Immunity to viruses: learning from successful human vaccines
Identifieur interne : 001155 ( Main/Exploration ); précédent : 001154; suivant : 001156Immunity to viruses: learning from successful human vaccines
Auteurs : Bali Pulendran [États-Unis] ; Jason Z. Oh [États-Unis] ; Helder I. Nakaya [États-Unis] ; Rajesh Ravindran [États-Unis] ; Dmitri A. Kazmin [États-Unis]Source :
- Immunological Reviews [ 0105-2896 ] ; 2013-09.
English descriptors
- Teeft :
- Adaptive, Adaptive immunity, Adaptive responses, Alpha kinase, Animal models, Antibody response, Antibody responses, Antibody titers, Antiviral immunity, Asibi strain, Attenuated, Attractive model, Bali pulendran, Biol, Biological sciences, Broad spectrum, Camkiv, Cell biol, Cell death, Cell differentiation, Cell memory, Cell responses, Clinical studies, Critical role, Curr opin immunol, Current studies, Days post vaccination, Dendritic, Dendritic cells, Early expression, Emory university, Encoding, Endoplasmic, Endoplasmic reticulum, Endoplasmic reticulum stress response, Erythroid cells, Expression levels, Fever vaccine, Gene, Gene expression, Gene signatures, Genetic polymorphisms, Germinal centers, High levels, Host microbiota, Housekeeping mrna, Human immunization, Human vaccines, Hypothesis building, Immune, Immune function, Immune response, Immune responses, Immune system, Immunity, Immunization, Immunogenicity, Immunol, Immunological, Immunological mechanisms, Immunological reviews, Immunological reviews pulendran, Innate, Innate immunity, Innate responses, Intestinal microbiota, John wiley sons, Kinase, Ligand, Memory responses, Metabolic adaptation, Microbiota, Molecular signatures, Mucosal tissues, Neutralizing, Neutralizing antibodies, Neutralizing antibody responses, Neutralizing antibody titers, Nobel prize, Novel insights, Other members, Pathway, Peripheral blood, Plasma cells, Plasmacytoid, Plasmacytoid dendritic cells, Polymorphism, Post vaccination, Proc natl acad, Protective immunity, Protein kinase, Protein response, Protein synthesis, Protein translation, Pulendran, Recent study, Receptor, Respiratory tract, Reticulum, Robust, Seasonal vaccine, Seasonal vaccines, Signature, Smallpox, Smallpox vaccination, Smallpox vaccine, Stress granules, Stress response, Striking correlation, Such cells, Such polymorphisms, Such studies, Such vaccines, Syst biol, Systems approaches, Systems biology, Systems vaccinology, Systems vaccinology approach, Tlrs, Transcriptional, Transcriptional activity, Transcriptional signatures, Translational control, Translational regulation, Trends biochem, Unexpected insights, Unpublished data, Vaccination, Vaccine, Vaccine immunity, Vaccine responses, Vaccine strain, Vaccinee, Vaccinology, Viral, Viral immunity, Viral infection, Viral infections, Viral vaccines, Virus, Virus infection, Viscerotropic, Viscerotropic disease, Whole virus, Wiley, Yellow fever, Yellow fever vaccine, Yellow fever vaccine causes, Yellow fever virus.
Abstract
For more than a century, immunologists and vaccinologists have existed in parallel universes. Immunologists have for long reveled in using ‘model antigens’, such as chicken egg ovalbumin or nitrophenyl haptens, to study immune responses in model organisms such as mice. Such studies have yielded many seminal insights about the mechanisms of immune regulation, but their relevance to humans has been questioned. In another universe, vaccinologists have relied on human clinical trials to assess vaccine efficacy, but have done little to take advantage of such trials for studying the nature of immune responses to vaccination. The human model provides a nexus between these two universes, and recent studies have begun to use this model to study the molecular profile of innate and adaptive responses to vaccination. Such ‘systems vaccinology’ studies are beginning to provide mechanistic insights about innate and adaptive immunity in humans. Here, we present an overview of such studies, with particular examples from studies with the yellow fever and the seasonal influenza vaccines. Vaccination with the yellow fever vaccine causes a systemic acute viral infection and thus provides an attractive model to study innate and adaptive responses to a primary viral challenge. Vaccination with the live attenuated influenza vaccine causes a localized acute viral infection in mucosal tissues and induces a recall response, since most vaccinees have had prior exposure to influenza, and thus provides a unique opportunity to study innate and antigen‐specific memory responses in mucosal tissues and in the blood. Vaccination with the inactivated influenza vaccine offers a model to study immune responses to an inactivated immunogen. Studies with these and other vaccines are beginning to reunite the estranged fields of immunology and vaccinology, yielding unexpected insights about mechanisms of viral immunity. Vaccines that have been proven to be of immense benefit in saving lives offer us a new fringe benefit: lessons in viral immunology.
Url:
DOI: 10.1111/imr.12099
Affiliations:
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when="2013-09">2013-09</date></imprint><idno type="ISSN">0105-2896</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0105-2896</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="Teeft" xml:lang="en"><term>Adaptive</term><term>Adaptive immunity</term><term>Adaptive responses</term><term>Alpha kinase</term><term>Animal models</term><term>Antibody response</term><term>Antibody responses</term><term>Antibody titers</term><term>Antiviral immunity</term><term>Asibi strain</term><term>Attenuated</term><term>Attractive model</term><term>Bali pulendran</term><term>Biol</term><term>Biological sciences</term><term>Broad spectrum</term><term>Camkiv</term><term>Cell biol</term><term>Cell death</term><term>Cell differentiation</term><term>Cell memory</term><term>Cell responses</term><term>Clinical studies</term><term>Critical role</term><term>Curr opin immunol</term><term>Current studies</term><term>Days post vaccination</term><term>Dendritic</term><term>Dendritic cells</term><term>Early expression</term><term>Emory university</term><term>Encoding</term><term>Endoplasmic</term><term>Endoplasmic reticulum</term><term>Endoplasmic reticulum stress response</term><term>Erythroid cells</term><term>Expression levels</term><term>Fever vaccine</term><term>Gene</term><term>Gene expression</term><term>Gene signatures</term><term>Genetic polymorphisms</term><term>Germinal centers</term><term>High levels</term><term>Host microbiota</term><term>Housekeeping mrna</term><term>Human immunization</term><term>Human vaccines</term><term>Hypothesis building</term><term>Immune</term><term>Immune function</term><term>Immune response</term><term>Immune responses</term><term>Immune system</term><term>Immunity</term><term>Immunization</term><term>Immunogenicity</term><term>Immunol</term><term>Immunological</term><term>Immunological mechanisms</term><term>Immunological reviews</term><term>Immunological reviews pulendran</term><term>Innate</term><term>Innate immunity</term><term>Innate responses</term><term>Intestinal microbiota</term><term>John wiley sons</term><term>Kinase</term><term>Ligand</term><term>Memory responses</term><term>Metabolic adaptation</term><term>Microbiota</term><term>Molecular signatures</term><term>Mucosal tissues</term><term>Neutralizing</term><term>Neutralizing antibodies</term><term>Neutralizing antibody responses</term><term>Neutralizing antibody titers</term><term>Nobel prize</term><term>Novel insights</term><term>Other members</term><term>Pathway</term><term>Peripheral blood</term><term>Plasma cells</term><term>Plasmacytoid</term><term>Plasmacytoid dendritic cells</term><term>Polymorphism</term><term>Post vaccination</term><term>Proc natl acad</term><term>Protective immunity</term><term>Protein kinase</term><term>Protein response</term><term>Protein synthesis</term><term>Protein translation</term><term>Pulendran</term><term>Recent study</term><term>Receptor</term><term>Respiratory tract</term><term>Reticulum</term><term>Robust</term><term>Seasonal vaccine</term><term>Seasonal vaccines</term><term>Signature</term><term>Smallpox</term><term>Smallpox vaccination</term><term>Smallpox vaccine</term><term>Stress granules</term><term>Stress response</term><term>Striking correlation</term><term>Such cells</term><term>Such polymorphisms</term><term>Such studies</term><term>Such vaccines</term><term>Syst biol</term><term>Systems approaches</term><term>Systems biology</term><term>Systems vaccinology</term><term>Systems vaccinology approach</term><term>Tlrs</term><term>Transcriptional</term><term>Transcriptional activity</term><term>Transcriptional signatures</term><term>Translational control</term><term>Translational regulation</term><term>Trends biochem</term><term>Unexpected insights</term><term>Unpublished data</term><term>Vaccination</term><term>Vaccine</term><term>Vaccine immunity</term><term>Vaccine responses</term><term>Vaccine strain</term><term>Vaccinee</term><term>Vaccinology</term><term>Viral</term><term>Viral immunity</term><term>Viral infection</term><term>Viral infections</term><term>Viral vaccines</term><term>Virus</term><term>Virus infection</term><term>Viscerotropic</term><term>Viscerotropic disease</term><term>Whole virus</term><term>Wiley</term><term>Yellow fever</term><term>Yellow fever vaccine</term><term>Yellow fever vaccine causes</term><term>Yellow fever virus</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">For more than a century, immunologists and vaccinologists have existed in parallel universes. Immunologists have for long reveled in using ‘model antigens’, such as chicken egg ovalbumin or nitrophenyl haptens, to study immune responses in model organisms such as mice. Such studies have yielded many seminal insights about the mechanisms of immune regulation, but their relevance to humans has been questioned. In another universe, vaccinologists have relied on human clinical trials to assess vaccine efficacy, but have done little to take advantage of such trials for studying the nature of immune responses to vaccination. The human model provides a nexus between these two universes, and recent studies have begun to use this model to study the molecular profile of innate and adaptive responses to vaccination. Such ‘systems vaccinology’ studies are beginning to provide mechanistic insights about innate and adaptive immunity in humans. Here, we present an overview of such studies, with particular examples from studies with the yellow fever and the seasonal influenza vaccines. Vaccination with the yellow fever vaccine causes a systemic acute viral infection and thus provides an attractive model to study innate and adaptive responses to a primary viral challenge. Vaccination with the live attenuated influenza vaccine causes a localized acute viral infection in mucosal tissues and induces a recall response, since most vaccinees have had prior exposure to influenza, and thus provides a unique opportunity to study innate and antigen‐specific memory responses in mucosal tissues and in the blood. Vaccination with the inactivated influenza vaccine offers a model to study immune responses to an inactivated immunogen. Studies with these and other vaccines are beginning to reunite the estranged fields of immunology and vaccinology, yielding unexpected insights about mechanisms of viral immunity. Vaccines that have been proven to be of immense benefit in saving lives offer us a new fringe benefit: lessons in viral immunology.</div></front></TEI><affiliations><list><country><li>États-Unis</li></country><region><li>Géorgie (États-Unis)</li></region></list><tree><country name="États-Unis"><region name="Géorgie (États-Unis)"><name sortKey="Pulendran, Bali" sort="Pulendran, Bali" uniqKey="Pulendran B" first="Bali" last="Pulendran">Bali Pulendran</name></region><name sortKey="Kazmin, Dmitri A" sort="Kazmin, Dmitri A" uniqKey="Kazmin D" first="Dmitri A." last="Kazmin">Dmitri A. Kazmin</name><name sortKey="Kazmin, Dmitri A" sort="Kazmin, Dmitri A" uniqKey="Kazmin D" first="Dmitri A." last="Kazmin">Dmitri A. Kazmin</name><name sortKey="Nakaya, Helder I" sort="Nakaya, Helder I" uniqKey="Nakaya H" first="Helder I." last="Nakaya">Helder I. Nakaya</name><name sortKey="Nakaya, Helder I" sort="Nakaya, Helder I" uniqKey="Nakaya H" first="Helder I." last="Nakaya">Helder I. Nakaya</name><name sortKey="Nakaya, Helder I" sort="Nakaya, Helder I" uniqKey="Nakaya H" first="Helder I." last="Nakaya">Helder I. Nakaya</name><name sortKey="Oh, Jason Z" sort="Oh, Jason Z" uniqKey="Oh J" first="Jason Z." last="Oh">Jason Z. Oh</name><name sortKey="Oh, Jason Z" sort="Oh, Jason Z" uniqKey="Oh J" first="Jason Z." last="Oh">Jason Z. Oh</name><name sortKey="Pulendran, Bali" sort="Pulendran, Bali" uniqKey="Pulendran B" first="Bali" last="Pulendran">Bali Pulendran</name><name sortKey="Pulendran, Bali" sort="Pulendran, Bali" uniqKey="Pulendran B" first="Bali" last="Pulendran">Bali Pulendran</name><name sortKey="Pulendran, Bali" sort="Pulendran, Bali" uniqKey="Pulendran B" first="Bali" last="Pulendran">Bali Pulendran</name><name sortKey="Pulendran, Bali" sort="Pulendran, Bali" uniqKey="Pulendran B" first="Bali" last="Pulendran">Bali Pulendran</name><name sortKey="Ravindran, Rajesh" sort="Ravindran, Rajesh" uniqKey="Ravindran R" first="Rajesh" last="Ravindran">Rajesh Ravindran</name><name sortKey="Ravindran, Rajesh" sort="Ravindran, Rajesh" uniqKey="Ravindran R" first="Rajesh" last="Ravindran">Rajesh Ravindran</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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