Argentinian mammarenavirus explained

Mammarenavirus juninense, better known as the Junin virus or Junín virus (JUNV),[1] is an arenavirus in the Mammarenavirus genus that causes Argentine hemorrhagic fever (AHF).[2] The virus took its original name from the city of Junín, around which the first cases of infection were reported, in 1958.

Virology

Structure

Argentinian mammarenavirus is a negative sense ssRNA enveloped virion with a variable diameter between 50 and 300 nm. The surface of the particle encompasses a layer of T-shaped glycoproteins, each extending up to 10 nm outwards from the envelope, which are important in mediating attachment and entry into host cells.

Genome

The Argentinian mammarenavirus genome is composed of two single-stranded RNA molecules, each encoding two different genes in an ambisense orientation. The two segments are termed 'short (S)' and 'long (L)' owing to their respective lengths. The short segment (around 3400 nucleotides in length) encodes the nucleocapsid protein and the glycoprotein precursor (GPC). The GPC is subsequently cleaved to form two viral glycoproteins, GP1 and GP2, which ultimately form the T-shaped glycoprotein spike which extends outwards from the viral envelope. https://web.archive.org/web/20070630181132/http://virology.ifas.ufl.edu/course/Arenavirus.ppt#285,14,Slide14. The long segment (around 7200 nucleotides in length) encodes the viral polymerase and a zinc-binding protein. The virus is spread by rodents.

Disease and epidemiology

A member of the genus Mammarenavirus, Argentinian mammarenavirus characteristically causes Argentine hemorrhagic fever (AHF). AHF leads to severe compromise of the vascular, neurological and immune systems and has a mortality rate between 20 and 30%.[3] Symptoms of the disease are conjunctivitis, purpura, petechiae and occasionally sepsis. The symptoms of the disease can be confusing; the condition can be mistaken for a different one, especially during the first week when it can resemble a flu.

Since the discovery of Argentinian mammarenavirus in 1958, the geographical distribution of the pathogen, although still confined to Argentina, has expanded. At the time of discovery, Argentinian mammarenavirus was confined to an area of around 15,000 km2. At the beginning of 2000, the region with reported cases grew to around 150,000 km2. The natural hosts of Argentinian mammarenavirus are rodents, particularly Mus musculus, Calomys spp. and Akodon azarae. Direct rodent-to-human transmission only takes place when a person makes direct contact with the excrement of an infected rodent; this can occur by ingestion of contaminated food or water, inhalation of particles in urine or direct contact of an open wound with rodent feces.

Prevention and control

An investigational (in the US) vaccine (Candid1[4]) was developed at the US Army Medical Research Institute for Infectious Disease (USAMRIID)[5] at Ft. Detrick, MD in the 1980s which has shown to be safe, well tolerated and effective in reducing mortality and morbidity due to AHF.[6] [7] [8] [9] The vaccine, which came from an XJ strain of the Argentinian mammarenavirus, was continually passaged a total of 44 times in newborn mouse brains, and a total of 19 times along with cloning in FRhL cells. Over 90% of the volunteers in Phase 1 and 2 clinical trials developed antibodies against the Argentinian mammarenavirus, and 99% developed an adequate immune response specific for Argentinian mammarenavirus. Moreover, a large efficacy study among 6,500 people, where 3,255 individuals were randomly selected to take Candid 1 and 3,245 individuals were randomly selected to take a placebo resulted in 23 cases of Junin-like infections, where 22 out of the 23 cases were from the placebo group. This efficacy study resulted in a 95% vaccine efficacy. Currently, the Candid 1 vaccine, otherwise known as the Junin vaccine, is licensed in Argentina by the regulatory agency of Argentina where Argentinian mammarenavirus is endemic to the region.[10] People in laboratories who come in constant contact with Argentinian mammarenavirus are also recommended to take the Junin vaccine to prevent transmission.[11]

References

  1. Web site: History of the taxon: Mammarenavirus juninense .
  2. Junín Virus Pathogenesis and Virus Replication . 2012 . . 3497054 . Junín virus, the etiological agent of Argentine hemorrhagic fever, causes significant morbidity and mortality.. Grant . A. . Seregin . A. . Huang . C. . Kolokoltsova . O. . Brasier . A. . Peters . C. . Paessler . S. . Viruses . 4 . 10 . 2317–2339 . 10.3390/v4102317 . 23202466 . free .
  3. Web site: Junin Virus . . Rebecca Wattam . 2004 . dead . https://web.archive.org/web/20060828224634/http://pathport.vbi.vt.edu/pathinfo/pathogens/Junin_virus.html . 2006-08-28 .
  4. Goñi. SE. Genomic features of attenuated Junín virus vaccine strain candidate. . Virus Genes . 2006 . 32 . 1 . 37–41 . 10.1007/s11262-005-5843-2 . 16525733 . 40149042 .
  5. Web site: McKee. Kelly. Safety and Immunogenicity of a Live-Attenuated Junin (Argentine Hemorrhagic Fever) Vaccine in Rhesus Monkeys. https://web.archive.org/web/20140201194743/http://www.dtic.mil/dtic/tr/fulltext/u2/a265569.pdf. live. February 1, 2014. American Journal of Tropical Medicine and Hygiene. 1993.
  6. Book: Enria. D. A.. Arenaviruses II. Oro. J. G. Barrera. Junin Virus Vaccines. 263. 2002. 239–261. 0070-217X. 10.1007/978-3-642-56055-2_12. Current Topics in Microbiology and Immunology. 11987817. 978-3-642-62724-8.
  7. Book: http://nihbrp.com/Citations/completed/HumanHealthEcologyTeam/JuninVirus/Enria_JuninVirus_MicrobiolImmun_2002.pdf . 2002 . Enria D.A. . Barrera Oro J.G. . Arenaviruses II . Junin Virus Vaccines . Current Topics in Microbiology and Immunology . 263 . 239–261 . 10.1007/978-3-642-56055-2_12 . 11987817 . 978-3-642-62724-8 . dead . https://web.archive.org/web/20140904203355/http://nihbrp.com/Citations/completed/HumanHealthEcologyTeam/JuninVirus/Enria_JuninVirus_MicrobiolImmun_2002.pdf . 2014-09-04 .
  8. Book: Arenaviruses. Field's Virology Third Edition. Peters CJ . Buchmeir M . Rollin Pierre E . Ksiazek Thomas G . 1996.
  9. Maiztegui JI, McKee KT Jr, Barrera Oro JG, Harrison LH, Gibbs PH, Feuillade MR, Enria DA, Briggiler AM, Levis SC, Ambrosio AM, Halsey NA, Peters CJ . February 1998 . Protective efficacy of a live attenuated vaccine against Argentine hemorrhagic fever. AHF Study Group . J Infect Dis . 177 . 2 . 277–283 . 10.1086/514211 . 9466512. free .
  10. Web site: Banco de Recursos de Comunicación del Ministerio de Salud de la Nación Calendario Nacional de Vacunación 2022 . 2023-05-25 . bancos.salud.gob.ar.
  11. Pittman, Phillip R., and Stanley A. Plotkin. (2013) "41 – Biodefense and Special Pathogen Vaccines." Biodefense and Special Pathogen Vaccines - Vaccines (Sixth Edition)