Henipavirus

Henipavirus is a genus of negative-strand RNA viruses in the family Paramyxoviridae, order Mononegavirales containing six established species,[1][2] and numerous others still under study.[3] Henipaviruses are naturally harboured by several species of small mammals, notably pteropid fruit bats (flying foxes), microbats of several species,[4] and shrews.[5][6] Henipaviruses are characterised by long genomes and a wide host range. Their recent emergence as zoonotic pathogens capable of causing illness and death in domestic animals and humans is a cause of concern.[7][8]

Henipavirus
Colored transmission electron micrograph of a Hendra henipavirus virion (ca. 300 nm length)
Virus classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Negarnaviricota
Class: Monjiviricetes
Order: Mononegavirales
Family: Paramyxoviridae
Subfamily: Orthoparamyxovirinae
Genus: Henipavirus
Species

In 2009, RNA sequences of three novel viruses in phylogenetic relationship to known henipaviruses were detected in African straw-colored fruit bats (Eidolon helvum) in Ghana. The finding of these novel henipaviruses outside Australia and Asia indicates that the region of potential endemicity of henipaviruses may be worldwide.[9] These African henipaviruses are slowly being characterised.[10]

Nipah and Hendra henipaviruses are both considered category C (USDA-HHS overlap) select agents.[11]

Structure

Structure of henipaviruses
The henipavirus genome (3’ to 5’ orientation) and products of the P gene

Henipavirions are pleomorphic (variably shaped), ranging in size from 40 to 600 nm in diameter.[12] They possess a lipid membrane overlying a shell of viral matrix protein. At the core is a single helical strand of genomic RNA tightly bound to N (nucleocapsid) protein and associated with the L (large) and P (phosphoprotein) proteins, which provide RNA polymerase activity during replication.

Embedded within the lipid membrane are spikes of F (fusion) protein trimers and G (attachment) protein tetramers. The function of the G protein (except in the case of MojV-G) is to attach the virus to the surface of a host cell via Ephrin B1, B2, or B3, a family of highly conserved mammalian proteins.[13][14][15] The structure of the attachment glycoprotein has been determined by X-ray crystallography.[16] The F protein fuses the viral membrane with the host cell membrane, releasing the virion contents into the cell. It also causes infected cells to fuse with neighbouring cells to form large, multinucleated syncytia.

Genome

Nipah virus (NiV) replication cycle

As all mononegaviral genomes, Hendra virus and Nipah virus genomes are non-segmented, single-stranded negative-sense RNA. Both genomes are 18.2 kb in length and contain six genes corresponding to six structural proteins.[17]

In common with other members of the Paramyxoviridae family, the number of nucleotides in the henipavirus genome is a multiple of six, consistent with what is known as the 'rule of six'.[18] Deviation from the rule of six, through mutation or incomplete genome synthesis, leads to inefficient viral replication, probably due to structural constraints imposed by the binding between the RNA and the N protein.

Henipaviruses employ an unusual process called RNA editing to generate multiple proteins from a single gene. The specific process in henipaviruses involves the insertion of extra guanosine residues into the P gene mRNA prior to translation. The number of residues added determines whether the P, V C, or W proteins are synthesised. The functions of the V and W proteins are unknown, but they may be involved in disrupting host antiviral mechanisms.

Causes of emergence

The emergence of henipaviruses parallels the emergence of other zoonotic viruses in recent decades. SARS coronavirus, Australian bat lyssavirus, Menangle virus, Marburg virus and possibly Ebola viruses are also harboured by bats, and are capable of infecting a variety of other species. The emergence of each of these viruses has been linked to an increase in contact between bats and humans, sometimes involving an intermediate domestic animal host. The increased contact is driven both by human encroachment into the bats' territory (in the case of Nipah, specifically pigpens in said territory) and by movement of bats towards human populations due to changes in food distribution and loss of habitat.

There is evidence that habitat loss for flying foxes, both in South Asia and Australia (particularly along the east coast) as well as encroachment of human dwellings and agriculture into the remaining habitats, is creating greater overlap of human and flying fox distributions.

Taxonomy

Genus Henipavirus: species and their viruses[19]
Genus Species Virus (Abbreviation)
Henipavirus Cedar henipavirus Cedar virus (CedV)
Ghanaian bat henipavirus Kumasi virus (KV)
Hendra henipavirus Hendra virus (HeV)
Mojiang henipavirus Mòjiāng virus (MojV)[3]
Nipah henipavirus Nipah virus (NiV)
Langya henipavirus Langya virus (LayV)[6][20]

See also

  • Animal viruses
  • Paramyxovirus

References

  1. Rima, B; Balkema-Buschmann, A; Dundon, WG; Duprex, WP; Easton, A; Fouchier, R; Kurath, G; Lamb, R; Lee, B; Rota, P; Wang, L; ICTV Report Consortium (December 2019). "ICTV Virus Taxonomy Profile: Paramyxoviridae". The Journal of General Virology. 100 (12): 1593–1594. doi:10.1099/jgv.0.001328. PMC 7273325. PMID 31609197.
  2. "ICTV Report Paramyxoviridae".
  3. Wu, Zhiqiang; et al. (2014). "Novel Henipa-like Virus, Mojiang Paramyxovirus, in Rats, China, 2012". Emerging Infectious Diseases. 20 (6): 1064–1066. doi:10.3201/eid2006.131022. PMC 4036791. PMID 24865545.
  4. Li, Y; Wang, J; Hickey, AC; Zhang, Y; Li, Y; Wu, Y; Zhang, Huajun; et al. (December 2008). "Antibodies to Nipah or Nipah-like viruses in bats, China [letter]". Emerging Infectious Diseases. 14 (12): 1974–6. doi:10.3201/eid1412.080359. PMC 2634619. PMID 19046545.
  5. Cheng, Amy (10 August 2022). "New Langya virus that may have spilled over from animals infects dozens". The Washington Post.
  6. Zhang, Xiao-Ai; et al. (2022). "A Zoonotic Henipavirus in Febrile Patients in China". The New England Journal of Medicine. 387 (5): 470–472. doi:10.1056/NEJMc2202705. PMID 35921459. S2CID 251315935.
  7. Sawatsky (2008). "Hendra and Nipah Virus". Animal Viruses: Molecular Biology. Caister Academic Press. ISBN 978-1-904455-22-6.
  8. "Nipah yet to be confirmed, 86 under observation: Shailaja". OnManorama. Retrieved 4 June 2019.
  9. Drexler JF, Corman VM, Gloza-Rausch F, Seebens A, Annan A (2009). Markotter W (ed.). "Henipavirus RNA in African Bats". PLOS ONE. 4 (7): e6367. Bibcode:2009PLoSO...4.6367D. doi:10.1371/journal.pone.0006367. PMC 2712088. PMID 19636378.
  10. Drexler JF, Corman VM; et al. (2012). "Bats host major mammalian paramyxoviruses". Nat Commun. 3: 796. Bibcode:2012NatCo...3..796D. doi:10.1038/ncomms1796. PMC 3343228. PMID 22531181.
  11. "Federal Select Agent Program". www.selectagents.gov. 8 January 2021. Retrieved 15 January 2021.
  12. Hyatt AD, Zaki SR, Goldsmith CS, Wise TG, Hengstberger SG (2001). "Ultrastructure of Hendra virus and Nipah virus within cultured cells and host animals". Microbes and Infection. 3 (4): 297–306. doi:10.1016/S1286-4579(01)01383-1. PMID 11334747.
  13. Bonaparte, M; Dimitrov, A; Bossart, K (2005). "Ephrin-B2 ligand is a functional receptor for Hendra virus and Nipah virus". Proceedings of the National Academy of Sciences. 102 (30): 10652–7. Bibcode:2005PNAS..10210652B. doi:10.1073/pnas.0504887102. PMC 1169237. PMID 15998730.
  14. Negrete OA, Levroney EL, Aguilar HC (2005). "EphrinB2 is the entry receptor for Nipah virus, an emergent deadly paramyxovirus". Nature. 436 (7049): 401–5. Bibcode:2005Natur.436..401N. doi:10.1038/nature03838. PMID 16007075. S2CID 4367038.
  15. Bowden, Thomas A.; Crispin, Max; Jones, E. Yvonne; Stuart, David I. (1 October 2010). "Shared paramyxoviral glycoprotein architecture is adapted for diverse attachment strategies". Biochemical Society Transactions. 38 (5): 1349–1355. doi:10.1042/BST0381349. PMC 3433257. PMID 20863312.
  16. Bowden, Thomas A.; Crispin, Max; Harvey, David J.; Aricescu, A. Radu; Grimes, Jonathan M.; Jones, E. Yvonne; Stuart, David I. (1 December 2008). "Crystal Structure and Carbohydrate Analysis of Nipah Virus Attachment Glycoprotein: a Template for Antiviral and Vaccine Design". Journal of Virology. 82 (23): 11628–11636. doi:10.1128/JVI.01344-08. PMC 2583688. PMID 18815311.
  17. Wang L, Harcourt BH, Yu M (2001). "Molecular biology of Hendra and Nipah viruses". Microbes and Infection. 3 (4): 279–87. doi:10.1016/S1286-4579(01)01381-8. PMID 11334745.
  18. Kolakofsky, D; Pelet, T; Garcin, D; Hausmann, S; Curran, J; Roux, L (February 1998). "Paramyxovirus RNA synthesis and the requirement for hexamer genome length: the rule of six revisited". Journal of Virology. 72 (2): 891–9. doi:10.1128/JVI.72.2.891-899.1998. PMC 124558. PMID 9444980.
  19. Amarasinghe, Gaya K.; Bào, Yīmíng; Basler, Christopher F.; Bavari, Sina; Beer, Martin; Bejerman, Nicolás; Blasdell, Kim R.; Bochnowski, Alisa; Briese, Thomas (7 April 2017). "Taxonomy of the order Mononegavirales: update 2017". Archives of Virology. 162 (8): 2493–2504. doi:10.1007/s00705-017-3311-7. ISSN 1432-8798. PMC 5831667. PMID 28389807.
  20. "Zoonotic Langya virus found in China, CDC says - Taipei Times". 9 August 2022.
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