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Human parainfluenza viruses

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Human parainfluenza viruses
Transmission electron micrograph of a parainfluenza virus. Two intact particles and free filamentous nucleocapsid
Transmission electron micrograph of a parainfluenza virus. Two intact particles and free filamentous nucleocapsid
Scientific classificationEdit this classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Negarnaviricota
Class: Monjiviricetes
Order: Mononegavirales
Family: Paramyxoviridae
Groups included
Cladistically included but traditionally excluded taxa

Human parainfluenza viruses (HPIVs) are the viruses that cause human parainfluenza. HPIVs are a paraphyletic group of four distinct single-stranded RNA viruses belonging to the Paramyxoviridae family. These viruses are closely associated with both human and veterinary disease.[2] Virions are approximately 150–250 nm in size and contain negative sense RNA with a genome encompassing about 15,000 nucleotides.[3]

Fusion glycoprotein trimer, Human parainfluenza virus 3 (HPIV3).

The viruses can be detected via cell culture, immunofluorescent microscopy, and PCR.[4] HPIVs remain the second main cause of hospitalisation in children under 5 years of age for a respiratory illness (only respiratory syncytial virus (RSV) causes more respiratory hospitalisations for this age group).[5]

Classification

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The first HPIV was discovered in the late 1950s. The taxonomic division is broadly based on antigenic and genetic characteristics, forming four major serotypes or clades, which today are considered distinct viruses.[6] These include:

Virus GenBank acronym NCBI taxonomy Notes
Human parainfluenza virus type 1 HPIV-1 12730 Most common cause of croup
Human parainfluenza virus type 2 HPIV-2 11212 Causes croup and other upper and lower respiratory tract illnesses
Human parainfluenza virus type 3 HPIV-3 11216 Associated with bronchiolitis and pneumonia
Human parainfluenza virus type 4 HPIV-4 11203 Includes subtypes 4a and 4b

HPIVs belong to two genera: Respirovirus (HPIV-1 & HPIV-3) and Rubulavirus (HPIV-2 & HPIV-4).[3]

Viral structure and organisation

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HPIVs are characterised by producing enveloped virions and containing single stranded negative sense RNA.[3] Non-infectious virions have also been reported to contain RNA with positive polarity.[3] HPIV genomes are about 15,000 nucleotides in length and encode six key structural proteins.[3]

The structural gene sequence of HPIVs is as follows: 3′-NP-P-M-F-HN-L-5′ (the protein prefixes and further details are outlined in the table below).[7]

Structural protein Location Function
Hemagglutinin-neuraminidase (HN) Envelope Attachment and cell entry
Fusion Protein (F) Envelope Fusion and cell entry
Matrix Protein (M) Within the envelope Assembly
Nucleoprotein (NP) Nucleocapsid Forms a complex with the RNA genome
Phosphoprotein (P) Nucleocapsid Forms as part of RNA polymerase complex
Large Protein (L) Nucleocapsid Forms as part of RNA polymerase complex

With the advent of reverse genetics, it has been found that the most efficient human parainfluenza viruses (in terms of replication and transcription) have a genome nucleotide total that is divisible by the number 6. This has led to the "rule of six" being coined. Exceptions to the rule have been found, and its exact advantages are not fully understood.[8]

Electrophoresis has shown that the molecular weight of the proteins for the four HPIVs are similar (with the exception of the phosphoprotein, which shows significant variation).[3][9]

Viral entry and replication

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Viral replication is initiated only after successful entry into a cell by attachment and fusion between the virus and the host cell lipid membrane. Viral RNA (vRNA) is initially associated with nucleoprotein (NP), phosphoprotein (P) and the large protein (L). The hemagglutininneuraminidase (HN) is involved with viral attachment and thus hemadsorption and hemagglutination. Furthermore, the fusion (F) protein is important in aiding the fusion of the host and viral cellular membranes, eventually forming syncytia.[10]

Initially the F protein is in an inactive form (F0) but can be cleaved by proteolysis to form its active form, F1 and F2, linked by di-sulphide bonds. Once complete, this is followed by the HPIV nucleocapsid entering the cytoplasm of the cell. Subsequently, genomic transcription occurs using the viruses own 'viral RNA-dependent RNA polymerase' (L protein). The cell's own ribosomes are then tasked with translation, forming the viral proteins from the viral mRNA.[10]

Towards the end of the process, (after the formation of the viral proteins) the replication of the viral genome occurs. Initially, this occurs with the formation of a positive-sense RNA (intermediate step, necessary for producing progeny), and finally, negative-sense RNA is formed which is then associated with the nucleoprotein. This may then be either packaged and released from the cell by budding or used for subsequent rounds of transcription and replication.[11]

The observable and morphological changes that can be seen in infected cells include the enlargement of the cytoplasm, decreased mitotic activity and 'focal rounding', with the potential formation of multi-nucleate cells (syncytia).[12]

The pathogenicity of HPIVs is mutually dependent on the viruses having the correct accessory proteins that are able to elicit anti-interferon properties. This is a major factor in the clinical significance of disease.[11]

Host range

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The main host remains the human. However, infections have been induced in other animals (both under natural and experimental situations), although these were always asymptomatic.[13]

Clinical significance

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It is estimated that there are 5 million children with lower respiratory infections (LRI) each year in the United States alone.[14] HPIV-1, HPIV-2 and HPIV-3 have been linked with up to a third of these infections.[15] Upper respiratory infections (URI) are also important in the context of HPIV, however, they are caused to a lesser extent by the virus.[16] The highest rates of serious HPIV illnesses occur among young children, and surveys have shown that about 75% of children aged 5 or older have antibodies to HPIV-1.[citation needed]

For infants and young children, it has been estimated that about 25% will develop "clinically significant disease".[17]

Repeated infection throughout the life of the host is not uncommon and symptoms of later breakouts include upper respiratory tract illness, such as cold and a sore throat.[3] The incubation period for all four serotypes is 1 to 7 days.[18] In immunosuppressed people, parainfluenza virus infections can cause severe pneumonia, which can be fatal.[19]

HPIV-1 and HPIV-2 have been demonstrated to be the principal causative agent behind croup (laryngotracheobronchitis), which is a viral disease of the upper airway and is mainly problematic in children aged 6–48 months of age.[20][21] Biennial epidemics starting in autumn are associated with both HPIV-1 and -2; however, HPIV-2 can also have yearly outbreaks.[14] Additionally, HPIV-1 tends to cause biennial outbreaks of croup in the fall. In the United States, large peaks have presently been occurring during odd-numbered years.[citation needed]

HPIV-3 has been closely associated with bronchiolitis and pneumonia, and principally targets those aged <1 year.[22]

HPIV-4 remains infrequently detected. It is now believed to be more common than previously thought but less likely to cause severe disease. By the age of 10, the majority of children are seropositive for HPIV-4 infection—this may be indicative of a large proportion of asymptomatic or mild infections.[3]

Those with compromised immunity have a higher risk of infection and mortality and may fall ill with more extreme forms of LRI.[13] Associations between HPIVs and neurologic disease are known. For example, hospitalisation with certain HPIVs has a strong association with febrile seizures.[23] HPIV-4b has the strongest association (up to 62%)[vague] followed by HPIV-3 and -1.[3]

HPIVs have also been linked with rare cases of viral meningitis[24] and Guillain–Barré syndrome.[12]

HPIVs are spread from person to person (i.e., horizontal transmission) by contact with infected secretions in respiratory droplets or contaminated surfaces or objects. Infection can occur when infectious material contacts the mucous membranes of the eyes, mouth, or nose, and possibly through the inhalation of droplets generated by a sneeze or cough. HPIVs can remain infectious in airborne droplets for over an hour.[citation needed]

Airway inflammation

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The inflammation of the airway is a common attribute of HPIV infection. It is believed to occur due to the large scale upregulation of inflammatory cytokines. Common cytokines observed to be upregulated include IFN–α, various interleukins (i.e., IL–2, IL-6), and TNF–α. Various chemokines and inflammatory proteins are also believed to be associated with the common symptoms of HPIV infection.[12]

Recent evidence suggests that the virus-specific antibody immunoglobulin E may be responsible for mediating the large-scale releases of histamine in the trachea that are believed to cause croup.[12][25]

Immunology

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The body's primary defense against HPIV infection is adaptive immunity involving both humoral and cellular immunity. With humoral immunity, antibodies that bind to the surface viral proteins HN and F protect against later infection.[26] Patients with defective cell-mediated immunity also experience more severe infection, suggesting that T cells are important in clearing infection.[12]

Diagnosis

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Diagnosis can be made in several ways, encompassing a range of multi-faceted techniques:[4]

Because of the similarity in terms of the antigenic profile between the viruses, hemagglutination assay (HA) or hemadsorption inhibition (HAdI) processes are often used. Both complement fixation, neutralisation, and enzyme linked immunosorbent assays – ELISA, can also be used to aid in the process of distinguishing between viral serotypes.[3]

Morbidity and mortality

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Mortality caused by HPIVs in developed regions of the world remains rare. Where mortality has occurred, it is principally in the three core risk groups (very young, elderly and immuno-compromised). Long-term changes can however be associated with airway remodeling and are believed to be a significant cause of morbidity.[27] The exact associations between HPIVs and diseases such as chronic obstructive pulmonary disease (COPD) are still being investigated.[28]

In developing regions of the world, preschool children remain the highest mortality risk group. Mortality may be a consequence of primary viral infection or secondary problems, such as bacterial infection. Predispositions, such as malnutrition and other deficiencies, may further elevate the chances of mortality associated with infection.[12]

Overall, LRIs cause approximately 25–30% of total deaths in preschool children in the developing world. HPIVs are believed to be associated with 10% of all LRI cases, thus remaining a significant cause of mortality.[12]

Risk factors

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Numerous factors have been suggested and linked to a higher risk of acquiring the infection, inclusive of malnutrition, vitamin A deficiency, absence of breastfeeding during the early stages of life, environmental pollution and overcrowding.[29]

Prevention

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Despite decades of research, no vaccines currently exist.[30]

Recombinant technology has however been used to target the formation of vaccines for HPIV-1, -2 and -3 and has taken the form of several live-attenuated intranasal vaccines. Two vaccines in particular were found to be immunogenic and well tolerated against HPIV-3 in phase I trials. HPIV-1 and -2 vaccine candidates remain less advanced.[17]

Vaccine techniques which have been used against HPIVs are not limited to intranasal forms, but also viruses attenuated by cold passage, host range attenuation, chimeric construct vaccines and also introducing mutations with the help of reverse genetics to achieve attenuation.[31]

Maternal antibodies may offer some degree of protection against HPIVs during the early stages of life via the colostrum in breast milk.[32]

Medication

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Ribavirin is one medication which has shown good potential for the treatment of HPIV-3 given recent in-vitro tests (in-vivo tests show mixed results).[12] Ribavirin is a broad-spectrum antiviral, and as of 2012, was being administered to those who are severely immuno-compromised, despite the lack of conclusive evidence for its benefit.[12] Protein inhibitors and novel forms of medication have also been proposed to relieve the symptoms of infection.[13]

Furthermore, antibiotics may be used if a secondary bacterial infection develops. Corticosteroid treatment and nebulizers are also a first line choice against croup if breathing difficulties ensue.[12]

Interactions with the environment

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Parainfluenza viruses last only a few hours in the environment and are inactivated by soap and water. Furthermore, the virus can also be easily destroyed using common hygiene techniques and detergents, disinfectants and antiseptics.[4]

Environmental factors which are important for HPIV survival are pH, humidity, temperature and the medium within which the virus is found. The optimal pH is around the physiologic pH values (7.4 to 8.0), whilst at high temperatures (above 37 °C) and low humidity, infectivity reduces.[33]

The majority of transmission has been linked to close contact, especially in nosocomial infections. Chronic care facilities and doctors' surgeries are also known to be transmission 'hotspots' with transmission occurring via aerosols, large droplets and also fomites (contaminated surfaces).[34]

The exact infectious dose remains unknown.[13]

Economic burden

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In economically disadvantaged regions of the world, HPIV infection can be measured in terms of mortality. In the developed world where mortality remains rare, the economic costs of the infection can be estimated. Estimates from the US are suggestive of a cost (based on extrapolation) in the region of $200 million per annum.[3]

References

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  1. ^ "Virus Taxonomy: 2018 Release". International Committee on Taxonomy of Viruses (ICTV). October 2018. Retrieved 25 January 2019.
  2. ^ Vainionpää R, Hyypiä T (April 1994). "Biology of parainfluenza viruses". Clin. Microbiol. Rev. 7 (2): 265–275. doi:10.1128/CMR.7.2.265. PMC 358320. PMID 8055470.
  3. ^ a b c d e f g h i j k Henrickson, KJ (April 2003). "Parainfluenza viruses". Clinical Microbiology Reviews. 16 (2): 242–264. doi:10.1128/CMR.16.2.242-264.2003. PMC 153148. PMID 12692097.
  4. ^ a b c "Human Parainfluenza Viruses". Centers for Disease Control and Prevention (2011). Archived from the original on 20 March 2012. Retrieved 21 March 2012.
  5. ^ Schmidt, Alexander; Anne Schaap-Nutt; Emmalene J Bartlett; Henrick Schomacker; Jim Boonyaratanakornkit; Ruth A Karron; Peter L Collins (1 February 2011). "Progress in the development of human parainfluenza virus vaccines". Expert Review of Respiratory Medicine. 5 (4): 515–526. doi:10.1586/ers.11.32. PMC 3503243. PMID 21859271.
  6. ^ Baron, S.; Enders, G. (1996). "Paramyxoviruses". Parainfluenza Viruses. University of Texas Medical Branch at Galveston. ISBN 9780963117212. PMID 21413341. Retrieved 2009-03-15.
  7. ^ Hunt, Dr. Margaret. "PARAINFLUENZA, RESPIRATORY SYNCYTIAL AND ADENO VIRUSES". Reference.MD. Retrieved 21 March 2012.
  8. ^ Vulliémoz, D; Roux, L (May 2001). "'Rule of six': how does the Sendai virus RNA polymerase keep count?". Journal of Virology. 75 (10): 4506–4518. doi:10.1128/JVI.75.10.4506-4518.2001. PMC 114204. PMID 11312321.
  9. ^ Henrickson, K. J (2003). "Parainfluenza Viruses". Clinical Microbiology Reviews. 16 (2): 242–264. doi:10.1128/CMR.16.2.242-264.2003. PMC 153148. PMID 12692097.
  10. ^ a b Moscona, A (July 2005). "Entry of parainfluenza virus into cells as a target for interrupting childhood respiratory disease". The Journal of Clinical Investigation. 115 (7): 1688–1698. doi:10.1172/JCI25669. PMC 1159152. PMID 16007245.
  11. ^ a b Chambers R, Takimoto T (2011). "Parainfluenza Viruses". Encyclopedia of Life Sciences. Wiley. doi:10.1002/9780470015902.a0001078.pub3. ISBN 978-0470016176. {{cite book}}: |journal= ignored (help)
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  16. ^ "Acute Respiratory Infections". WHO. Archived from the original on March 24, 2006. Retrieved 21 March 2012.
  17. ^ a b Durbin, AP; Karron, RA (December 15, 2003). "Progress in the development of respiratory syncytial virus and parainfluenza virus vaccines". Clinical Infectious Diseases. 37 (12): 1668–1677. doi:10.1086/379775. PMID 14689350. S2CID 41967381.
  18. ^ "General information: human parainfluenza viruses". Health Protection Agency. 27 August 2008. Retrieved 21 March 2012.
  19. ^ Sable CA, Hayden FG (December 1995). "Orthomyxoviral and paramyxoviral infections in transplant patients". Infect. Dis. Clin. North Am. 9 (4): 987–1003. doi:10.1016/S0891-5520(20)30712-1. PMID 8747776.
  20. ^ "CDC - Human Parainfluenza Viruses: Common cold and croup". Archived from the original on 2009-03-03. Retrieved 2009-03-15.
  21. ^ "Croup Background". Medscape Reference. Retrieved 21 March 2012.
  22. ^ "Parainfluenza Virus Review". Medscape. Retrieved 21 March 2012.
  23. ^ Stephen B Greenberg; Robert L Atmar. "Parainfluenza Viruses—New Epidemiology and Vaccine Developments". Touch Infectious Disease. Archived from the original on 21 February 2020. Retrieved 21 March 2012.
  24. ^ Arguedas, A; Stutman, HR; Blanding, JG (March 1990). "Parainfluenza type 3 meningitis. Report of two cases and review of the literature". Clinical Pediatrics. 29 (3): 175–178. doi:10.1177/000992289002900307. PMID 2155085. S2CID 25043753.
  25. ^ "Human Parainfluenza Viruses (HPIV) and Other Parainfluenza Viruses: Background, Pathophysiology, Etiology". 17 October 2021. Retrieved 18 March 2023.
  26. ^ Branche, Angela; Falsey, Ann (2016-08-03). "Parainfluenza Virus Infection". Seminars in Respiratory and Critical Care Medicine. 37 (4): 538–554. doi:10.1055/s-0036-1584798. ISSN 1069-3424. PMC 7171724. PMID 27486735.
  27. ^ Dimopoulos, G; Lerikou, M; Tsiodras, S; Chranioti, A; Perros, E; Anagnostopoulou, U; Armaganidis, A; Karakitsos, P (February 2012). "Viral epidemiology of acute exacerbations of chronic obstructive pulmonary disease". Pulmonary Pharmacology & Therapeutics. 25 (1): 12–8. doi:10.1016/j.pupt.2011.08.004. PMC 7110842. PMID 21983132.
  28. ^ Beckham, JD; Cadena, A; Lin, J; Piedra, PA; Glezen, WP; Greenberg, SB; Atmar, RL (May 2005). "Respiratory viral infections in patients with chronic, obstructive pulmonary disease". The Journal of Infection. 50 (4): 322–30. doi:10.1016/j.jinf.2004.07.011. PMC 7132437. PMID 15845430.
  29. ^ Berman, S (May–Jun 1991). "Epidemiology of acute respiratory infections in children of developing countries". Reviews of Infectious Diseases. 13 (Suppl 6): S454–62. doi:10.1093/clinids/13.supplement_6.s454. PMID 1862276.
  30. ^ Sato M, Wright PF (October 2008). "Current status of vaccines for parainfluenza virus infections". Pediatr. Infect. Dis. J. 27 (10 Suppl): S123–5. doi:10.1097/INF.0b013e318168b76f. PMID 18820572.
  31. ^ "Parainfluenza Viruses". eLS. Retrieved 21 March 2012.
  32. ^ "Definition of Human parainfluenza virus". MedicineNet. Archived from the original on 5 January 2012. Retrieved 21 March 2012.
  33. ^ HAMBLING, MH (December 1964). "Survival of the Respiratory Syncytial Virus During Storage Under Various Conditions". British Journal of Experimental Pathology. 45 (6): 647–55. PMC 2093680. PMID 14245166.
  34. ^ "Common Cold, Croup and Human Parainfluenza Viruses: Symptoms and Prevention". NewsFlu. Retrieved 21 March 2012.

Further reading

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