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<p><b>Новая страница</b></p><div>{{Short description|Type of nonhereditary genetic change involving swapping of DNA or RNA}}<br />
[[Image:Reassortment.svg|300px|thumb|Performing reassortment with flu viruses]]<br />
'''Reassortment''' is the mixing of the [[genetics|genetic material]] of a species into new combinations in different individuals. The product of reassortment is called a '''reassortant'''. It is particularly used when two similar [[virus]]es that are infecting the same cell exchange genetic material. More specifically, it refers to the swapping of entire segments of the genome, which only occurs between viruses with segmented genomes.<ref>{{cite web |title=Genetic Exchange |url=https://www.atsu.edu/faculty/chamberlain/website/tritzmed/lects/genexch.htm |website=www.atsu.edu}}</ref> (All known viruses with segmented genomes are RNA viruses.)<br />
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== Flu virus ==<br />
The classical example of reassortment is seen in the [[Orthomyxoviridae|influenza viruses]], whose genomes consist of eight distinct segments of RNA. These segments act like mini-chromosomes, and each time a flu virus is assembled, it requires one copy of each segment.<br />
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If a single host (a human, a chicken, or other animal) is infected by two different strains of the influenza virus, then it is possible that new assembled viral particles will be created from segments whose origin is mixed, some coming from one strain and some coming from another. The new reassortant strain will share properties of both of its parental lineages.<br />
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Reassortment is responsible for some of the major [[antigenic shift]]s in the history of the influenza virus. In the 1957 "[[1957–1958 influenza pandemic|Asian flu]]" and 1968 "[[Hong Kong flu]]" [[pandemic]]s, flu strains were caused by reassortment between an avian virus and a human virus.<ref>{{Cite web|last=|first=|date=2019-01-22|title=1968 Pandemic (H3N2 virus)|url=https://www.cdc.gov/flu/pandemic-resources/1968-pandemic.html|archive-url=|archive-date=|access-date=2021-01-18|website=US Centers for Disease Control and Prevention (CDC)|language=en-us}}</ref><ref>{{Cite journal|last1=Saunders-Hastings|first1=Patrick R.|last2=Krewski|first2=Daniel|date=2016-12-06|title=Reviewing the History of Pandemic Influenza: Understanding Patterns of Emergence and Transmission|journal=Pathogens|volume=5|issue=4|page=66|doi=10.3390/pathogens5040066|issn=2076-0817|pmc=5198166|pmid=27929449|doi-access=free}}</ref> In addition, the [[H1N1]] virus responsible for the [[2009 swine flu pandemic]] has an unusual mix of swine, avian and human influenza genetic sequences.<ref name="NewSci-20090424-pandemic">{{cite news|url=https://www.newscientist.com/article/dn17025-deadly-new-flu-virus-in-us-and-mexico-may-go-pandemic.html|title=Deadly new flu virus in US and Mexico may go pandemic|work=[[New Scientist]]|date=2009-04-24|access-date=2009-04-26}}</ref><br />
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===Multiplicity reactivation===<br />
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When [[influenza A virus|influenza viruses]] are inactivated by [[ultraviolet|UV]] irradiation or [[ionizing radiation]], they remain capable of multiplicity reactivation in infected host cells.<ref>{{cite journal | last1 = Barry | first1 = RD | date = Aug 1961 | title = The multiplication of influenza virus. II. Multiplicity reactivation of ultraviolet irradiated virus | url = | journal = Virology | volume = 14 | issue = 4| pages = 398–405 | doi = 10.1016/0042-6822(61)90330-0 | pmid = 13687359 }}</ref><ref>{{cite journal | last1 = Henle | first1 = W | last2 = Liu | first2 = OC | date = Oct 1951 | title = Studies on host-virus interactions in the chick embryo-influenza virus system. VI. Evidence for multiplicity reactivation of inactivated virus | journal = J Exp Med | volume = 94 | issue = 4| pages = 305–22 | pmid = 14888814 | pmc = 2136114 }}</ref><ref>{{cite journal | last1 = Gilker | first1 = JC | last2 = Pavilanis | first2 = V | last3 = Ghys | first3 = R | year = 1967 | title = Multiplicity reactivation in gamma irradiated influenza viruses | url = | journal = Nature | volume = 214 | issue = 5094| pages = 1235–7 | doi = 10.1038/2141235a0 | pmid = 6066111 }}</ref> If any of a virus's [[genome]] segments is damaged in such a way as to prevent replication or expression of an essential [[gene]], the virus is inviable when it, alone, infects a host cell (single infection). However, when two or more damaged viruses infect the same cell (multiple infection), the infection can often succeed (multiplicity reactivation) due to reassortment of segments, provided that each of the eight genome segments is present in at least one undamaged copy.<ref>{{cite journal | last1 = Michod | first1 = RE | last2 = Bernstein | first2 = H | last3 = Nedelcu | first3 = AM | date = May 2008 | title = Adaptive value of sex in microbial pathogens | url = | journal = Infect Genet Evol | volume = 8 | issue = 3| pages = 267–85 | doi = 10.1016/j.meegid.2008.01.002 | pmid = 18295550 }}</ref><br />
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== Other viruses ==<br />
The [[arenavirus|reptarenavirus]] family, responsible for [[inclusion body disease]] in snakes, shows a very high degree of genetic diversity due to reassortment of genetic material from multiple strains in the same infected animal.<br />
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The '''[[2009 swine flu pandemic]]''' resulted from a triple [[reassortment]] of bird, swine, and human flu viruses which further combined with a Eurasian pig flu virus, leading to the term "[[swine flu]]". <br />
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==See also==<br />
* Other kinds of nonhereditary genetic change<br />
** [[Antigenic shift]]<br />
** [[Horizontal gene transfer]]<br />
* [[Genetic recombination]]<br />
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==References==<br />
{{Reflist}}<br />
* [http://www.bionyt.dk/swineflu History of April-2009 flu] collected by [[Bionyt]].<br />
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==External links==<br />
* [http://www.hhmi.org/biointeractive/animations/subunit/sub_frames.htm An animation from hhmi.org illustrating the process] {{Webarchive|url=https://web.archive.org/web/20051123201209/http://www.hhmi.org/biointeractive/animations/subunit/sub_frames.htm |date=2005-11-23 }}<br />
* {{cite journal |author=Hood E |title=Flu Vaccine Production Gets a Shot in the Arm |journal=Environ Health Perspect |volume=114 |issue= 2|pages=A108–11 |date=February 2006 |doi=10.1289/ehp.114-a108 |pmid=16451835 |pmc=1367863}}<br />
* {{cite journal|doi=10.1038/nrmicro2614|pmid=21725337|pmc=3324781|title=Why do RNA viruses recombine?|journal=Nature Reviews Microbiology|volume=9|issue=8|pages=617–626|year=2011|last1=Simon-Loriere|first1=Etienne|last2=Holmes|first2=Edward C.}} Offers a good introduction with figures on the concept of reassortment (as well as recombination).<br />
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[[Category:Genetics]]<br />
[[Category:Virology]]<br />
[[Category:Influenza]]</div>ru>Rjwilmsi