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Murine coronavirus

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Murines Coronavirus ( Alemão )

fornecido por wikipedia DE

Das Murine Coronavirus ist eine Virusart der Gattung Betacoronavirus und deren Typusart.

Sie wurde 2009 aufgrund genetisch zu naher Verwandtschaft („>97% a[mino]a[cid] identity“) aus den damaligen Arten Murine hepatitis virus, Rat coronavirus und Puffinosis coronavirus gebildet, die dann zu den Unterarten Murines Hepatitisvirus, Ratten-Coronavirus und Puffinosis coronavirus wurden. Sie wurde als Typusart der Gattung Betacoronavirus ausgewählt, welche zur gleichen Zeit aus den bisherigen Gruppe-2-Coronaviren neugebildet wurde.[2]

Einzelnachweise

  1. a b c d e f g h i j ICTV: ICTV Master Species List 2019.v1. MSL #35, März 2020
  2. Raoul J. de Groot, Alexander E. Gorbalenya, Ralph S. Baric und weitere Mitglieder der Coronavirus Study Group: Revision of the family Coronaviridae (en) In: International Committee on Taxonomy of Viruses (ICTV). 2009. Archiviert vom Original am 7. Februar 2019. Abgerufen am 23. Januar 2020: „Murine coronavirus (new) (comprised of existing species Murine hepatitis virus, Rat coronavirus and puffinosis virus) […] Species Murine hepatitis virus; Puffinosis coronavirus; Rat coronavirus (these are to be united in a new species Murine coronavirus in a new genus Betacoronavirus)“
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Murines Coronavirus: Brief Summary ( Alemão )

fornecido por wikipedia DE

Das Murine Coronavirus ist eine Virusart der Gattung Betacoronavirus und deren Typusart.

Sie wurde 2009 aufgrund genetisch zu naher Verwandtschaft („>97% a[mino]a[cid] identity“) aus den damaligen Arten Murine hepatitis virus, Rat coronavirus und Puffinosis coronavirus gebildet, die dann zu den Unterarten Murines Hepatitisvirus, Ratten-Coronavirus und Puffinosis coronavirus wurden. Sie wurde als Typusart der Gattung Betacoronavirus ausgewählt, welche zur gleichen Zeit aus den bisherigen Gruppe-2-Coronaviren neugebildet wurde.

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cc-by-sa-3.0
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Autoren und Herausgeber von Wikipedia
original
visite a fonte
site do parceiro
wikipedia DE

Murine coronavirus ( Inglês )

fornecido por wikipedia EN

Murine coronavirus (M-CoV) is a virus in the genus Betacoronavirus that infects mice.[3] Belonging to the subgenus Embecovirus,[4] murine coronavirus strains are enterotropic or polytropic. Enterotropic strains include mouse hepatitis virus (MHV) strains D, Y, RI, and DVIM, whereas polytropic strains, such as JHM and A59, primarily cause hepatitis, enteritis, and encephalitis.[5] Murine coronavirus is an important pathogen in the laboratory mouse and the laboratory rat. It is the most studied coronavirus in animals other than humans, and has been used as an animal disease model for many virological and clinical studies.[6]

Types

Murine hepatitis virus

Murine coronavirus was first discovered in 1949. The researchers isolated the virus from the brain, spinal cord, liver, lung, spleen, and kidney of a rat with symptoms of encephalitis and severe myelin injury, and gave it the strain name mouse hepatitis virus (MHV)-JHM.[7] MHV is now the most studied coronavirus in animals other than humans,[8] acting as a model organism for coronaviruses.[9]

There are more than 25 different strains of murine coronavirus. Transmitted by the fecal–oral or respiratory route, these viruses infect the livers of mice and have been used as an animal disease model for hepatitis.[10] Transmitted in fecal matter, the strains MHV-D, MHV-DVIM, MHV-Y and MHV-RI mainly infect the digestive tract, sometimes infecting the spleen, liver and lymphatic tissue.[8] MHV-1, MHV-2, MHV-3, MHV-A59, MHV-S, MHV-JHM and other virus strains replicate in the respiratory tract and then spread to other organs such as the liver, lungs and brain. MHV-JHM mainly infects the central nervous system and has been widely studied since 1949. In rats, these nerve-infecting hepatitis viruses can cause acute or chronic neurological symptoms[11] and stimulate the immunity of mice upon infection. Infection leads to demyelination, serving as an animal disease model of multiple sclerosis.[12] MHV-2, MHV-3 and MHV-A59 can also infect the liver; the first two of these are more virulent. MHV-3 is the main virus strain used to study hepatitis; MHV-1 mainly infects the lungs.[13]

Murine hepatitis virus is highly infectious and is one of the most common pathogens in laboratory mice. The symptoms of infection vary according to the type, path of infection, genotype and age of mouse. MHV-1, MHV-S and MHV-Y are weak viral strains; MHV-2, MHV-3, MHV-A5 9 and MHV-JHM are more virulent, being relatively mild in adult mice but having a high mortality in newborns.[8] Infection, even if it does not cause obvious symptoms, may affect the immune system of laboratory subjects and cause errors in the interpretation of experimental results.[14] For example, the virus can replicate in macrophages and affect their function, as well as in the spleen, where infection stimulates natural killer cells and affects T cell and B cells. There is no vaccine to prevent and treat hepatitis virus infection in mice, mainly because of the high mutation rate and the variety of virus strains, as well as concerns that vaccination may itself interfere with the interpretation of experimental research results, but this virus can be used as an experimental model for the development of other coronavirus vaccines.[8]

In 1991, Michael M. C. Lai's laboratory completed the whole genome sequencing of the murine hepatitis virus. With a total length of 31,000 nucleotides, it was the largest RNA virus genome known at that time.[15] In 2002, American virologist Ralph S. Baric developed a reverse genetic system for mouse hepatitis virus in which a complete MHV cDNA was assembled from smaller fragments.[16]

Fancy rat coronavirus

In fancy rats, the rat coronavirus (RCoV or RCV) consists mainly of two virus strains, sialodacryoadenitis virus (SDAV) and Parker's RCoV (RCoV-P), both of which cause respiratory tract infections, with the former also affecting the eyes, Harderian gland, and salivary glands. In the past, it was believed that the symptoms caused by the two infections were different, but in recent years, it has been argued that the symptoms of both include eye and nasal discharge, large salivary gland enlargement, sialadenitis, photosensitivity, keratitis, shortness of breath, and pneumonia, among others.[17][18][19] There is little to no obvious difference,[20] and it has been suggested that Parker's rat coronavirus is only one type of rat salivary adenovirus.[19] It is highly infectious. Generally, the symptoms in young rats are more serious, and some individuals suffer permanent eye damage.[19]

Others

In 1982, researchers found a coronavirus in the brains of mice after isolation of puffinosis coronavirus (PCoV), which causes skin and eye disease in Manx shearwaters. The virus found was very similar to rat hepatitis virus, but due to the use of laboratory mice in the isolation process, the possibility cannot be excluded that it was derived from a mouse and not from the birds.[21] Subsequent studies have shown that the virus has hemagglutinin esterase (HE).[22] If the coronavirus did indeed originate from shearwater, it is one of few bird coronaviruses that is not a gammacoronavirus or deltacoronavirus.[23] In 2009, the International Committee on Taxonomy of Viruses (ICTV) classified this bird coronavirus as belonging to the murine coronavirus clade.[2]

From 2011 to 2013, researchers collected mouse samples at several locations in Zhejiang, China, and discovered three new virus strains in Longquan lesser ricefield rat, collectively described in 2015 as Longquan Rl rat coronavirus (LRLV).[24]

Genome

Rat coronavirus is a positive-stranded single-strand RNA virus with an outer membrane. It has a genome size of about 31,000 nucleotides. In addition to the four structural proteins of coronaviruses — spike protein (S), membrane protein (M), envelope protein (E) and nucleocapsid protein (N) — some mouse coronavirus surfaces also have hemagglutinin esterase (HE). HE can bind to sialic acid on the surface of the host cell and promote viral infection, and has acetyl esterase activity, which can degrade receptors to release the bound virus.[11] The virus also has four auxiliary proteins — 2a, 4, 5a and I (or N2) (known as NS2, 15k, 12.6k and 7b[17] in rat salivary adenophritis virus or as 2a, 5a, 5b and N2 in Longquan Luosai mouse coronavirus[24]). These auxiliary proteins may counter the host's immune response. The auxiliary protein NS2 (encoded by the 2a gene) has 2′,5′-phosphodiesterase activity; it can degrade 2′,5′-oligoadenylate in the cell and avoid its activation. Ribonuclease L in cells activates the defense mechanism for degrading viral RNA[25] and auxiliary protein 5a inhibits host interferon.[26] The types of auxiliary proteins in different virus strains may differ. For example, MHV-S lacks auxiliary protein 5a, so it is less resistant to interferon.[26] All four auxiliary proteins are dispensable for viral replication.[27][28] The E protein is divided into the E1 and E2 glycoproteins, which are believed to serve different purposes.[29] The genome is ordered 1ab-2a-HE-S-4-5a-E-M-N-I, where 5a and 5b proteins are encoded by the same mRNA[27] and the open reading frame of I is located within the open reading frame of capsid protein N.[30]

Infection

When coronavirus infects the host cell, its spike protein (S) binds to the receptor on the surface of the host cell, which enables the virus to enter the cell. The spike protein is cut by the host's protease at all stages of the formation, transportation and infection of the new cell. The domain that helps the external membrane of the virus fuse with the cell membrane is exposed to facilitate infection. The host cell receptor used by rat coronavirus is generally CEACAM1 (mCEACAM1). The type of infected tissue and the time at which the spike protein is cut vary according to the virus strain. Among them is S1 in the spike protein of MHV-A59. The cleavage site of S2 is cut by proteases such as furin in the host cell when the virus is produced and assembled, and when the virus infects a new cell, further cleavage in the lysosomal pathway is also required for successful infection.[31] The ocyrosin of MHV-2 does not have the S1/S2 cleavage site and is not cut during the assembly process. Its infection depends on cleavage of the spike protein by endosomal enzymes.[32] MHV-JHM (especially the more virulent JHM.SD and JHM-cl2), which infects nerve tissue, may not require surface exposure. The body can infect the cell, that is, it can achieve membrane fusion without binding to the cell receptor, so it can infect structures in the nervous system with little expression of mCEACAM1,[33][34] and its infection may mainly depend on the cutting of its spike protein by the cell surface protease.[35]

When rat hepatitis viruses of different strains infects cells at the same time, template switching can occur while genetic replication is carried out, resulting in gene recombination, which may be important for the evolution of viral diversity.[36][37]

Classification and evolution

Murine coronavirus is believed to be most closely related to human coronavirus HKU1.[38] These two species, along with Betacoronavirus 1, rabbit coronavirus HKU14, and China Rattus coronavirus HKU24, form subgenus Embecovirus[39] within genus Betacoronavirus, according to the classification from the International Committee on Taxonomy of Viruses. This subgenus is distinguished by the presence of a gene encoding hemaglutinin esterase (HE),[38][40] although in many laboratory murine hepatitis virus strains (such as MHV-A59 and MHV-1), this gene has been lost to mutation and persists only as a pseudogene. HE is dispensable for rat hepatitis virus infection and replication,[41] and indeed, hepatitis strains lacking HE appear to have a competitive advantage in vitro.[42]

The N-terminal domain (NTD) of the spike protein of coronavirus is similar to galectin in animal cells.[43] Therefore, it has been suggested that this domain was originally derived from a host animal cell. The cell acquires the gene for a lectin, which can bind to the sugar on the surface of the host cell as an infected cell. Subsequently, the virus in this clade of coronaviruses acquires HE to help the virus get rid of infected cells, but later the NTD of the mouse coronavirus evolved into a new structure that can be associated with the protein receptor mCEACAM1. Combination greatly increases the binding ability of viruses and murine cells. Because it is no longer necessary to bind to sugars, it gradually loses the lectin function, and further loses the HE. In contrast, bovine coronavirus, human coronavirus OC43, and others are still sugar receptors, so the spike NTD retains the function of glutin.[44]

Alphacoronaviruses and betacoronaviruses may all originate from bat viruses, but the subgenus Embecovirus contains many viruses infecting rats (in addition to mouse coronavirus, there are also the Lucheng Rn rat coronavirus, China Rattus coronavirus HKU24 and Myodes coronavirus 2JL14, with a large number of related virus strains[45] found since 2015), and no bat virus has been found. Some scholars suggest that the common ancestor of this clade may be a mouse virus, which was then transmitted by rats to humans and cattle.[45][46]

RNA–RNA recombination

Genetic recombination can occur when at least two RNA viral genomes are present in the same infected host cell. RNA–RNA recombination between different strains of the murine coronavirus was found to occur at a high frequency both in tissue culture[47] and in the mouse central nervous system.[36] These findings suggest that RNA–RNA recombination may play a significant role in the natural evolution and neuropathogenesis of coronaviruses.[36] The mechanism of recombination appears to involve template switching during viral genome replication, a process referred to as copy choice recombination.[36]

Strains

Sialodacryoadenitis virus[48] is a highly infectious coronavirus of laboratory rats that can be transmitted between individuals by direct contact and indirectly by aerosol. Acute infections have high morbidity and tropism for the salivary, lachrymal and Harderian glands.

Rabbit enteric coronavirus causes acute gastrointestinal disease and diarrhea in young European rabbits.[49] Mortality rates are high.[50]

Research

Infection of mice with mouse hepatitis virus has been used as a model system to examine ivermectin as a treatment for coronaviruses.[51]

References

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  49. ^ "Chapter 24 – Coronaviridae". Fenner's Veterinary Virology (Fifth ed.). Academic Press. 2017. pp. 435–461. doi:10.1016/B978-0-12-800946-8.00024-6. ISBN 978-0-12-800946-8. S2CID 219575461.
  50. ^ "Enteric Coronavirus". Diseases of Research Animals. Archived from the original on 1 July 2019. Retrieved 24 January 2020.
  51. ^ Arévalo, A. P.; Pagotto, R.; Pórfido, J. L.; Daghero, H.; Segovia, M.; Yamasaki, K.; Varela, B.; Hill, M.; Verdes, J. M.; Duhalde Vega, M.; Bollati-Fogolín, M.; Crispo, M. (December 2021). "Ivermectin reduces in vivo coronavirus infection in a mouse experimental model". Scientific Reports. 11 (1): 7132. Bibcode:2021NatSR..11.7132A. doi:10.1038/s41598-021-86679-0. PMC 8010049. PMID 33785846.
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Murine coronavirus: Brief Summary ( Inglês )

fornecido por wikipedia EN

Murine coronavirus (M-CoV) is a virus in the genus Betacoronavirus that infects mice. Belonging to the subgenus Embecovirus, murine coronavirus strains are enterotropic or polytropic. Enterotropic strains include mouse hepatitis virus (MHV) strains D, Y, RI, and DVIM, whereas polytropic strains, such as JHM and A59, primarily cause hepatitis, enteritis, and encephalitis. Murine coronavirus is an important pathogen in the laboratory mouse and the laboratory rat. It is the most studied coronavirus in animals other than humans, and has been used as an animal disease model for many virological and clinical studies.

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Coronavirus murin ( Francês )

fornecido por wikipedia FR

Le coronavirus murin (MCoV), connu avant 2009 sous le nom de virus de l’hépatite murine (MHV pour murine hepatitis virus en anglais), aussi appelé virus de la gastroentérite murine (murine gastroenteritis virus en anglais), est un coronavirus à ARN qui est responsable d’une hépatite chez la souris.

C’est le pathogène le plus important des souris de laboratoire, responsable d’épidémies dans cette population. Bien que l’infection soit la plupart du temps asymptomatique chez les souris adultes, elle est responsable de modifications du système immunitaire qui peuvent perturber les résultats scientifiques, raison pour laquelle les souris utilisées en expérimentation animale doivent en être indemnes.

Ce virus fait partie du groupe 2 des coronavirus. Vingt-cinq souches différentes ont été identifiées, les plus importantes étant MHV 1, MHV 2, MHV 3 et MHV 4. MHV 3 est responsable de l'hépatite la plus importante et est donc utilisé pour étudier les mécanismes immunitaires d'une hépatite virale chez la souris. MHV 4, également appelé MHV-JHM, a quant à lui un tropisme neurologique. Cette souche, responsable d’une encéphalite démyélinisante progressive, est utilisée comme modèle murin de la sclérose en plaques.

Position phylogénétique

Le virus est un betacoronavirus, renommé « Murine coronavirus » et élevé au rang d'espèce en 2009. Depuis 2018, il est classé dans le sous-genre Embecovirus.

β-CoV[2]
Embecovirus

Coronavirus humain HKU1 (HCoV HKU1)



Coronavirus murin (MCoV ou MHV)





MrufCoV 2JL14




Betacoronavirus 1 (BCoV, HCoV OC43, etc.)



ChRCoV HKU24






Merbecovirus

EriCoV 1[3]




MERSr-CoV




Ty-BatCoV HKU4



Pi-BatCoV HKU5






Nobecovirus

Ei-BatCoV C704




RO-BatCoV GCCDC1



RO-BatCoV HKU9





Hibecovirus

Hp-betaCoV Zhejiang2013


Sarbecovirus

SARSr-CoV JL2012 (chauve-souris)[4]




(…)





SARSr-CoV WIV1 (Rhinolophus sinicus)



SARSr-CoV RsSHC014 (Rhinolophus sinicus)





Civet-SARSr-CoV (civette)



SARS-CoV-1 (humain ; SRAS)








Rc-o319 (Rhinolophus cornutus, Japon)[5]




(…)




Pangolin SARSr-CoV-GX[6]




Pangolin SARSr-CoV-GD[7]





RshSTT182 (Rhinolophus shameli, Cambodge)[8]



RshSTT200 (Rhinolophus shameli, Cambodge)[8]





RacCS203 (Rhinolophus acuminatus, Thaïlande)[9]



RmYN02 (Rhinolophus malayanus, Mengla, Yunnan)[10]





RaTG13 (Rhinolophus affinis, Mojiang, Yunnan)[11]



SARS-CoV-2 (humain ; CoViD-19)














Références

  1. (en) « Virus Taxonomy: 2019 Release », ICTV, juillet 2019 (consulté le 7 mai 2021).
  5. Shin Murakami, Tomoya Kitamura, Jin Suzuki, Ryouta Sato, Toshiki Aoi, Marina Fujii, Hiromichi Matsugo, Haruhiko Kamiki, Hiroho Ishida, Akiko Takenaka-Uema, Masayuki Shimojima et Taisuke Horimoto, « Detection and Characterization of Bat Sarbecovirus Phylogenetically Related to SARS-CoV-2, Japan », Emerging Infectious Diseases, vol. 26, no 12,‎ décembre 2020, p. 3025–3029 (DOI )
  6. Tommy Tsan-Yuk Lam, Na Jia, Ya-Wei Zhang, Marcus Ho-Hin Shum, Jia-Fu Jiang, Hua-Chen Zhu, Yi-Gang Tong, Yong-Xia Shi, Xue-Bing Ni, Yun-Shi Liao, Wen-Juan Li, Bao-Gui Jiang, Wei Wei, Ting-Ting Yuan, Kui Zheng, Xiao-Ming Cui, Jie Li, Guang-Qian Pei, Xin Qiang, William Yiu-Man Cheung, Lian-Feng Li, Fang-Fang Sun, Si Qin, Ji-Cheng Huang, Gabriel M. Leung, Edward C. Holmes, Yan-Ling Hu, Yi Guan et Wu-Chun Cao, « Identifying SARS-CoV-2-related coronaviruses in Malayan pangolins », Nature, vol. 583, no 7815,‎ 9 juillet 2020, p. 282–285 (DOI )
  7. Ping Liu, Jing-Zhe Jiang, Xiu-Feng Wan, Yan Hua, Linmiao Li, Jiabin Zhou, Xiaohu Wang, Fanghui Hou, Jing Chen, Jiejian Zou et Jinping Chen, « Are pangolins the intermediate host of the 2019 novel coronavirus (SARS-CoV-2)? », PLOS Pathogens, vol. 16, no 5,‎ 14 mai 2020, e1008421 (DOI )
  8. a et b (en) Vibol Hul, Deborah Delaune, Erik A. Karlsson, Alexandre Hassanin, Putita Ou Tey, Artem Baidaliuk, Fabiana Gámbaro, Vuong Tan Tu, Lucy Keatts, Jonna Mazet, Christine Johnson, Philippe Buchy, Philippe Dussart, Tracey Goldstein, Etienne Simon-Lorière et Veasna Duong, « A novel SARS-CoV-2 related coronavirus in bats from Cambodia », sur bioRxiv, 26 janvier 2021 (DOI ), p. 2021.01.26.428212
  9. S Wacharapluesadee, CW Tan, P Maneeorn, P Duengkae, F Zhu, Y Joyjinda, T Kaewpom, WN Chia, W Ampoot, BL Lim, K Worachotsueptrakun, VC Chen, N Sirichan, C Ruchisrisarod, A Rodpan, K Noradechanon, T Phaichana, N Jantarat, B Thongnumchaima, C Tu, G Crameri, MM Stokes, T Hemachudha et LF Wang, « Evidence for SARS-CoV-2 related coronaviruses circulating in bats and pangolins in Southeast Asia. », Nature Communications, vol. 12, no 1,‎ 9 février 2021, p. 972 (PMID , PMCID , DOI )
  10. H Zhou, X Chen, T Hu, J Li, H Song, Y Liu, P Wang, D Liu, J Yang, EC Holmes, AC Hughes, Y Bi et W Shi, « A Novel Bat Coronavirus Closely Related to SARS-CoV-2 Contains Natural Insertions at the S1/S2 Cleavage Site of the Spike Protein. », Current biology : CB, vol. 30, no 11,‎ 8 juin 2020, p. 2196-2203.e3 (PMID , DOI )
  11. « Addendum: A pneumonia outbreak associated with a new coronavirus of probable bat origin », Nature, vol. 588, no 7836,‎ décembre 2020, E6 (PMID , DOI , lire en ligne)
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Coronavirus murin: Brief Summary ( Francês )

fornecido por wikipedia FR

Le coronavirus murin (MCoV), connu avant 2009 sous le nom de virus de l’hépatite murine (MHV pour murine hepatitis virus en anglais), aussi appelé virus de la gastroentérite murine (murine gastroenteritis virus en anglais), est un coronavirus à ARN qui est responsable d’une hépatite chez la souris.

C’est le pathogène le plus important des souris de laboratoire, responsable d’épidémies dans cette population. Bien que l’infection soit la plupart du temps asymptomatique chez les souris adultes, elle est responsable de modifications du système immunitaire qui peuvent perturber les résultats scientifiques, raison pour laquelle les souris utilisées en expérimentation animale doivent en être indemnes.

Ce virus fait partie du groupe 2 des coronavirus. Vingt-cinq souches différentes ont été identifiées, les plus importantes étant MHV 1, MHV 2, MHV 3 et MHV 4. MHV 3 est responsable de l'hépatite la plus importante et est donc utilisé pour étudier les mécanismes immunitaires d'une hépatite virale chez la souris. MHV 4, également appelé MHV-JHM, a quant à lui un tropisme neurologique. Cette souche, responsable d’une encéphalite démyélinisante progressive, est utilisée comme modèle murin de la sclérose en plaques.

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Auteurs et éditeurs de Wikipedia
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wikipedia FR
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