Secretory leukoprotease inhibitor and pulmonary surfactant serve as principal defenses against influenza A virus infection in the airway and chemical agents up-regulating their levels may have therapeutic potential
Identifieur interne : 001676 ( Main/Exploration ); précédent : 001675; suivant : 001677Secretory leukoprotease inhibitor and pulmonary surfactant serve as principal defenses against influenza A virus infection in the airway and chemical agents up-regulating their levels may have therapeutic potential
Auteurs : Hiroshi Kido [Japon] ; Yuushi Okumura [Japon] ; Hiroshi Yamada [Japon] ; Dai Mizuno [Japon] ; Youichirou Higashi [Japon] ; Mihiro Yano [Japon]Source :
- Biological Chemistry [ 1431-6730 ] ; 2004.
English descriptors
- Teeft :
- Airway, Airway fluids, Ambroxol, Beppu, Chemical agents, Clara, Defense compounds, Defense factors, Early phase, Glycoprotein, Infection, Infectivity, Influenza, Influenza virus, Influenza virus infection, Inhibitor, Inhibitory, Inhibitory activity, Inhibitory compounds, Inhibitory effects, Intranasal administration, Kido, Late phase, Lethal dose, Leukoprotease, Macrolide antibiotic, Mucosal, Mucosal immunity, Murine parainfluenza virus type, Processing proteases, Progeny, Protease, Proteolytic activation, Pulmonary surfactant, Rslpi, Secretory, Secretory leukoprotease inhibitor, Sendai, Sendai virus, Slpi, Surfactant, Survival rate, Trypsin, Tryptase, Tryptase clara, Viral, Viral replication, Virus, Virus multiplication, Virus proliferation.
Abstract
Influenza A virus (IAV) is one of the most common infectious pathogens in humans. Entry of this virus into cells is primarily determined by host cellular trypsin-type processing proteases, which proteolytically activate viral membrane fusion glycoprotein precursors. Human IAV and murine parainfluenza virus type 1 Sendai virus are exclusively pneumotropic, and the infectious organ tropism of these viruses is determined by the susceptibility of the viral envelope glycoprotein to cleavage by proteases in the airway. Proteases in the upper respiratory tract are suppressed by secretory leukoprotease inhibitor, and those in the lower respiratory tract are suppressed by pulmonary surfactant, which by adsorption inhibits the interaction between the proteases and viral membrane proteins. Although the protease activities are predominant over the activities of inhibitory compounds under normal airway conditions, intranasal administration of inhibitors was able to significantly suppress multi-cycles of viral replication in the airway. In addition, we identified chemical agents that could act as defensive factors by up-regulating the levels of the natural inhibitors and immunoglobulin A (IgA) in airway fluids. One of these compounds, ambroxol, is a mucolytic and anti-oxidant agent that stimulates the release of secretory leukoprotease inhibitor and pulmonary surfactant in the early phase, and IgA in the late phase of infection at an optimal dose, i.e. a dose sufficient to inhibit virus proliferation and increase the survival rate of animals after treatment with a lethal dose of IAV. Another agent, clarithromycin, is a macrolide antibiotic that increases IgA levels through augmentation of interleukin-12 levels and mucosal immunization in the airway. In addition to the sialidase inhibitors, which prevent the release of IAV from infected cells, inhibitors of the processing proteases and chemical agents that augment mucosal immunity and/or levels of the relevant defensive compounds may also ultimately prove to be useful as new anti-influenza agents.
Url:
DOI: 10.1515/BC.2004.133
Affiliations:
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phase</term><term>Glycoprotein</term><term>Infection</term><term>Infectivity</term><term>Influenza</term><term>Influenza virus</term><term>Influenza virus infection</term><term>Inhibitor</term><term>Inhibitory</term><term>Inhibitory activity</term><term>Inhibitory compounds</term><term>Inhibitory effects</term><term>Intranasal administration</term><term>Kido</term><term>Late phase</term><term>Lethal dose</term><term>Leukoprotease</term><term>Macrolide antibiotic</term><term>Mucosal</term><term>Mucosal immunity</term><term>Murine parainfluenza virus type</term><term>Processing proteases</term><term>Progeny</term><term>Protease</term><term>Proteolytic activation</term><term>Pulmonary surfactant</term><term>Rslpi</term><term>Secretory</term><term>Secretory leukoprotease inhibitor</term><term>Sendai</term><term>Sendai virus</term><term>Slpi</term><term>Surfactant</term><term>Survival rate</term><term>Trypsin</term><term>Tryptase</term><term>Tryptase clara</term><term>Viral</term><term>Viral replication</term><term>Virus</term><term>Virus multiplication</term><term>Virus proliferation</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Influenza A virus (IAV) is one of the most common infectious pathogens in humans. Entry of this virus into cells is primarily determined by host cellular trypsin-type processing proteases, which proteolytically activate viral membrane fusion glycoprotein precursors. Human IAV and murine parainfluenza virus type 1 Sendai virus are exclusively pneumotropic, and the infectious organ tropism of these viruses is determined by the susceptibility of the viral envelope glycoprotein to cleavage by proteases in the airway. Proteases in the upper respiratory tract are suppressed by secretory leukoprotease inhibitor, and those in the lower respiratory tract are suppressed by pulmonary surfactant, which by adsorption inhibits the interaction between the proteases and viral membrane proteins. Although the protease activities are predominant over the activities of inhibitory compounds under normal airway conditions, intranasal administration of inhibitors was able to significantly suppress multi-cycles of viral replication in the airway. In addition, we identified chemical agents that could act as defensive factors by up-regulating the levels of the natural inhibitors and immunoglobulin A (IgA) in airway fluids. One of these compounds, ambroxol, is a mucolytic and anti-oxidant agent that stimulates the release of secretory leukoprotease inhibitor and pulmonary surfactant in the early phase, and IgA in the late phase of infection at an optimal dose, i.e. a dose sufficient to inhibit virus proliferation and increase the survival rate of animals after treatment with a lethal dose of IAV. Another agent, clarithromycin, is a macrolide antibiotic that increases IgA levels through augmentation of interleukin-12 levels and mucosal immunization in the airway. In addition to the sialidase inhibitors, which prevent the release of IAV from infected cells, inhibitors of the processing proteases and chemical agents that augment mucosal immunity and/or levels of the relevant defensive compounds may also ultimately prove to be useful as new anti-influenza agents.</div></front></TEI><affiliations><list><country><li>Japon</li></country></list><tree><country name="Japon"><noRegion><name sortKey="Kido, Hiroshi" sort="Kido, Hiroshi" uniqKey="Kido H" first="Hiroshi" last="Kido">Hiroshi Kido</name></noRegion><name sortKey="Higashi, Youichirou" sort="Higashi, Youichirou" uniqKey="Higashi Y" first="Youichirou" last="Higashi">Youichirou Higashi</name><name sortKey="Mizuno, Dai" sort="Mizuno, Dai" uniqKey="Mizuno D" first="Dai" last="Mizuno">Dai Mizuno</name><name sortKey="Okumura, Yuushi" sort="Okumura, Yuushi" uniqKey="Okumura Y" first="Yuushi" last="Okumura">Yuushi Okumura</name><name sortKey="Yamada, Hiroshi" sort="Yamada, Hiroshi" uniqKey="Yamada H" first="Hiroshi" last="Yamada">Hiroshi Yamada</name><name sortKey="Yano, Mihiro" sort="Yano, Mihiro" uniqKey="Yano M" first="Mihiro" last="Yano">Mihiro Yano</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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