. D., Oker-Blom, N., Pettersson, R. F., Porterfield, J. S., Russell, P. K., Shope, R. E. & Westaway, E. G. (1980).  Bunyaviridae. Intervirology 14, 125-143. [PubMed]

Booth, T. F., Gould, E. A. & Nuttall, P. A. (1991).  Structure and morphogenesis of Dugbe virus (Bunyaviridae, Nairovirus) studied by immunogold electron microscopy of ultrathin cryosections. Virus Res 21, 199-212. [PubMed]

Burt, F. J., Spencer, D. C., Leman, P. A., Patterson, B. & Swanepoel, R. (1996).  Investigation of tick-borne viruses as pathogens of humans in South Africa and evidence of Dugbe virus infection in a patient with prolonged thrombocytopenia. Epidemiol Infect 116, 353-361. [PubMed]

Converse, J. D., Hoogstraal, H., Moussa, M. I., Casals, J. & Kaiser, M. N. (1975).  Pretoria virus: a new African agent in the tickborne Dera Ghazi Khan (DGK) group and antigenic relationships within the DKG group. J Med Entomol 12, 202-205

Dacheux, L., Cervantes-Gonzalez, M., Guigon, G., Thiberge, J.-M., Vandenbogaert, M., Maufrais, C., Caro, V. & Bourhy, H. (2014).  A preliminary study of viral metagenomics of French bat species in contact with humans: identification of new mammalian viruses. PLoS One 9, e87194. [PubMed]

Doherty, R. L., Carley, J. G., Filippich, C. & Kay, B. H. (1976).  Isolation of virus-strains related to Kao-Shuan virus from Argas robertsi in Northern Territory, Australia. Search 7, 484-485

Edgar, R. C. (2004).  MUSCLE: a multiple sequence alignment method with reduced time and space complexity. BMC Bioinformatics 5, 113. [PubMed]

Ergünay, K., Dinçer, E., Kar, S., Emanet, N., Yalçınkaya, D., Polat Dinçer, P. F., Brinkmann, A., Hacıoğlu, S., Nitsche, A., Özkul, A. & Linton, Y.-M. (2020).  Multiple orthonairoviruses including Crimean-Congo hemorrhagic fever virus, Tamdy virus and the novel Meram virus in Anatolia. Ticks and Tick-borne Diseases 11, doi: 10.1016/j.ttbdis.2020.101448

Garrison, A. R., Radoshitzky, S. R., Kota, K. P., Pegoraro, G., Ruthel, G., Kuhn, J. H., Altamura, L. A., Kwilas, S. A., Bavari, S., Haucke, V. & Schmaljohn, C. S. (2013).  Crimean-Congo hemorrhagic fever virus utilizes a clathrin- and early endosome-dependent entry pathway. Virology 444, 45-54. [PubMed]

Gould, E. A., Chanas, A. C., Buckley, A. & Varma, M. G. R. (1983).  Immunofluorescence studies on the antigenic interrelationships of the Hughes virus serogroup (genus Nairovirus) and identification of a new strain. J Gen Virol 64, 739-742. [PubMed]

Holm, T., Kopicki, J.-D., Busch, C., Olschewski, S., Rosenthal, M., Uetrecht, C., Günther, S. & Reindl, S. (2018).  Biochemical and structural studies reveal differences and commonalities among cap-snatching endonucleases from segmented negative-strand RNA viruses. J Biol Chem 293, doi: 10.1074/jbc.RA1118.004373. [PubMed]

Käfer, S., Paraskevopoulou, S., Zirkel, F., Wieseke, N., Donath, A., Petersen, M., Jones, T. C., Liu, S., Zhou, X., Middendorf, M., Junglen, S., Misof, B. & Drosten, C. (2019).  Re-assessing the diversity of negative strand RNA viruses in insects. PLoS Pathog 15, e1008224. [PubMed]

Kearse, M., Moir, R., Wilson, A., Stones-Havas, S., Cheung, M., Sturrock, S., Buxton, S., Cooper, A., Markowitz, S., Duran, C., Thierer, T., Ashton, B., Meintjes, P. & Drummond, A. (2012).  Geneious Basic: an integrated and extendable desktop software platform for the organization and analysis of sequence data. Bioinformatics 28, 1647-1649. [PubMed]

L'vov, D. K., Kostûkov, M. A., Daniârov, O. A., Tuhtaev, T. M., Šerikov, B. K., Bun'etbekov, A. A., Bulyčev, V. P. & Gordeeva, È. E. (1984a).  Outbreak of arbovirus infection in the Tajik SSR caused by Issyk-kul virus (Issyk-kul fever) [Львов, Д. К., Костюков, М. А., Данияров, О. А., Тухтаев, Т. М., Шериков, Б. К., Буньетбеков, А. А., Булычев, В. П., & Гордеева, Э. Е. Вспышка арбовирусной инфекции в Таджикской ССР, вызванной вирусом Иссык-куль (Иссык-кульская лихорадка)]. Вопр Вирусол 29, 89-92. [PubMed]

L'vov, D. K., Sidorova, G. A., Gromaševskij, V. L., Skvorcova, T. M., Aristova, V. A., Ipatov, V. P., Neronov, V. M., Zakarân, V. A. & Karimov, S. K. (1984b).  Isolation of Tamdy virus (Bunyaviridae) pathogenic for humans from natural sources in Central Asia, Kazakhstan, and the Caucasus [Львов, Д. К., Сидорова, Г. А., Громашевский, В. Л., Скворцова, Т. М., Аристова, В. А., Ипатов, В. П., Неронов, В. M., Закарян, В. А., Каримов, С. К. Изоляция патогенного для человека вируса Тамды (Bunyaviridae) из природных источников в Центральной Азии, Казахстане и Кавказе]. Вопр Вирусол 29, 487-490. [PubMed]

Li, C.-X., Shi, M., Tian, J.-H., Lin, X.-D., Kang, Y.-J., Chen, L.-J., Qin, X.-C., Xu, J., Holmes, E.-C. & Zhang, Y.-Z. (2015).  Unprecedented genomic diversity of RNA viruses in arthropods reveals the ancestry of negative-sense RNA viruses. Elife 4, e05378. [PubMed]

Lvov, D. K. (1994).  Arboviral zoonoses of Northern Eurasia (Eastern Europe and the Commonwealth of Independent States. In Handbook of Zoonoses Section B: Viral, 2nd edn, pp. 237-260. Edited by G. W. Beran. Boca Raton, Florida, USA: CRC Press. 

Lvov, D. K., Shchelkanov, M. Y., Alkhovsky, S. V. & Deryabin, P. G. (2015).  Zoonotic viruses of northern Eurasia: taxonomy and ecology. Amsterdam, Netherlands: Elsevier. 

Moss, S. R., Petersen, Æ. & Nuttall, P. A. (1986).  Tick-borne viruses in Icelandic seabird colonies. Acta Nat Isl 32, 1-19

Nuttall, P. A., Carey, D., Moss, S. R., Green, B. M. & Spence, R. P. (1986).  Hughes group viruses (Bunyaviridae) from the seabird tick Ixodes (Ceratixodes) uriae (Acari, Ixodidae). J Med Entomol 23, 437-440

Price, M. N., Dehal, P. S. & Arkin, A. P. (2010).  FastTree 2 - approximately maximum-likelihood trees for large alignments. PLoS One 5, e9490. [PubMed]

Rambaut, A. (2020).  FigTree v1. 4. http://tree.bio.ed.ac.uk/software/figtree/. 

Ritter, D. G. & Feltz, E. T. (1974).  On the natural occurrence of California encephalitis virus and other arboviruses in Alaska. Can J Microbiol 20, 1359-1366

Rodhain, R., Metselaar, D., Ardoin, P., Hannoun, C., Shope, R. E. & Casals, J. (1985).  The Omo virus: a new virus from the Qalyub group (Bunyaviridae, Nairovirus) isolated from rodents in southern Ethiopia [Le virus Omo: Un nouveau virus du groupe Qalyub (Bunyaviridae, Nairovirus) isolé de rongeurs en éthiopie méridionale  [Le virus Omo: Un nouveau virus du groupe Qalyub (Bunyaviridae, Nairovirus) isolé de rongeurs en éthiopie méridionale]. Ann Inst Pasteur/Virol 136E, 243-247

Rwambo, P. M., Shaw, M. K., Rurangirwa, F. R. & DeMartini, J. C. (1996).  Ultrastructural studies on the replication and morphogenesis of Nairobi sheep disease virus, a Nairovirus. Arch Virol 141, 1479-1492. [PubMed]

Sanchez, A. J., Vincent, M. J., Erickson, B. R. & Nichol, S. T. (2006).  Crimean-Congo hemorrhagic fever virus glycoprotein precursor is cleaved by furin-like and SKI-1 proteases to generate a novel 38-kilodalton glycoprotein. J Virol 80, 514-525. [PubMed]

Shtanko, O., Nikitina, R. A., Altuntas, C. Z., Chepurnov, A. A. & Davey, R. A. (2014).  Crimean-Congo hemorrhagic fever virus entry into host cells occurs through the multivesicular body and requires ESCRT regulators. PLoS Pathog 10, e1004390. [PubMed]

Simon, M., Johansson, C. & Mirazimi, A. (2009).  Crimean-Congo hemorrhagic fever virus entry and replication is clathrin-, pH- and cholesterol-dependent. J Gen Virol 90, 210-215. [PubMed]

Surtees, R., Ariza, A., Punch, E. K., Trinh, C. H., Dowall, S. D., Hewson, R., Hiscox, J. A., Barr, J. N. & Edwards, T. A. (2015).  The crystal structure of the Hazara virus nucleocapsid protein. BMC Struct Biol 15, 24. [PubMed]

Vincent, M. J., Sanchez, A. J., Erickson, B. R., Basak, A., Chretien, M., Seidah, N. G. & Nichol, S. T. (2003).  Crimean-Congo hemorrhagic fever virus glycoprotein proteolytic processing by subtilase SKI-1. J Virol 77, 8640-8649. [PubMed]

Walker, P. J., Widen, S. G., Firth, C., Blasdell, K. R., Wood, T. G., Travassos da Rosa, A. P. A., Guzman, H., Tesh, R. B. & Vasilakis, N. (2015).  Genomic characterization of Yogue, Kasokero, Issyk-kul, Keterah, Gossas, and Thiafora viruses: nairoviruses naturally infecting bats, shrews, and ticks. Am J Trop Med Hyg 93, 1041-1051. [PubMed]

Wang, W., Liu, X., Wang, X., Dong, H., Ma, C., Wang, J., Liu, B., Mao, Y., Wang, Y., Li, T., Yang, C. & Guo, Y. (2015).  Structural and functional diversity of nairovirus-encoded nucleoproteins. J Virol 89, 11740-11749. [PubMed]

Whelan, S. & Goldman, N. (2001).  A general empirical model of protein evolution derived from multiple protein families using a maximum-likelihood approach. Mol Biol Evol 18, 691-699. [PubMed]

Wolf, Y. I., Kazlauskas, D., Iranzo, J., Lucía-Sanz, A., Kuhn, J. H., Krupovic, M., Dolja, V. V. & Koonin, E. V. (2018).  Origins and evolution of the global RNA virome. MBio 9, e02329-02318. [PubMed]