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Human bocavirus

December 15, 2023

Not to be confused with Bornavirus or Bocas virus, a Coronavirus.

Human bocavirus (HBoV) is the name given to all viruses in the genus Bocaparvovirus of virus family Parvoviridae[2] that are known to infect humans. HBoV1 and HBoV3 (and gorilla bocaparvovirus) are members of species Primate bocaparvovirus 1 whereas viruses HBoV2 and HBoV4 belong to species Primate bocaparvovirus 2. Some of these viruses cause human disease. HBoV1 is strongly implicated in causing some cases of lower respiratory tract infection, especially in young children, and several of the viruses have been linked to gastroenteritis, although the full clinical role of this emerging infectious disease remains to be elucidated.

Human bocavirus
Scientific classification
(unranked): Virus
Realm: Monodnaviria
Kingdom: Shotokuvirae
Phylum: Cossaviricota
Class: Quintoviricetes
Order: Piccovirales
Family: Parvoviridae
Subfamily: Parvovirinae
Genus: Bocaparvovirus
Groups included
Member viruses[1]
  • Human bocavirus-1
  • Human bocavirus-2
  • Human bocavirus-3
  • Human bocavirus-4
Cladistically included but traditionally excluded taxa

All other viruses and strains in species:

  • Primate bocaparvovirus 1
  • Primate bocaparvovirus 2

History edit

Allander and colleagues at the Karolinska Institutet in Stockholm, Sweden, first cloned the coding sequence of this new member of the family of Parvoviridae in 2005 from pooled nasopharyngeal aspirates (NPA, collection of aspirated fluid from the back of the nasal cavity).[3] They used a novel technique called molecular virus screening, based on random cloning and bioinformatical analysis. This technique has led to the discovery of new viruses such as polyomavirus KI (Karolinska Institute)[4] and WU (Washington University),[5] which are closely related to each other and have been isolated from respiratory secretions.

Several groups of scientists have since then found that HBoV is the fourth most common virus in respiratory samples,[6][7] behind rhinoviruses, respiratory syncytial virus, and adenoviruses.[8]

The name bocavirus is derived from bovine and canine, referring to the two known hosts for the founder members of this genus; bovine parvovirus which infects cattle, and minute virus of canines which infects dogs.[9] Parvoviruses (Latin: small viruses) have a 5 kilobase long single-stranded DNA, and they use some of their host's replication proteins to copy their DNA.

Virology edit

The virions are small (diameter 18–26 nanometers), icosahedral and non enveloped. The capsid has T = 1 symmetry and consists of 60 copies of coat protein. The coat proteins have a conserved, eight stranded beta barrel motif that forms the core of the capsid. There is also a conserved alpha helix.[10]

The HBoV capsid shares three characteristic features also found in the other vertebrate parvoviruses:[10] (1) a dimple like depression at each icosahedral 2-fold axis; (2) a large trimeric protrusion at or surrounding each 3-fold axis; (3) a cylindrical projection surrounding each 5-fold axis that encloses a central channel which connects the inside of the particle with its exterior and serves as the entry and exit portal for viral DNA. This 5-fold cylinder is itself encircled by a wide canyon like depression. While the dimple is also found among the invertebrate parvoviruses, they typically lack the 3-fold protrusions and canyon around the 5-fold channel. The external diameter of the capsid ranges from ~21.5 nanometers (nm) at the lowest points of the dimple and canyon to ~28 nm at the top of the protrusion.

The genome is a linear, single-stranded DNA 5.5 kilobases in length with disparate terminal hairpin structures at each end.

The genome encodes 3 open reading frames (ORF1, 2 and 3). The left ORF encodes 4 non structural proteins (NS1, NS2, NS3 and NS4). The middle ORF encodes NP1. The right hand ORF (ORF3) encodes the capsid proteins (VP1, VP2, and VP3). The NP1 gene is in an alternate reading frame to VP1 and overlaps the start of VP1 by 13 nucleotides. Similarly, VP3 is collinear to VP1 and VP2 and results from initiation of translation at a downstream ATG and co-terminates. VP2 is translated from a non-canonical start codon GUG.

A viral noncoding RNA of 140 nucleotides, named as bocavirus-encoded small RNA (BocaSR), is expressed from the 3' noncoding region after the VP ORF.

NP1 is a small non-structural protein that could induce apoptosis in transfection of HeLa cells.[11]

There is a single promoter located within the 3' hairpin. This is responsible for, by alternative splicing and alternative polyadenylation, for the generation of several (at least 6) mRNAs.[12] The poly A tail is about 150 nucleotides in length.

After nuclear import the single stranded genome is converted to double stranded DNA and production of the viral NS1 protein commences.

The genome is replicated through a unique linear rolling hairpin mechanism that is dependent on the NS1 protein.[13] Replication has been reported to result in the creation of a series of circular head to tail sequences.[14]

A sequence conserved among the Parvoviridae TAAAAAT is found close to the 3' terminus.

Other parvoviruses replicate only when the host cell is in S phase: viral replication results in the death of the host cell. This pattern has not yet been experimentally confirmed for the bocaviruses but seems likely to be the case. Expression of the viral proteins alone does not cause host cell death.[15] unlike other parvoviruses where this has been examined.

The receptor for bovine parvovirus 1 is sialic acid.

Molecular biology edit

As overviewed in reference 2, parvoviral rolling hairpin replication is a linear adaptation of the rolling-circle replication (RCR) mechanisms used by many small plasmids and viruses. NS1, the multifunctional viral replication initiation protein, forms an oligomeric multidomain molecule that has both site- and strand-specific HuH endonuclease and superfamily III (SF3) helicase activity. All SF3 helicases travel along DNA in a 3-to-5 direction. Four conserved sequence motifs are found in SF3 helicases (A, B, B, and C). These motifs form the nucleoside triphosphate binding pocket, the metal ion coordination site, the DNA-binding site and the sensory element. These motifs are in a stretch of approximately 100 amino acid residues in the middle of NS1. These helicases surround DNA as a ring of six or eight subunits with the ATP binding pocket lying between adjacent subunits. The first subunit provides the A and B motifs, and the arginine residue of the second subunit functions as a trans-acting arginine finger sensor for ATP binding and hydrolysis status. The arginine finger lies after the C motif but in three dimensions it is often embedded in a cluster of positively charged amino acids. In a ring configuration this domain interacts with the ATP binding pocket of the neighboring subunit.

The atomic structure of the HuH endonuclease domain of HBoV1 NS1[16] closely resembles the nickase structures encoded by other parvoviruses and by more-distant RCR replicons. This structure also mediates site-specific duplex DNA-recognition, which allows NS1 to bind site-specifically to viral replication origins positioned at each end of its genome (derived from the sequences of the viral hairpin telomeres). Origin recognition, which for some parvoviruses must be enhanced by the binding of additional cellular cofactors, leads to strand- and site-specific nicking of viral duplex DNA replication intermediates, processes that require ATP for tight binding and subsequent nicking. The NS1 protein remains covalently linked to the 5 end of nicked DNA, while the new 3-hydroxyl group is able to prime synthesis of additional linear sequences. Replication of the genome is thought to be mediated by DNA repair DNA polymerases. This process involves the single strand-binding protein replication protein A and NS1. In this process NS1 acts as an ATP powered helicase to resolve terminal hairpin structures of the viral genome.

NS1 is also responsible for the cytopathic effect of some parvoviruses, and there is evidence to indicate that some form of this protein associates with one of the 5-fold cylinders of newly assembled capsids where it serves as a molecular motor, using its 3'-to-5' helicase activity to drive the encapsidation of progeny single stranded DNA into the particle.[17]

Genetics edit

There are four known human genotypes of this virus: type 1 to 4. Types 1 and 2 appear to have diverged recently (circa 1985)[18] The estimated mean evolutionary rate is 8.6×10−4 substitutions/site/year. The 1st + 2nd codon positions evolve 15 times more slowly than those of the 3rd codon position.

There is 78%, 67%, and 80% identity between Human Bocavirus 1 and 2 NS1, NP1, and VP1/VP2 proteins respectively.[19] Recombination may occur between strains. Human bocavirus 3 appears to be a recombinant of human bocavirus 1 and human bocavirus 2 and 4.[20]

Bocaviruses have been isolated from pigs.[21] Phylogenetic analysis of swine bocavirus places it with canine minute virus.[22]

Incomplete sequences of bocaviruses have been obtained from wild chimpanzees.[23] These sequences phylogenetically lie within the known human bocavirus isolates but also show evidence of recombination.

Clinical edit

 
Chest radiograph of a 16-month-old boy in Finland with human bocavirus 1 pneumonia, on day 2 of hospitalization. Bilateral pulmonary infiltrations and atelectasis of the upper right lobe can be seen.

HBoV is found in respiratory samples from healthy subjects.[24] In patients with respiratory complaints, it can be found alone or, more often, in combination with other viruses known to cause respiratory complaints.[6] Newborns are probably protected by passive immunisation.[25] The age group most frequently affected appear to be children between the ages of six months to two years,[25][26] although cases in children older than five and even in a 28-year-old have been reported.[27]

HBoV can be detected not only in respiratory samples but also in blood, urine, and stools. The latter two may merely reflect viral shedding, although diarrhoea has been described in animal bocaviral infections, and some patients with HBoV seem to have diarrhoea independent of respiratory symptoms.[28][29]

A study in Jordan found that 9% of 220 children hospitalised with lower respiratory tract infection were infected with bocavirus.[30] Of those infected the median age was 4 months. Coughing (100%), wheezing (82.7%) and fever (68.2%) were the most common clinical findings with bronchopneumonia (35%) and bronchiolitis (30%) being the most common ultimate diagnoses.

HBoV1 has been generally associated with respiratory symptoms while other HBoV tend to be associated with diarrhea and acute flaccid paralysis.

Although most cases are mild, severe respiratory disease has also been reported.[31]

Life-threatening infection caused by human bocavirus was described in previously healthy 20-months old prematurely born child.[32]

References edit

  1. ^ "ICTV 10th Report (2018)Bocaparvovirus".[dead link]
  2. ^ "ICTV 10th Report (2018)".
  3. ^ Allander T, Tammi MT, Eriksson M, Bjerkner A, Tiveljung-Lindell A, Andersson B (September 2005). "Cloning of a human parvovirus by molecular screening of respiratory tract samples". Proc. Natl. Acad. Sci. U.S.A. 102 (36): 12891–6. Bibcode:2005PNAS..10212891A. doi:10.1073/pnas.0504666102. PMC 1200281. PMID 16118271.
  4. ^ Allander T, Andreasson K, Gupta S, et al. (2007). "Identification of a third human polyomavirus". J. Virol. 81 (8): 4130–6. doi:10.1128/JVI.00028-07. PMC 1866148. PMID 17287263.
  5. ^ Gaynor AM, Nissen MD, Whiley DM, et al. (2007). "Identification of a novel polyomavirus from patients with acute respiratory tract infections". PLOS Pathog. 3 (5): e64. doi:10.1371/journal.ppat.0030064. PMC 1864993. PMID 17480120.
  6. ^ a b Ricour C, Goubau P (2008). "Human bocavirus, a newly discovered parvovirus of the respiratory tract". Acta Clin Belg. 63 (5): 329–34. doi:10.1179/acb.2008.064. PMID 19186566. S2CID 11719085.
  7. ^ Allander T, Jartti T, Gupta S, et al. (April 2007). "Human bocavirus and acute wheezing in children". Clin. Infect. Dis. 44 (7): 904–10. doi:10.1086/512196. PMC 7107819. PMID 17342639.
  8. ^ Pozo F, García-García ML, Calvo C, Cuesta I, Pérez-Breña P, Casas I (November 2007). "High incidence of human bocavirus infection in children in Spain". J. Clin. Virol. 40 (3): 224–8. doi:10.1016/j.jcv.2007.08.010. PMC 7108365. PMID 17904416.
  9. ^ Schwartz D, Green B, Carmichael LE, Parrish CR (October 2002). "The canine minute virus (minute virus of canines) is a distinct parvovirus that is most similar to bovine parvovirus". Virology. 302 (2): 219–23. doi:10.1006/viro.2002.1674. PMID 12441065.
  10. ^ a b Gurda BL, Parent KN, Bladek H, Sinkovits RS, DiMattia MA, Rence C, Castro A, McKenna R, Olson N, Brown K, Baker TS, Agbandje-McKenna M (2010). "Human bocavirus capsid structure: insights into the structural repertoire of the parvoviridae". J. Virol. 84 (12): 5880–9. doi:10.1128/JVI.02719-09. PMC 2876641. PMID 20375175.
  11. ^ Sun B, Cai Y, Li Y, Li J, Liu K, Li Y, Yang Y (2013). "The nonstructural protein NP1 of human bocavirus 1 induces cell cycle arrest and apoptosis in Hela cells". Virology. 440 (1): 75–83. doi:10.1016/j.virol.2013.02.013. PMID 23507451.
  12. ^ Qiu J, Cheng F, Johnson FB, Pintel D (2007). "The transcription profile of the bocavirus bovine parvovirus is unlike those of previously characterized parvoviruses". J. Virol. 81 (21): 12080–5. doi:10.1128/JVI.00815-07. PMC 2168810. PMID 17715221.
  13. ^ Tattersall P, Ward DC (1976). "Rolling hairpin model for replication of parvovirus and linear chromosomal DNA". Nature. 263 (5573): 106–9. Bibcode:1976Natur.263..106T. doi:10.1038/263106a0. PMID 967244. S2CID 4216631.
  14. ^ Zhao H, Zhao L, Sun Y, Qian Y, Liu L, Jia L, Zhang Y, Dong H (2012). "Detection of a bocavirus circular genome in fecal specimens from children with acute diarrhea in Beijing, China". PLOS ONE. 7 (11): e48980. Bibcode:2012PLoSO...748980Z. doi:10.1371/journal.pone.0048980. PMC 3487788. PMID 23133667.
  15. ^ Chen AY, Cheng F, Lou S, Luo Y, Liu Z, Delwart E, Pintel D, Qiu J (2010). "Characterization of the gene expression profile of human bocavirus". Virology. 403 (2): 145–54. doi:10.1016/j.virol.2010.04.014. PMC 2879452. PMID 20457462.
  16. ^ Tewary SK, Zhao H, Shen W, Qiu J, Tang L (2013). "Structure of the NS1 protein N-terminal origin recognition/nickase domain from the emerging human bocavirus". J. Virol. 87 (21): 11487–93. doi:10.1128/JVI.01770-13. PMC 3807368. PMID 23966383.
  17. ^ Plevka P, Hafenstein S, Li L, D'Abrgamo A Jr, Cotmore SF, Rossmann MG, Tattersall P (2011). "Structure of a packaging-defective mutant of minute virus of mice indicates that the genome is packaged via a pore at a 5-fold axis". J. Virol. 85 (10): 4822–7. doi:10.1128/JVI.02598-10. PMC 3126206. PMID 21367911.
  18. ^ Zehender G, De Maddalena C, Canuti M, Zappa A, Amendola A, Lai A, Galli M, Tanzi E (2010). "Rapid molecular evolution of human bocavirus revealed by Bayesian coalescent inference". Infect. Genet. Evol. 10 (2): 215–20. doi:10.1016/j.meegid.2009.11.011. PMID 19932194.
  19. ^ Kapoor A, Slikas E, Simmonds P, Chieochansin T, Naeem A, Shaukat S, Alam MM, Sharif S, Angez M, Zaidi S, Delwart E (2009). "A newly identified bocavirus species in human stool". J. Infect. Dis. 199 (2): 196–200. doi:10.1086/595831. PMC 2678954. PMID 19072716.
  20. ^ Cheng W, Chen J, Xu Z, Yu J, Huang C, Jin M, Li H, Zhang M, Jin Y, Duan ZJ (2011). "Phylogenetic and recombination analysis of human bocavirus 2". BMC Infect. Dis. 11: 50. doi:10.1186/1471-2334-11-50. PMC 3056791. PMID 21345238.
  21. ^ Lau SK, Woo PC, Yip CC, Li KS, Fu CT, Huang Y, Chan KH, Yuen KY (2011). "Co-existence of multiple strains of two novel porcine bocaviruses in the same pig, a previously undescribed phenomenon in members of the family Parvoviridae, and evidence for inter- and intra-host genetic diversity and recombination". J. Gen. Virol. 92 (Pt 9): 2047–59. doi:10.1099/vir.0.033688-0. PMID 21632566.
  22. ^ Zeng S, Wang D, Fang L, Ma J, Song T, Zhang R, Chen H, Xiao S (2011). "Complete coding sequences and phylogenetic analysis of porcine bocavirus". J. Gen. Virol. 92 (Pt 4): 784–8. doi:10.1099/vir.0.028340-0. PMID 21228124.
  23. ^ Sharp CP, LeBreton M, Kantola K, Nana A, Diffo Jle D, Djoko CF, Tamoufe U, Kiyang JA, Babila TG, Ngole EM, Pybus OG, Delwart E, Delaporte E, Peeters M, Soderlund-Venermo M, Hedman K, Wolfe ND, Simmonds P (2010). "Widespread infection with homologues of human parvoviruses B19, PARV4, and human bocavirus of chimpanzees and gorillas in the wild". J. Virol. 84 (19): 10289–96. doi:10.1128/JVI.01304-10. PMC 2937811. PMID 20668071.
  24. ^ Fry AM, Lu X, Chittaganpitch M, et al. (April 2007). "Human bocavirus: a novel parvovirus epidemiologically associated with pneumonia requiring hospitalization in Thailand". J. Infect. Dis. 195 (7): 1038–45. doi:10.1086/512163. PMC 7109861. PMID 17330795.
  25. ^ a b Ma X, Endo R, Ishiguro N, et al. (March 2006). "Detection of human bocavirus in Japanese children with lower respiratory tract infections". J. Clin. Microbiol. 44 (3): 1132–4. doi:10.1128/JCM.44.3.1132-1134.2006. PMC 1393160. PMID 16517912.
  26. ^ Endo R, Ishiguro N, Kikuta H, et al. (October 2007). "Seroepidemiology of human bocavirus in Hokkaido prefecture, Japan". J. Clin. Microbiol. 45 (10): 3218–23. doi:10.1128/JCM.02140-06. PMC 2045318. PMID 17699639.
  27. ^ Kupfer B, Vehreschild J, Cornely O, et al. (October 2006). "Severe pneumonia and human bocavirus in adult". Emerging Infect. Dis. 12 (10): 1614–6. doi:10.3201/eid1210.060520. PMC 3290954. PMID 17176591.
  28. ^ Lau SK, Yip CC, Que TL, et al. (October 2007). "Clinical and molecular epidemiology of human bocavirus in respiratory and fecal samples from children in Hong Kong" (PDF). J. Infect. Dis. 196 (7): 986–93. doi:10.1086/521310. PMC 7111856. PMID 17763318.
  29. ^ Vicente D, Cilla G, Montes M, Pérez-Yarza EG, Pérez-Trallero E (April 2007). "Human bocavirus, a respiratory and enteric virus". Emerging Infect. Dis. 13 (4): 636–7. doi:10.3201/eid1304.061501. PMC 2725986. PMID 17553287.
  30. ^ Al-Rousan HO, Meqdam MM, Alkhateeb A, Al-Shorman A, Qaisy LM, Al-Moqbel MS (2011). "Human bocavirus in Jordan: prevalence and clinical symptoms in hospitalised paediatric patients and molecular virus characterisation" (PDF). Singapore Med J. 52 (5): 365–9. PMID 21633772.
  31. ^ Edner N, Castillo-Rodas P, Falk L, Hedman K, Söderlund-Venermo M, Allander T (2012). "Life-threatening respiratory tract disease with human bocavirus-1 infection in a 4-year-old child". J. Clin. Microbiol. 50 (2): 531–2. doi:10.1128/JCM.05706-11. PMC 3264148. PMID 22135260.
  32. ^ Ursic T, Steyer A, Kopriva S, Kalan G, Krivec U, Petrovec M (2011). "Human bocavirus as the cause of a life-threatening infection". J. Clin. Microbiol. 49 (3): 1179–81. doi:10.1128/JCM.02362-10. PMC 3067724. PMID 21227992.

External links edit

 
Wikimedia Commons has media related to Human bocavirus.
  • Allander T (January 2008). "Human bocavirus". J. Clin. Virol. 41 (1): 29–33. doi:10.1016/j.jcv.2007.10.026. PMID 18055252.
  • ViralZone: Bocavirus
  • "Human bocavirus". NCBI Taxonomy Browser. 329641.

December 15, 2023
human, bocavirus, confused, with, bornavirus, bocas, virus, coronavirus, hbov, name, given, viruses, genus, bocaparvovirus, virus, family, parvoviridae, that, known, infect, humans, hbov1, hbov3, gorilla, bocaparvovirus, members, species, primate, bocaparvovir. Not to be confused with Bornavirus or Bocas virus a Coronavirus Human bocavirus HBoV is the name given to all viruses in the genus Bocaparvovirus of virus family Parvoviridae 2 that are known to infect humans HBoV1 and HBoV3 and gorilla bocaparvovirus are members of species Primate bocaparvovirus 1 whereas viruses HBoV2 and HBoV4 belong to species Primate bocaparvovirus 2 Some of these viruses cause human disease HBoV1 is strongly implicated in causing some cases of lower respiratory tract infection especially in young children and several of the viruses have been linked to gastroenteritis although the full clinical role of this emerging infectious disease remains to be elucidated Human bocavirusScientific classification unranked VirusRealm MonodnaviriaKingdom ShotokuviraePhylum CossaviricotaClass QuintoviricetesOrder PiccoviralesFamily ParvoviridaeSubfamily ParvovirinaeGenus BocaparvovirusGroups includedMember viruses 1 Human bocavirus 1 Human bocavirus 2 Human bocavirus 3 Human bocavirus 4Cladistically included but traditionally excluded taxaAll other viruses and strains in species Primate bocaparvovirus 1 Primate bocaparvovirus 2 Contents 1 History 2 Virology 3 Molecular biology 4 Genetics 5 Clinical 6 References 7 External linksHistory editAllander and colleagues at the Karolinska Institutet in Stockholm Sweden first cloned the coding sequence of this new member of the family of Parvoviridae in 2005 from pooled nasopharyngeal aspirates NPA collection of aspirated fluid from the back of the nasal cavity 3 They used a novel technique called molecular virus screening based on random cloning and bioinformatical analysis This technique has led to the discovery of new viruses such as polyomavirus KI Karolinska Institute 4 and WU Washington University 5 which are closely related to each other and have been isolated from respiratory secretions Several groups of scientists have since then found that HBoV is the fourth most common virus in respiratory samples 6 7 behind rhinoviruses respiratory syncytial virus and adenoviruses 8 The name bocavirus is derived from bovine and canine referring to the two known hosts for the founder members of this genus bovine parvovirus which infects cattle and minute virus of canines which infects dogs 9 Parvoviruses Latin small viruses have a 5 kilobase long single stranded DNA and they use some of their host s replication proteins to copy their DNA Virology editThe virions are small diameter 18 26 nanometers icosahedral and non enveloped The capsid has T 1 symmetry and consists of 60 copies of coat protein The coat proteins have a conserved eight stranded beta barrel motif that forms the core of the capsid There is also a conserved alpha helix 10 The HBoV capsid shares three characteristic features also found in the other vertebrate parvoviruses 10 1 a dimple like depression at each icosahedral 2 fold axis 2 a large trimeric protrusion at or surrounding each 3 fold axis 3 a cylindrical projection surrounding each 5 fold axis that encloses a central channel which connects the inside of the particle with its exterior and serves as the entry and exit portal for viral DNA This 5 fold cylinder is itself encircled by a wide canyon like depression While the dimple is also found among the invertebrate parvoviruses they typically lack the 3 fold protrusions and canyon around the 5 fold channel The external diameter of the capsid ranges from 21 5 nanometers nm at the lowest points of the dimple and canyon to 28 nm at the top of the protrusion The genome is a linear single stranded DNA 5 5 kilobases in length with disparate terminal hairpin structures at each end The genome encodes 3 open reading frames ORF1 2 and 3 The left ORF encodes 4 non structural proteins NS1 NS2 NS3 and NS4 The middle ORF encodes NP1 The right hand ORF ORF3 encodes the capsid proteins VP1 VP2 and VP3 The NP1 gene is in an alternate reading frame to VP1 and overlaps the start of VP1 by 13 nucleotides Similarly VP3 is collinear to VP1 and VP2 and results from initiation of translation at a downstream ATG and co terminates VP2 is translated from a non canonical start codon GUG A viral noncoding RNA of 140 nucleotides named as bocavirus encoded small RNA BocaSR is expressed from the 3 noncoding region after the VP ORF NP1 is a small non structural protein that could induce apoptosis in transfection of HeLa cells 11 There is a single promoter located within the 3 hairpin This is responsible for by alternative splicing and alternative polyadenylation for the generation of several at least 6 mRNAs 12 The poly A tail is about 150 nucleotides in length After nuclear import the single stranded genome is converted to double stranded DNA and production of the viral NS1 protein commences The genome is replicated through a unique linear rolling hairpin mechanism that is dependent on the NS1 protein 13 Replication has been reported to result in the creation of a series of circular head to tail sequences 14 A sequence conserved among the Parvoviridae TAAAAAT is found close to the 3 terminus Other parvoviruses replicate only when the host cell is in S phase viral replication results in the death of the host cell This pattern has not yet been experimentally confirmed for the bocaviruses but seems likely to be the case Expression of the viral proteins alone does not cause host cell death 15 unlike other parvoviruses where this has been examined The receptor for bovine parvovirus 1 is sialic acid Molecular biology editAs overviewed in reference 2 parvoviral rolling hairpin replication is a linear adaptation of the rolling circle replication RCR mechanisms used by many small plasmids and viruses NS1 the multifunctional viral replication initiation protein forms an oligomeric multidomain molecule that has both site and strand specific HuH endonuclease and superfamily III SF3 helicase activity All SF3 helicases travel along DNA in a 3 to 5 direction Four conserved sequence motifs are found in SF3 helicases A B B and C These motifs form the nucleoside triphosphate binding pocket the metal ion coordination site the DNA binding site and the sensory element These motifs are in a stretch of approximately 100 amino acid residues in the middle of NS1 These helicases surround DNA as a ring of six or eight subunits with the ATP binding pocket lying between adjacent subunits The first subunit provides the A and B motifs and the arginine residue of the second subunit functions as a trans acting arginine finger sensor for ATP binding and hydrolysis status The arginine finger lies after the C motif but in three dimensions it is often embedded in a cluster of positively charged amino acids In a ring configuration this domain interacts with the ATP binding pocket of the neighboring subunit The atomic structure of the HuH endonuclease domain of HBoV1 NS1 16 closely resembles the nickase structures encoded by other parvoviruses and by more distant RCR replicons This structure also mediates site specific duplex DNA recognition which allows NS1 to bind site specifically to viral replication origins positioned at each end of its genome derived from the sequences of the viral hairpin telomeres Origin recognition which for some parvoviruses must be enhanced by the binding of additional cellular cofactors leads to strand and site specific nicking of viral duplex DNA replication intermediates processes that require ATP for tight binding and subsequent nicking The NS1 protein remains covalently linked to the 5 end of nicked DNA while the new 3 hydroxyl group is able to prime synthesis of additional linear sequences Replication of the genome is thought to be mediated by DNA repair DNA polymerases This process involves the single strand binding protein replication protein A and NS1 In this process NS1 acts as an ATP powered helicase to resolve terminal hairpin structures of the viral genome NS1 is also responsible for the cytopathic effect of some parvoviruses and there is evidence to indicate that some form of this protein associates with one of the 5 fold cylinders of newly assembled capsids where it serves as a molecular motor using its 3 to 5 helicase activity to drive the encapsidation of progeny single stranded DNA into the particle 17 Genetics editThere are four known human genotypes of this virus type 1 to 4 Types 1 and 2 appear to have diverged recently circa 1985 18 The estimated mean evolutionary rate is 8 6 10 4 substitutions site year The 1st 2nd codon positions evolve 15 times more slowly than those of the 3rd codon position There is 78 67 and 80 identity between Human Bocavirus 1 and 2 NS1 NP1 and VP1 VP2 proteins respectively 19 Recombination may occur between strains Human bocavirus 3 appears to be a recombinant of human bocavirus 1 and human bocavirus 2 and 4 20 Bocaviruses have been isolated from pigs 21 Phylogenetic analysis of swine bocavirus places it with canine minute virus 22 Incomplete sequences of bocaviruses have been obtained from wild chimpanzees 23 These sequences phylogenetically lie within the known human bocavirus isolates but also show evidence of recombination Clinical edit nbsp Chest radiograph of a 16 month old boy in Finland with human bocavirus 1 pneumonia on day 2 of hospitalization Bilateral pulmonary infiltrations and atelectasis of the upper right lobe can be seen HBoV is found in respiratory samples from healthy subjects 24 In patients with respiratory complaints it can be found alone or more often in combination with other viruses known to cause respiratory complaints 6 Newborns are probably protected by passive immunisation 25 The age group most frequently affected appear to be children between the ages of six months to two years 25 26 although cases in children older than five and even in a 28 year old have been reported 27 HBoV can be detected not only in respiratory samples but also in blood urine and stools The latter two may merely reflect viral shedding although diarrhoea has been described in animal bocaviral infections and some patients with HBoV seem to have diarrhoea independent of respiratory symptoms 28 29 A study in Jordan found that 9 of 220 children hospitalised with lower respiratory tract infection were infected with bocavirus 30 Of those infected the median age was 4 months Coughing 100 wheezing 82 7 and fever 68 2 were the most common clinical findings with bronchopneumonia 35 and bronchiolitis 30 being the most common ultimate diagnoses HBoV1 has been generally associated with respiratory symptoms while other HBoV tend to be associated with diarrhea and acute flaccid paralysis Although most cases are mild severe respiratory disease has also been reported 31 Life threatening infection caused by human bocavirus was described in previously healthy 20 months old prematurely born child 32 References edit ICTV 10th Report 2018 Bocaparvovirus dead link ICTV 10th Report 2018 Allander T Tammi MT Eriksson M Bjerkner A Tiveljung Lindell A Andersson B September 2005 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521310 PMC 7111856 PMID 17763318 Vicente D Cilla G Montes M Perez Yarza EG Perez Trallero E April 2007 Human bocavirus a respiratory and enteric virus Emerging Infect Dis 13 4 636 7 doi 10 3201 eid1304 061501 PMC 2725986 PMID 17553287 Al Rousan HO Meqdam MM Alkhateeb A Al Shorman A Qaisy LM Al Moqbel MS 2011 Human bocavirus in Jordan prevalence and clinical symptoms in hospitalised paediatric patients and molecular virus characterisation PDF Singapore Med J 52 5 365 9 PMID 21633772 Edner N Castillo Rodas P Falk L Hedman K Soderlund Venermo M Allander T 2012 Life threatening respiratory tract disease with human bocavirus 1 infection in a 4 year old child J Clin Microbiol 50 2 531 2 doi 10 1128 JCM 05706 11 PMC 3264148 PMID 22135260 Ursic T Steyer A Kopriva S Kalan G Krivec U Petrovec M 2011 Human bocavirus as the cause of a life threatening infection J Clin Microbiol 49 3 1179 81 doi 10 1128 JCM 02362 10 PMC 3067724 PMID 21227992 External links edit nbsp Wikimedia Commons has media related to Human bocavirus Allander T January 2008 Human bocavirus J Clin Virol 41 1 29 33 doi 10 1016 j jcv 2007 10 026 PMID 18055252 ViralZone Bocavirus Human bocavirus NCBI Taxonomy Browser 329641 Retrieved from https en wikipedia org w index php title Human bocavirus amp oldid 1179733877, wikipedia, wiki, book, books, library,

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