Duck plague
Anatid alphaherpesvirus 1 | |
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Blood-stained ice from the nasal discharge of a mallard dying from duck plague | |
Virus classification | |
(unranked): | Virus |
Realm: | Duplodnaviria |
Kingdom: | Heunggongvirae |
Phylum: | Peploviricota |
Class: | Herviviricetes |
Order: | Herpesvirales |
Family: | Orthoherpesviridae |
Genus: | Mardivirus |
Species: | Anatid alphaherpesvirus 1
|
Synonyms | |
Duck plague (also known as duck viral enteritis) is a worldwide disease caused by Anatid alphaherpesvirus 1 (AnHV-1) of the family Herpesviridae that causes acute disease with high mortality rates in flocks of ducks, geese, and swans. It is spread both vertically and horizontally—through contaminated water and direct contact. Migratory waterfowl are a major factor in the spread of this disease as they are often asymptomatic carriers of disease. The incubation period is three to seven days.[3] Birds as young as one week old can be infected.[4] DEV is not zoonotic.
Clinical signs and diagnosis
[edit]Upon exposure to DEV there is a 3-7 day for domestic fowl and up to a 14 day for wildfowl incubation period for the onset of symptoms.[5] Sudden and persistent increases in flock mortality is often the first observation of DEV. Symptoms in individual birds include loss of appetite, decreased egg production (nearing 20-40% decreases), nasal discharge, increased thirst, diarrhea, ataxia, tremors, a drooped-wing appearance, and in males a prolapsed penis.[5] Mortality rates for DEV may reach 90 percent.[6] Death usually occurs within 5 days after onset of symptoms.[4] The clinical signs of DEV "vary with virulence of virus strain, species, sex, and immune system status" of the host.[7]
Due to the formation of diphtheroid plaques on the eyelids and the mucosae of the respiratory system and gastrointestinal system the bird may show ophthalmic signs and refuse to drink.
Anatid alphaherpesvirus 1 can only infect birds of the family Anatidae of the order Anseriformes, with the possible exception of coots. A study of lesions found in "coots (order Gruiformes)" found similarities to DEV lesions. This could be evidence that DEV is able to "cross to different orders and families" or "adapted to new hosts."[8] Waterfowl species have differing susceptibility to DEV, with wild fowl tending to be more resistant. Nonwaterfowl have not been shown to be infected by duck plague.[7] Blue-winged teal have been found to be one of the most susceptible species and mallards one of the least.[7] In another it took 300,000 more virus material to infect northern pintail than to infect blue-winged teal.[9]
Diagnosis can usually be made based on the clinical signs and postmortem findings:
On post-mortem, petechial haemorrhage in the conjunctivae, mucous membranes, trachea, syrinx and intestine are pathognomonic for DEV. Diagnosis can also be confirmed with presence of virus inclusion bodies in tissues or a positive immunohistochemical staining for viral antigen.[5]
Epidemiology
[edit]DEV is found during the spring seasons across the globe. The United States, Netherlands, and UK have the most occurrences from March to June. Whereas, Southern Hemisphere populations, such as in Brazil, are more likely to have outbreaks November through February during their spring season.[7]
If host organisms survive primary infection, they enter a latent stage lasting up to 4 years.[7] Latent stage leads to vertical and horizontal transmission of DEV. Virus particles can be shed by the latent host in shared water or through direct contact (horizontal transmission), contributing to on-going epizootics.[7] There is also evidence of vertical transmission from latent host carriers to their eggs and offspring, which will also be asymptomatic.[7] However, during times of stress AHV-1 may move to nerve roots from nerve ganglia and "induce herpetic lesions", a visible symptom of latency carrying.[7] Environmental and physiological cues cause latent carriers to shed viral particles. Examples of physiological cues include "stress of migration, breeding season, [and] social interaction."[7] Primary latency sites in carries are the trigeminal ganglion, lymphoid tissue, and blood lymphocytes. The latency sites of APV-1 is similar to other herpesviruses.[4]
Treatment and control
[edit]Vaccination for duck viral enteritis is now routine in the United States.[3] Only attenuated vaccines are efficacious. Once DEV is present, depopulation, relocation and intensive disinfection are required to overcome an outbreak. Solid natural immunity develops in recovered birds. There is no treatment for DEV, but resveratrol has shown to have some antiviral activity against the virus.[4]
Management practices such as preventing exposure to wild waterfowl and contaminated water and screening of new stock should be performed to prevent disease.
Pathogenesis
[edit]DEV is considered pantropic because it is able to replicate and spread to multiple organs within the host.[4] Viral replication causes an increase in vascular permeability, which leads to the lesions and hemorrhaging of organs, namely the liver, spleen, thymus, and bursa of Fabricius.[4][7] DVH-1 replicates in the mucous membranes of bird's esophagus and cloaca, the two primary entrances of the virus.[7] The means of infection influences which tissues will be affected first and the incubation time before symptoms show.[7] Typically viral replication begins in the digestive track and moves to bursa of Fabricuis, thymus, spleen, and liver.[4]
Virology
[edit]Classification
[edit]Anatid alphaherpesvirus 1 is classified under the subfamily Alphaherpesvirinae of the family Herpesviridae in the order Herpesvirales.[5] The genus was identified as Mardivirus. Genomic evidence shows that APV-1 is genetically similar to Human alphaherpesvirus 1 and 2 (HSV-1 and HSV-2), Suid alphaherpesvirus 1, Equid alphaherpesvirus 1 and 4 (EHV-1 and EHV-4), and Bovine alphaherpesvirus 1 (BHV-1).[10]
Genome
[edit]Anatid alphaherpesvirus 1, similar to other herpesviruses, has a linear double stranded DNA genome.[5] The dsDNA weight is 119×106 daltons and approximately 158,091 base pairs long.[11] AHV-1 has 67 genes in its genome, 65 of which are likely coding genes. Three of the genes have no homologs to other herpesviruses, and are unique to AHV-1. Unique long (UL), unique (US), unique short internal repeat (IRS), and unique short terminal repeat (TRS) regions make up the genome. The genomic arrangement is ordered as UL-IRS-US-TRS. There are 78 predicted proteins encoded by the genome.[11]
Structure
[edit]DEV has similar morphology to other Herpesvirales viruses.[12] Common elements of herpesviruses include a "DNA core, icosahedral capsid, tegument, and envelope."[5] The nucleocapsid of HPV-1 is 75 micrometers wide and the envelope diameter is 181 micrometers.[7]
Replication & transcription cycle
[edit]Three phases (immediate early (IE), early (E), and late (L)) of infection dictate the transcription of certain DEV genes. Immediate early begins after infection and before viral DNA replication.[4] During this phase IE genes are transcribed without other proteins.[10] The E genes are also transcribed before viral DNA replication, but are dependent on the IE gene products.[10] After entering the host organism a virion begins the process of replication by first attaching to cells using glycoprotein spikes. gB, gC, gD, gH, and gL are known to be involved.[4] Similar Alphaviruses use gC protein to aid in binding the virion to the cell and gD to stabilize it, if required.[13] gB, gD, gH, and gL proteins allow for fusion of the cell and envelope, and are necessary for survival.[10]
Entrance to host cells begins infection, and is largely controlled by the US 2 viral protein.[4] Envelope fusion with the plasma membrane of the host cell causes separation of the nucleocapsid from viral DNA and proteins.[4] Multiple necessary viral proteins are located within the envelope.[13] DNA and proteins enter the host cell nucleus and turn-off host cell synthesis of nucleic acids, proteins, and other macro molecules. There are two hypothesized origins of replication in the IRS and TRS regions of the genome.[11][4] Immature capsids are formed from coiled DNA.[4] L genes are transcribed "after the synthesis of DNA and viral protein onset."[10] Virion DNA maturation occurs as the nucleocapsids "bud through nuclear membrane."[4] Completed viral replication occurs within 12 hours of infection. Vacuoles of mature virions are formed and released via exocytosis to other cells. Epithelial, lymphocytes, and macrophages are the favored sites of replication in the host organism.[4]
History
[edit]The first report of a DEV outbreak was 1923 in the Netherlands.[14] Duck plague was first reported in the United States on Long Island, New York. The outbreak had economically devastating effects on the duck industry.[4] The 1973 Lake Andes, South Dakota DEV outbreak was the other major incidence of the disease in the United States.[14] The outbreak resulted in 43,000 deaths.[4] In 2005 DEV was removed from the World Organization for Animal Health (OIE) mandatory reporting list due to lack of evidence for international spread and minimal threat to public health.[15] However, there are economic concerns for regions depending on fowl industry, such as India.[4]
References
[edit]- ^ Davison, Andrew (27 January 2016). "Rename species in the family Herpesviridae to incorporate a subfamily designation" (PDF). International Committee on Taxonomy of Viruses (ICTV). p. 2. Retrieved 7 May 2019.
Subfamily Genus Current species name Proposed species name Alphaherpesvirinae Mardivirus Anatid herpesvirus 1 Anatid alphaherpesvirus 1
- ^ a b "ICTV 9th Report (2011) Other related viruses". International Committee on Taxonomy of Viruses (ICTV). 2011. Retrieved 7 May 2019.
Anatid herpesvirus 1 (AnHV-1) (Duck enteritis virus) (Duck plague virus) [EU082088 = NC_013036]
[dead link] - ^ a b Fenner, Frank J.; Gibbs, E. Paul J.; Murphy, Frederick A.; Rott, Rudolph; Studdert, Michael J.; White, David O. (1993). Veterinary Virology (2nd ed.). Academic Press, Inc. ISBN 978-0-12-253056-2.
- ^ a b c d e f g h i j k l m n o p q r Dhama, Kuldeep; Kumar, Naveen; Saminathan, Mani; Tiwari, Ruchi; Karthik, Kumaragurubaran; Kumar, M. Asok; Palanivelu, M.; Shabbir, Muhammad Zubair; Malik, Yashpal Singh (2017-01-01). "Duck virus enteritis (duck plague) – a comprehensive update". Veterinary Quarterly. 37 (1): 57–80. doi:10.1080/01652176.2017.1298885. ISSN 0165-2176. PMID 28320263.
- ^ a b c d e f Fenner's veterinary virology. Maclachlan, Nigel James., Dubovi, Edward J., Fenner, Frank, 1914–2010. (4th ed.). Amsterdam: Elsevier Academic Press. 2011. ISBN 978-0123751584. OCLC 690641300.
{{cite book}}
: CS1 maint: others (link) - ^ Carter, G.R.; Flores, E.F.; Wise, D.J. (2006). "Herpesviridae". A Concise Review of Veterinary Virology. Retrieved 2006-06-10.
- ^ a b c d e f g h i j k l m Hansen, Wallace R. (2007). Thomas, Nancy J. (ed.). Infectious diseases of wild birds. Ames, Iowa: Blackwell Publ. pp. 87–107. ISBN 978-0-8138-2812-1.
- ^ Salguero, Francisco J.; Sánchez-Cordón, Pedro J.; Núñez, Alejandro; Gómez-Villamandos, José C. (2002-04-01). "Histopathological and ultrastructural changes associated with herpesvirus infection in waterfowl". Avian Pathology. 31 (2): 133–140. doi:10.1080/03079450120118612. ISSN 0307-9457. PMID 12396357.
- ^ Field manual of wildlife diseases : general field procedures and diseases of birds. Friend, Milton., Franson, J. Christian., Ciganovich, Elizabeth A., Geological Survey (U.S.). Biological Resources Division. Washington, D.C.: U.S. Dept. of the Interior, U.S. Geological Survey. 1999. ISBN 978-0607880960. OCLC 693130725.
{{cite book}}
: CS1 maint: others (link) - ^ a b c d e Liu, Chaoyue; Cheng, Anchun; Wang, Mingshu; Chen, Shun; Jia, Renyong; Zhu, Dekang; Liu, Mafeng; Sun, Kunfeng; Yang, Qiao (2015-11-25). "Duck enteritis virus UL54 is an IE protein primarily located in the nucleus". Virology Journal. 12 (1): 198. doi:10.1186/s12985-015-0424-z. ISSN 1743-422X. PMC 4658773. PMID 26606920.
- ^ a b c Li, Yufeng; Huang, Bing; Ma, Xiuli; Wu, Jing; Li, Feng; Ai, Wu; Song, Minxun; Yang, Hanchun (2009). "Molecular characterization of the genome of duck enteritis virus". Virology. 391 (2): 151–161. doi:10.1016/j.virol.2009.06.018. PMID 19595405.
- ^ Yuan, Gui-ping; Cheng, An-chun; Wang, Ming-shu; Liu, Fei; Han, Xiao-ying; Liao, Yong-hong; Xu, Chao (2005-03-01). "Electron Microscopic Studies of the Morphogenesis of Duck Enteritis Virus". Avian Diseases. 49 (1): 50–55. doi:10.1637/7237-071004r. ISSN 0005-2086. PMID 15839412.
- ^ a b Spear, Patricia G.; Eisenberg, Roselyn J.; Cohen, Gary H. (2000). "Three Classes of Cell Surface Receptors for Alphaherpesvirus Entry". Virology. 275 (1): 1–8. doi:10.1006/viro.2000.0529. PMID 11017782.
- ^ a b Swayne, David E.; Glisson, John R.; McDougald, Larry R.; Nolan, Lisa K.; Suarez, David L.; Nair, Venugopal, eds. (2013). Diseases of Poultry (13th ed.). Somerset: Wiley. ISBN 9781118719732. OCLC 958568928.
- ^ "Report of the Meeting of the OIE Terrestrial Animal Health Standards Commission". Paris. January 17–28, 2005.
External links
[edit]- "Duck Viral Enteritis – WikiVet English"., expert reviewed and published by Wikivet, accessed January 9, 2011