The ecology of influenza viruses in ducks and analysis of influenza viruses with monoclonal antibodies
Identifieur interne : 002792 ( Main/Exploration ); précédent : 002791; suivant : 002793The ecology of influenza viruses in ducks and analysis of influenza viruses with monoclonal antibodies
Auteurs : V. S Hinshaw [États-Unis] ; R. G Webster [États-Unis] ; W. J Bean [États-Unis] ; G. Sriram [États-Unis]Source :
- Comparative Immunology, Microbiology and Infectious Diseases [ 0147-9571 ] ; 1980.
English descriptors
- Teeft :
- Antigenic, Antigenic analysis, Antigenic determinants, Antigenic shift, Antigenic subtypes, Antigenic variation, Antigenically, Avian, Avian influenza, Avian influenza viruses, Avian sources, Avian species, Avian viruses, Canadian feral ducks, Canard, Canards migrateurs, Cloacal samples, Determinant, Different antigenic subtypes, Different combinations, Different influenza, Duck, Economic importance, Embryonated hens, Fecal material, Fecal samples, Feral, Feral duck population, Feral ducks, Figures show, Genetic information, Genetic interaction, Genetic reassortment, Hemagglutinin, Hemagglutinin molecule, Hemagglutinin subtype, Hswln1, Human influenza viruses, Human pandemic strains, Human strain, Human strains, Influenza, Influenza virus, Influenza viruses, Intestinal tract, Juvenile mallard ducks, Laboratory studies, Large pool, Lower mammals, Major reservoir, Mammalian species, Migratory ducks, Monoclonal, Monoclonal antibodies, Pandemic strains, Previous studies, Reassortment, Recombinant viruses, Same bird, Sriram table, Studies show, Subtypes, Surface antigens, Virus, Virus grippaux, Virus isolation.
Abstract
Abstract: It has been suggested that influenza A viruses from lower animals may be involved in the origin of human pandemic strains. To test this hypothesis, we have been analyzing the influenza A viruses present in lower mammals and birds.Over the past few years, it has become increasingly evident that a major reservoir of influenza viruses exists in both domestic and feral avian species, particularly ducks. For example, studies on migratory ducks in Canada in 1978 showed that 50% of these healthy birds were infected with influenza viruses. These viruses included 16 different combinations of hemagglutinin and neuraminidase subtypes, including those related to human strains as hemagglutinins, Hav7, H2, and Hsw1 and neuraminidases, N1 and N2. The duck isolates which were antigenically related to the Hsw1N1 viruses from pigs and man were evaluated by in vivo pathogenicity tests in ferrets, ducks, pigs, and chickens; the results indicated that these avian Hsw1N1 viruses replicated in both avian and mammalian species, underlining their potential for interspecies transmission.Since the reassortment of genetic information between human and animal influenza A viruses has been suggested as the mechanism for the origin of new human strains, we also examined the migratory ducks for evidence of mixed infections, i.e. infection with two antigenically distinct viruses to determine if this phenomenon occurs in nature. Antisera to the original isolate was used to select for antigenically different viruses in the original cloacal sample. Mixtures of two and, on rare occasions, three distinct subtypes (e.g., Hav7N2, Hav6N2, and Hav7Neq2) were isolated from one bird. Analysis of the RNAs of these viruses by polyacrylamide gel electrophoresis suggested that genetic reassortment between viruses in the mixedly infected birds was occurring. These findings agree with laboratory studies in which recombinant viruses were isolated from mixedly infected ducks. These data indicate that mixed infections do occur in the natural setting, thus establishing the situation where genetic reassortment between viruses could occur.The avian species, particularly ducks, continue to represent an impressive reservoir of influenza A viruses and may well contribute to the appearance of related influenza viruses in other species, including humans.
Résumé: On a suggéré que les virus grippaux A des animaux inférieurs peuvent être impliqués dans l'origine des souches pandémiques humaines. Pour mettre cette hypothèse à l'épreuve nous avons analysé l'influence des virus A présents chez les petits mammifères et les oiseaux.Ces dernières années, il est devenu de plus en plus évident que le principal réservoir de virus grippaux existe chez les aspèces aviaires domestiques, plus particulièrement chez les canards. Par exemple, des études sur les canards migrateurs du Canada en 1978, ont montré que 50% de ces oiseaux bien portants étaient infectés par des virus grippaux. Ces virus comprenaient 16 combinaision différentes d'hémaglutinine et de sous-types de neuraminidases, y compris celles en relation avec les souches humaines, telle que les hémaglutinines Havt, H2 et Hsw1 et les neuraminidases N1 et N2. Les prélèvements effectués sur les canards qui étaient antigéniquement liés aux virus HswINI porcins et humains, furent évalués par des tests de pathogénicité in vivo chez les canards, les porcs et les poulets. Les résultats ont montré que ces virus aviaires Hsw1N1 se produisaient dans les espèces avaires et mammifères, soulignant leur potential pour la transmission inter-espèces.Depuis que le ressortiment de l'information génétique entre les virus grippaux A humains et animaux a été supposé être un mécanisme pour l'origine de nouvelles souches humaines, nous avons également examiné les canards migrateurs pour mettre en évidence les infections mixtes, c'est à dire l'infection avec deux virus antigéniquement différents si ce phénomène se produit en nature.
Url:
DOI: 10.1016/0147-9571(80)90051-X
Affiliations:
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S" last="Hinshaw">V. S Hinshaw</name><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><wicri:regionArea>Division of Virology, St Jude children's Research Hospital, 332 N. Lauderdale, P.O. Box 318, Memphis, TN 38101</wicri:regionArea><placeName><region type="state">Tennessee</region></placeName></affiliation></author><author><name sortKey="Webster, R G" sort="Webster, R G" uniqKey="Webster R" first="R. G" last="Webster">R. G Webster</name><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><wicri:regionArea>Division of Virology, St Jude children's Research Hospital, 332 N. Lauderdale, P.O. Box 318, Memphis, TN 38101</wicri:regionArea><placeName><region type="state">Tennessee</region></placeName></affiliation></author><author><name sortKey="Bean, W J" sort="Bean, W J" uniqKey="Bean W" first="W. J" last="Bean">W. 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Box 318, Memphis, TN 38101</wicri:regionArea><placeName><region type="state">Tennessee</region></placeName></affiliation></author></analytic><monogr></monogr><series><title level="j">Comparative Immunology, Microbiology and Infectious Diseases</title><title level="j" type="abbrev">CIMID</title><idno type="ISSN">0147-9571</idno><imprint><publisher>ELSEVIER</publisher><date type="published" when="1980">1980</date><biblScope unit="volume">3</biblScope><biblScope unit="issue">1–2</biblScope><biblScope unit="page" from="155">155</biblScope><biblScope unit="page" to="164">164</biblScope></imprint><idno type="ISSN">0147-9571</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0147-9571</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="Teeft" xml:lang="en"><term>Antigenic</term><term>Antigenic analysis</term><term>Antigenic determinants</term><term>Antigenic shift</term><term>Antigenic subtypes</term><term>Antigenic variation</term><term>Antigenically</term><term>Avian</term><term>Avian influenza</term><term>Avian influenza viruses</term><term>Avian sources</term><term>Avian species</term><term>Avian viruses</term><term>Canadian feral ducks</term><term>Canard</term><term>Canards migrateurs</term><term>Cloacal samples</term><term>Determinant</term><term>Different antigenic subtypes</term><term>Different combinations</term><term>Different influenza</term><term>Duck</term><term>Economic importance</term><term>Embryonated hens</term><term>Fecal material</term><term>Fecal samples</term><term>Feral</term><term>Feral duck population</term><term>Feral ducks</term><term>Figures show</term><term>Genetic information</term><term>Genetic interaction</term><term>Genetic reassortment</term><term>Hemagglutinin</term><term>Hemagglutinin molecule</term><term>Hemagglutinin subtype</term><term>Hswln1</term><term>Human influenza viruses</term><term>Human pandemic strains</term><term>Human strain</term><term>Human strains</term><term>Influenza</term><term>Influenza virus</term><term>Influenza viruses</term><term>Intestinal tract</term><term>Juvenile mallard ducks</term><term>Laboratory studies</term><term>Large pool</term><term>Lower mammals</term><term>Major reservoir</term><term>Mammalian species</term><term>Migratory ducks</term><term>Monoclonal</term><term>Monoclonal antibodies</term><term>Pandemic strains</term><term>Previous studies</term><term>Reassortment</term><term>Recombinant viruses</term><term>Same bird</term><term>Sriram table</term><term>Studies show</term><term>Subtypes</term><term>Surface antigens</term><term>Virus</term><term>Virus grippaux</term><term>Virus isolation</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Abstract: It has been suggested that influenza A viruses from lower animals may be involved in the origin of human pandemic strains. To test this hypothesis, we have been analyzing the influenza A viruses present in lower mammals and birds.Over the past few years, it has become increasingly evident that a major reservoir of influenza viruses exists in both domestic and feral avian species, particularly ducks. For example, studies on migratory ducks in Canada in 1978 showed that 50% of these healthy birds were infected with influenza viruses. These viruses included 16 different combinations of hemagglutinin and neuraminidase subtypes, including those related to human strains as hemagglutinins, Hav7, H2, and Hsw1 and neuraminidases, N1 and N2. The duck isolates which were antigenically related to the Hsw1N1 viruses from pigs and man were evaluated by in vivo pathogenicity tests in ferrets, ducks, pigs, and chickens; the results indicated that these avian Hsw1N1 viruses replicated in both avian and mammalian species, underlining their potential for interspecies transmission.Since the reassortment of genetic information between human and animal influenza A viruses has been suggested as the mechanism for the origin of new human strains, we also examined the migratory ducks for evidence of mixed infections, i.e. infection with two antigenically distinct viruses to determine if this phenomenon occurs in nature. Antisera to the original isolate was used to select for antigenically different viruses in the original cloacal sample. Mixtures of two and, on rare occasions, three distinct subtypes (e.g., Hav7N2, Hav6N2, and Hav7Neq2) were isolated from one bird. Analysis of the RNAs of these viruses by polyacrylamide gel electrophoresis suggested that genetic reassortment between viruses in the mixedly infected birds was occurring. These findings agree with laboratory studies in which recombinant viruses were isolated from mixedly infected ducks. These data indicate that mixed infections do occur in the natural setting, thus establishing the situation where genetic reassortment between viruses could occur.The avian species, particularly ducks, continue to represent an impressive reservoir of influenza A viruses and may well contribute to the appearance of related influenza viruses in other species, including humans.</div><div type="abstract" xml:lang="fr">Résumé: On a suggéré que les virus grippaux A des animaux inférieurs peuvent être impliqués dans l'origine des souches pandémiques humaines. Pour mettre cette hypothèse à l'épreuve nous avons analysé l'influence des virus A présents chez les petits mammifères et les oiseaux.Ces dernières années, il est devenu de plus en plus évident que le principal réservoir de virus grippaux existe chez les aspèces aviaires domestiques, plus particulièrement chez les canards. Par exemple, des études sur les canards migrateurs du Canada en 1978, ont montré que 50% de ces oiseaux bien portants étaient infectés par des virus grippaux. Ces virus comprenaient 16 combinaision différentes d'hémaglutinine et de sous-types de neuraminidases, y compris celles en relation avec les souches humaines, telle que les hémaglutinines Havt, H2 et Hsw1 et les neuraminidases N1 et N2. Les prélèvements effectués sur les canards qui étaient antigéniquement liés aux virus HswINI porcins et humains, furent évalués par des tests de pathogénicité in vivo chez les canards, les porcs et les poulets. Les résultats ont montré que ces virus aviaires Hsw1N1 se produisaient dans les espèces avaires et mammifères, soulignant leur potential pour la transmission inter-espèces.Depuis que le ressortiment de l'information génétique entre les virus grippaux A humains et animaux a été supposé être un mécanisme pour l'origine de nouvelles souches humaines, nous avons également examiné les canards migrateurs pour mettre en évidence les infections mixtes, c'est à dire l'infection avec deux virus antigéniquement différents si ce phénomène se produit en nature.</div></front></TEI><affiliations><list><country><li>États-Unis</li></country><region><li>Tennessee</li></region></list><tree><country name="États-Unis"><region name="Tennessee"><name sortKey="Hinshaw, V S" sort="Hinshaw, V S" uniqKey="Hinshaw V" first="V. S" last="Hinshaw">V. S Hinshaw</name></region><name sortKey="Bean, W J" sort="Bean, W J" uniqKey="Bean W" first="W. J" last="Bean">W. J Bean</name><name sortKey="Sriram, G" sort="Sriram, G" uniqKey="Sriram G" first="G" last="Sriram">G. Sriram</name><name sortKey="Webster, R G" sort="Webster, R G" uniqKey="Webster R" first="R. G" last="Webster">R. G Webster</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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