Definition of Amino Acid Residues on the Epitope Responsible for Recognition by Influenza A Virus H1-Specific, H2-Specific, and H1- and H2-Cross-Reactive Murine Cytotoxic T-Lymphocyte Clones

We defined the epitopes recognized by three influenza A virus-specific, H-2K^d-restricted CD8⁺ cytotoxic T-lymphocyte (CTL) clones: H1-specific clone A-12, H2-specific clone F-4, and H1- and H2-cross-reactive clone B7-B7. The A-12 and B7-B7 clones recognized the same peptide, which comprises amino acids 533 to 541 (IYSTVASSL) of A/PR/8 hemagglutinin (HA). The F-4 and B7-B7 clones both recognized the peptide which comprise amino acids 529 to 537 (IYATVAGSL) of A/Jap HA. Amino acids 533 to 541 of A/PR/8 HA are compatible with amino acids 529 to 537 of A/Jap HA. Amino acid S at positions 3 and 7 was responsible for recognition by H1-specific clone A-12, while amino acid G at position 7 was responsible for recognition by H2-specific clone F-4. Two conserved amino acids, T at position 4 and A at position 6, were responsible for recognition by H1-, and H2-cross-reactive clone B7-B7. These results indicate that a single nine-amino-acid region is recognized by HA-specific CTL clones of three different subtype specificities and that the amino acids responsible for the recognition by the CTL clones are different.     

A common neutralizing epitope conserved between the hemagglutinins of influenza A virus H1 and H2 strains.

When mice were immunized with the A/Okuda/57 (H2N2) strain of influenza virus, a unique monoclonal antibody designated C179 was obtained. Although C179 was confirmed to recognize the hemagglutinin (HA) glycoprotein by immunoprecipitation assays, it did not show hemagglutination inhibition activity to any of the strains of the three subtypes of influenza A virus. However, it neutralized all of the H1 and H2 strains but not the H3 strains. Moreover, it inhibited polykaryon formation induced by the H1 and H2 strains but not by the H3 strains. Two antigenic variants against C179 were obtained, and nucleotide sequence analysis revealed that amino acid sequences, from 318 to 322 of HA1 and from 47 to 58 of HA2, conserved among H1 and H2 strains were responsible for the recognition of C179. Since the two sites were located close to each other at the middle of the stem region of the HA molecule, C179 seemed to recognize these sites conformationally. These data indicated that binding of C179 to the stem region of HA inhibits the fusion activity of HA and thus results in virus neutralization and inhibition of cell-cell fusion. This is the first report which describes the presence of conserved antigenic sites on HA not only in a specific subtype but also in two subtypes of influenza A virus.     

Design of Escherichia coli-Expressed Stalk Domain Immunogens of H1N1 Hemagglutinin That Protect Mice from Lethal Challenge

The hemagglutinin protein (HA) on the surface of influenza virus is essential for viral entry into the host cells. The HA1 subunit of HA is also the primary target for neutralizing antibodies. The HA2 subunit is less exposed on the virion surface and more conserved than HA1. We have previously designed an HA2-based immunogen derived from the sequence of the H3N2 A/HK/68 virus. In the present study, we report the design of an HA2-based immunogen from the H1N1 subtype (PR/8/34). This immunogen (H1HA0HA6) and its circular permutant (H1HA6) were well folded and provided complete protection against homologous viral challenge. Antisera of immunized mice showed cross-reactivity with HA proteins of different strains and subtypes. Although no neutralization was observable in a conventional neutralization assay, sera of immunized guinea pigs competed with a broadly neutralizing antibody, CR6261, for binding to recombinant Viet/04 HA protein, suggesting that CR6261-like antibodies were elicited by the immunogens. Stem domain immunogens from a seasonal H1N1 strain (A/NC/20/99) and a recent pandemic strain (A/Cal/07/09) provided cross-protection against A/PR/8/34 viral challenge. HA2-containing stem domain immunogens therefore have the potential to provide subtype-specific protection.     

Complete structure of the hemagglutinin gene from the human influenza A/Victoria/3/75 (H3N2) strain as determined from cloned DNA

The complete sequence of a hemagglutinin (HA) gene of a recent human influenza A strain, A/Victoria/3/75, is 1768 nucleotides long and contains the information for 567 amino acids. It codes for a signal peptide of 16 amino acids, the HA1 chain of the mature hemagglutinin of 329 amino acids, a connecting region between HA1 and HA2 consisting of a single arginine residue and the HA2 portion of 221 amiino acids. The sequence is compared with the hemagglutinin of two members of other subtypes, the human H2 strain A/Jap/305/57 and the avian Hav1 strain A/FPV/Rostock/34, and with one of the same H3 subtype, A/Memphis/3/72. To align the HA1 chain of different major subtypes several deletions/insertions of single amino acids must be invoked, but two more extensive differences are found at both ends, one leading to an extension of the amino terminal sequence of HA1 and the other (four residues) occurring in the region processed away between HA1 and HA2. Comparison of the HA1 of two H3 strains suggests that drift probably depends on single base mutations, some of which change antigenic determinants. The HA2 region, which apparently is not involved in the immune response, is highly conserved even between different subtypes, and single base substitutions account for all the observed diversity. A hydrophobic segment of 24 residues is present in the same position close to the carboxyl terminus of HA2 in both Victoria and FPV, and presumably functions in implantation into the lipid bilayer. The many conserved features not only in HA2 but also in HA1 suggest a rather rigid architecture for the whole hemagglutinin molecule.     

Characterization of subtype-specific and cross-reactive helper-T-cell clones recognizing influenza virus hemagglutinin

The specificity and function of two T-cell clones derived from A/Memphis/1/71 (H3) influenza virus (Mem 71)-immune BALB/c spleen cells have been compared. One clone, X-31 clone 1, was subtype specific, proliferating in response to influenza strains of the H3 subtype only. The other, Jap clone 3, cross-reacted in proliferation assays with heterologous subtypes of influenza A, but not type B. Both clones recognized the HA1 chain of the hemagglutinin (HA) molecule and their proliferation in response to detergent-disrupted virus could be specifically inhibited by monoclonal antibodies to the HA. The T-cell clones were of the L3T4+ phenotype. Both recognized antigen in association with I-Ed, as indicated by studies with H-2 recombinant strains of mice and by blocking with monoclonal anti-I-E antibody. In vivo, both clones elicited a delayed-type hypersensitivity (DTH) reaction when inoculated into mouse footpads together with virus, X-31 clone 1 again displaying subtype specificity and Jap clone 3 being cross-reactive. The clones were also able to provide factor-mediated help in vitro to virus-primed B cells in an anti-HA antibody response. The cross-reactive T-cell clone provided help not only for B cells primed with influenza A subtype H3 and responding to H3 virus in culture, but also for H2 virus-primed B cells making anti-H2 antibody.     

The recognition of a viral antigenic moiety by class I MHC-restricted cytolytic T lymphocytes is limited by the availability of the endogenously processed antigen.

The transmembrane hydrophobic domain of the type A influenza A/JAPAN/305/57 (H2N2) hemagglutinin (HA) contains an immunodominant site encompassing amino acids 523-545 (J523-545) recognized by class I MHC-restricted cytolytic T lymphocytes (CTL). Class I CTL of two fine specificity subsets map to this transmembrane (TM) site. One of these CTL subpopulations is subtype specific. These T lymphocytes recognize the site generated during infection of target cells with A/JAPAN/305/57 virus (H2N2) but not target cells expressing the comparable TM site of the influenza A/PR/8/34 virus (H1N1) hemagglutinin (P527-549) after infection with this virus. The other CTL subpopulation is cross-reactive and recognizes the TM site of the A/JAPAN/305/57 HA and the A/PR/8/34 HA with similar efficiency. Analyses of the critical amino acids in the TM site necessary for CTL recognition with the use of synthetic peptides unexpectedly revealed reactivity for the A/PR/8 HA TM site by subtype-specific CTL. This reactivity was only observed with truncated peptides corresponding to a limited portion of the A/PR/8 HA TM site but also required peptide concentrations greater than 10(-7) M. These results suggested either that the endogenously processed A/PR/8 HA TM site generated during infection was larger than the site defined by the truncated cross-reactive peptides or that the concentration of endogenously processed TM site produced during infection was limiting. To distinguish between these possibilities, we expressed in target cells synthetic minigenes encoding only the portion of the A/PR/8 HA transmembrane sites defined by the synthetic peptides. Unlike the peptides, the "preprocessed" endogenous minigene products were not recognized by subtype-specific CTL. These data suggest that the level of available endogenously processed Ag rather than selectivity in the site of fragmentation of newly synthesized Ag may play a critical role in determining whether the complex of the antigenic moiety and class I MHC is efficiently presented to and recognized by class I CTL.     

抗H9亚型禽流感病毒血凝素单克隆抗体的制备和鉴定

目的:获得分泌抗H9亚型禽流感病毒(AIV)血凝素单克隆抗体的杂交瘤细胞。方法:以H9N2亚型AIV为免疫原,免疫6～8周龄雌性BALB/c小鼠,取其脾细胞与骨髓瘤细胞Sp2/0-Ag-14,在PEG4000的作用下进行细胞融合,通过血凝抑制(HI)试验筛选分泌抗H9亚型AIV血凝素单克隆抗体的杂交瘤细胞。结果:经过连续3～4次克隆化,获得能稳定分泌抗H9亚型AIV血凝素的单克隆抗体细胞系6株,分别命名为1B2、1C10、1G2、2B7、2E3和5E11。6株细胞培养上清HI效价为24～28,腹水HI效价为210～213。除1G2为IgM外,其余5株均为IgG1。Western blotting结果显示,1B2、1C10、2B7和2E3能与AIVH9蛋白在Mr为75000处反应,表明其是针对AIVH9亚型血凝素蛋白的单抗。特异性试验表明该6株单抗均只与H9亚型AIV发生特异性HI反应,而不与其他14个HA亚型的AIV及新城疫病毒、传染性支气管炎病毒发生交叉反应,显示出良好的特异性。结论:制备了针对H9亚型禽流感病毒血凝素的单克隆抗体,为禽流感的快速诊断和病毒的抗原性分析等奠定了基础。     

Identification of a highly conserved H1 subtype-specific epitope with diagnostic potential in the hemagglutinin protein of influenza A virus

Subtype specificity of influenza A virus (IAV) is determined by its two surface glycoproteins, hemagglutinin (HA) and neuraminidase (NA). For HA, 16 distinct subtypes (H1–H16) exist, while nine exist for NA. The epidemic strains of H1N1 IAV change frequently and cause annual seasonal epidemics as well as occasional pandemics, such as the notorious 1918 influenza pandemic. The recent introduction of pandemic A/H1N1 IAV (H1N1pdm virus) into humans re-emphasizes the public health concern about H1N1 IAV. Several studies have identified conserved epitopes within specific HA subtypes that can be used for diagnostics. However, immune specific epitopes in H1N1 IAV have not been completely assessed. In this study, linear epitopes on the H1N1pdm viral HA protein were identified by peptide scanning using libraries of overlapping peptides against convalescent sera from H1N1pdm patients. One epitope, P5 (aa 58–72) was found to be immunodominant in patients and to evoke high titer antibodies in mice. Multiple sequence alignments and in silico coverage analysis showed that this epitope is highly conserved in influenza H1 HA [with a coverage of 91.6% (9,860/10,767)] and almost completely absent in other subtypes [with a coverage of 3.3% (792/23,895)]. This previously unidentified linear epitope is located outside the five well-recognized antigenic sites in HA. A peptide ELISA method based on this epitope was developed and showed high correlation (χ² = 51.81, P<0.01, Pearson correlation coefficient R = 0.741) with a hemagglutination inhibition test. The highly conserved H1 subtype-specific immunodominant epitope may form the basis for developing novel assays for sero-diagnosis and active surveillance against H1N1 IAVs.     

Specific subtyping of influenza A virus using a recombinant hemagglutinin protein expressed in baculovirus

Influenza A viruses are subtyped according to antigen characterization of hemagglutinin (HA) and neuraminidase surface glycoproteins. The hemagglutination inhibition (HI) assay using reference antiserum is currently applied to serologic screening of subtype-specific antibodies in sera. The reference antiserum is made by injecting chickens with live or inactivated whole virus preparations. Nonspecific inhibitors of antisera prepared by the conventional method may affect the specificity of HI assay. In this study, highly pure recombinant proteins generated using baculovirus expression vector system based on full-length of HA (HAF) and antigenic region of HA₁ genes of H9 subtype, and also inactivated whole virus were used to immunization of chickens. Measurable antibody titers were present for treated birds after 3 weeks and generally increased after each boost. The performance of the prepared antisera was evaluated by testing a panel of known standard strains of influenza virus representing five HA subtypes. Relative to the conventional method using whole virus immunization and recombinant HAF protein, the antiserum prepared by recombinant HA₁ had a specificity of 100% for all tested subtypes. The antiserum prepared by expression of HA1 protein in baculovirus has the potential for rapid and specific HA subtyping of influenza viruses without producing antibodies specific to other viral proteins.     

Antigenic Characterization of Recombinant Hemagglutinin Proteins Derived from Different Avian Influenza Virus Subtypes

Since the advent of highly pathogenic variants of avian influenza virus (HPAIV), the main focus of avian influenza research has been the characterization and detection of HPAIV hemagglutinin (HA) from H5 and H7 subtypes. However, due to the high mutation and reassortation rate of influenza viruses, in theory any influenza strain may acquire increased pathogenicity irrespective of its subtype. A comprehensive antigenic characterization of influenza viruses encompassing all 16 HA and 9 neuraminidase subtypes will provide information useful for the design of differential diagnostic tools, and possibly, vaccines. We have expressed recombinant HA proteins from 3 different influenza virus HA subtypes in the baculovirus system. These proteins were used to generate polyclonal rabbit antisera, which were subsequently employed in epitope scanning analysis using peptide libraries spanning the entire HA. Here, we report the identification and characterization of linear, HA subtype-specific as well as inter subtype-conserved epitopes along the HA proteins. Selected subtype-specific epitopes were shown to be suitable for the differentiation of anti-HA antibodies in an ELISA.     

Fine specificity analysis of human influenza-specific cloned cell lines

Influenza-specific human-T-cell clones, proliferating in the presence of virus-infected cells with restriction by class II molecules and displaying class II-restricted CTL activity or specific helper activity in antibody synthesis, have been analyzed for antigenic specificities. All of them were obtained by in vitro stimulation against influenza A/Texas virus. In all cases the virus specificity appeared identical in cytolytic and proliferative responses. Three of the clones were broadly cross-reactive, recognizing all or almost all type A influenza strains. The three remaining clones were subtype specific when tested with human strains and recognized the surface glycoproteins of influenza virus. One of these lines reacted with an epitope of the neuraminidase N2 while the other two recognized the hemagglutinin H3. By using a large panel of mammalian and avian influenza strains, it can be demonstrated that hemagglutinin-specific human T cells can recognize a cross-reacting determinant shared by H3 and H4 subtypes of hemagglutinin which has never been detected with antibodies.     

Formation of mixed hemagglutinin trimers during double infection with influenza virus strains of the same subtype

Formation of hemagglutinin spikes in the course of the mixed infection of cell culture by two influenza virus strains belonging to the same antigenic subtype or to different subtypes was studied by means of immunoprecipitation of [14C]-labelled hemagglutinins from cell lysates. The immunoprecipitates were further analysed by polyacrylamide gel electrophoresis. Lysates of separately infected cells mixed before lysis were used as control samples. The analysis of immunoprecipitates revealed the formation of chimeric hemagglutinin spikes in the cells infected by the strains possessing hemagglutinins of the same subtype but not in the cells infected by the strains of different subtypes (H1 and H3). The results are discussed in connection with the homology of amino-acid sequences of influenza virus hemagglutinins.     

Determinants of glycan receptor specificity of H2N2 influenza A virus hemagglutinin

The H2N2 subtype of influenza A virus was responsible for the Asian pandemic of 1957-58. However, unlike other subtypes that have caused pandemics such as H1N1 and H3N2, which continue to circulate among humans, H2N2 stopped circulating in the human population in 1968. Strains of H2 subtype still continue to circulate in birds and occasionally pigs and could be reintroduced into the human population through antigenic drift or shift. Such an event is a potential global health concern because of the waning population immunity to H2 hemagglutinin (HA). The first step in such a cross-species transmission and human adaptation of influenza A virus is the ability for its surface glycoprotein HA to bind to glycan receptors expressed in the human upper respiratory epithelia. Recent structural and biochemical studies have focused on understanding the glycan receptor binding specificity of the 1957-58 pandemic H2N2 HA. However, there has been considerable HA sequence divergence in the recent avian-adapted H2 strains from the pandemic H2N2 strain. Using a combination of structural modeling, quantitative glycan binding and human respiratory tissue binding methods, we systematically identify mutations in the HA from a recent avian-adapted H2N2 strain (A/Chicken/PA/2004) that make its quantitative glycan receptor binding affinity (defined using an apparent binding constant) comparable to that of a prototypic pandemic H2N2 (A/Albany/6/58) HA.     

Induction and activity of class II-restricted, Lyt-2+ cytolytic T lymphocytes specific for the influenza H5 hemagglutinin

In influenza A virus infections, CTL are a significant component of the host immune response which limits viral replication and promotes recovery. To examine the CTL response to the influenza virus A/Ty/Ont/7732/66[H5N9], particularly the H5 hemagglutinin, a long term CTL line was generated from spleen cells of A/Ty/Ont-immune Balb/c [H-2d] mice secondarily stimulated in vitro with A/Ty/Cal/Hurst-2/71[H5N2]. This CTL line was highly specific for influenza viruses of the H5 subtype. From this line, clones were isolated by limiting dilution and shown to be H5 hemagglutinin-specific based on recognition of an H5 vaccinia virus recombinant (H5 Vac). The clones exhibited the classical CTL surface phenotype Lyt-1-2+L3T4-; however, unlike the typically class I-restricted Lyt-2+ CTL, they were restricted in antigen recognition by class II (I-E) MHC molecules based on target cell recognition and antibody blocking of cytotoxicity. The clones recognized both infectious and non-infectious A/Ty/Ont presented by class II+ target cells. In adoptive transfer studies to assess the biologic role of the clones in vivo, these class II-restricted clones did not appear to alter mortality. However, these cells significantly reduced both morbidity and virus titers in the lungs of infected animals at 5 days post-infection. Thus, in the immune response to this virus, class II-restricted Lyt-2+ CTL specific for the H5 hemagglutinin were readily generated and their biologic role in vivo involved viral clearance.     

Antigen-specific human T lymphocyte clones: viral antigen specificity of influenza virus-immune clones

Human T lymphocyte clones (TLC) specific for type A (A/Texas/1/77) influenza virus and maintained in continuous culture with T cell growth factor, were analyzed to define the cellular specificity pattern of virus recognition. A panel of TLC were stimulated with strains of serologically characterized type A influenza subtypes. Five TLC recognized all the viral subtypes; the remaining clones recognized only subtypes that shared serologically defined determinants with the immunizing subtype. In addition, the 11 TLC were analyzed for their fine antigenic specificity by using the purified viral components hemagglutinin (HA), neuraminidase (NA), matrix protein (MP), and nucleoprotein (NP). Five TLC proliferated in response to NA, four to MP, one to HA, and one to NP. None of the clones responded to the unrelated B strain influenza virus, B/Singapore. Furthermore, the fine specificity of an MP-reactive TLC was confirmed by subcloning.     

Fine specificity and antigen receptor expression among influenza virus-specific cytolytic T lymphocyte clones

Influenza virus stimulates a vigorous cytolytic T lymphocyte (CTL) response in the mouse that is directed to several virion polypeptides. This report examines the fine specificity of a panel of murine influenza-specific CTL clones restricted by MHC class I products of the H-2d haplotype. Ten of 22 A/JAPAN/305/57-specific CTL clones analyzed were directed to the A/JAPAN/305/57 hemagglutinin protein as detected by using target cells infected with a recombinant vaccinia virus containing hemagglutinin gene. Based on their fine specificity of hemagglutinin recognition, these clones defined four functional epitopes on the hemagglutinin. The remaining 12 cytolytic clones exhibited cross-reactivity for type A influenza viruses of the major human subtypes, and approximately 60% of these clones were directed to the nucleocapsid protein. KJ16-133 monoclonal antibody analysis of the utilization of the T cell receptor V beta 8 gene segment subfamily revealed that members of this V beta gene subfamily are expressed by both hemagglutinin- and nucleocapsid-specific MHC class I-restricted CTL (and by influenza-specific MHC class II-restricted T lymphocytes as well). These results suggest that CTL detect several distinct antigenic sites on the hemagglutinin. In addition, these results reveal no direct correlation between viral antigenic specificity and V beta gene expression by these virus-specific CLT clones.     

Characterization of two distinct major histocompatibility complex class I Kk-restricted T-cell epitopes within the influenza A/PR/8/34 virus hemagglutinin.

Cytotoxic T-lymphocyte (CTL) clones specific for the influenza A/PR/8/34 virus hemagglutinin (HA) were isolated by priming CBA mice with a recombinant vaccinia virus expressing the HA molecule. The epitopes recognized by two of these clones, which were CD8+, Kk restricted, and HA subtype specific, were defined by using a combination of recombinant vaccinia viruses expressing HA fragments and synthetic peptides. One epitope is in the HA1 subunit at residues 259 to 266 (numbering from the initiator methionine), amino acid sequence FEANGNLI, and the other epitope is in the HA2 subunit at residues 10 to 18 (numbering from the amino terminus of the HA2 subunit), sequence IEGGWTGMI. These two peptides are good candidates for naturally processed HA epitopes presented during influenza infection, as they are the same length (eight and nine residues) as other naturally processed viral peptides presented to CTL. A comparison of the sequences of these two new epitopes with those of the three previously published Kk-restricted T-cell epitopes showed some homology among all of the epitopes, suggesting a binding motif. In particular, an isoleucine residue at the carboxy-terminal end is present in all of the epitopes. On the basis of this homology, we predicted that the Kk-restricted epitope in influenza virus nucleoprotein, previously defined as residues 50 to 63, was contained within residues 50 to 57, sequence SDYEGRLI. This shorter peptide was found to sensitize target cells at a 200-fold lower concentration than did nucleoprotein residues 50 to 63 when tested with a CTL clone, confirming the alignment of Kk-restricted epitopes.     

Targeting pseudoknots in H5N1 hemagglutinin using designed aptamers

Influenza A virus subtype H5N1 is highly contagious among birds, causing high mortality among domestic poultry. The viral genome is contained on eight single RNA strands of which HA encode the antigenic glycoprotein called hemagglutinin. Hemagglutinin found on the surface of the influenza viruses and is responsible for binding the virus to the cell that is being infected. Among the most prevalent RNA structures the pseudoknot motif represents an important piece of RNA architecture, as it provides a means for a single RNA strand to fold upon itself to produce a globular structure capable of performing important biological functions. In this analysis we have identified the pseudoknot motifs in the hemagglutinin gene of HPAI A (H5N1) Asian strains. Specific aptamers have been designed against these pseudoknots. These in-silico aptamers can be used to hinder the ability of pseudoknots to facilitate ribosomal frameshifting. This may ultimately lead to reduce the coding efficiency of the HA that encodes hemagglutinin and might be used as molecular medicine for H5N1.     

A CD4+ cytotoxic T-lymphocyte clone to a conserved epitope on human immunodeficiency virus type 1 p24: cytotoxic activity and secretion of interleukin-2 and interleukin-6.

A CD4+ cytotoxic T-lymphocyte (CTL) clone, established from the peripheral blood of a human immunodeficiency virus (HIV)-seropositive donor, lysed autologous target cells that were infected with a recombinant vaccinia virus containing the gag gene of HIV type 1 and target cells pulsed with p24gag construct expressed in Escherichia coli. The recognition of the HLA-DQ-restricted epitope by this clone was further defined by using overlapping synthetic peptides. The epitope recognized by this CD4+ CTL clone (amino acids 140 to 148) overlaps with a CD8+ epitope and is highly conserved among all isolates of HIV type 1 that have been sequenced. Production and secretion of lymphokines such as interleukin-2 and interleukin-6 after specific antigenic stimulation were demonstrated by this gag-specific CD4+ CTL clone.     

Hemagglutinin Stalk-Based Universal Vaccine Constructs Protect against Group 2 Influenza A Viruses

Current influenza virus vaccines contain H1N1 (phylogenetic group 1 hemagglutinin), H3N2 (phylogenetic group 2 hemagglutinin), and influenza B virus components. These vaccines induce good protection against closely matched strains by predominantly eliciting antibodies against the membrane distal globular head domain of their respective viral hemagglutinins. This domain, however, undergoes rapid antigenic drift, allowing the virus to escape neutralizing antibody responses. The membrane proximal stalk domain of the hemagglutinin is much more conserved compared to the head domain. In recent years, a growing collection of antibodies that neutralize a broad range of influenza virus strains and subtypes by binding to this domain has been isolated. Here, we demonstrate that a vaccination strategy based on the stalk domain of the H3 hemagglutinin (group 2) induces in mice broadly neutralizing anti-stalk antibodies that are highly cross-reactive to heterologous H3, H10, H14, H15, and H7 (derived from the novel Chinese H7N9 virus) hemagglutinins. Furthermore, we demonstrate that these antibodies confer broad protection against influenza viruses expressing various group 2 hemagglutinins, including an H7 subtype. Through passive transfer experiments, we show that the protection is mediated mainly by neutralizing antibodies against the stalk domain. Our data suggest that, in mice, a vaccine strategy based on the hemagglutinin stalk domain can protect against viruses expressing divergent group 2 hemagglutinins.