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Information about Nipah Virus

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Henipaviruses
Virus classification
Group:Group V ((-)ssRNA)
Order:Mononegavirales
Family:Paramyxoviridae
Genus:Henipavirus
Species
Hendravirus
Nipahvirus
Henipavirus is a genus of the family Paramyxoviridae, order Mononegavirales containing two members, Hendravirus and Nipahvirus. The henipaviruses are naturally harboured by Pteropid fruit bats (flying foxes) and are characterised by a large genome, a wide host range and their recent emergence as zoonotic pathogens capable of causing illness and death in domestic animals and humans.[1]

Virus structure

The henipavirus genome (3’ to 5’ orientation) and products of the P gene
Henipaviruses are pleomorphic (variably shaped), ranging in size from 40 to 600 nm in diameter [2]. 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 is to attach the virus to the surface of a host cell via ephrin B2, a highly conserved protein present in many mammals [3][4]. 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 structure

As with all viruses in the Mononegavirales order, the Hendra virus and Nipah virus genomes are non-segmented, single-stranded negative-sense RNA. Both genomes are 18.2 kb in size and contain six genes corresponding to six structural proteins [5].

In common with other members of the Paramyxovirinae subfamily, the number of nucleotides in the henipavirus genome is a multiple of six, known as the 'rule of six'. 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 process 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 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.

Hendra virus

Emergence

Hendra virus (originally Equine morbillivirus) was discovered in September 1994 when it caused the deaths of thirteen horses, and the prominent horse trainer Vic Rail at a training complex in Hendra, a suburb of Brisbane in Queensland, Australia.

The index case, a pregnant mare named Drama Series, [6] was housed with 23 other horses after falling ill and died two days later. Subsequently, 19 of the remaining horses succumbed with 12 dying. Both the trainer and a stable hand were involved in nursing the index case and both fell ill within one week of the horse’s death with an influenza-like illness. The stable hand recovered while the trainer died of respiratory and renal failure. The source of virus was most likely frothy nasal discharge from the index case.

A second outbreak occurred in August 1994 (chronologically preceding the first outbreak) in Mackay 1000km north of Brisbane resulting in the deaths of two horses and their owner [7]. The owner assisted in autopsies of the horses and within three weeks was admitted to hospital suffering from meningitis. He recovered, but 14 months later developed neurologic signs and died. This outbreak was diagnosed retrospectively by the presence of Hendra virus in the brain of the patient.

A survey of wildlife in the outbreak areas was conducted and identified pteropid fruit bats as the most likely source of Hendra virus with a seroprevalence of 47%. All of the other 46 species sampled were negative. Virus isolations from the reproductive tract and urine of wild bats indicated that transmission to horses may have occurred via exposure to bat urine or birthing fluids [8].

Outbreaks

Four more incidents, in Cairns in January 1999 and October 2004, in Townsville in December 2004 and on the Sunshine Coast in June 2006 each resulted in the death of one horse. A vet involved in autopsy of the horse from the 2004 Townsville incident developed a Hendra-related illness soon after and recovered.

The distribution of black and spectacled flying foxes covers Townsville and Cairns, and the timing of incidents indicates a seasonal pattern of outbreaks possibly related to the seasonality of fruit bat birthing. As there is no evidence of transmission to humans directly from bats, it is thought that human infection only occurs via an intermediate host.

Pathology

Flying foxes are unaffected by Hendra virus infection. Symptoms of Hendra virus infection of humans may be respiratory, including haemorrhage and oedema of the lungs, or encephalitic resulting in meningitis. In horses, infection usually causes pulmonary oedema and congestion.

Nipah virus

Emergence

Enlarge picture
Pteropus vampyrus (Malayan flying fox), one of the natural reservoirs of Nipah virus
Nipah virus was identified in 1999 when it caused an outbreak of neurological and respiratory disease on pig farms in peninsular Malaysia, resulting in 105 human deaths and the culling of one million pigs [7]. In Singapore, 11 cases including one death occurred in abattoir workers exposed to pigs imported from the affected Malaysian farms. The Nipah virus has been classified by the CDC as a Category C agent ([1]

Symptoms of infection from the Malaysian outbreak were primarily encephalitic in humans and respiratory in pigs. Later outbreaks have caused respiratory illness in humans, increasing the likelihood of human-to-human transmission and indicating the existence of more dangerous strains of the virus.

Based on seroprevalence data and virus isolations, the primary reservoir for Nipah virus was identified as Pteropid fruit bats including Pteropus vampyrus (Malayan flying fox) and Pteropus hypomelanus (Island flying fox), both of which occur in Malaysia.

The transmission of Nipah virus from flying foxes to pigs is thought to be due to an increasing overlap between bat habitats and piggeries in peninsular Malaysia. At the index farm, fruit orchards were in close proximity to the piggery, allowing the spillage of urine, faeces and partially eaten fruit onto the pigs [10]. Retrospective studies demonstrate that viral spillover into pigs may have been occurring in Malaysia since 1996 without detection [7]. During 1998, viral spread was aided by the transfer of infected pigs to other farms where new outbreaks occurred.

Outbreaks

Seven more outbreaks of Nipah virus have occurred since 1998, all within Bangladesh and neighbouring parts of India. The outbreak sites lie within the range of Pteropus species (Pteropus giganteus). As with Hendra virus, the timing of the outbreaks indicates a seasonal effect.

  • 2001 January 31 – February 23, Siliguri, India: 66 cases with a 74% mortality rate [12]. 75% of patients were either hospital staff or had visited one of the other patients in hospital, indicating person-to-person transmission.
  • 2001 April – May, Meherpur district, Bangladesh: 13 cases with nine fatalities (69% mortality) [13].
  • 2003 January, Naogaon district, Bangladesh: 12 cases with eight fatalities (67% mortality) [13].
  • 2004 January – February, Manikganj and Rajbari provinces, Bangladesh: 42 cases with 14 fatalities (33% mortality).
  • 2004 19 February16 April, Faridpur district, Bangladesh: 36 cases with 27 fatalities (75% mortality). Epidemiological evidence strongly suggests that this outbreak involved person-to-person transmission of Nipah virus, which had not previously been confirmed [15]. 92% of cases involved close contact with at least one other person infected with Nipah virus. Two cases involved a single short exposure to an ill patient, including a rickshaw driver who transported a patient to hospital. In addition, at least six cases involved acute respiratory distress syndrome which has not been reported previously for Nipah virus illness in humans. This symptom is likely to have assisted human-to-human transmission through large droplet dispersal.
  • 2005 January, Tangail district, Bangladesh: 12 cases with 11 fatalities (92% mortality). The virus was probably contracted from drinking date palm juice contaminated by fruit bat droppings or saliva [16].
  • 2007 February – May, Nadia District, India: up to 50 cases with five fatalities. The outbreak site borders the Bangladesh district of Kushtia where 50 suspected cases of Nipah virus encephalitis with six fatalities occurred during April 2007.
Eleven isolated cases of Nipah virus encephalitis have also been documented in Bangladesh since 2001.

Nipah virus has been isolated from Lyle's flying fox (Pteropus lylei) in Cambodia [17] and viral RNA found in urine and saliva from P. lylei and Horsfield's roundleaf bat (Hipposideros larvartus) in Thailand [18]. Antibodies to henipaviruses have also been found in fruit bats (Pteropus rufus, Eidolon dupreanum) in Madagascar indicating a wide geographic distribution of the viruses [19]. No infection of humans or other species have been observed in Cambodia, Thailand or Madagascar.

Pathology

In humans, the infection presents as fever, headache and drowsiness. Cough, abdominal pain, nausea, vomiting, weakness, problems with swallowing and blurred vision are relatively common. About a quarter of the patients have seizures and about 60% become comatose and might need mechanical ventilation. In patients with severe disease, their conscious state may deteriorate and they may develop severe hypertension, fast heart rate, and very high temperature.

Nipah virus is also known to cause relapse encephalitis. In the initial Malaysian outbreak, a patient presented with relapse encephalitis some 53 months after his initial infection. There is no definitive treatment for Nipah encephalitis, apart from supportive measures, such as mechanical ventilation and prevention of secondary infection. Ribavirin, an antiviral drug, was tested in the Malaysian outbreak and the results were encouraging, though further studies are still needed.

In animals, especially in pigs, the virus causes porcine respiratory and neurologic syndrome also known as barking pig syndrome or one mile cough.

Causes of Emergence

The emergence of henipaviruses parallels the emergence of other zoonotic viruses in recent decades. SARS coronavirus, Australian bat lyssavirus, Menangle virus and probably Ebola virus and Marburg virus 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 of 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, creating greater overlap of human and flying fox distributions.

See also

References

1. ^ Sawatsky et al (2008). "Hendra and Nipah Virus", Animal Viruses: Molecular Biology. Caister Academic Press. ISBN 978-1-904455-22-6. 
2. ^ Hyatt, A, Zaki, S, Goldsmith, C, et al. Ultrastructure of Hendra virus and Nipah virus within cultured cells and host animals. Microbes and Infection 2001; 3: 297–306. PMID 11334747
3. ^ Bonaparte, M, Dimitrov, A, Bossart, K, et al. Ephrin-B2 ligand is a functional receptor for Hendra virus and Nipah virus. Proc Natl Acad Sci 2005; 102: 10652–10657. PMID 15998730. Full text at PMC: 15998730
4. ^ Negrete OA, Levroney EL, Aguilar HC, Bertolotti-Ciarlet Aet al. EphrinB2 is the entry receptor for Nipah virus, an emergent deadly paramyxovirus Nature 2005; 436: 401–405. PMID 16007075.
5. ^ Wang L, Harcourt BH, Yu M, et al. Molecular biology of Hendra and Nipah viruses. Microbes and Infection 2001; 3: 279–287. PMID 11334745
6. ^ David Quammen, Deadly Contact, National Geographic Magazine October 2007.
7. ^ Field H, Young P, Yob JM, et al. The natural history of Hendra and Nipah viruses. Microbes and Infection 2001; 3:307–314. PMID 11334748
8. ^ Halpin K, Young PL, Filed HE, Mackenzie JS. Isolation of Hendra virus from pteropid bats: a natural reservoir of Hendra virus. Journal of General Virology 2000; 81:1927–1932. PMID 10900029. Available from http://vir.sgmjournals.org/cgi/content/full/81/8/1927
9. ^ Field H, Young P, Yob JM, et al. The natural history of Hendra and Nipah viruses. Microbes and Infection 2001; 3:307–314. PMID 11334748
10. ^ Chua KB, Chua BH, Wang CW. Anthropogenic deforestation, El Nino and the emergence of Nipah virus in Malaysia. Malaysian J Pathol 2002; 24: 15–21. PMID 16329551
11. ^ Field H, Young P, Yob JM, et al. The natural history of Hendra and Nipah viruses. Microbes and Infection 2001; 3:307–314. PMID 11334748
12. ^ Chadha MS, James AC, Lowe L et al. Nipah virus-associated encephalitis outbreak, Siliguri, India. Emerging Infectious Diseases 2006; 12:235–240. PMID 16494748
13. ^ Hsu VP, Hossain MJ, Parashar UD, et al. Nipah virus encephalitis reemergence, Bangladesh. Emerging Infectious Disease 2004; 10: 2082–2087. PMID 15663842. Available from http://www.cdc.gov/ncidod/EID/vol10no12/04-0701.htm
14. ^ Hsu VP, Hossain MJ, Parashar UD, et al. Nipah virus encephalitis reemergence, Bangladesh. Emerging Infectious Disease 2004; 10: 2082–2087. PMID 15663842. Available from http://www.cdc.gov/ncidod/EID/vol10no12/04-0701.htm
15. ^ ICDDR,B. (2004). Nipah encephalitis outbreak over wide area of Western Bangladesh, 2004. Health and Science Bulletin. 2(1):7–11.
16. ^ ICDDR,B. (2005). Nipah virus outbreak from date palm juice. Health and Science Bulletin. 3(4):1–5.
17. ^ Reynes JM, Counor D, Ong S, et al. Nipah virus in Lyle’s flying foxes, Cambodia. Emerging Infectious Diseases 2005; 11:1042–7. PMID 16022778. Available from http://www.cdc.gov/ncidod/EID/vol11no07/04-1350.htm
18. ^ Wacharapluesadee S, Lumlertdacha B, Boongird K, et al. Bat Nipah virus, Thailand. Emerging Infectious Diseases 2005; 11: 1949-51. PMID 16485487. Available from http://www.cdc.gov/ncidod/EID/vol11no12/05-0613.htm
19. ^ Iehle, C, Razafitrimo, G, Razainirina, J, et al. Henipavirus and Tioman virus in Pteropodid bats, Madagascar. Emerging Infectious Diseases 2007; 13(1). Available from http://www.cdc.gov/EID/13/1/06-0791.htm

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Virus classification involves naming and placing viruses into a taxonomic system. Like the relatively consistent classification systems seen for cellular organisms, virus classification is the subject of ongoing debate and proposals.
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Mononegavirales

Families
Paramyxoviridae
Rhabdoviridae
Filoviridae
Bornaviridae
The Mononegavirales are an order of viruses comprising species that have a non-segmented, negative sense RNA genome.
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Paramyxoviruses are viruses of the Paramyxoviridae family of the Mononegavirales order; they are negative-sense single-stranded RNA viruses responsible for a number of human and animal diseases.
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Henipavirus is a genus of the family Paramyxoviridae, order Mononegavirales containing two members, Hendravirus and Nipahvirus. The henipaviruses are naturally harboured by Pteropid fruit bats (flying foxes) and are characterised by a large genome,
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Henipavirus is a genus of the family Paramyxoviridae, order Mononegavirales containing two members, Hendravirus and Nipahvirus. The henipaviruses are naturally harboured by Pteropid fruit bats (flying foxes) and are characterised by a large genome,
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genus (plural: genera) is part of the Latinized name for an organism. It is a name which reflects the classification of the organism by grouping it with other closely similar organisms.
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family (Latin: familia, plural familiae) is a rank, or a taxon in that rank. Exact details of formal nomenclature depend on the Nomenclature Code which applies.
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Paramyxoviruses are viruses of the Paramyxoviridae family of the Mononegavirales order; they are negative-sense single-stranded RNA viruses responsible for a number of human and animal diseases.
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order (Latin: ordo, plural ordines) is a rank between class and family (termed a taxon at that rank). The superorder is a rank between class and order. Exact details of formal nomenclature depend on the Nomenclature Code which applies.
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Mononegavirales

Families
Paramyxoviridae
Rhabdoviridae
Filoviridae
Bornaviridae
The Mononegavirales are an order of viruses comprising species that have a non-segmented, negative sense RNA genome.
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Pteropus
Erxleben, 1777

Species

Pteropus admiralitatum
Pteropus aldabrensis
Pteropus alecto
Pteropus anetianus
Pteropus aruensis
Pteropus banakrisi
Pteropus brunneus
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Megachiroptera
Dobson, 1875

Family: Pteropodidae
Gray, 1821

Subfamilies

Macroglossinae
Pteropodinae

Fruit bats constitute a single suborder, the Megachiroptera
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