Related references
Note: Only part of the references are listed.Human-infecting influenza A (H9N2) virus: A forgotten potential pandemic strain?
Wenjun Song et al.
ZOONOSES AND PUBLIC HEALTH (2020)
A Global Perspective on H9N2 Avian Influenza Virus
T. (homas). P. Peacock et al.
VIRUSES-BASEL (2019)
Isolation and Characterization of a Distinct Influenza A Virus from Egyptian Bats
Ahmed Kandeil et al.
JOURNAL OF VIROLOGY (2019)
Flexibility In Vitro of Amino Acid 226 in the Receptor-Binding Site of an H9 Subtype Influenza A Virus and Its Effect In Vivo on Virus Replication, Tropism, and Transmission
Adebimpe O. Obadan et al.
JOURNAL OF VIROLOGY (2019)
Association of Increased Receptor-Binding Avidity of Influenza A(H9N2) Viruses with Escape from Antibody-Based Immunity and Enhanced Zoonotic Potential
Joshua E. Sealy et al.
EMERGING INFECTIOUS DISEASES (2019)
Influenza A virus hemagglutinin glycosylation compensates for antibody escape fitness costs
Ivan Kosik et al.
PLOS PATHOGENS (2018)
Host Immune Response to Influenza A Virus Infection
Xiaoyong Chen et al.
FRONTIERS IN IMMUNOLOGY (2018)
The molecular basis of antigenic variation among A(H9N2) avian influenza viruses
Thomas P. Peacock et al.
EMERGING MICROBES & INFECTIONS (2018)
Immune Escape Variants of H9N2 Influenza Viruses Containing Deletions at the Hemagglutinin Receptor Binding Site Retain Fitness In Vivo and Display Enhanced Zoonotic Characteristics
Thomas P. Peacock et al.
JOURNAL OF VIROLOGY (2017)
Variability in H9N2 haemagglutinin receptor-binding preference and the pH of fusion
Thomas P. Peacock et al.
EMERGING MICROBES & INFECTIONS (2017)
Glycosylation at 11Asn on hemagglutinin of H5N1 influenza virus contributes to its biological characteristics
Yuncong Yin et al.
VETERINARY RESEARCH (2017)
Amino Acid Substitutions That Affect Receptor Binding and Stability of the Hemagglutinin of Influenza A/H7N9 Virus
Eefje J. A. Schrauwen et al.
JOURNAL OF VIROLOGY (2016)
Identification of Low- and High-Impact Hemagglutinin Amino Acid Substitutions That Drive Antigenic Drift of Influenza A (H1N1) Viruses
William T. Harvey et al.
PLOS PATHOGENS (2016)
Antigenic mapping of an H9N2 avian influenza virus reveals two discrete antigenic sites and a novel mechanism of immune escape
Thomas Peacock et al.
SCIENTIFIC REPORTS (2016)
A RESTful API for Access to Phylogenetic Tools via the CIPRES Science Gateway
Mark A. Miller et al.
EVOLUTIONARY BIOINFORMATICS (2015)
Characterization of H5N1 Influenza Virus Variants with Hemagglutinin Mutations Isolated from Patients
Yohei Watanabe et al.
MBIO (2015)
Role of receptor binding specificity in influenza A virus transmission and pathogenesis
Miranda de Graaf et al.
EMBO JOURNAL (2014)
Enabling the 'host jump': structural determinants of receptor-binding specificity in influenza A viruses
Yi Shi et al.
NATURE REVIEWS MICROBIOLOGY (2014)
Comparative analysis of receptor-binding specificity and pathogenicity in natural reassortant and non-reassortant H3N2 swine influenza virus
Yanlong Cong et al.
VETERINARY MICROBIOLOGY (2014)
Expression and distribution of sialic acid influenza virus receptors in wild birds
M. Franca et al.
AVIAN PATHOLOGY (2013)
The genesis and source of the H7N9 influenza viruses causing human infections in China
Tommy Tsan-Yuk Lam et al.
NATURE (2013)
Substitutions Near the Receptor Binding Site Determine Major Antigenic Change During Influenza Virus Evolution
Bjorn F. Koel et al.
SCIENCE (2013)
Chinese and Global Distribution of H9 Subtype Avian Influenza Viruses
Wenming Jiang et al.
PLOS ONE (2012)
A Computational Framework for Influenza Antigenic Cartography
Zhipeng Cai et al.
PLOS COMPUTATIONAL BIOLOGY (2010)
Hemagglutinin Receptor Binding Avidity Drives Influenza A Virus Antigenic Drift
Scott E. Hensley et al.
SCIENCE (2009)
Amino acid 226 in the hemagglutinin of H9N2 influenza viruses determines cell tropism and replication in human airway epithelial cells
Hongquan Wan et al.
JOURNAL OF VIROLOGY (2007)
Mapping the antigenic and genetic evolution of influenza virus
DJ Smith et al.
SCIENCE (2004)
Structural differences among hemagglutinins of influenza A virus subtypes are reflected in their antigenic architecture: Analysis of H9 escape mutants
NV Kaverin et al.
JOURNAL OF VIROLOGY (2004)
A DNA transfection system for generation of influenza A virus from eight plasmids
E Hoffmann et al.
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2000)