Antigenicity and evolution amongst recent influenza viruses of H1N1 subtype

Epitope mapping of the hemagglutinin molecule of A/(H1N1)pdm09 influenza virus by using monoclonal antibody escape mutants

We determined the antigenic structure of pandemic influenza A(H1N1)pdm09 virus hemagglutinin (HA) using 599 escape mutants that were selected using 16 anti-HA monoclonal antibodies (MAbs) against A/Narita/1/2009. The sequencing of mutant HA genes revealed 43 amino acid substitutions at 24 positions in three antigenic sites, Sa, Sb, and Ca2, which were previously mapped onto A/Puerto Rico/8/34 (A/PR/8/34) HA (A. J. Caton, G. G. Brownlee, J. W. Yewdell, and W. Gerhard, Cell 31:417-427, 1982), and an undesignated site, i.e., amino acid residues 141, 142, 143, 171, 172, 174, 177, and 180 in the Sa site, residues 170, 173, 202, 206, 210, 211, and 212 in the Sb site, residues 151, 154, 156, 157, 158, 159, 200, and 238 in the Ca2 site, and residue 147 in the undesignated site (numbering begins at the first methionine). Sixteen MAbs were classified into four groups based on their cross-reactivity with the panel of escape mutants in the hemagglutination inhibition test. Among them, six MAbs targeting the Sa and Sb sites recognized both residues at positions 172 and 173. MAb n2 lost reactivity when mutations were introduced at positions 147, 159 (site Ca2), 170 (site Sb), and 172 (site Sa). We designated the site consisting of these residues as site Pa. From 2009 to 2013, no antigenic drift was detected for the A(H1N1)pdm09 viruses. However, if a novel variant carrying a mutation at a position involved in the epitopes of several MAbs, such as 172, appeared, such a virus would have the advantage of becoming a drift strain.

IMPORTANCE

The first influenza pandemic of the 21st century occurred in 2009 with the emergence of a novel virus originating with swine influenza, A(H1N1)pdm09. Although HA of A(H1N1)pdm09 has a common origin (1918 H1N1) with seasonal H1N1, the antigenic divergence of HA between the seasonal H1N1 and A(H1N1)pdm09 viruses gave rise to the influenza pandemic in 2009. To take precautions against the antigenic drift of the A(H1N1)pdm09 virus in the near future, it is important to identify its precise antigenic structure. To obtain various mutants that are not neutralized by MAbs, it is important to neutralize several plaque-cloned parent viruses rather than only a single parent virus. We characterized 599 escape mutants that were obtained by neutralizing four parent viruses of A(H1N1)pdm09 in the presence of 16 MAbs. Consequently, we were able to determine the details of the antigenic structure of HA, including a novel epitope.

Playing hide and seek: how glycosylation of the influenza virus hemagglutinin can modulate the immune response to infection

Seasonal influenza A viruses (IAV) originate from pandemic IAV and have undergone changes in antigenic structure, including addition of glycans to the hemagglutinin (HA) glycoprotein. The viral HA is the major target recognized by neutralizing antibodies and glycans have been proposed to shield antigenic sites on HA, thereby promoting virus survival in the face of widespread vaccination and/or infection. However, addition of glycans can also interfere with the receptor binding properties of HA and this must be compensated for by additional mutations, creating a fitness barrier to accumulation of glycosylation sites. In addition, glycans on HA are also recognized by phylogenetically ancient lectins of the innate immune system and the benefit provided by evasion of humoral immunity is balanced by attenuation of infection. Therefore, a fine balance must exist regarding the optimal pattern of HA glycosylation to offset competing pressures associated with recognition by innate defenses, evasion of humoral immunity and maintenance of virus fitness. In this review, we examine HA glycosylation patterns of IAV associated with pandemic and seasonal influenza and discuss recent advancements in our understanding of interactions between IAV glycans and components of innate and adaptive immunity.

Antibody pressure by a human monoclonal antibody targeting the 2009 pandemic H1N1 virus hemagglutinin drives the emergence of a virus with increased virulence in mice

In 2009, a novel H1N1 influenza A virus (2009 pH1N1) emerged and caused a pandemic. A human monoclonal antibody (hMAb; EM4C04), highly specific for the 2009 pH1N1 virus hemagglutinin (HA), was isolated from a severely ill 2009 pH1N1 virus-infected patient. We postulated that under immune pressure with EM4C04, the 2009 pH1N1 virus would undergo antigenic drift and mutate at sites that would identify the antibody binding site. To do so, we infected MDCK cells in the presence of EM4C04 and generated 11 escape mutants, displaying 7 distinct amino acid substitutions in the HA. Six substitutions greatly reduced MAb binding (K123N, D131E, K133T, G134S, K157N, and G158E). Residues 131, 133, and 134 are contiguous with residues 157 and 158 in the globular domain structure and contribute to a novel pH1N1 antibody epitope. One mutation near the receptor binding site, S186P, increased the binding affinity of the HA to the receptor. 186P and 131E are present in the highly virulent 1918 virus HA and were recently identified as virulence determinants in a mouse-passaged pH1N1 virus. We found that pH1N1 escape variants expressing these substitutions enhanced replication and lethality in mice compared to wild-type 2009 pH1N1 virus. The increased virulence of these viruses was associated with an increased affinity for α2,3 sialic acid receptors. Our study demonstrates that antibody pressure by an hMAb targeting a novel epitope in the Sa region of 2009 pH1N1 HA is able to inadvertently drive the development of a more virulent virus with altered receptor binding properties. This broadens our understanding of antigenic drift.

Influenza viruses accumulate amino acid substitutions to evade the antibody response in a process known as antigenic drift, making it necessary to vaccinate against influenza annually. Mapping human monoclonal antibody (hMAb) epitopes is a necessary step towards understanding antigenic drift in humans. We defined the specificity of an hMAb that specifically targeted the 2009 pH1N1 virus and describe a novel epitope. In addition, we identified a previously unappreciated potential for antibody escape to enhance the pathogenicity of a virus. The escape mutation that we identified with in vitro immune pressure was independently reported by other investigators using in vivo selection in nonimmune mice. Although in vitro generation of escape mutants is unlikely to recapitulate antigenic drift in its entirety, the data demonstrate that pressure by a human monoclonal antibody targeting a novel epitope in the hemagglutinin of the 2009 pandemic H1N1 virus can inadvertently drive the development of escape mutants, of which a subset have increased virulence and altered receptor binding properties.

Neutralizing anti-influenza virus monoclonal antibodies: therapeutics and tools for discovery

The human antibody response to influenza virus infection plays a protective role against re-infection, yet little molecular detail is available regarding how human antibodies, when characterized at the monoclonal level, neutralize this important human pathogen. Recent studies, using a diverse array of strategies, have isolated and characterized human anti-virus neutralizing antibodies and shed light not only on the specificity and origin of these antibodies but on their potential for therapeutic use against influenza virus infection.

Different evolutionary trajectories of European avian-like and classical swine H1N1 influenza A viruses

In 1979, a lineage of avian-like H1N1 influenza A viruses emerged in European swine populations independently from the classical swine H1N1 virus lineage that had circulated in pigs since the Spanish influenza pandemic of 1918. To determine whether these two distinct lineages of swine-adapted A/H1N1 viruses evolved from avian-like A/H1N1 ancestors in similar ways, as might be expected given their common host species and origin, we compared patterns of nucleotide and amino acid change in whole genome sequences of both groups. An analysis of nucleotide compositional bias across all eight genomic segments for the two swine lineages showed a clear lineage-specific bias, although a segment-specific effect was also apparent. As such, there appears to be only a relatively weak host-specific selection pressure. Strikingly, despite each lineage evolving in the same species of host for decades, amino acid analysis revealed little evidence of either parallel or convergent changes. These findings suggest that although adaptation due to evolutionary lineages can be distinguished, there are functional and structural constraints on all gene segments and that the evolutionary trajectory of each lineage of swine A/H1N1 virus has a strong historical contingency. Thus, in the context of emergence of an influenza A virus strain via a host switch event, it is difficult to predict what specific polygenic changes are needed for mammalian adaptation.

The Structure and Receptor Binding Properties of the 1918 Influenza Hemagglutinin

The 1918 influenza pandemic resulted in about 20 million deaths. This enormous impact, coupled with renewed interest in emerging infections, makes characterization of the virus involved a priority. Receptor binding, the initial event in virus infection, is a major determinant of virus transmissibility that, for influenza viruses, is mediated by the hemagglutinin (HA) membrane glycoprotein. We have determined the crystal structures of the HA from the 1918 virus and two closely related HAs in complex with receptor analogs. They explain how the 1918 HA, while retaining receptor binding site amino acids characteristic of an avian precursor HA, is able to bind human receptors and how, as a consequence, the virus was able to spread in the human population.

Virus-cell interactions in the induction of type 1 interferon by influenza virus in mouse spleen cells

Inactivated influenza A virus and fixed, virus-infected cells induce type 1 interferon (IFN-alpha/beta) production in murine splenocytes. In this study, we have explored the nature of the virus-spleen cell interaction that leads to IFN-alpha/beta induction and the reason for the poor response to some virus strains. IFN-alpha/beta induction by horse serum-sensitive, but not -resistant, strains of influenza virus was inhibited in the presence of horse serum, indicating that binding of the virus to sialylated cell receptors is a necessary step in the induction process. Furthermore, influenza viruses A/PR/8/34 (H1N1) and A/WS/33 (H1N1), which were poor inducers of IFN-alpha/beta in spleen cells, were shown to have a more active neuraminidase than strains that induced higher IFN levels, and IFN-alpha/beta induction by A/PR/8/34 (H1N1) and A/WS/33 (H1N1) was restored in the presence of a neuraminidase inhibitor. Growth of virus in different cell types altered the level of IFN-alpha/beta induced in spleen cells by particular virus strains, suggesting that the nature of the carbohydrate moieties on the viral glycoproteins may also influence IFN-alpha/beta induction in this system. Consistent with this notion, treatment of egg-grown virus with periodate to oxidize viral carbohydrate greatly reduced its capacity for IFN-alpha/beta induction. Furthermore, induction of IFN-alpha/beta was inhibited in the presence of the saccharides yeast mannan and laminarin. Together these findings indicate: (i) a requirement for interaction of the virus with sialylated receptors on the IFN-producing cell; (ii) an influence of viral carbohydrate on the response; and (iii) possible involvement of a lectin-like receptor on the IFN-producing cell in the induction of IFN-alpha/beta or in regulation of this response.

The emergence of novel swine influenza viruses in North America

Since 1997, novel viruses of three different subtypes and five different genotypes have emerged as agents of influenza among pigs in North America. The appearance of these viruses is remarkable because there were no substantial changes in the overall epidemiology of swine influenza in the United States and Canada for over 60 years prior to this time. Viruses of the classical H1N1 lineage were virtually the exclusive cause of swine influenza from the time of their initial isolation in 1930 through 1998. Antigenic drift variants of these H1N1 viruses were isolated in 1991-1998, but a much more dramatic antigenic shift occurred with the emergence of H3N2 viruses in 1997-1998. In particular, H3N2 viruses with genes derived from human, swine and avian viruses have become a major cause of swine influenza in North America. In addition, H1N2 viruses that resulted from reassortment between the triple reassortant H3N2 viruses and classical H1N1 swine viruses have been isolated subsequently from pigs in at least six states. Finally, avian H4N6 viruses crossed the species barrier to infect pigs in Canada in 1999. Fortunately, these H4N6 viruses have not been isolated beyond their initial farm of origin. If these viruses spread more widely, they will represent another antigenic shift for our swine population, and could pose a threat to the world's human population. Research on these novel viruses may offer important clues to the genetic basis for interspecies transmission of influenza viruses.

The predicted antigenicity of the haemagglutinin of the 1918 Spanish influenza pandemic suggests an avian origin

In 1982 we characterized the antigenic sites of the haemagglutinin of influenza A/PR/8/34, which is an influenza strain of the H1 subtype that was isolated from humans in 1934, by studying mutants which escaped neutralization by antibody. Four antigenic sites, namely Cb, Sa, Sb and Ca, were found to be located near the tip of the trimeric haemagglutinin spike. Based on the sequence of the haemagglutinin of the 1918 Spanish influenza, we can now specify the extent of divergence of antigenic sites of the haemagglutinin during the antigenic drift of the virus between 1918 and 1934. This divergence was much more extensive (40%) than the divergence (20%) in predicted antigenic sites between the 1918 Spanish influenza and an avian H1 subtype consensus sequence. These results support the hypothesis that the human 1918 pandemic originated from an avian virus of the H1 subtype that crossed the species barrier from birds to humans and adapted to humans, presumably by mutation and/or reassortment, shortly before 1918.

Influence of the amino acid differences between the hemagglutinin HA1 domains of influenza virus H1N1 strains on their reaction with antibody

For influenza H1N1 strains, including some of their escape variants, the association of amino acid differences located at their hemagglutinin HA1 domains with their antigenic relationship was examined. The antigenic relationship was recorded in terms of the ratios of hemagglutination inhibition (HI) titers, the concentration of antibody molecules recognized by the virus, and the equilibrium constant of epitope-paratope interaction determined with heterologous virus compared to that found with homologous virus. The HI titers of antisera were found to depend primarily on the concentration of antibody molecules recognized by the virus and much less on the equilibrium constants. The avidity of antibody in sera raised against historically later strains with earlier strains was higher than vice versa. In contrast to the results obtained with antisera, the same concentration of monoclonal antibody directed to the Sb site of A/Brazil virus was recognized by both heterologous and homologous viruses, and the differences in HI titers observed were due to avidity changes only. Some of the amino acid differences located at each of the antigenic sites were found to be associated with a reduction in the HI titers and in the concentration of antibody molecules recognized by heterologous virus, whereas other differences in addition decreased the avidity of epitope-paratope interaction. Further amino acid differences decreased the avidity only. The strains tested differed also in their amino acids located outside the antigenic sites. However, an influence of these differences on the reaction of virus with antibody could not be evidenced. For the strains tested, the antigenic hemagglutinin drift occurred by reduction of the concentration of antibody molecules recognized by the virus and by avidity changes, which, in turn, were caused by exchanges of some key residues located at the antigenic sites.

Statistical analysis of nucleotide sequences of the hemagglutinin gene of human influenza A viruses

To examine whether positive selection operates on the hemagglutinin 1 (HA1) gene of human influenza A viruses (H1 subtype), 21 nucleotide sequences of the HA1 gene were statistically analyzed. The nucleotide sequences were divided into antigenic and nonantigenic sites. The nucleotide diversities for antigenic and nonantigenic sites of the HA1 gene were computed at synonymous and nonsynonymous sites separately. For nonantigenic sites, the nucleotide diversities were larger at synonymous sites than at nonsynonymous sites. This is consistent with the neutral theory of molecular evolution. For antigenic sites, however, the nucleotide diversities at nonsynonymous sites were larger than those at synonymous sites. These results suggest that positive selection operates on antigenic sites of the HA1 gene of human influenza A viruses (H1 subtype).

Genetic and antigenic analyses of influenza A (H1N1) viruses, 1986-1991

Eighteen strains of human influenza A (H1N1) viruses isolated between August 1986 and January 1991 were analyzed in this study. Examination of the total viral genome of 12 strains by T1 mapping revealed that considerable genetic heterogeneity exists among these viruses. Partial sequencing of each of the non-HA RNA segments of 4 viruses having divergent T1 oligonucleotide maps indicated that only one was a reassortant virus that had genes from both the influenza A (H1N1) and (H3N2) subtypes. This reassortant obtained its PB2 gene from a virus of the H3N2 subtype and the other 7 RNA segments from an H1N1 parent. Sequencing studies of the HA1 domains of the hemagglutinin (HA) genes of these 18 strains revealed that although these viruses are antigenically similar to the reference strains A/Taiwan/1/86 and A/Singapore/6/86, 7 conserved amino acid substitutions that are shared by recently isolated H1N1 viruses have occurred in the main stream of evolution of the H1N1 subtype. Our data indicate that: (1) Genetic reassortment continues to contribute to genetic variability of H1N1 viruses. (2) Genetic variants of non-reassortant H1N1 viruses are co-circulating in the world. (3) The HA's of recent H1N1 viruses are related to those of the 1986 reference strains. (4) Although there has been little detectable antigenic variability, the HA genes of human epidemic influenza A (H1N1) viruses have continued to evolve at an evolutionary rate similar to that for the H1N1 and H3N2 viruses analyzed previously.

Human mannose-binding protein functions as an opsonin for influenza A viruses

Influenza A viruses (IAVs) cause substantial morbidity and mortality in yearly epidemics, which result from the ability of the virus to alter the antigenicity of its envelope proteins. Despite the rapid replication of this virus and its ability to infect a wide variety of cell types, viremia is rare and the infection is generally limited to the upper respiratory tract. The preimmune host defense response against IAV is generally, therefore, successful. We have previously provided (and summarized) evidence that neutrophils contribute to defense against IAV, although neutrophil dysfunction and local tissue damage may be less salutory byproducts of this response. Here we provide evidence that the serum lectin mannose-binding protein directly inhibits hemagglutinin activity and infectivity of several strains of IAV. In addition mannose-binding protein acts as an opsonin, enhancing neutrophil reactivity against IAV. Opsonization of IAV by mannose-binding protein also protects the neutrophil from IAV-induced dysfunction. These effects are observed with physiologically relevant concentrations of mannose-binding protein. Two different allelic forms of recombinant mannose-binding protein are found to have similar effects. We believe, on the basis of these data, that mannose-binding protein alone and in conjunction with phagocytic cells is an important constituent of natural immunity (i.e., preimmune defense) against IAV.

Two distinct serum mannose-binding lectins function as beta inhibitors of influenza virus: identification of bovine serum beta inhibitor as conglutinin

Normal bovine and mouse sera contain a component, termed beta inhibitor, that inhibits the infectivity and hemagglutinating activity of influenza A viruses of the H1 and H3 subtypes. We have previously shown these beta inhibitors to be mannose-binding lectins that apparently act by binding to carbohydrate on the viral hemagglutinin, blocking access of the receptor-binding site to receptors on host cells (E. M. Anders, C. A. Hartley, and D. C. Jackson, Proc. Natl. Acad. Sci. USA 87:4485-4489, 1990). For the H3-subtype virus A/Memphis/1/71 x A/Bel/42 (H3N1), sensitivity to beta inhibitors is determined by the oligosaccharide at residue 165 of the hemagglutinin, this glycosylation site being lost in a resistant mutant selected by growth in the presence of bovine serum. In the present study, we sequenced the hemagglutinin genes of additional bovine serum-resistant mutants derived from influenza viruses A/Philippines/2/82 (H3N2) and A/Brazil/11/78 (H1N1). The results confirm the importance of carbohydrate at residue 165 for inhibitor sensitivity of H3 viruses and implicate carbohydrate at residue 87 (94a in the H3 numbering system) as an important determinant in the sensitivity of H1-subtype viruses to the bovine inhibitor. Unlike the two H3 mutants, which had also gained resistance to hemagglutination inhibition by mouse serum, the H1 bovine serum-resistant mutant remained sensitive to the mouse beta inhibitor, suggesting that inhibition by the two types of sera is mediated by distinct mannose-binding lectins. In support of this hypothesis, the beta inhibitors in bovine and mouse sera were shown to differ in their pattern of inhibition by monosaccharides and in their sensitivity to 2-mercaptoethanol. In these and other properties, the bovine inhibitor closely resembled conglutinin, a Ca(2+)-dependent N-acetylglucosamine- and mannose-binding lectin present in bovine serum but absent from the serum of other species. Furthermore, polyclonal and monoclonal anticonglutinin antibodies abrogated the hemagglutination-inhibiting activity of bovine serum. Direct binding of conglutinin to the parent viruses and reduced binding to their respective mutants were confirmed by radioimmunoassay.

Direct determination of the point mutation rate of a murine retrovirus

The point mutation rate of a murine leukemia virus (MuLV) genome (AKV) was determined under conditions in which the number of replicative cycles was carefully controlled and the point mutation rate was determined by direct examination of the RNA genomes of progeny viruses. A clonal cell line infected at a low multiplicity of infection (2 x 10(-3)) was derived to provide a source of virus with high genetic homogeneity. Virus stocks from this cell line were used to infect cells at a low multiplicity of infection, and the cells were seeded soon after infection to obtain secondary clonal cell lines. RNase T1-oligonucleotide fingerprinting analyses of virion RNAs from 93 secondary lines revealed only 3 base changes in nearly 130,000 bases analyzed. To obtain an independent assessment of the mutation rate, we directly sequenced virion RNAs by using a series of DNA oligonucleotide primers distributed across the genome. RNA sequencing detected no mutations in over 21,000 bases analyzed. The combined fingerprinting and sequencing analyses yielded a mutation rate for infectious progeny viruses of one base change per 50,000 (2 x 10(-5)) bases per replication cycle. Our results suggest that over 80% of infectious progeny MuLVs may be replicated with complete fidelity and that only a low percentage undergo more than one point mutation during a replication cycle. Previous estimates of retroviral mutation rates suggest that the majority of infectious progeny viruses have undergone one or more point mutations. Recent studies of the mutation rates of marker genes in spleen necrosis virus-based vectors estimate a base substitution rate lower than estimates for infectious avian retroviruses and nearly identical to our determinations with AKV. The differences between mutation rates observed in studies of retroviruses may reflect the imposition of different selective conditions.

Nucleotide sequence analysis of the HA1 coding portion of the haemagglutinin gene of swine H1N1 influenza viruses

The nucleotide and deduced amino acid sequences coding for the HA1 portion of the haemagglutinin (HA) genes of three swine influenza viruses were determined and compared with published HA sequence data for human H1N1 influenza viruses. Sequence differences between the classic swine influenza HAs sw37 (A/swine/29/37) and NJ76 (A/New Jersey/11/76) were randomly distributed in the molecule without being confined to antigenic sites. In contrast, sequence differences between the HAs of sw37 and the antigenically atypical strains sw38 (A/swine/Northern Ireland/38) and sw39 (A/swine/Cambridge/39) were clustered in hypervariable regions, similar to the pattern of changes that was present between sw37 and the human strains PR834 (A/PR/8/34) and WSN33 (A/WSN/33). Sequence homologies of the European swine influenza strains (sw38, sw39) were higher with the HAs of the human strains (PR834, WSN33) than with the classic swine influenza HAs (sw37, NJ76). Phylogenetic analysis showed that the HA genes of these two European swine influenza strains emerged from a different evolutionary lineage of H1 HAs than the HAs of classic swine influenza strains.

Hemagglutinin mutations related to antigenic variation in H1 swine influenza viruses

The hemagglutinin (HA) of a recent swine influenza virus, A/Sw/IN/1726/88 (H1N1), was shown previously to have four antigenic sites, as determined from analysis of monoclonal antibody (MAb)-selected escape mutants. To define the HA mutations related to these antigenic sites, we cloned and sequenced the HA genes amplified by polymerase chain reaction of parent virus and MAb-selected escape mutants. The genetic data indicated the presence of four amino acid changes. After alignment with the three-dimensional structure of H3 HA, three changes were located on the distal tip of the HA, and the fourth was located within the loop on the HA. We then compared our antigenic sites, as defined by the changed amino acids, with the well-defined sites on the H1 HA of A/PR/8/34. The four amino acid residues corresponded with three antigenic sites on the HA of A/PR/8/34. This finding, in conjunction with our previous antigenic data, indicated that two of the four antigenic sites were overlapping. In addition, our previous studies indicated that one MAb-selected mutant and a recent, naturally occurring swine isolate reacted similarly with the MAb panel. However, their amino acid changes were different and also distant on the primary sequence but close topographically. This finding indicates that changes outside the antigenic site may also affect the site. A comparison of the HA amino acid sequences of early and recent swine isolates showed striking conservation of genetic sequences as well as of the antigenic sites. Thus, swine influenza viruses evolve more slowly than human viruses, possibly because they are not subjected to the same degree of immune selection.

Sequence analysis of the equine H7 influenza virus haemagglutinin gene

The nucleotide sequences of ten haemagglutinin genes of representative H7N7 equine influenza viruses isolated between 1956 and 1977 have been determined by primer extension sequencing. Their nucleotide and deduced amino acid sequences demonstrate a high degree of homology. These equine viruses can be divided into two distinct subgroups, the prototype-like, and a group comprising the early American isolates and the remaining equine viruses. The equine H7 haemagglutinins form a quite distinct group compared to H7 haemagglutinins isolated from other species. Each of these equine H7 haemagglutinins possess a tetrabasic amino acid cleavage site separating the HA1 and HA2 domains but, in addition, all ten contain a nine amino acid insertion prior to the tetrabasic sequence. The haemagglutinin glycoproteins of all ten viruses are capable of cleavage activation in virus infected primary chicken embryo fibroblast cells.

Evolution of influenza A(H1N1) viruses during a period of low antigenic drift in 1986-91: sequence of the HA1 domain of influenza A/Finland/158/91

This study used the nucleotide sequence coding for the HA1 domain of virus haemagglutinin to show that influenza A/Finland/158/91, which represents the H1N1 subtype viruses prevalent in Finland in 1990/91, was a direct descendant of a virus (A/NN/1605/88) isolated during the 1988/89 epidemic season in Japan. The elevated rate of 7.4 x 10(-3) nucleotide substitutions per site per year is discussed. The new branch of H1N1 subtype viruses is characterized by loss of a glycosylation site, which may affect subsequent antigenic drift.

Phylogenetic relationship of the nonstructural (NS) genes of influenza A viruses

Phylogenetic trees were constructed using 38 sequences of the A group and 10 sequences of the B group of the NS gene of influenza A viruses. Within the A group we found avian as well as mammalian influenza a viruses, while within the B group exclusively avian strains were found. The avian and human NS genes of the A group were derived from a common ancestor existing at about 1912. At 13 positions of the amino acid sequences of the NS1 protein two subtypes of the A group can be differentiated, a human and a non-human subtype. Starting at the time of the introduction of an avian PB1 gene into human strains during the antigenic shift at 1957 the NS1 protein of the human strains came under an enhanced selection pressure which might indicate a cooperation of the NS1 protein with and adaptation of the NS1 protein on the newly introduced PB1 gene. Such a selection pressure on the NS2 protein is completely missing. Comparison of all sequences of the NS1 protein revealed four highly conserved regions within the amino-terminal half of the molecule. One of this regions seems to contain the nuclear migration signal. The carboxy-terminal half is completely variable and seems to be dispensable.

Phosphoprotein and nucleocapsid protein evolution of vesicular stomatitis virus New Jersey

The entire phosphoprotein (P) and nucleocapsid (N) protein gene sequences and deduced amino acid sequences for 18 selected vesicular stomatitis virus isolates representative of the natural genetic diversity within the New Jersey serotype are reported. Phylogenetic analysis of the data using maximum parsimony allowed construction of evolutionary trees for the individual genes and the combined N, P, and glycoprotein (G) genes of these viruses. Virtually identical rates of nucleotide substitutions were found for each gene, indicating that evolution of these genes occurs at essentially the same rate. Although up to 19 and 17% sequence differences were evident in the P and N genes, respectively, no variation in gene length or evidence of recombinational rearrangements was found. However, striking evolutionary differences were observed among the amino acid sequences of vesicular stomatitis virus New Jersey N, P, and G proteins. The N protein amino acid sequence was the most highly conserved among the different isolates, indicating strong functional and structural constraints. Conversely, the P protein amino acid sequences were highly variable, indicating considerably fewer constraints or greater evolutionary pressure on the P protein. Much of the remarkable amino acid variability of the P protein resided in a hypervariable domain located between amino acids 153 and 205. The variability within this region would be consistent with it playing a structural role as a spacer to maintain correct conformational presentation of the separate active domains of this multifunctional protein. In marked contrast, the adjacent domain I of the P protein (previously thought to be under little evolutionary constraint) contained a highly conserved region. The colocalization of a short, potentially functional overlapping open reading frame to this region may explain this apparent anomaly.

Rapid detection of influenza virus H1 by the polymerase chain reaction

We applied a combination of reverse transcription (RT) with the polymerase chain reaction (PCR) for a rapid detection of influenza virus H1 subtype. We amplified a 441 bp segment of relatively high genetic stability of the hemagglutinin gene. Experimental conditions were established using plasmid DNA and infected cell cultures. The test was applied to 28 nasopharyngeal lavages from patients, two of which were positive for influenza virus H1. When the amplified DNA of a positive sample was sequenced we found 97% homology with the recent strain A/USSR/70.

Independent and disparate evolution in nature of influenza A virus hemagglutinin and neuraminidase glycoproteins

The hemagglutinin (HA) and neuraminidase (NA) external glycoprotein antigens of H1N1 and H3N2 subtypes of epidemiologically important influenza A viruses prevalent during recent decades were subjected to intensive antigenic analysis by four different methods. Prior to serological analysis with polyclonal rabbit antisera, HA and NA antigens of four viruses of each subtype were segregated by genetic reassortment to forestall nonspecific steric hindrance during antigen-antibody combination. This analysis has demonstrated that with respect to antigenic phenotype, HA and NA proteins have evolved at different rates. With H1N1 viruses, an arrest of significant evolution of the NA discordant with the continuing antigenic drift of HA was found in the 1980-1983 period. It is probable that the different and independent rates of evolution of HA and NA reflect the greater selective pressure of HA antibodies, which forces the more rapid emergence of HA escape mutants. The slower antigenic change found for NA further supports the potential for NA-specific infection-permissive immunization as a useful stratagem against influenza.

The carbohydrate chains of influenza virus hemagglutinin

The major surface antigen of influenza virus A/Leningrad/385/80 (H3N2), H3 hemagglutinin, as well as its heavy and light subunits were obtained by bromelain treatment, followed by gel chromatography. Carbohydrate chains were split off from both subunits by lithium borohydride-lithium hydroxide in aqueous 2-methyl-2-propanol, and individual oligosaccharides isolated. The main oligosaccharides, whose structure was determined by 1H-n.m.r. spectroscopy and chemical methods, are of the ordinary oligomannoside and complex types. It was found that, in spite of the great difference in number of glycosylation sites in heavy and light subunits, the amount and even relative abundance of variants of carbohydrate chains in both subunits are very similar.

Location on the evolutionary tree of influenza H3 haemagglutinin genes of Japanese strains isolated during 1985-6 season

The nucleotide sequences of the haemagglutinin (HA) genes of influenza A (H3N2) isolates from the 1985-6 season in Japan along with those of several viruses isolated between 1982-5 from other countries were analyzed to determine the origin of the 1985-6 Japanese strains. The HA genes of these viruses consisted of 1762 nucleotides and had a three-nucleotide deletion downstream from the stop codon when compared to the sequences of earlier Hong Kong H3N2 viruses. An evolutionary tree of the HA genes of these viruses was drawn using the A/Bangkok/1/79 sequence as the starting point. Eight strains isolated from Asian and Pacific regions including Japan in the 1985-6 season (one in May) had the HA genes located closely on the evolutionary tree but away from those of the isolates in North America and Europe during the 1984-5 season, and a common ancestry for these viruses was suggested.

Genetic variants of influenza A/Taiwan/1/86 cocirculating in Canada during the winter of 1986 to 1987

The first isolate of influenza virus in Canada during the winter of 1986 to 1987 was a genetic variant of A/Taiwan/1/86. This genetic variant type was the predominant strain obtained from several of the western provinces. The variant strains were antigenically indistinguishable from A/Taiwan/1/86 but were remarkably distinct by T1 oligonucleotide mapping. T1 mapping of individual genome segments indicated that the variants evolved from an A/Taiwan/1/86-like virus through the accumulation of point mutation or deletion or insertion events and probably do not contain foreign genes. The relative distribution of genetic variation was approximately equal among the individual genes, with the possible exception of segments 1 or 2 that were analyzed in combination and thus could not be individually associated with the observed variation.

Antigenic and amino acid sequence analysis of the variants of H1N1 influenza virus in 1986

Since their reintroduction to human populations in 1977, influenza A viruses of the H1N1 subtype have undergone antigenic drift. Recently a distinct antigenic variant, A/Singapore/6/86, has been almost exclusively isolated internationally, and the antigenic properties and amino acid sequence of its haemagglutinin have been determined and compared with those of the haemagglutinins of other H1N1 viruses, in particular A/Chile/1/83. Fourteen amino acid sequence differences are detected between the HA1 components of these two viruses, ten of which are different from equivalent residues in the haemagglutinins of all H1N1 viruses isolated between 1982 and 1983, and seven of which are novel in the haemagglutinins of all H1N1 viruses sequenced to date. The results are discussed in relation to the three-dimensional structure of the haemagglutinin and the location of the previously defined antigenically important regions.

Epidemiology of influenza C virus in man: multiple evolutionary lineages and low rate of change

The nucleotide sequences of nonstructural protein (NS) genes of human influenza C viruses isolated between 1947 and 1983 were determined and compared. Assuming constant evolutionary rates, the extent of nucleotide differences among NS genes does not correspond to the isolation years of the strains. This suggests that more than one gene lineage is present in the population. Furthermore, examination of the eight C virus NS gene sequences by the maximum parsimony method (W. M. Fitch, 1971, Syst. Zool. 20, 406-416) yielded phylogenetic trees that were grossly different from those obtained using the hemagglutinin genes for the same eight isolates. This result is compatible with the idea of reassortment of genes in nature across lineages of influenza C viruses. The sequence analysis also suggests that nucleotide substitutions occur at a lower rate in the C virus NS genes than in influenza A virus NS genes.

Evolution of human influenza A viruses over 50 years: rapid, uniform rate of change in NS gene

Variation in influenza A viruses was examined by comparison of nucleotide sequences of the NS gene (890 bases) of 15 human viruses isolated over 53 years (1933 to 1985). Changes in the genes accumulate with time, and an evolutionary tree based on the maximum parsimony method can be constructed. The evolutionary rate is approximately 2 X 10(-3) substitution per site per year in the NS genes, which is about 10(6) times the evolutionary rate of germline genes in mammals. This uniform and rapid rate of evolution in the NS gene is a good molecular clock and is compatible with the hypothesis that positive selection is operating on the hemagglutinin (or perhaps some other viral genes) to preserve random mutations in the NS gene.

Selection of influenza A virus adsorptive mutants by growth in the presence of a mixture of monoclonal antihemagglutinin antibodies

The influenza virus hemagglutinin contains four major regions that are recognized by antibodies able to neutralize viral infectivity. To investigate the effect of an antibody response directed against each of these sites on viral evolution, influenza virus A/PR/8/34 (H1N1) was grown in allantois-on-shell cultures in the presence of a mixture of monoclonal antihemagglutinin antibodies. This selection mixture contained antibodies (two or three antibodies per antigenic site) whose concentrations were adjusted to achieve equal neutralization titers against each of the four antigenic sites. By varying the ratio of input virus to selection mixture concentration, we observed that variant viruses emerged under conditions of partial neutralization. Each of the four variants characterized in detail differed from the parental virus in its interaction with cellular receptors and exhibited minimal changes in antigenicity. Thus, these variants were virtually indistinguishable from wild-type viruses, as assessed by the binding of 103 monoclonal antihemagglutinin antibodies in an indirect radioimmunoassay. Despite this, many of the same antibodies demonstrated decreased titers to the variants in hemagglutination inhibition tests. The magnitude of the differences depended on the indicator erythrocytes used (much greater differences were detected with chicken erythrocytes than with human erythrocytes). Hemagglutination mediated by the variants was more resistant to neuraminidase treatment of erythrocytes than hemagglutination mediated by the parental virus. These findings are consistent with the idea that the variants were initially selected by virtue of their increased avidity for host cell receptors. Sequencing of viral RNA revealed that each of the variants differed from the parental virus by a single amino acid alteration in its HA1 subunit. Two of the changes were close to the proposed receptor binding site on hemagglutinin and could directly alter receptor binding, while a third was located near the trimer interface and may have increased receptor binding by altering monomer-monomer interactions.

The antigenicity and evolution of influenza H1 haemagglutinin, from 1950-1957 and 1977-1983: two pathways from one gene

Nucleotide sequence analysis of the region of the haemagglutinin gene coding for the HA1 domain of the protein was performed on 19 human influenza A strains of H1 subtype representative of the two epidemic periods from 1977-1983 and from 1950-1957. The amino acid changes relative to A/USSR/90/77 are summarised and are consistent with the view that variation in these field strains involves changes largely at the Sb and Ca antigenic sites previously characterised in laboratory mutants of the haemagglutinin of influenza A/PR/8/34. The Sa and Cb sites are less variant and are probably masked by carbohydrate side chains. We discuss the significance of other amino acid changes which do not correspond to previously defined antigenic sites. We also define the "mainstream" amino acid changes characteristic of the divergent evolutionary pathways of the 1950-1957 and 1977-1983 periods and note that the rate of evolution is faster in the earlier period.

Forecasting the epidemic potential of influenza virus variants based on their molecular properties

Sequence analysis of the influenza haemagglutinin, HA (H1 and H3) suggests that many antigenic variants that are identified but which do not become predominant differ from contemporary epidemic strains in one or two amino acids, in the region 188-193. This information may assist in the optimum selection of vaccine strains when multiple variants are co-circulating. Genome analysis of H1N1 virus, from 1977 to 1983 (but not of H3N2 virus thus far) has identified two instances when large changes in total genome sequence was associated with major epidemic activity. The early detection of such gross genetic changes may provide a further indicator that can be used to forecast the likelihood of more widespread activity than normal.

Alterations in the hemagglutinin associated with adaptation of influenza B virus to growth in eggs

In 1943 Burnet reported on changes in the hemagglutinating properties of human influenza virus which occurred during adaptation of the virus to growth in chicken eggs. Only recently has direct evidence been presented that these changes affect the antigenic properties of the virus. Schild et al. (G. C. Schild, J. S. Oxford, J. C. deJong, and R. G. Webster (1983), Nature (London) 303, 706-709) demonstrated that egg adaptation of influenza B virus selects variants which are antigenically distinct from virus grown from the same source in mammalian cells. The molecular changes in the hemagglutinin (HA) of influenza B virus associated with adaptation to growth in eggs have now been identified. A specific glycosylation site at the distal tip of the HA of influenza B virus grown exclusively in mammalian cell culture is lost or altered during egg adaptation. Since the HA functions in adsorption of virus to cells, it is concluded that removal or modification of an oligosaccharide structure at this position is required for influenza B virus to attach to and infect the allantois cells of the egg and that this has important implications for the antigenic configuration of the molecule.

A carbohydrate side chain on hemagglutinins of Hong Kong influenza viruses inhibits recognition by a monoclonal antibody

A single amino acid substitution, Asp-63 to Asn-63, was detected in the hemagglutinin of an antigenic variant of the 1968 Hong Kong (H3) influenza virus that was selected by growth of the wild-type virus in the presence of a monoclonal antibody. The mutation generates an oligosaccharide attachment site, Asn-Cys-Thr at residues 63-65, that is glycosylated. Immunoprecipitation experiments with extracts from variant virus-infected cells prepared in the presence or absence of tunicamycin, which inhibits glycosylation, demonstrate that addition of the new oligosaccharide side chain is required to prevent reaction with the monoclonal antibody. Similar experiments with the virus of the 1969 Hong Kong influenza epidemic, A/England/878/69, which also contains a hemagglutinin glycosylated at residue 63, support this conclusion and provide evidence for the epidemiological significance of carbohydrate-mediated modifications of hemagglutinin antigenicity.