Host-adaptive strategies, such as the E627K substitution in the PB2 protein, are critical for replication of
avian influenza A viruses in mammalian hosts. Here we show that mutation
PB2-K526R is present in some
human H7N9 influenza isolates, in nearly 80% of H5N1 human isolates from Indonesia
and, in conjunction with E627K, in almost all seasonal H3N2 viruses since 1970.
Polymerase complexes containing PB2-526R derived from H7N9, H5N1 or H3N2 viruses exhibit increased
polymerase activity. PB2-526R also
enhances viral transcription and replication in cells. In comparison with viruses
carrying 627K, H7N9 viruses carrying both 526R and 627K replicate more efficiently
in mammalian (but not avian) cells and in mouse lung tissues, and cause greater body
weight loss and mortality in infected mice. PB2-K526R interacts with nuclear export protein and our results
suggest that it contributes to enhance replication for certain influenza virus
subtypes, particularly in combination with 627K.
Antigenic profiles of post-2002 H5N1 viruses representing major genetic clades and various geographic sources were investigated using a panel of 17 monoclonal antibodies raised from five H5N1 strains. Four antigenic groups from seven clades of H5N1 virus were distinguished and characterized based on their cross-reactivity to the monoclonal antibodies in hemagglutination inhibition and cell-based neutralization assays. Genetic polymorphisms associated with the variation of antigenicity of H5N1 strains were identified and further verified in antigenic analysis with recombinant H5N1 viruses carrying specific mutations in the hemagglutinin protein. Modification of some of these genetic variations produced marked improvement to the immunogenicity and cross-reactivity of H5N1 strains in assays utilizing monoclonal antibodies and ferret antisera raised against clade 1 and 2 H5N1 viruses, suggesting that these sites represent antigenically significant amino acids. These results provide a comprehensive antigenic profile for H5N1 virus strains circulating in recent years and will facilitate the recognition of emerging antigenic variants of H5N1 virus and aid in the selection of vaccine strains.
The nonstructural protein (NS1) of influenza A virus performs multiple functions in the virus life cycle. Proteomic screening for cellular proteins which interact with NS1 identified the cellular protein RAP55, which is one of the components of cellular processing bodies (P-bodies) and stress granules. To verify whether NS1 interacts with cellular P-bodies, interactions between NS1, RAP55, and other P-body-associated proteins (Ago1, Ago2, and DCP1a) were confirmed using coimmunoprecipitation and cellular colocalization assays. Overexpression of RAP55 induced RAP55-associated stress granule formation and suppressed virus replication. Knockdown of RAP55 with small interfering RNA (siRNA) or expression of a dominant-negative mutant RAP55 protein with defective interaction with P-bodies blocked NS1 colocalization to P-bodies in cells. Expression of NS1 inhibited RAP55 expression and formation of RAP55-associated P-bodies/stress granules. The viral nucleoprotein (NP) was found to be targeted to stress granules in the absence of NS1 but localized to P-bodies when NS1 was coexpressed. Restriction of virus replication via P-bodies occurred in the early phases of infection, as the number of RAP55-associated P-bodies in cells diminished over the course of virus infection. NS1 interaction with RAP55-associated P-bodies/stress granules was associated with RNA binding and mediated via a protein kinase R (PKR)-interacting viral element. Mutations introduced into either RNA binding sites (R38 and K41) or PKR interaction sites (I123, M124, K126, and N127) caused NS1 proteins to lose the ability to interact with RAP55 and to inhibit stress granules. These results reveal an interplay between virus and host during virus replication in which NP is targeted to P-bodies/stress granules while NS1 counteracts this host restriction mechanism.
Serological surveillance conducted in areas of an outbreak of influenza A(H7N9) infection in China found no seropositivity for antibodies specific for avian-origin influenza A(H7N9) among 1129 individuals of the general population, whereas >6% of 396 poultry workers were positive (on the basis of a hemagglutination inhibition titer of ≥ 80) for this subtype, confirming that infected poultry is the principal source of human infections and that subclinical infections are possible. Fourteen days after symptom onset, elevated levels of antibodies to A(H7N9) were found in 65.8% of patients (25/38) who survived but in only 28.6% of those (2/7) who died, suggesting that the presence of antibodies may improve clinical outcome in infected patients.
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