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Arenavirus

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Arenaviridae
(A) Electron micrograph of Lassa virus, bar = 100nm (B) diagram and (C) genome of arenavirus
Virus classification Edit this classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Negarnaviricota
Class: Ellioviricetes
Order: Bunyavirales
Family: Arenaviridae
Genera

An arenavirus is a bi- or trisegmented ambisense RNA virus that is a member of the family Arenaviridae.[1][2] These viruses infect rodents and occasionally humans. A class of novel, highly divergent arenaviruses, properly known as reptarenaviruses, have also been discovered which infect snakes to produce inclusion body disease, mostly in boa constrictors. At least eight arenaviruses are known to cause human disease. The diseases derived from arenaviruses range in severity. Aseptic meningitis, a severe human disease that causes inflammation covering the brain and spinal cord, can arise from the lymphocytic choriomeningitis virus. Hemorrhagic fever syndromes, including Lassa fever, are derived from infections such as Guanarito virus, Junin virus, Lassa virus, Lujo virus,[3] Machupo virus, Sabia virus, or Whitewater Arroyo virus.[4] Because of the epidemiological association with rodents, some arenaviruses and bunyaviruses are designated as roboviruses.

Structure

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Mammarenavirus structure and genome composition.

Viewed in cross-section, arenaviruses contain grainy particles that are ribosomes acquired from their host cells. It is from this characteristic that they acquired the name arena, from the Latin root meaning sand.[5] The ribosomal structures are not believed to be essential for virus replication. Virus particles, or virions, are pleomorphic (variable in shape) but are often spherical, with a diameter of 60–300 nm, and are covered with surface glycoprotein spikes.[6]

The virus contains a beaded nucleocapsid with two single-stranded RNA segments. The nucleocapsid consists of a core of nucleic acid enclosed in a protein coat. Although they are categorized as negative-sense viruses,[7] arenaviruses are ambisense. While sections of their genome encode genes in the negative sense (reverse polarity), other sections encode genes in the opposite (forward/positive sense) direction. This complex gene expression structure is theorized to be a primitive regulatory system, allowing the virus to control what proteins are synthesized at what point in the life cycle. The life cycle of the arenavirus is restricted to the cell cytoplasm.[citation needed]

Genome

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Genomes of Arenaviridae

Arenaviruses have a segmented RNA genome that consists of two single-stranded ambisense RNAs.[8] As with all negative-sense RNA viruses, the genomic RNA alone is not infectious and the viral replication machinery is required to initiate infection within a host cell.[9] Genomic sense RNA packaged into the arenavirus virion is designated negative-sense RNA, and must first be copied into a positive-sense mRNA in order to produce viral protein.[10] The RNA segments are denoted Small (S), Medium (M; if present), and Large (L),[8][11] and code for four viral proteins in a unique ambisense coding strategy.[12][13] For mammarenaviruses and reptarenaviruses, each RNA segment codes for two viral proteins in opposite orientation such that the negative-sense RNA genome serves as the template for transcription of a single mRNA and the positive-sense copy of the RNA genome templates a second mRNA.[10] The separate coding sequences of the two viral proteins are divided by an intergenic region RNA sequence that is predicted to fold into a stable hairpin structure.[14]

The extreme termini of each RNA segment contains a 19 nucleotide highly conserved sequence that is critical for recruitment of the viral replication machinery and initiation of viral mRNA transcription and genomic replication.[15][16][17][18][19] The conserved 5' and 3' RNA termini sequences are complementary and allows each RNA segment to adopt a double-stranded RNA panhandle structure[20] that maintains the termini in close proximity and results in a circular appearance to purified arenavirus genomic templates visualized by electron microscopy.[21][22] The double-stranded RNA panhandle structure is critical for efficient viral RNA synthesis,[18][23] but potential interterminal double-stranded RNA interactions must be transiently relieved in order to recruit the viral polymerase.[19]

The S-segment RNA is approximately 3.5 kb, and encodes the viral nucleocapsid protein (NP) and glycoprotein (GPC).[24] The L-segment RNA is approximately 7.2 kb, and encodes the viral RNA-dependent RNA-polymerase (L) and a small RING-domain containing protein (Z).[25][26][27]

The Z protein forms homo oligomers and a structural component of the virions.[28] The formation of these oligomers is an essential step for particle assembly and budding. Binding between Z and the viral envelope glycoprotein complex is required for virion infectivity. Z also interacts with the L and NP proteins. Polymerase activity appears to be modulated by the association between the L and Z proteins. Interaction between the Z and NP proteins is critical for genome packaging.[citation needed]

Microbiology

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Arenavirus replication cycle.

The glycoprotein (GP) is synthesised as a precursor molecule.[29] It is cleaved into three parts - GP1, GP2 and a stable signal peptide (SSP). These reactions are catalysed by cellular signal peptidases and the cellular enzyme Subtilisin Kexin Isozyme-1 (SKI-1)/Site-1 Protease (S1P). These processes are essential for fusion competence and incorporation of mature GP into nascent budding virion particles.[citation needed]

Taxonomy

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Within the family Arenaviridae, arenaviruses were formerly all placed in the genus Arenavirus, but in 2015 were divided into the genera Mammarenavirus for those with mammalian hosts and Reptarenavirus for those infecting snakes.[30][31] Reptarenaviruses and mammarenavirus are separated by an impenetrable species barrier. Infected rodents cannot pass disease onto snakes, and IBD in captive snakes is not transmissible to humans.[citation needed]

A third genus, Hartmanivirus (not to be confused with genus Haartmanvirus of vibrio phages in family Demerecviridae, order Caudovirales), has also been established,[32] including other species that infect snakes. The organisation of the genome of this genus is typical of arenaviruses but their glycoproteins resemble those of filoviruses. Species in this genus lack the matrix protein.[33]

A fourth genus, Antennavirus, has also been established[34] to accommodate two arenaviruses found in striated frogfish (Antennarius striatus).[35] A third antennavirus has been detected in Chinook salmon and sockeye salmon.[36]

Mammarenaviruses can be divided into two serogroups, which differ genetically and by geographical distribution:[37] When the virus is classified "Old World" this means it was found in the Eastern Hemisphere in places such as Europe, Asia, and Africa. When it is found in the Western Hemisphere, in places such as Argentina, Bolivia, Venezuela, Brazil, and the United States, it is classified "New World". Lymphocytic choriomeningitis (LCM) virus is the only mammarenavirus found worldwide because of its ubiquitous Old World host, the house mouse. Old and New World area viruses appear to have diverged ~45,000 years ago.[38] The Old World Mammarenaviruses originated ~23.1-1.88 thousand years ago, most likely in Southern Africa, while the New World Mammarenaviruses evolved in the Latin America-Caribbean region ~41.4-3.3 thousand years ago.[38]

Mammarenavirus

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Old World complex

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Arenavirus taxonomy and location

New World complex

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Reptarenavirus

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Hartmanivirus

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Antennavirus

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Evolution

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The evolution of the Mammarenavirus genus has been studied.[38] The New World and Old World species diverged less than 45,000 years ago. The New World species evolved between 41,400 and 3,300 years ago in the Latin America-Caribbean region. The Old World species evolved between 23,100 and 1,880 years ago, most likely in southern Africa.[38]

Reservoirs

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Some arenaviruses are zoonotic pathogens and are generally associated with rodent—transmitted disease in humans. Each virus usually is associated with a particular rodent host species in which it is maintained. Arenaviruses persist in nature by infecting rodents first and then transmitted into humans. Humans can be infected through mucosal exposure to aerosols, or by direct contact of abraded skin with the infectious material, derived from infected rodents.[6] Aerosols are fine mists or sprays of rodent dried excreta, especially urine that is dropped in the environment. Most of the Arenaviruses caught by humans are within their own homes when these rodents seek shelter. The virus can be caught in factories, from food that has been contaminated, or within agricultural work areas. Humans' risk of contracting the Arenavirus infection is related to age, race, or sex within the degree of contact with the dried rodent excreta.[citation needed]

Epidemiology

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Hosts

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Arenavirus diseases and hosts
Virus Disease Host Distribution
Dandenong[39] Dandenong hemorrhagic fever Unknown old world ( Australian cases from Serbia )
Lymphocytic choriomeningitis virus Lymphocytic choriomeningitis House mouse (Mus musculus) Worldwide
Lassa virus Lassa fever Natal Multimammate Mouse (Mastomys natalensis) West Africa
Junin virus Argentine hemorrhagic fever Drylands Vesper Mouse (Calomys musculinus) Argentina
Machupo virus Bolivian hemorrhagic fever Large Vesper Mouse (Calomys callosus) Bolivia
Guanarito virus Venezuelan hemorrhagic fever Short-tailed Cane Mouse (Zygodontomys brevicauda) Venezuela
Sabiá virus Brazilian hemorrhagic fever Unknown Brazil
Tacaribe virus Bat (Artibeus) Trinidad
Flexal virus Influenza-like illness Rice rat (Oryzomys) Brazil
Whitewater Arroyo virus Hemorrhagic fever Woodrat (Neotoma) Southwestern United States

Clinical diseases

[edit]
Comparison of disease phenotypes of OW and NW arenaviruses
  1. Lymphocytic choriomeningitis (LCM) viruses cause influenza-like febrile illness, but occasionally they may cause meningitis, characteristically accompanied by large numbers of lymphocytes in the cerebrospinal fluid (as the name LCM suggests).
  2. Lassa virus causes Lassa fever. Lassa fever is endemic in west Africa. The virus was first isolated from Americans stationed in the village of Lassa, Nigeria. The virus can be transmitted person-to-person.
    • Subclinical diseases: Serological studies suggest that inapparent infections particularly among members of hunting tribes are common.
    • Clinical infections: Lassa fever is characterised by high fever, severe myalgia, coagulopathy, haemorrhagic skin rash, and occasional visceral haemorrhage as well as necrosis of liver and spleen.
  3. Other Arenaviruses like Junin virus, Machupo virus cause haemorrhagic fevers.

All of these diseases pose a great threat to public health in the regions where it is taking place. For example, when the Old World Lassa virus turns into Lassa fever, this usually results in a significant amount of mortality. Similarly the New World Junin virus causes Argentine hemorrhagic fever. This fever is a severe illness with hemorrhagic and neurological manifestations and a case fatality of fifteen to thirty percent.[6] The way this virus spreads is through increased traveling to and from endemic regions. This traveling has led to the importation of Lassa fever into non-endemic metropolitan areas all over the world.

Recent outbreaks

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A new species of arenavirus named the Lujo virus has been linked to five patients who exhibited symptoms of viral hemorrhagic fever in South Africa.[40] The disease originated near Lusaka, Zambia and spread to Johannesburg, South Africa, after the first patient was transported to a hospital there. The results of genetic sequencing tests conducted by epidemiologists at Columbia University in New York City, USA, and at the Special Pathogens Branch of the Centers for Disease Control in Atlanta, USA, provided evidence that the causative agent of the disease is a virus from the family Arenaviridae, which ultimately resulted in the deaths of four out of the five infected in Zambia and South Africa during the outbreak which began in September 2008.[citation needed]

Arenavirus has also pinpointed as the cause of death of three donor organ recipients in Australia who contracted the virus after receiving kidney and a liver donations from a single infected organ donor in late 2006. All three died in the first week of 2007.[41][42]

WHO and its Global Outbreak Alert and Response Network (GOARN) partners continue to support the Ministries of Health of the two countries in various facets of the outbreak investigation, including laboratory diagnosis, investigations, active case finding and follow-up of contacts.[43]

Treatments

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Very few treatment methods are available. The current lack of a licensed vaccine and limited therapeutic options for the arenavirus make it arguably among the most neglected virus groups. The only licensed drug for the treatment of human arenavirus infection is the nucleoside analogue ribavirin.[44] Ribavirin reduces morbidity and mortality in humans infected with certain arenaviruses, such as LASV and JUNV infections, if it is taken in the early stages of the disease. Ribavirin displays mixed success in treating severe arenaviral disease and is associated with significant toxicities.[45]

Experimental approaches

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Effective antiviral drugs need to be produced at a low cost, taken orally, and able to withstand tropical climates due to the regions where these infections are occurring. For this reason high throughput screening (HTS) of small molecular libraries could be the answer to finding a better remedy. HTS collects libraries of small synthetic molecules that can be used to identify protein promoting "agonist" molecules or protein inhibiting "antagonist" interactions.[44] With HTS sustainable antiviral drugs can be discovered against possible new human pathogenic viruses.

Immunotherapy is another potential approach. Monoclonal antibodies against Junin virus have been tested in animal models. An immunotherapeutic agent active against all tested mammarenaviruses that use the transferrin receptor 1 as their receptor was under investigation in 2020.[46]

References

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  1. ^ Radoshitzky, SR; Buchmeier, MJ; Charrel, RN; Clegg, JCS; Gonzalez, JJ; Günther, S; Hepojoki, J; Kuhn, JH; Lukashevich, IS; Romanowski, V; Salvato, MS; Sironi, M; Stenglein, MD; de la Torre, JC; ICTV Report, Consortium (August 2019). "ICTV Virus Taxonomy Profile: Arenaviridae". The Journal of General Virology. 100 (8): 1200–1201. doi:10.1099/jgv.0.001280. hdl:10281/509719. PMID 31192784.
  2. ^ Shi, Mang; Lin, Xian-Dan; Chen, Xiao; Tian, Jun-Hua; Chen, Liang-Jun; Li, Kun; Wang, Wen; Eden, John-Sebastian; Shen, Jin-Jin; Li, Liu; Holmes, Edward C.; Zhang, Yong-Zhen (2018). "The evolutionary history of vertebrate RNA viruses". Nature. 561 (7722): 202. doi:10.1038/s41586-018-0310-0. PMID 29946168. S2CID 49433735.
  3. ^ Briese T, Paweska JT, McMullan LK, et al. (May 2009). "Genetic detection and characterization of Lujo virus, a new hemorrhagic fever-associated arenavirus from southern Africa". PLOS Pathog. 5 (5): e1000455. doi:10.1371/journal.ppat.1000455. PMC 2680969. PMID 19478873.
  4. ^ Botten, J; Whitton, JL; Barrowman, P; Sidney, J; Whitmire, JK; Alexander, J; Kotturi, MF; Sette, A; Buchmeier, MJ (2010). "A Multivalent Vaccination Strategy for the Prevention of Old World Arenavirus Infection in Humans". Journal of Virology. 84 (19): 9947–56. doi:10.1128/JVI.00672-10. PMC 2937778. PMID 20668086.
  5. ^ Rowe, Wallace P.; Murphy, Frederick A.; Bergold, Gernot H.; Casals, Jordi; Hotchin, John; Johnson, Karl M.; Lehmann-Grube, Fritz; Mims, Cedric A.; Traub, Eric; Webb, Patricia A. (May 1970). "Arenoviruses: Proposed Name for a Newly Defined Virus Group". Journal of Virology. 5 (5): 652. doi:10.1128/jvi.5.5.651-652.1970. PMC 376052. PMID 4986852.
  6. ^ a b c Emonet, Sebastien E.; Urata, Shuzo; De La Torre, Juan C. (2011). "Arenavirus reverse genetics: New approaches for the investigation of arenavirus biology and development of antiviral strategies". Virology. 411 (2): 416–425. doi:10.1016/j.virol.2011.01.013. PMC 3057228. PMID 21324503.
  7. ^ "Arenaviridae - Negative Sense RNA Viruses - Negative Sense RNA Viruses (2011)". International Committee on Taxonomy of Viruses (ICTV). Archived from the original on 19 December 2018. Retrieved 23 May 2019.
  8. ^ a b Añón MC, Grau O, Segovia ZM, Franzefernández MT (June 1976). "RNA composition of Junin virus". J. Virol. 18 (3): 833–8. doi:10.1128/JVI.18.3.833-838.1976. PMC 354781. PMID 178925.
  9. ^ Lee KJ, Novella IS, Teng MN, Oldstone MB, de La Torre JC (April 2000). "NP and L proteins of lymphocytic choriomeningitis virus (LCMV) are sufficient for efficient transcription and replication of LCMV genomic RNA analogs". J. Virol. 74 (8): 3470–7. doi:10.1128/jvi.74.8.3470-3477.2000. PMC 111854. PMID 10729120.
  10. ^ a b Meyer BJ, de la Torre JC, Southern PJ (2002). "Arenaviruses: Genomic RNAs, Transcription, and Replication". Arenaviruses I. Current Topics in Microbiology and Immunology. Vol. 262. pp. 139–57. doi:10.1007/978-3-642-56029-3_6. ISBN 978-3-540-42244-0. PMID 11987804. {{cite book}}: |journal= ignored (help)
  11. ^ Pedersen IR (March 1973). "Different classes of ribonucleic acid isolated from lymphocytic choriomeningitis virus". J. Virol. 11 (3): 416–23. doi:10.1128/JVI.11.3.416-423.1973. PMC 355116. PMID 4734917.
  12. ^ Auperin DD, Romanowski V, Galinski M, Bishop DH (December 1984). "Sequencing studies of pichinde arenavirus S RNA indicate a novel coding strategy, an ambisense viral S RNA". J. Virol. 52 (3): 897–904. doi:10.1128/JVI.52.3.897-904.1984. PMC 254611. PMID 6492264.
  13. ^ Auperin DD, McCormick JB (February 1989). "Nucleotide sequence of the Lassa virus (Josiah strain) S genome RNA and amino acid sequence comparison of the N and GPC proteins to other arenaviruses". Virology. 168 (2): 421–5. doi:10.1016/0042-6822(89)90287-0. PMID 2916333.
  14. ^ Auperin DD, Galinski M, Bishop DH (April 1984). "The sequences of the N protein gene and intergenic region of the S RNA of pichinde arenavirus". Virology. 134 (1): 208–19. doi:10.1016/0042-6822(84)90286-1. PMID 6324469.
  15. ^ Auperin D, Dimock K, Cash P, Rawls WE, Leung WC, Bishop DH (January 1982). "Analyses of the genomes of prototype pichinde arenavirus and a virulent derivative of Pichinde Munchique: evidence for sequence conservation at the 3' termini of their viral RNA species". Virology. 116 (1): 363–7. doi:10.1016/0042-6822(82)90429-9. PMID 6278715.
  16. ^ Auperin DD, Compans RW, Bishop DH (August 1982). "Nucleotide sequence conservation at the 3' termini of the virion RNA species of New World and Old World arenaviruses". Virology. 121 (1): 200–3. doi:10.1016/0042-6822(82)90130-1. PMID 6287720.
  17. ^ Mattsson L (1989). "Chronic non-A, non-B hepatitis with special reference to the transfusion-associated form". Scand J Infect Dis Suppl. 59: 1–55. doi:10.3109/inf.1988.20.suppl-59.01. PMID 2502835.
  18. ^ a b Hass M, Westerkofsky M, Müller S, Becker-Ziaja B, Busch C, Günther S (December 2006). "Mutational analysis of the lassa virus promoter". J. Virol. 80 (24): 12414–9. doi:10.1128/JVI.01374-06. PMC 1676312. PMID 17005649.
  19. ^ a b Kranzusch PJ, Schenk AD, Rahmeh AA, et al. (November 2010). "Assembly of a functional Machupo virus polymerase complex". Proc. Natl. Acad. Sci. U.S.A. 107 (46): 20069–74. Bibcode:2010PNAS..10720069K. doi:10.1073/pnas.1007152107. PMC 2993349. PMID 20978208.
  20. ^ Bishop DH, Auperin DD (1987). "Arenavirus Gene Structure and Organization". Arenaviruses. Current Topics in Microbiology and Immunology. Vol. 133. pp. 5–17. doi:10.1007/978-3-642-71683-6_2. ISBN 978-3-642-71685-0. PMID 2435460. {{cite book}}: |journal= ignored (help)
  21. ^ Young PR, Howard CR (April 1983). "Fine structure analysis of Pichinde virus nucleocapsids". J. Gen. Virol. 64 (4): 833–42. doi:10.1099/0022-1317-64-4-833. PMID 6682139.
  22. ^ Palmer EL, Obijeski JF, Webb PA, Johnson KM (September 1977). "The circular, segmented nucleocapsid of an arenavirus-Tacaribe virus". J. Gen. Virol. 36 (3): 541–5. doi:10.1099/0022-1317-36-3-541. PMID 199698.
  23. ^ Perez M, de la Torre JC (January 2003). "Characterization of the genomic promoter of the prototypic arenavirus lymphocytic choriomeningitis virus". J. Virol. 77 (2): 1184–94. doi:10.1128/jvi.77.2.1184-1194.2003. PMC 140842. PMID 12502835.
  24. ^ Ghiringhelli PD, Rivera-Pomar RV, Lozano ME, Grau O, Romanowski V (September 1991). "Molecular organization of Junin virus S RNA: complete nucleotide sequence, relationship with other members of the Arenaviridae and unusual secondary structures". J. Gen. Virol. 72 (9): 2129–41. CiteSeerX 10.1.1.325.5606. doi:10.1099/0022-1317-72-9-2129. PMID 1654373.
  25. ^ Iapalucci S, López N, Rey O, Zakin MM, Cohen GN, Franze-Fernández MT (November 1989). "The 5' region of Tacaribe virus L RNA encodes a protein with a potential metal binding domain". Virology. 173 (1): 357–61. doi:10.1016/0042-6822(89)90257-2. PMID 2510403.
  26. ^ Iapalucci S, Lopez R, Rey O, et al. (May 1989). "Tacaribe virus L gene encodes a protein of 2210 amino acid residues". Virology. 170 (1): 40–7. doi:10.1016/0042-6822(89)90349-8. PMID 2718387.
  27. ^ Salvato MS, Shimomaye EM (November 1989). "The completed sequence of lymphocytic choriomeningitis virus reveals a unique RNA structure and a gene for a zinc finger protein". Virology. 173 (1): 1–10. doi:10.1016/0042-6822(89)90216-X. PMID 2510401.
  28. ^ Loureiro ME, D'Antuono A, Levingston Macleod JM, López N (September 2012). "Uncovering viral protein-protein interactions and their role in arenavirus life cycle". Viruses. 4 (9): 1651–67. doi:10.3390/v4091651. PMC 3499824. PMID 23170177.
  29. ^ Burri DJ, da Palma JR, Kunz S, Pasquato A (October 2012). "Envelope glycoprotein of arenaviruses". Viruses. 4 (10): 2162–81. doi:10.3390/v4102162. PMC 3497046. PMID 23202458.
  30. ^ ICTV proposals 2014.011a-dV et al. Archived 4 March 2016 at the Wayback Machine, Mark D. Stenglein et al.
  31. ^ ICTV proposals 2014.012aV et al. Archived 4 March 2016 at the Wayback Machine, Michael J. Buchmeier et al.
  32. ^ Stenglein MD, Sanders C, Kistler AL, et al. (2012). "Identification, characterization, and in vitro culture of highly divergent arenaviruses from boa constrictors and annulated tree boas: candidate etiological agents for snake inclusion body disease". mBio. 3 (4): e00180–12. doi:10.1128/mBio.00180-12. PMC 3419519. PMID 22893382.
  33. ^ Hepojoki, Jussi; Hepojoki, Satu; Smura, Teemu; Szirovicza, Leonóra; Dervas, Eva; Prähauser, Barbara; Nufer, Lisbeth; Schraner, Elisabeth M.; Vapalahti, Olli; Kipar, Anja; Hetzel, Udo (2018). "Characterization of Haartman Institute snake virus-1 (HISV-1) and HISV-like viruses—The representatives of genus Hartmanivirus, family Arenaviridae". PLOS Pathogens. 14 (11): e1007415. doi:10.1371/journal.ppat.1007415. PMC 6261641. PMID 30427944.
  34. ^ "Virus Taxonomy: 2019 Release". talk.ictvonline.org. International Committee on Taxonomy of Viruses. Retrieved 6 May 2020.
  35. ^ Zhang YZ, Wu WC, Shi M, Holmes EC (2018) The diversity, evolution and origins of vertebrate RNA viruses. Curr Opin Virol 31:9-16
  36. ^ Mordecai, GJ; Miller, KM; Di Cicco, E; Schulze, AD; Kaukinen, KH; Ming, TJ; Li, S; Tabata, A; Teffer, A; Patterson, DA; Ferguson, HW; Suttle, CA (2019). "Endangered wild salmon infected by newly discovered viruses". eLife. 8: e47615. doi:10.7554/eLife.47615. PMC 6721791. PMID 31478480.
  37. ^ Delgado S, Erickson BR, Agudo R, et al. (April 2008). "Chapare virus, a newly discovered arenavirus isolated from a fatal hemorrhagic fever case in Bolivia". PLOS Pathog. 4 (4): e1000047. doi:10.1371/journal.ppat.1000047. PMC 2277458. PMID 18421377.
  38. ^ a b c d Forni, D; Pontremoli, C; Pozzoli, U; Clerici, M; Cagliani, R; Sironi, M (1 March 2018). "Ancient evolution of Mammarenaviruses: Adaptation via changes in the L protein and no evidence for host-virus codivergence". Genome Biology and Evolution. 10 (3): 863–874. doi:10.1093/gbe/evy050. PMC 5863214. PMID 29608723. Retrieved 16 February 2019.
  39. ^ Paweska, Janusz T.; Sewlall, Nivesh H.; Ksiazek, Thomas G.; Blumberg, Lucille H.; Hale, Martin J.; Lipkin, W. Ian; Weyer, Jacqueline; Nichol, Stuart T.; Rollin, Pierre E.; McMullan, Laura K.; Paddock, Christopher D.; Briese, Thomas; Mnyaluza, Joy; Dinh, Thu-Ha; Mukonka, Victor; Ching, Pamela; Duse, Adriano; Richards, Guy; de Jong, Gillian; Cohen, Cheryl; Ikalafeng, Bridget; Mugero, Charles; Asomugha, Chika; Malotle, Mirriam M.; Nteo, Dorothy M.; Misiani, Eunice; Swanepoel, Robert; Zaki, Sherif R. (October 2009). "Nosocomial Outbreak of Novel Arenavirus Infection, Southern Africa". Emerging Infectious Diseases. 15 (10): 1598–1602. doi:10.3201/eid1510.090211. PMC 2866397. PMID 19861052.
  40. ^ Scientists identify new lethal virus in Africa
  41. ^ "Three women had organ transplants from one donor. They all died in the same week". ABC News. 10 October 2020. Retrieved 11 October 2020.
  42. ^ "Virus identified - nurse ill". News24.com. Archived from the original on 13 October 2008. Retrieved 13 October 2008.
  43. ^ "Virus kills organ recipients". www.theage.com.au. Retrieved 16 October 2009.
  44. ^ a b Lee, A. M.; Pasquato, A.; Kunz, S. (2011). "Novel approaches in anti-arenaviral drug development". Virology. 411 (2): 163–169. doi:10.1016/j.virol.2010.11.022. PMC 3057354. PMID 21183197.
  45. ^ Mendenhall, M.; Russell, A.; Juelich, T.; Messina, E. L.; Smee, D. F.; Freiberg, A. N.; Holbrook, M. R.; Furuta, Y.; et al. (2010). "T-705 (Favipiravir) Inhibition of Arenavirus Replication in Cell Culture". Antimicrobial Agents and Chemotherapy. 55 (2): 782–787. doi:10.1128/AAC.01219-10. PMC 3028760. PMID 21115797.
  46. ^ Hadas Cohen-Dvashi; Ron Amon; Krystle N. Agans; Robert W. Cross; Aliza Borenstein-Katz; Mathieu Mateo; Sylvain Baize; Vered Padler-Karavani; Thomas W. Geisbert; Ron Diskin (2020). "Rational design of universal immunotherapy for TfR1-tropic arenaviruses". Nature Communications. 11 (1): 67. Bibcode:2020NatCo..11...67C. doi:10.1038/s41467-019-13924-6. PMC 6941993. PMID 31900422.
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