Astroviridae
Electron micrograph of Astroviruses
Astrovirus virion
Virus classification Edit this classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Pisuviricota
Class: Stelpaviricetes
Order: Stellavirales
Family: Astroviridae
Genera

Astroviruses (Astroviridae) are a type of virus that was first discovered in 1975 using electron microscopes following an outbreak of diarrhea in humans.[1] In addition to humans, astroviruses have now been isolated from numerous mammalian animal species (and are classified as genus Mamastrovirus) and from avian species such as ducks, chickens, and turkey poults (classified as genus Avastrovirus). Astroviruses are 28–35 nm diameter, icosahedral viruses that have a characteristic five- or six-pointed star-like surface structure when viewed by electron microscopy. Along with the Picornaviridae and the Caliciviridae, the Astroviridae comprise a third family of nonenveloped viruses whose genome is composed of plus-sense, single-stranded RNA.[2] Astrovirus has a non-segmented, single stranded, positive sense RNA genome within a non-enveloped icosahedral capsid.[3] Human astroviruses have been shown in numerous studies to be an important cause of gastroenteritis in young children worldwide.[2] In animals, Astroviruses also cause infection of the gastrointestinal tract but may also result in encephalitis (humans and cattle), hepatitis (avian) and nephritis (avian).[4]

Microbiology

Taxonomy

This family of viruses consists of two genera, Avastrovirus (AAstV) and Mamastrovirus (MAstV).[5]

The International Committee on Taxonomy of Viruses (ICTV) established Astroviridae as a viral family in 1995.[6] There have been over 50 astroviruses reported, although the ICTV officially recognizes 22 species.[7] The genus Avastrovirus comprises three species; Chicken astrovirus (Avian nephritis virus types 1–3), Duck astrovirus (Duck astrovirus C-NGB), and Turkey astrovirus (Turkey astrovirus 1). The genus Mamastrovirus includes Bovine astroviruses 1 and 2, Human astrovirus (types 1-8), Feline astrovirus 1, Porcine astrovirus 1, Mink astrovirus 1 and Ovine astrovirus 1.[7]

Structure

Schematics and crystal structures of HAstV-1 CP core and spike.

Astroviruses have a star-like appearance with five or six points. Their name is derived from the Greek word "astron" meaning star. They are non-enveloped RNA viruses with cubic capsids, approximately 28–35 nm in diameter with T=3 symmetry.[8][9] Human astroviruses are part of the Mammastrovirus genus and contains 8 serotypes. The human astrovirus capsid spikes have a distinct structure. The spike domain in particular has a 3-layered beta-sandwiches fold and a core, 6-stranded beta-barrel structure. The beta-barrel has a hydrophobic core. The triple-layered beta-sandwich is packed outside the beta-barrel. The spike also forms a dimer. This unique structure was found to be similar to the protein projections found on the capsid of the hepatitis E virus. The projection domain of the human astrovirus contains a receptor binding site for polysaccharides. The amino acid sequence of the astrovirus capsid protein does not have similar homology to other known viral proteins, but the closest would be hepatitis E virus.[10]

Life cycle

Astroviruses infect birds and mammals through the fecal-oral route. They have a tissue tropism for enterocytes. Entry into the host cell is achieved by attachment to host receptors, which mediates endocytosis. Replication follows the positive-strand RNA virus replication model.[11] Astrovirus RNA is infectious and functions as a messenger RNA for ORF1a and ORF1b.[12] A frame-shifting mechanism between these two nonstructural polypeptides translates RNA-dependent RNA polymerase.[13] In replication complexes near intracellular membranes, ORF1a and ORF1b are cleaved to generate individual nonstructural proteins that are involved in replication. The resulting subgenomic RNA contains ORF2 and encodes precursor capsid protein (VP90). VP90 is proteolytically cleaved during packaging and produces immature capsids made of VP70. Following encapsidation, immature capsids are released from the cell without lysis.[6] Extracellular virions are cleaved by Trypsin and form mature infectious virions.[14]

Morphology

Astroviruses are 28-30 nm non-enveloped viruses with T-3 icosahedral symmetry. They have spherical shapes and consist of a capsid protein shell. Astroviruses have distinctive five or six pointed star-like projections on 10% of the virions (the other virions have smooth surfaces).[4] The virion capsid is expressed from a subgenomic mRNA and its precursor undergoes multiple cleavages to make the VP70 protein. Capsids that are made of the VP70 protein are cleaved by trypsin to make particles that are very infectious (VP25/26, VP27/29 and VP34). The spikes that create the star-like appearance on the virion surface are made by two structural proteins (VP25 and VP27) while the capsid shell is made from VP34.[15]

Genome

Schematic representation of the genomic organization of the two novel Passerine Astroviruses.

Astroviruses have a genome composed of a single strand of positive sense RNA. The strand has a poly A tail at the 3' end, but no 5' cap. With the exclusion of polyadenylation at the 3' end, the genome is between 6.8–7.9 kb long. The genome is arranged into three open reading frames (ORFs), with an overlap of approximately 70 nucleotides between ORF1a and ORF1b. The remaining ORF is known as ORF2.[16] ORF2 encode the structural proteins,[17] which are -at least- VP26, VP29 and VP32, the most antigenic and immunogenic of these being VP26. This protein is probably involved in the first steps of viral infection, being a key factor in the biological cycle of astroviruses.[18] The human astrovirus genome mutation rate has been estimated to be 3.7×10−3 nucleotide substitutions per site per year with the synonymous changes rate of 2.8×10−3 nucleotide substitutions per site per year.[19] The capability for genetic recombination appears to be present in type-3 and type-4 human astroviruses,[20][21] and in porcine astrovirus strains.[22]

Replication

Replication of astroviruses occur in the cytoplasm.[23] Astrovirus RNA is infectious and functions as a messenger RNA for ORF1a and ORF1b.[24] A frame-shifting mechanism between these two nonstructural polypeptides translates RNA-dependent RNA polymerase.[25] In replication complexes near intracellular membranes, ORF1a and ORF1b are cleaved to generate individual nonstructural proteins that are involved in replication. The resulting subgenomic RNA contains ORF2 and encodes precursor capsid protein (VP90). VP90 is proteolytically cleaved during packaging and produces immature capsids made of VP70. Following encapsidation, immature capsids are released from the cell without lysis.[6] Extracellular virions are cleaved by Trypsin and form mature infectious virions.[26]

Evolution

The Astroviridae capsid is related to those of the Tymoviridae. The non-structural region is related to the Potyviridae. It appears that this group of viruses may have arise at some point in the past as a result of recombination event between two distinct viruses and that this even occurred at the junction of the structural and non-structural coding regions.[27]

Species infected

Avastrovirus

Phylogenetic tree of astroviruses and the species infected by them

Avastrovirus 1–3 are associated with enteric infections in turkeys, ducks, chicken and guinea fowl. In turkey poults 1–3 weeks of age, some symptoms of enteritis include diarrhea, listlessness, liver eating and nervousness. These symptoms are usually mild but in cases of poult enteritis and mortality syndrome (PEMS), which has dehydration, immune dysfunction and anorexia as symptoms, mortality is high.[28] Post mortem examination of the intestines of infected birds show fluid filled intestines. Hyperplasia of enterocytes is also observed in histopathology studies. However, in contrast to other enteric viruses, there isn't villous supply.[4]

Avastrovirus species often infect extraintestinal sites such as the kidney or liver resulting in hepatitis and nephritis.[4] Birds infected by avian nephritis virus typically die within 3 weeks of infection. The viral particles can be detected in fecal matter within 2 days and peak virus shedding occurs 4–5 days after infection.[29] The virus can be found in the kidney, jejunum, spleen, liver and bursa of infected birds. Symptoms of this disease include diarrhea and weight loss. Necropsies show swollen and discolored kidneys and there is evidence of death of the epithelial cells and lymphocytic interstitial nephritis.[4] Another extraintestinal avastrovirus is avian hepatitis virus which infects ducks. Hepatitis in ducks caused by this duck astrovirus (DAstV) is often fatal.[30]

In birds, Avastroviruses are detected by antigen-capture ELISA. In the absence of vaccines, sanitation is the prevalent way to prevent Avastrovirus infections.[4]

Mamastrovirus

Mamastroviruses often cause gastroenteritis in infected mammals. In animals, gastroenteritis is usually undiagnosed because most astrovirus infections are asymptomatic. However, in mink and humans, astroviruses can cause diarrhea and can be fatal. The incubation period for Mamastrovirus is 1–4 days. When symptoms occur, the incubation period is followed by diarrhea for several days. In mink, symptoms include increased secretion from apocrine glands.[4] Human astroviruses are associated with gastroenteritis in children and immunocompromised adults.[31] 2–8% of acute non-bacterial gastroenteritis in children is associated with human astrovirus. These viral particles are usually detected in epithelial cells of the duodenum.[4] In sheep, ovine astroviruses were found in the villi of the small intestine.[32]

Mamastroviruses also cause diseases of the nervous system.[33] These diseases most commonly occur in cattle, mink and humans. In cattle, this occurs sporadically and infects individual animals. Symptoms of this infection include seizure, lateral recumbency and impaired coordination. Histological examinations showed neuronal necrosis and gliosis of the cerebral cortex, cerebellum, spinal cord and brainstem.[34]

Signs and symptoms in humans

Members of a relatively new virus family, the astroviridae, astroviruses are now recognised as a cause of gastroenteritis in children, whose immune systems are underdeveloped, and elderly adults, whose immune systems are generally somewhat compromised. Presence of viral particles in fecal matter and in epithelial intestinal cells indicate that the virus replicates in the gastrointestinal tract of humans.[35] The main symptoms are diarrhoea, followed by nausea, vomiting, fever, malaise and abdominal pain. Some research studies have shown that the incubation period of the disease is approximately three to four days. Astrovirus infection is not usually a severe situation and only in some rare cases leads to dehydration. The severity and variation in symptoms correlates with the region the case develops in. This could be due to climatic factors influencing the life cycle or transmission method for that particular strain of Astrovirus. Malnutrition and immunodeficiency tend to exacerbate the condition, leading to more severe cases or secondary conditions that could require hospital care.[36] Otherwise, infected people do not need hospitalization because symptoms will reduce by themselves, after 2 to 4 days.[37]

Human infections are usually self-limiting but may also spread systematically and infect immunocompromised individuals.[38]

Astroviruses most frequently cause infection of the gastrointestinal tract but in some animals they may result in encephalitis (humans and cattle), hepatitis (avian) and nephritis (avian).[39]

Diagnosis

Electron microscopy, enzyme-immunoassay (ELISA), immunofluorescence, and polymerase chain reaction have all been used for detecting virus particle, antigens or viral nucleic acid in the stools of infected people.[40] A method using real-time RT-PCR, which can detect all human astrovirus genotypes, has been reported.[41] Some RT-qPCR techniques are able to simultaneously detect human astroviruses and other enteric viruses associated with gastroenteritis.[42] Microarrays are also used to differentiate between the eight different human astrovirus serotypes.[2]

Pathogenesis

Astroviruses cause gastroenteritis by causing destruction of the intestinal epithelium, leading to the inhibition of usual absorption mechanism, loss of secretory functions, and decrease in epithelial permeability in the intestines. Inflammatory responses were seen to not affect astrovirus pathogenesis.[43]

Epidemiology

Astroviruses are associated with 5–9% of the cases of gastroenteritis in young children.[44] Humans of all ages are susceptible to astrovirus infection, but children, the elderly, and those that are immunocompromised are most prone. A study of intestinal disease in the UK, published in 1999, determined incidence as 3.8/1000 patient years in the community (95% CI, range 2.3–6.4), the fourth most common known cause of viral gastroenteritis.[45] Studies in the USA have detected astroviruses in the stools of 2–9% of children presenting symptoms; illness is most frequent in children younger than two years, although outbreaks among adults and the elderly have been reported. Early studies carried out in Glasgow demonstrated that a significant proportion of babies excreting virus particles did not exhibit gastrointestinal symptoms.[46] Seroprevalence studies carried out in the US have shown that 90% of children have antibody to HastV-1 by age 9, suggesting that (largely asymptomatic) infection is common. Looking at the pattern of disease, it suggests that antibodies provide protection through adult life until the antibody titre begins to decline later in life.[47][48]

The occurrence of astrovirus infections vary depending on the season. In temperate climates, infection is highest during winter months possibly due to lower temperatures which enhance the stability of the virus.[49] This is in contrast to tropical regions where prevalence is highest during the rainy season. The seasonal distribution in tropical climates can be explained by the effect of rain particularly on the breakdown of sanitation in developing countries.[46]

Human astroviruses are transmitted by the fecal–oral route. The main mode of astrovirus transmission is by contaminated food and water. Young children in childcare backgrounds or adults in military barracks are most likely to develop the disease. Human astroviruses may be released in large quantities in the stool of infected individuals and contaminate groundwater, fresh water and marine water due to inadequate wastewater treatment. Fruits and vegetables grown in such contaminated water may also act as sources of viral infection. Poor food handling practices, poor hand hygiene and contamination of inanimate objects are other factors that encourage enteric virus transmission.[50]

Astroviruses can also be transmitted to humans from other animal species. In comparison to individuals who had no contact with turkey, turkey abattoir workers were three times more likely to test positive for antibodies against turkey astroviruses.[51] Furthermore, some human, duck, chicken and turkey astroviruses are phylogenetically related and share genetic features.[52]

Prevention

Human astroviruses can be prevented by detection and inactivation in contaminated food and water in addition to disinfection of contaminated fomites.[7]

Treatment

Astrovirus Immunoglobulin

In a study by Bjorkholm et al., a 78-year-old patient diagnosed with Waldenstrom's macroglobulinemia was given 0.4 g/kg of astrovirus immunoglobulin for four days, and the symptoms dissolved leading to a full recovery from astrovirus; however, further testing has yet to be completed.[53]

Achyrocline bogotensis antiviral therapy

In a study by Tellez et al., extracts from a plant Achyrocline bogotensis was used to develop an antiviral therapy for both rotavirus and astrovirus. Achyrocline bogotensis was commonly used for skin and urinary infections. Drug testing methodology involved application of the extract to cell for pre-treatment (blocking), direct viral activity (evidence of killing the virus), and treatment (a decrease in the viral load after an infection is established). The extract demonstrated direct viral activity by killing astroviruses directly and treatment by leading to a decrease in the viral load after an established infection. A pre-treatment effect was not evident during the experiment.[54]

Timeline

1975: Appleton and Higgins first discovered astrovirus in stool samples of children suffering from gastroenteritis by using electron microscopy (EM)

1975: Madeley and Cosgrove named the 20–30 nm viral particle Astrovirus based on the star-like EM (electron microscopy) appearance

1976-1992: Lee and Kurtz serotyped 291 astrovirus stool samples in Oxford; discovered serotypes 6 and 7

1981: Lee and Kurtz were able to grow astrovirus in tripsin-dependent tissue culture by using human embryo kidney cells (HEK)

1985: Lee and Kurtz discover two serotypes of astrovirus that are used to type 13 strains of community-acquired astrovirus

1987: Gray et al. discovered that a 22-day long gastroenteritis outbreak in an elderly home was caused by astrovirus type 1 and calicivirus

1988: Hermann and Hudson use antigen characterization of HEK grown astroviruses to develop monoclonal antibodies

1992: Cruz et al. analyzed 5,000 stool samples 7.5% of the diarrheal diseases found in Guatemalan ambulatory rural children were caused by astroviruses

1993: Jiang et al. sequence astrovirus RNA and determine the presence of three ORFs and ribosomal frameshifting

1993: Monroe et al. classify subgenomic data for astrovirus, providing support for astrovirus to be classified as a viral family

1994: Oishi et al. determine astrovirus as the main cause of gastroenteritis in schools in Katano City, Osaka, Japan

1995: Bjorkholm elt al. conducted a clinical study, and 78-year-old male Waldenström's macroglobulinemia patient with astrovirus-associated gastroenteritis was successfully treated with intravenous immunoglobulin

1995: Jonassen et al. uses PCR to detect all known serotypes (7) of astrovirus

1995: In their sixth report, ICTV establishes Astroviridae as a viral family

1996: Glass et al. states an epidemiological shift regarding astrovirus due to improvements in RT-PCT (reverse transcription PCR), monoclonal antibodies, and enzyme immunoassays (EIA); astroviruses are now considered one of the main causes of diarrheal disease worldwide

1996: Palombo and Bishop the epidemiology of astrovirus infections in children suffering from gastroenteritis in Melbourne, Australia (data collected include total incidence, genetic diversity, serotype characterization)

1998: Unicomb et al. conduct a clinical study in Bangladesh and conclude astrovirus infections involving nosocomial, acute, and persistent diarrheal diseases

1998: Gaggero et al. identify human astrovirus type 1 to be the main cause of acute gastroenteritis in Chilean children

1999: Bon et al. discover astrovirus in a gastroenteritis outbreak in Dijon, France

2001: Dennehy et al. collected stool samples from hospitalized children suffering from acute gastroenteritis; astrovirus was determined the second leading cause of gastroenteritis after rotavirus

2002: Guix et al. completes an epidemiological study on the presence of astrovirus in Barcelona, Spain; the total incidence of astrovirus in 2,347 samples was 4.95 with a peak in the number of cases in the winter

2003: Basu et al. discovered astrovirus in 2.7% of stool samples collected from 346 children suffering from gastroenteritis in Gaborone, Botswana

2009: Finkbeiner et al. used Sanger sequencing to discover a novel astrovirus in stool samples from children suffering from an acute gastroenteritis outbreak at a childcare center

2009: Using RT-PCR, Kapoor et al. discover novel astrovirus strains HMOAstV species A, B, C which are very similar to astroviruses found in mink and ovine species; this showed that the virus may have the ability to jump species

References

  1. Madeley CR, Cosgrove BP (September 1975). "Letter: 28 nm particles in faeces in infantile gastroenteritis". Lancet. 2 (7932): 451–2. doi:10.1016/S0140-6736(75)90858-2. PMID 51251. S2CID 54289244.
  2. 1 2 3 Brown DW, Gunning KB, Henry DM, Awdeh ZL, Brinker JP, Tzipori S, Herrmann JE (January 2008). "A DNA oligonucleotide microarray for detecting human astrovirus serotypes". Journal of Virological Methods. 147 (1): 86–92. doi:10.1016/j.jviromet.2007.07.028. PMC 2238180. PMID 17905448.
  3. Matsui SM, Kiang D, Ginzton N, Chew T, Geigenmüller-Gnirke U (2001). "Molecular biology of astroviruses: Selected highlights". Gastroenteritis Viruses. Novartis Foundation Symposia. Vol. 238. pp. 219–33, discussion 233–6. doi:10.1002/0470846534.ch13. ISBN 978-0-470-84653-7. PMID 11444028. {{cite book}}: |journal= ignored (help)
  4. 1 2 3 4 5 6 7 8 Maclachlan NJ, Dubovi EJ, Barthold SW, Swayne DE, Winton JR (2017). Fenner's Veterinary Virology (Fifth ed.). Amsterdam: Elsevier/Academic Press. ISBN 978-0-12-800946-8.{{cite book}}: CS1 maint: overridden setting (link)
  5. Virus taxonomy: classification and nomenclature of viruses: Ninth Report of the International Committee on Taxonomy of Viruses. (2012) Ed: King, A.M.Q., Adams, M.J., Carstens, E.B. and Lefkowitz, E.J. San Diego: Elsevier.
  6. 1 2 3 Bosch A, Pintó RM, Guix S (2014). "Human Astroviruses". Clinical Microbiology Reviews. 27 (4): 1048–1074. doi:10.1128/CMR.00013-14. ISSN 0893-8512. PMC 4187635. PMID 25278582.
  7. 1 2 3 Bosch A, Pintó RM, Guix S (October 2014). "Human astroviruses". Clinical Microbiology Reviews. 27 (4): 1048–74. doi:10.1128/CMR.00013-14. PMC 4187635. PMID 25278582.
  8. Krishna NK (2005). "Identification of structural domains involved in astrovirus capsid biology". Viral Immunology. 18 (1): 17–26. doi:10.1089/vim.2005.18.17. PMC 1393289. PMID 15802951.
  9. "Viral Zone". ExPASy. Retrieved 12 June 2015.
  10. Dong J, Dong L, Méndez E, Tao Y (August 2011). "Crystal structure of the human astrovirus capsid spike". Proceedings of the National Academy of Sciences of the United States of America. 108 (31): 12681–6. Bibcode:2011PNAS..10812681D. doi:10.1073/pnas.1104834108. PMC 3150915. PMID 21768348.
  11. "Astroviridae ~ ViralZone". viralzone.expasy.org. Retrieved 21 May 2021.
  12. Geigenmüller U, Ginzton NH, Matsui SM (1 February 1997). "Construction of a genome-length cDNA clone for human astrovirus serotype 1 and synthesis of infectious RNA transcripts". Journal of Virology. 71 (2): 1713–1717. doi:10.1128/JVI.71.2.1713-1717.1997. ISSN 0022-538X. PMC 191237. PMID 8995706.
  13. Marczinke B, Bloys AJ, Brown TD, Willcocks MM, Carter MJ, Brierley I (1 September 1994). "The human astrovirus RNA-dependent RNA polymerase coding region is expressed by ribosomal frameshifting". Journal of Virology. 68 (9): 5588–5595. doi:10.1128/JVI.68.9.5588-5595.1994. ISSN 0022-538X. PMC 236959. PMID 8057439.
  14. Speroni S, Rohayem J, Nenci S, Bonivento D, Robel I, Barthel J, Luzhkov VB, Coutard B, Canard B, Mattevi A (17 April 2009). "Structural and Biochemical Analysis of Human Pathogenic Astrovirus Serine Protease at 2 Resolution". Journal of Molecular Biology. 387 (5): 1137–1152. doi:10.1016/j.jmb.2009.02.044. ISSN 0022-2836. PMID 19249313.
  15. Arias CF, DuBois RM (19 January 2017). "The Astrovirus Capsid: A Review". Viruses. 9 (1): 15. doi:10.3390/v9010015. ISSN 1999-4915. PMC 5294984. PMID 28106836.
  16. Willcocks MM, Brown TD, Madeley CR, Carter MJ (July 1994). "The complete sequence of a human astrovirus". The Journal of General Virology. 75 (7): 1785–8. doi:10.1099/0022-1317-75-7-1785. PMID 8021608.
  17. Payne S (2017). Family Astroviridae. Academic Press. ISBN 9780128031094.
  18. Royuela E, Sánchez-Fauquier A (January 2010). "Molecular cloning, expression and first antigenic characterization of human astrovirus VP26 structural protein and a C-terminal deleted form". Comparative Immunology, Microbiology and Infectious Diseases. 33 (1): 1–14. doi:10.1016/j.cimid.2008.07.010. PMID 18790534.
  19. Babkin IV, Tikunov AY, Zhirakovskaia EV, Netesov SV, Tikunova NV (March 2012). "High evolutionary rate of human astrovirus". Infection, Genetics and Evolution. 12 (2): 435–42. doi:10.1016/j.meegid.2012.01.019. PMID 22326537.
  20. Medici MC, Tummolo F, Martella V, Banyai K, Bonerba E, Chezzi C, et al. (June 2015). "Genetic heterogeneity and recombination in type-3 human astroviruses". Infection, Genetics and Evolution. 32: 156–60. doi:10.1016/j.meegid.2015.03.011. hdl:11586/158908. PMID 25784567.
  21. Martella V, Medici MC, Terio V, Catella C, Bozzo G, Tummolo F, et al. (December 2013). "Lineage diversification and recombination in type-4 human astroviruses". Infection, Genetics and Evolution. 20: 330–5. doi:10.1016/j.meegid.2013.09.015. hdl:10447/88045. PMID 24084291.
  22. Lv SL, Zhang HH, Li JY, Hu WQ, Song YT, Opriessnig T, Xiao CT (October 2019). "High genetic diversity and recombination events of porcine astrovirus strains identified from ill and asymptomatic pigs in 2017, Hunan Province, China". Virus Genes. 55 (5): 673–681. doi:10.1007/s11262-019-01692-w. hdl:20.500.11820/5e7c9e5b-ce5c-4bfc-94dc-c490d04b159b. PMID 31372920. S2CID 199380888.
  23. Dong J, Dong L, Méndez E, Tao Y (2 August 2011). "Crystal structure of the human astrovirus capsid spike". Proceedings of the National Academy of Sciences. 108 (31): 12681–12686. Bibcode:2011PNAS..10812681D. doi:10.1073/pnas.1104834108. ISSN 0027-8424. PMC 3150915. PMID 21768348.
  24. Geigenmüller U, Ginzton NH, Matsui SM (1 February 1997). "Construction of a genome-length cDNA clone for human astrovirus serotype 1 and synthesis of infectious RNA transcripts". Journal of Virology. 71 (2): 1713–1717. doi:10.1128/JVI.71.2.1713-1717.1997. ISSN 0022-538X. PMC 191237. PMID 8995706.
  25. Marczinke B, Bloys AJ, Brown TD, Willcocks MM, Carter MJ, Brierley I (1 September 1994). "The human astrovirus RNA-dependent RNA polymerase coding region is expressed by ribosomal frameshifting". Journal of Virology. 68 (9): 5588–5595. doi:10.1128/JVI.68.9.5588-5595.1994. ISSN 0022-538X. PMC 236959. PMID 8057439.
  26. Speroni S, Rohayem J, Nenci S, Bonivento D, Robel I, Barthel J, Luzhkov VB, Coutard B, Canard B, Mattevi A (17 April 2009). "Structural and Biochemical Analysis of Human Pathogenic Astrovirus Serine Protease at 2 Resolution". Journal of Molecular Biology. 387 (5): 1137–1152. doi:10.1016/j.jmb.2009.02.044. ISSN 0022-2836. PMID 19249313.
  27. Kelly AG, Netzler NE, White PA (October 2016). "Ancient recombination events and the origins of hepatitis E virus". BMC Evolutionary Biology. 16 (1): 210. Bibcode:2016BMCEE..16..210K. doi:10.1186/s12862-016-0785-y. PMC 5062859. PMID 27733122.
  28. Jindal N, Patnayak DP, Ziegler AF, Lago A, Goyal SM (May 2009). "Experimental reproduction of poult enteritis syndrome: clinical findings, growth response, and microbiology". Poultry Science. 88 (5): 949–58. doi:10.3382/ps.2008-00490. PMC 7107170. PMID 19359682.
  29. Swayne DE, Glisson JR (2013). Diseases of Poultry. John Wiley & Sons, Incorporated. ISBN 9781118720028.{{cite book}}: CS1 maint: overridden setting (link)
  30. Fu Y, Pan M, Wang X, Xu Y, Xie X, Knowles NJ, et al. (May 2009). "Complete sequence of a duck astrovirus associated with fatal hepatitis in ducklings". The Journal of General Virology. 90 (Pt 5): 1104–1108. doi:10.1099/vir.0.008599-0. PMID 19264607.
  31. Cortez V, Freiden P, Gu Z, Adderson E, Hayden R, Schultz-Cherry S (February 2017). "Persistent Infections with Diverse Co-Circulating Astroviruses in Pediatric Oncology Patients, Memphis, Tennessee, USA". Emerging Infectious Diseases. 23 (2): 288–290. doi:10.3201/eid2302.161436. PMC 5324824. PMID 28098537.
  32. "Astroviridae - Positive Sense RNA Viruses - Positive Sense RNA Viruses (2011)". International Committee on Taxonomy of Viruses (ICTV). Retrieved 1 May 2020.
  33. Bouzalas IG, Wüthrich D, Walland J, Drögemüller C, Zurbriggen A, Vandevelde M, et al. (September 2014). Onderdonk AB (ed.). "Neurotropic astrovirus in cattle with nonsuppurative encephalitis in Europe". Journal of Clinical Microbiology. 52 (9): 3318–24. doi:10.1128/JCM.01195-14. PMC 4313157. PMID 24989603.
  34. Bouzalas IG, Wüthrich D, Walland J, Drögemüller C, Zurbriggen A, Vandevelde M, et al. (September 2014). "Neurotropic astrovirus in cattle with nonsuppurative encephalitis in Europe". Journal of Clinical Microbiology. 52 (9): 3318–24. doi:10.1128/JCM.01195-14. PMC 4313157. PMID 24989603.
  35. "The Epidemiology of Astroviruses". web.stanford.edu. Retrieved 15 October 2016.
  36. "Astroviruses - Infectious Disease and Antimicrobial Agents". www.antimicrobe.org. Retrieved 15 October 2016.
  37. "Astroviridae". web.stanford.edu. Retrieved 11 November 2016.
  38. Wunderli W, Meerbach A, Guengoer T, Berger C, Greiner O, Caduff R, Trkola A, Bossart W, Gerlach D, Schibler M, Cordey S (11 November 2011). "Astrovirus Infection in Hospitalized Infants with Severe Combined Immunodeficiency after Allogeneic Hematopoietic Stem Cell Transplantation". PLOS ONE. 6 (11): e27483. Bibcode:2011PLoSO...627483W. doi:10.1371/journal.pone.0027483. ISSN 1932-6203. PMC 3214048. PMID 22096580.
  39. Dubovi EJ (30 November 2016). Fenner's Veterinary Virology (Fifth ed.). Elsevier Science. ISBN 978-0-12-800946-8.
  40. Guix S, Bosch A, Pintó RM (2005). "Human astrovirus diagnosis and typing: current and future prospects". Letters in Applied Microbiology. 41 (2): 103–5. doi:10.1111/j.1472-765X.2005.01759.x. PMID 16033504. S2CID 20344500.
  41. Royuela E, Negredo A, Sánchez-Fauquier A (April 2006). "Development of a one step real-time RT-PCR method for sensitive detection of human astrovirus". Journal of Virological Methods. 133 (1): 14–9. doi:10.1016/j.jviromet.2005.10.012. PMID 16321452.
  42. Liu Y, Xu ZQ, Zhang Q, Jin M, Yu JM, Li JS, et al. (July 2012). "Simultaneous detection of seven enteric viruses associated with acute gastroenteritis by a multiplexed Luminex-based assay". Journal of Clinical Microbiology. 50 (7): 2384–9. doi:10.1128/JCM.06790-11. PMC 3405628. PMID 22518865.
  43. Bosch A, Pintó RM, Guix S (October 2014). "Human astroviruses". Clinical Microbiology Reviews. 27 (4): 1048–74. doi:10.1128/cmr.00013-14. PMC 4187635. PMID 25278582.
  44. Monroe SS, Holmes JL, Belliot GM (2001). "Molecular epidemiology of human astroviruses". Gastroenteritis Viruses. Novartis Foundation Symposia. Vol. 238. pp. 237–45, discussion 245–9. doi:10.1002/0470846534.ch14. ISBN 978-0-470-84653-7. PMID 11444029. {{cite book}}: |journal= ignored (help)
  45. "Infectious diseases in England and Wales: January to March 1999". Communicable Disease Report. CDR Supplement. 9 (4): S1-20. July 1999. PMID 10434464.
  46. 1 2 Glass RI, Noel J, Mitchell D, Herrmann JE, Blacklow NR, Pickering LK, et al. (1996). "The changing epidemiology of astrovirus-associated gastroenteritis: A review". Viral Gastroenteritis. Archives of Virology. Vol. 12. pp. 287–300. doi:10.1007/978-3-7091-6553-9_31. ISBN 978-3-211-82875-5. PMID 9015126. {{cite book}}: |journal= ignored (help)
  47. Koopmans MP, Bijen MH, Monroe SS, Vinjé J (January 1998). "Age-stratified seroprevalence of neutralizing antibodies to astrovirus types 1 to 7 in humans in The Netherlands". Clinical and Diagnostic Laboratory Immunology. 5 (1): 33–7. doi:10.1128/CDLI.5.1.33-37.1998. PMC 121387. PMID 9455876.
  48. Midthun K, Greenberg HB, Kurtz JB, Gary GW, Lin FY, Kapikian AZ (April 1993). "Characterization and seroepidemiology of a type 5 astrovirus associated with an outbreak of gastroenteritis in Marin County, California". Journal of Clinical Microbiology. 31 (4): 955–62. doi:10.1128/JCM.31.4.955-962.1993. PMC 263593. PMID 8385155.
  49. Abad FX, Villena C, Guix S, Caballero S, Pintó RM, Bosch A (September 2001). "Potential role of fomites in the vehicular transmission of human astroviruses". Applied and Environmental Microbiology. 67 (9): 3904–7. Bibcode:2001ApEnM..67.3904A. doi:10.1128/AEM.67.9.3904-3907.2001. PMC 93108. PMID 11525984.
  50. Todd EC, Greig JD, Bartleson CA, Michaels BS (August 2007). "Outbreaks where food workers have been implicated in the spread of foodborne disease. Part 2. Description of outbreaks by size, severity, and settings". Journal of Food Protection. 70 (8): 1975–93. doi:10.4315/0362-028X-70.8.1975. PMID 17803160.
  51. Meliopoulos VA, Kayali G, Burnham A, Oshansky CM, Thomas PG, Gray GC, et al. (14 May 2014). Kapoor A (ed.). "Detection of antibodies against Turkey astrovirus in humans". PLOS ONE. 9 (5): e96934. Bibcode:2014PLoSO...996934M. doi:10.1371/journal.pone.0096934. PMC 4020816. PMID 24826893.
  52. Bosch A, Pintó RM, Guix S (October 2014). "Human astroviruses". Clinical Microbiology Reviews. 27 (4): 1048–74. doi:10.1128/CMR.00013-14. PMC 4187635. PMID 25278582.
  53. Björkholm M, Celsing F, Runarsson G, Waldenström J (August 1995). "Successful intravenous immunoglobulin therapy for severe and persistent astrovirus gastroenteritis after fludarabine treatment in a patient with Waldenström's macroglobulinemia". International Journal of Hematology. 62 (2): 117–20. doi:10.1016/0925-5710(95)00396-A. PMID 8590772.
  54. Téllez MA, Téllez AN, Vélez F, Ulloa JC (December 2015). "In vitro antiviral activity against rotavirus and astrovirus infection exerted by substances obtained from Achyrocline bogotensis (Kunth) DC. (Compositae)". BMC Complementary and Alternative Medicine. 15 (1): 428. doi:10.1186/s12906-015-0949-0. PMC 4668688. PMID 26630872.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.