Orthopoxvirus

(Redirected from Orthopox)

Orthopoxvirus is a genus of viruses in the family Poxviridae and subfamily Chordopoxvirinae. Vertebrates, including mammals and humans, and arthropods serve as natural hosts. There are 12 species in this genus. Diseases associated with this genus include smallpox, cowpox, horsepox, camelpox, and mpox.[1][2] The most widely known member of the genus is Variola virus, which causes smallpox. It was eradicated globally by 1977, through the use of Vaccinia virus as a vaccine. The most recently described species is the Borealpox virus, first isolated in 2015.[3]

Orthopoxvirus
Virus classification Edit this classification
(unranked): Virus
Realm: Varidnaviria
Kingdom: Bamfordvirae
Phylum: Nucleocytoviricota
Class: Pokkesviricetes
Order: Chitovirales
Family: Poxviridae
Subfamily: Chordopoxvirinae
Genus: Orthopoxvirus
Species

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Microbiology

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Structure

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Schematic drawing of (cross section) of Orthopoxvirus virions (one enveloped, one not) and structural proteins

Orthopoxviruses are enveloped with brick-shaped geometries and virion dimensions around 200 nm wide and 250 nm long.[1]

Genome

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Member viruses have linear double-stranded DNA genomes around 170–250 kb in length.[1]

Lifecycle

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Orthopoxvirus replication cycle

Viral replication is cytoplasmic. Entry into the host cell is achieved by attachment of the viral proteins to host glycosaminoglycans (GAGs), which mediate cellular endocytosis of the virus. Fusion of the viral envelope with the plasma membrane releases the viral core into the host cytoplasm. Expression of early-phase genes by viral RNA polymerase begins at 30 minutes after infection. The viral core is completely uncoated as early expression ends, releasing the viral genome into the cytoplasm. At this point, intermediate genes are expressed, triggering genomic DNA replication by the viral DNA polymerase about 100 minutes post-infection. Replication follows the DNA strand displacement model. Late genes are expressed from 140 min to 48 hours postinfection, producing all viral structural proteins. Assembly of progeny virions begins in cytoplasmic viral factories, producing a spherical immature particle. This virus particle matures into the brick-shaped intracellular mature virion, which can be released upon cell lysis, or can acquire a second membrane from the Golgi apparatus and bud as extracellular enveloped virions. In this latter case, the virion is transported to the plasma membrane via microtubules.[1]

Transmission

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Natural hosts of orthopoxviruses are mammals and arthropods. Member viruses are transmitted by respiratory droplets, contact, and zoonosis.[1]

Distribution

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Some orthopoxviruses, including the mpox, cowpox, and buffalopox viruses, have the ability to infect non-reservoir species. Others, such as ectromelia and camelpox viruses, are highly host-specific. Vaccinia virus, maintained in vaccine institutes and research laboratories, has a very wide host range. Vaccine-derived vaccinia has been found replicating in the wild in Brazil, where it has caused infections in rodents, cattle, and even humans.[4] Following the eradication of variola virus, camelpox has become one of the most economically important Orthopoxvirus infections, because many subsistence-level nomadic communities depend heavily on camels.[citation needed]

Taxonomy

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The genus contains the following species:

Members of the Orthopox genus[5]
Species Common name
Orthopoxvirus abatinomacacapox Abatino macacapox virus, orthopoxvirus Abatino
Orthopoxvirus akhmetapox Akhmeta virus
Orthopoxvirus camelpox camelpox virus
Orthopoxvirus cowpox cowpox virus
Orthopoxvirus ectromelia ectromelia virus
Orthopoxvirus monkeypox monkeypox virus
Orthopoxvirus raccoonpox raccoonpox virus
Orthopoxvirus skunkpox skunkpox virus
Orthopoxvirus taterapox taterapox virus
Orthopoxvirus vaccinia vaccinia virus
Orthopoxvirus variola variola virus
Orthopoxvirus volepox volepox virus

The related Borealpox virus, also known as Alaskapox virus, has not been classified as of 2024.[3][5]

Evolution

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Among the path of evolution of the Orthopoxvirus species, many genes are truncated (but still functional), fragmented, or lost. Cowpox strains tend to have the most intact genes. Predicting the phylogeny by sequence or by gene content produces somewhat different results:[6]

Orthopoxvirus phylogeny
By sequence By gene content

Orthopoxvirus ectromelia

Some of the differences in the two trees are attributed to the procedure of passage in producing vaccinia strains. The Modified vaccinia Ankara strain in this regard has much gene loss related to in vitro passage, and horsepox being a vaccinia strain found in a natural outbreak has less.[6]

Infection in humans

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Zoonoses

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Following the eradication of the human-specific variola virus (smallpox), all human Orthopoxvirus infections are zoonoses.[7] Mpox occurs naturally only in Africa, particularly in the Democratic Republic of the Congo.[8] However, human and prairie dog cases have occurred in the US due to contact with animals imported from Ghana,[9] while in May 2022 an outbreak of mpox began spreading globally. Cowpox only occurs in Europe and adjacent Russian states, and despite its name, occurs only rarely in cattle. One common host is the domestic cat, from which human infections are most often acquired.[10][11] Cowpox virus has also infected a variety of animals in European zoos, such as elephants, resulting in human infection.[12]

Laboratory transmission

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Aerosols of concentrated virus may result in Orthopoxvirus infection, especially in unimmunized individuals.[13] In addition, needle sticks with concentrated virus or scratches from infected animals may result in local infection of the skin even in immunized individuals. Cowpox infection in Europe is an occupational hazard for veterinary workers, and to a lesser extent, farm workers.[11]

Signs and symptoms

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The initial symptoms of Orthopoxvirus infection include fever, malaise, head and body aches, and occasionally vomiting. With the exception of mpox infection, one lesion is the norm, although satellite lesions may be produced by accidental autoinoculation. Individual lesions, surrounded by inflammatory tissue, develop and progress through macules, papules, vesicles, and pustules, and eventually become dry crusts. (Lesions alone are not diagnostic for Orthopoxvirus infection and may be mistaken for zoonotic Parapoxvirus infections, anthrax or Herpesvirus infections.[11]) Severe edema and erythema may affect large areas of the body in cases of severe infection. Encephalitis (alteration of mental status and focal neurologic deficits), myelitis (upper- and lower-motor neuron dysfunction, sensory level, and bowel and bladder dysfunction), or both may result from Orthopoxvirus infection. Rarely, orthopoxviruses may be detected in cerebrospinal fluid.[citation needed]

Regarding specific Orthopoxvirus infections, human mpox most resembles mild smallpox.[8] Human cowpox is a relatively severe localized infection. A survey of 54 cases reported three cases of generalized infection, including one death.[11]

Treatment

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Vaccinia-specific immunoglobulins may be administered to infected individuals. The only product currently available for treatment of complications of Orthopoxvirus infection is vaccinia immunoglobulin (VIG), which is an isotonic sterile solution of the immunoglobulin fraction of plasma from persons vaccinated with vaccinia virus. It is effective for treatment of eczema vaccinatum and certain cases of progressive vaccinia. However, VIG is contraindicated for the treatment of vaccinial keratitis. VIG is recommended for severe generalized vaccinia if the patient is extremely ill or has a serious underlying disease. VIG provides no benefit in the treatment of postvaccinal encephalitis and has no role in the treatment of smallpox. Current supplies of VIG are limited, and its use is reserved for treatment of vaccine complications with serious clinical manifestations. The recommended dosage of the currently available VIG is 0.6 ml/kg of body weight. VIG must be administered intramuscularly and is ideally administered as early as possible after the onset of symptoms. Because therapeutic doses of VIG might be substantial (e.g., 42 ml for a person weighing 70 kg), the product may be administered in divided doses over a 24- to 36-hour period. Doses can be repeated, usually at intervals of 2–3 days, until recovery begins (i.e., no new lesions appear). The CDC is currently the only source of VIG for civilians.[citation needed]

Certain antiviral compounds such as tecovirimat (ST-246)[14] have been reported to be 100% active against vaccinia virus or other orthopoxviruses in vitro and among test animals. Tecovirimat has been granted orphan drug status by the Food and Drug Administration (FDA) and is currently under study to determine its safety and effectiveness in humans. Another example is brincidofovir. In June 2021, the FDA approved this drug for the treatment of smallpox in humans, making it the first drug approved for an effectively extinct mechanism of action. The decision followed a priority review by the agency, motivated by growing concern of potential bioweapon development. Since the target virus is eradicated the efficacy could not be directly verified but was inferred via proxy, animal survival following infection by related species of Orthopoxvirus. In contrast, safety data was available from trials of the drug in treating Cytomegalovirus infections in humans.[15]

Imatinib, a compound approved by the FDA for cancer treatment, has been shown to limit the release of extracellular enveloped virions and to protect mice from a lethal challenge with vaccinia.[16] Currently, imatinib and related compounds are being evaluated by the CDC for their efficacy against variola virus and mpox virus.

Lab synthesis

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In the summer of 2017, researchers at the University of Alberta recreated horsepox via lab synthesis to conduct research into using viruses to treat cancer.[17]

References

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  1. ^ a b c d e "Viral Zone". ExPASy. Archived from the original on 18 June 2015. Retrieved 15 June 2015.
  2. ^ "Virus Taxonomy: 2020 Release". International Committee on Taxonomy of Viruses (ICTV). March 2021. Archived from the original on 8 April 2020. Retrieved 22 May 2021.
  3. ^ a b Gigante, Crystal M.; Gao, Jinxin; Tang, Shiyuyun; McCollum, Andrea M.; Wilkins, Kimberly; Reynolds, Mary G.; Davidson, Whitni; McLaughlin, Joseph; Olson, Victoria A.; Li, Yu (August 2019). "Genome of Alaskapox Virus, a Novel Orthopoxvirus Isolated from Alaska". Viruses. 11 (8): 708. doi:10.3390/v11080708. PMC 6723315. PMID 31375015.
  4. ^ Trindade, Giliane S.; Emerson, Ginny L.; Carroll, Darin S.; Kroon, Erna G.; Damon, Inger K. (1 July 2007). "Brazilian Vaccinia Viruses and Their Origins". Emerging Infectious Diseases. 13 (7): 965–972. doi:10.3201/eid1307.061404. ISSN 1080-6040. PMC 2878226. PMID 18214166.
  5. ^ a b "Genus: Orthopoxvirus | ICTV". ictv.global. Archived from the original on 18 August 2024. Retrieved 23 August 2024.
  6. ^ a b Hendrickson, RC; Wang, C; Hatcher, EL; Lefkowitz, EJ (September 2010). "Orthopoxvirus genome evolution: the role of gene loss". Viruses. 2 (9): 1933–67. doi:10.3390/v2091933. PMC 3185746. PMID 21994715.
  7. ^ Baxby, Derrick (1988). "Human poxvirus infection after the eradication of smallpox". Epidem, Inf. 100 (3): 321–34. doi:10.1017/s0950268800067078. PMC 2249357. PMID 2837403.
  8. ^ a b Jezek, Z.; Fenner, F. (1988). Human monkeypox. Basel: Karger. ISBN 3-8055-4818-4.
  9. ^ Centers for Disease Control Prevention (CDC) (2003). "Update:Multistate Outbreak of Monkeypox - Illinois, Indiana, Kansas, Missouri, Ohio, and Wisconsin, 2003". MMWR. 52 (27): 642–6. PMID 12855947.
  10. ^ Bennett, M; Gaskell, C.J.; Baxby, D.; Gaskell, R.M.; Kelly, D.F.; Naidoo, J. (1990). "Feline cowpox virus infection". Journal of Small Animal Practice. 31 (4): 167–73. doi:10.1111/j.1748-5827.1990.tb00760.x.
  11. ^ a b c d Baxby, D.; Bennett, M.; Getty, B. (1994). "Human cowpox 1969-93: a review based on 54 cases". Br. J. Dermatol. 131 (5): 598–607. doi:10.1111/j.1365-2133.1994.tb04969.x. PMID 7999588. S2CID 12289212.
  12. ^ Kurth, A.; Wibbelt G; Gerber H-P; Petschaelis A; Pauli G; Nitsche A. (April 2008). "Rat-to-Elephant-to-Human Transmission of Cowpox Virus". Emerging Infectious Diseases. 14 (4): 670–671. doi:10.3201/eid1404.070817. PMC 2570944. PMID 18394293.
  13. ^ Martinez, Mark; Michael P. Bray; John W. Huggins (2000). "A Mouse Model of Aerosol-Transmitted Orthopoxviral Disease". Archives of Pathology & Laboratory Medicine. 124 (3): 362–77. doi:10.5858/2000-124-0362-AMMOAT. PMID 10705388. Archived from the original on 23 August 2023. Retrieved 11 February 2018.
  14. ^ Yang G, Pevear DC, Davies MH, et al. (October 2005). "An orally bioavailable antipoxvirus compound (ST-246) inhibits extracellular virus formation and protects mice from lethal orthopoxvirus Challenge". J. Virol. 79 (20): 13139–49. doi:10.1128/JVI.79.20.13139-13149.2005. PMC 1235851. PMID 16189015.
  15. ^ "FDA approves drug to treat smallpox". FDA. 4 June 2021. Archived from the original on 8 June 2021. Retrieved 11 June 2021.
  16. ^ Reeves, P. M.; Bommarius, B.; Lebeis, S.; McNulty, S.; Christensen, J.; Swimm, A.; Chahroudi, A.; Chavan, R.; Feinberg, M. B.; Veach, D.; Bornmann, W.; Sherman, M.; Kalman, D. (2005). "Disabling poxvirus pathogenesis by inhibition of Abl-family tyrosine kinases". Nature Medicine. 11 (7): 731–739. doi:10.1038/nm1265. PMID 15980865. S2CID 28325503.
  17. ^ Riley, Kim (10 August 2017). "Bioterrorism threats require common global experimentation oversight, expert says". Homeland Preparedness News. Archived from the original on 27 May 2023. Retrieved 7 November 2017.
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