Conservation and variation in the hemagglutinins of Hong Kong subtype influenza viruses during antigenic drift

The alphaviruses: gene expression, replication, and evolution

The alphaviruses are a genus of 26 enveloped viruses that cause disease in humans and domestic animals. Mosquitoes or other hematophagous arthropods serve as vectors for these viruses. The complete sequences of the +/- 11.7-kb plus-strand RNA genomes of eight alphaviruses have been determined, and partial sequences are known for several others; this has made possible evolutionary comparisons between different alphaviruses as well as comparisons of this group of viruses with other animal and plant viruses. Full-length cDNA clones from which infectious RNA can be recovered have been constructed for four alphaviruses; these clones have facilitated many molecular genetic studies as well as the development of these viruses as expression vectors. From these and studies involving biochemical approaches, many details of the replication cycle of the alphaviruses are known. The interactions of the viruses with host cells and host organisms have been exclusively studied, and the molecular basis of virulence and recovery from viral infection have been addressed in a large number of recent papers. The structure of the viruses has been determined to about 2.5 nm, making them the best-characterized enveloped virus to date. Because of the wealth of data that has appeared, these viruses represent a well-characterized system that tell us much about the evolution of RNA viruses, their replication, and their interactions with their hosts. This review summarizes our current knowledge of this group of viruses.

The alphaviruses: gene expression, replication, and evolution

The alphaviruses are a genus of 26 enveloped viruses that cause disease in humans and domestic animals. Mosquitoes or other hematophagous arthropods serve as vectors for these viruses. The complete sequences of the +/- 11.7-kb plus-strand RNA genomes of eight alphaviruses have been determined, and partial sequences are known for several others; this has made possible evolutionary comparisons between different alphaviruses as well as comparisons of this group of viruses with other animal and plant viruses. Full-length cDNA clones from which infectious RNA can be recovered have been constructed for four alphaviruses; these clones have facilitated many molecular genetic studies as well as the development of these viruses as expression vectors. From these and studies involving biochemical approaches, many details of the replication cycle of the alphaviruses are known. The interactions of the viruses with host cells and host organisms have been exclusively studied, and the molecular basis of virulence and recovery from viral infection have been addressed in a large number of recent papers. The structure of the viruses has been determined to about 2.5 nm, making them the best-characterized enveloped virus to date. Because of the wealth of data that has appeared, these viruses represent a well-characterized system that tell us much about the evolution of RNA viruses, their replication, and their interactions with their hosts. This review summarizes our current knowledge of this group of viruses.

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.

Evolutionary pattern of the H 3 haemagglutinin of equine influenza viruses: multiple evolutionary lineages and frozen replication

The nucleotide and deduced amino acid sequences of the haemagglutinin genes coding for the HA 1 domain of H3N8 equine influenza viruses isolated over wide regions of the world were analyzed in detail to determine their evolutionary relationships. We have constructed a phylogenetic model tree by the neighbour-joining method using nucleotide sequences of 15 haemagglutinin genes, including those of five viruses determined in the present study. This gene tree revealed the existence of two major evolutionary pathways during a twenty five-year period between 1963 to 1988, and each pathway appeared to consist of two distinct lineages of haemagglutinin genes. Furthermore, our analysis of nucleotide sequences showed that two distinct lineages of equine H3N8 viruses were involved in an equine influenza outbreak during the period of December 1971-January 1972 in Japan. The number of nucleotide changes between strains was proportional to the length of time (in years) between their isolation except for three of the HA genes. However, there are three exceptional strains isolated in 1971, 1987, and 1988, respectively. The haemagglutinin gene in these strains showed a small number of nucleotide substitutions after they branched off around 1963, suggesting an example of frozen replication. Although the estimated rate (0.0094/site/year) of synonymous (silent) substitutions of the haemagglutinin gene of equine H3N8 viruses was nearly the same as that of human H 1 and H 3 haemagglutinin genes, the rate of nonsynonymous (amino-acid changing) substitutions of the former equine virus gene was estimated to be 0.00041/site/year--that is about 5 times lower than that estimated for the human H 3 haemagglutinin gene. The present study is the first demonstration that multiple evolutionary lineages of equine H3N8 influenza virus circulated since 1963.

Evolution of the H3 influenza virus hemagglutinin from human and nonhuman hosts

The nucleotide and amino acid sequences of 40 influenza virus hemagglutinin genes of the H3 serotype from mammalian and avian species and 9 genes of the H4 serotype were compared, and their evolutionary relationships were evaluated. From these relationships, the differences in the mutational characteristics of the viral hemagglutinin in different hosts were examined and the RNA sequence changes that occurred during the generation of the progenitor of the 1968 human pandemic strain were examined. Three major lineages were defined: one containing only equine virus isolates; one containing only avian virus isolates; and one containing avian, swine, and human virus isolates. The human pandemic strain of 1968 was derived from an avian virus most similar to those isolated from ducks in Asia, and the transfer of this virus to humans probably occurred in 1965. Since then, the human viruses have diverged from this progenitor, with the accumulation of approximately 7.9 nucleotide and 3.4 amino acid substitutions per year. Reconstruction of the sequence of the hypothetical ancestral strain at the avian-human transition indicated that only 6 amino acids in the mature hemagglutinin molecule were changed during the transition between an avian virus strain and a human pandemic strain. All of these changes are located in regions of the molecule known to affect receptor binding and antigenicity. Unlike the human H3 influenza virus strains, the equine virus isolates have no close relatives in other species and appear to have diverged from the avian viruses much earlier than did the human virus strains. Mutations were estimated to have accumulated in the equine virus lineage at approximately 3.1 nucleotides and 0.8 amino acids per year. Four swine virus isolates in the analysis each appeared to have been introduced into pigs independently, with two derived from human viruses and two from avian viruses. A comparison of the coding and noncoding mutations in the mammalian and avian lineages showed a significantly lower ratio of coding to total nucleotide changes in the avian viruses. Additionally, the avian virus lineages of both the H3 and H4 serotypes, but not the mammalian virus lineages, showed significantly greater conservation of amino acid sequence in the internal branches of the phylogenetic tree than in the terminal branches. The small number of amino acid differences between the avian viruses and the progenitor of the 1968 pandemic strain and the great phenotypic stability of the avian viruses suggest that strains similar to the progenitor strain will continue to circulate in birds and will be available for reintroduction into humans.

Sequence and crystallization of influenza virus B/Beijing/1/87 neuraminidase

Influenza B/Beijing/1/87 neuraminidase heads were isolated from virus via trypsin digestion and characterized by PAGE, N-terminal sequencing, electron microscopy, and enzyme activity. The heads were crystallized into two crystal forms; tetragonal plates, like other neuraminidase crystals described before, that diffract to medium resolution (3 A) and a new form consisting of trigonal prisms or needles that diffract to high resolution (at least 2 A). The gene segment coding for neuraminidase was sequenced and compared with the neuraminidase sequence of B/Lee/40. The deduced amino acid sequences for neuraminidase showed only a 7% difference, whereas those for the NB proteins differed by 20%.

Phenotypic hiding: the carryover of mutations in RNA viruses as shown by detection of mar mutants in influenza virus

When influenza virus monoclonal antibody-resistant (mar) mutants are selected by incubation in vitro with excess antibody, 90 to 99% of the mutants are not detectable. This observation may be explained by encapsidation of mar mutant RNAs within phenotypically wild-type envelopes. This phenotypic hiding can be revealed by selection of mar mutants in vivo after virus uncoating. Using experimental procedures appropriate to detect all viable mar mutants in a virus population, we determined precisely the mutation rates to the mar genotype by the fluctuation test for two nonoverlapping monoclonal antibodies.

Immune recognition of influenza virus haemagglutinin

Haemagglutinin glycoproteins are the components of influenza virus membranes against which infectivity-neutralizing antibodies are directed. Sequence analysis of natural and laboratory-selected variant haemagglutinins indicates the regions of the molecule recognized by antibodies and by helper T cells; the identity of these regions and the relations between them are discussed.

Sequence analysis of the hemagglutinin of B/Ann Arbor/1/86, an epidemiologically significant variant of influenza B virus

Influenza B/Ann Arbor/1/86 is representative of antigenic variants responsible for the most important influenza epidemics during the 1985/1986 season. The nucleotide sequence of the hemagglutinin HA1 region and the deduced amino acid sequence are presented. Compared to the previous winter's vaccine strain B/USSR/100/83, B/AA/1/86 possesses 18 amino acid substitutions and 2 amino acid insertions, 50% of which are distributed within the vicinity of the reported single immunodominant antigenic site.

Nucleotide sequence of the fusion and phosphoprotein genes of human respiratory syncytial (RS) virus Long strain: evidence of subtype genetic heterogeneity

The nucleotide and deduced amino acid sequences of the fusion (F) and phosphoprotein (P) genes of the Long strain of human respiratory syncytial (RS) virus have been determined from cDNA copies cloned into pBSV9 shuttle vector. Comparison of these sequences with their counterparts of other strains reveals genetic heterogeneity within the same subtype. The percentage of nucleotide and amino acid changes occurring in both proteins is similar. Thus, the Long F and P proteins share 97.9% and 98.3% amino acid identity, respectively, with their homologs of the A2 strain. Nevertheless the F2 subunit of the fusion protein accumulates 3.1 times more amino acid changes than the F1 subunit. In addition, the percentage of nucleotide changes in the 3' extracistronic sequences is 6 times higher in the P than in the F gene. These results are discussed in terms of selective pressures operating in the evolution of RS virus in nature.

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.

Origin of the hemagglutinin gene of H3N2 influenza viruses from pigs in China

Influenza viruses of the H3N2 subtype similar to Aichi/2/68 and Victoria/3/75 persist in pigs many years after their antigenic counterparts have disappeared from humans (Shortridge et al. (1977). Science 19, 1454-1455). To provide information on the mechanism of conservation of these influenza viruses in pigs, the hemagglutinin (HA) of four isolates from swine derived from Taiwan and Southern China were analyzed antigenically and genetically. The reactivity pattern of these viruses with a panel of monoclonal antibodies indicates that the HAs of these swine viruses were antigenically closely related to duck H3 and early human H3 viruses. Sequence analysis of the H3 genes from three swine viruses revealed that the swine H3 genes are more closely related to the duck genes than to early human H3 virus (A/Aichi/2/68). The degree of sequence homology of these genes is extremely high (more than 96.5%). Furthermore, the deduced amino acid sequence of the three swine HAs at residues 226 to 228 in the proposed receptor-binding site is Gln-Ser-Gly and is common with the majority of avian influenza viruses. These findings indicate that these H3 viruses may have been introduced into pigs from ducks. The HA gene of the fourth swine influenza virus from Southern China was genetically equally related to avian and early human H3 strains although the sequence through the receptor-binding pocket (226-228) was typical of a human H3 virus, suggesting that either this swine HA gene was derived from ducks or an early human H3 virus was introduced into the pig population where the virus accumulated substantial mutations. The present strains revealed genetic heterogeneity of swine H3 influenza viruses in nature.

Anti-peptide antibodies detect steps in a protein conformational change: low-pH activation of the influenza virus hemagglutinin

At low pH, the hemagglutinin (HA) of influenza virus undergoes an irreversible conformational change that potentiates its essential membrane fusion function. We have probed the details of this conformational change using a panel of 14 anti-HA-peptide antibodies. Whereas some antibodies reacted equally well with both the neutral and low-pH HA conformations, others reacted to a significantly greater extent with the low-pH form. The locations of the peptides recognized by the latter antibodies in the three-dimensional HA structure indicated regions of the protein that change in response to low pH. Moreover, kinetic experiments suggested steps in the conformational change. In addition to their relevance to membrane fusion, our results show that anti-peptide antibodies can be used to study some types of biologically important protein conformational changes.

Antigenic and genetic conservation of H3 influenza virus in wild ducks

The hemagglutinins of H3 influenza viruses isolated from migratory ducks on the Pacific flyway in Japan during the period 1977 to 1985 were analyzed antigenically and genetically. Antigenic analysis using monoclonal antibodies to the hemagglutinins of A/Aichi/2/68 (H3N2) and A/duck/Hokkaido/8/80 (H3N8) viruses showed that antigenic drift occurred extensively in human strains, whereas the hemagglutinins of duck viruses were highly conserved. It was also found that the hemagglutinins of duck viruses were antigenically closely related to that of human 1968 H3 prototype strains. Nucleotide sequence analysis of seven duck H3 hemagglutinin genes showed a limited number of changes among the six duck isolates and between these duck isolates and Aichi/68. The deduced amino acid sequence revealed amino acid changes randomly distributed throughout the molecule and not confined to antigenic sites. These findings indicate that the duck virus hemagglutinin genes are conserved in nature and that viruses of different lineages cocirculate.

A single amino acid substitution in influenza hemagglutinin abrogates recognition by monoclonal antibody and a spectrum of subtype-specific L3T4+ T cell clones

A fine specificity analysis of influenza hemagglutinin-specific IAk-restricted T cell clones using natural virus variants of the H3N2 subtype, monoclonal antibody-selected variants and a synthetic peptide corresponding to a variable region of the HA1 polypeptide has provided insight on the structural basis for T cell recognition. A glycine to arginine substitution at HA1 135 abrogates recognition by a panel of T cell clones which, according to their reactivity for natural virus variants, have different antigenic specificities: three clones recognize a synthetic peptide (HA1 residues 118-138) but fail to recognize the monoclonal antibody-selected mutant (Gly135/Arg). There is no correlation, however, between differences in T cell specificity for the natural virus variants and HA1 amino acid sequences in this region. Two further clones have a reduced proliferative response to mutant recognize a completely different spectrum of natural variants, and only one of these clones recognizes the synthetic peptide. We speculate that influenza hemagglutinin employs a common strategy during antigenic drift to evade antibody recognition and effective processing/presentation to subtype-specific T cell clones.

Comparison of the structural organizations in the 3'-terminal regions of five avian retrovirus strains: RAV 7, RAV 50, B77, PR-B, and SR-B

In order to obtain information on the phylogenies of viral strains which belong to RSV (Rous sarcoma virus) and ALV (avian leukosis virus), the nucleotide sequences of noncoding regions adjacent to the U3 region in two ALV strains, Rous-associated virus 7 (RAV 7) and RAV 50, and three RSV strains, Bratislava 77 (B77), Prague:subgroup B (PR-B), and Schmidt-Ruppin:subgroup B (SR-B) were determined by extension from a common primer. The sequences thus deduced were compared with known sequences of other RSV and ALV strains and the structural features of the newly determined viral genomes were discussed.

Nucleotide sequence analysis of the nucleoprotein gene of an avian and a human influenza virus strain identifies two classes of nucleoproteins

The nucleotide sequences of RNA segment 5 of an avian influenza A virus, A/Mallard/NY/6750/78 (H2N2), and a human influenza A virus, A/Udorn/307/72 (H3N2), were determined and the deduced amino acid sequences of the nucleoprotein (NP) of these viruses were compared to two other avian and two other human influenza A NP sequences. The results indicated that there are separate classes of avian and human influenza A NP genes that can be distinguished on the basis of sites containing amino acids specific for avian and human influenza viruses and also by amino acid composition. The human influenza A virus NP genes appear to follow a linear pathway of evolution with the greatest homology (96.9%) between A/NT/60/68 (H3N2) and A/Udorn/72, isolated only 4 years apart, and the least homology (91.1%) between A/PR/8/34 (H1N1) and A/Udorn/72, isolated 38 years apart. Furthermore, 84% of the nucleotide substitutions between A/PR/8/34 and A/NT/60/68 are preserved in the NP gene of the A/Udorn/72 strain. In contrast, a distinct linear pathway is not present in the avian influenza NP genes since the homology (90.3%) between the two avian influenza viruses A/Parrot/Ulster/73 (H7N1) and A/Mallard/78 isolated only 5 years apart is not significantly greater than the homology (90.1%) between strains A/FPV/Rostock/34 and A/Mallard/78 isolated 44 years apart and only 49% of the nucleotide substitutions between A/FPV/34 and A/Parrot/73 are found in A/Mallard/78. A determination of the rate of evolution of the human influenza A virus NP genes suggested that there were a greater number of nucleotide substitutions per year during the first several years immediately following the emergence of a new subtype in 1968.

Antigenic relationships between avian paramyxoviruses. I. Quantitative characteristics based on hemagglutination and neuraminidase inhibition tests

Comprehensive hemagglutination inhibition (HI) and neuraminidase inhibition (NI) cross reaction tests were performed using 8 of 9 serotypes of avian paramyxoviruses (PMV). The studies were designed as full scale repeating experiments which permitted an adequate statistical treatment and elaboration of quantitative criteria of antigenic kinship. The results have shown diverse antigenic relationships between different avian paramyxovirus (PMV) serotypes which were asymmetric in some cases. The antigenic relationships found by HI test did not always parallel those found by NI tests. The antigenic inter-relationships have been displayed quantitatively in a diagram. This has given a basis for some suggestions concerning: the independent antigenic drift of the HA and Nase antigenic sites of hemagglutinin-neuraminidase (HN) glycoprotein of avian PMVs; a tentative subdivision of the whole group of avian PMVs into two subgroups: the first including PMV-2 and PMV-6 serotypes and the second including PMV-1, PMV-3, PMV-4, PMV-7, PMV-8 and PMV-9 serotypes; the conception that genomic material coding for the HN glycoprotein consists of a "common-to-all-the-PMVs" portion and a "serotype-specific" portion, on one hand, and of a "conserved" portion and a "variable" portion, on the other; the ratios between the portions have been shown to be different for, at least, certain PMV serotypes; the evolutionary pathways of the avain PMV HN antigenic drift.

Noncumulative sequence changes in the hemagglutinin genes of influenza C virus isolates

Sequence analysis and comparison of hemagglutinin (HA) genes of different influenza C viruses isolated between 1947 and 1983 reveals that (1) the extent of difference among the HA genes is independent of the year in which these viruses were isolated and that (2) changes in the HA genes do not appear to accumulate with time. These results suggest that epidemiologically dominant variants of influenza C viruses do not emerge successively with time and that C virus variants derived from multiple evolutionary pathways cocirculate at any one time. Thus the epidemiology of influenza C viruses differs markedly from that of influenza A viruses, which is characterized by the emergence of successive variants. Based on the nucleotide sequence data, we propose different evolutionary models for influenza A and influenza C viruses.

Rabies virulence: effect on pathogenicity and sequence characterization of rabies virus mutations affecting antigenic site III of the glycoprotein

Using four neutralizing monoclonal antibodies which presumably bind to the same antigenic site on the CVS glycoprotein (antigenic site III as defined by cross-neutralization tests), we isolated 58 mutants of the CVS strain of rabies virus. These mutants were highly resistant to the selecting antibodies and grew efficiently in cell cultures. We classified them into five groups on the basis of the pattern of resistance to the four antibodies. We determined pathogenicities of the mutants for adult mice by intracerebral inoculation. Group 2 mutants were nonpathogenic or had attenuated pathogenicity. On the contrary, mutants from the other groups were pathogenic, causing paralysis and death as does CVS. We determined the nucleotide alterations of representative mutants from each group by using the dideoxy method of RNA sequencing. In the glycoproteins of eight nonpathogenic or attenuated mutants, we identified an amino acid substitution at position 333. Arginine 333 was replaced by either glutamine or glycine. In the glycoprotein of eight pathogenic mutants, we identified an amino acid substitution at lysine 330, asparagine 336, or isoleucine 338. Thus, although all substitutions affected neutralization and were located close to each other in the glycoprotein sequence, only substitutions at position 333 affected pathogenicity.

Heterogeneity among influenza H3N2 isolates recovered during an outbreak. Brief report

Isolates of the H3N2 subtype recovered during an outbreak have been analyzed at the genomic and protein level. No reassortant genomes were detected. By T1-oligonucleotide fingerprinting of RNA segments coding for hemagglutinin (HA), nucleoprotein (NP), and neuraminidase (NA) two genotypes were found.

Immunochemistry of variants of influenza virus hemagglutinin and neuraminidase

Influenza is impossible to control by vaccination because of variation in the two surface antigens of the virus, the hemagglutinin (HA) and neuraminidase (NA). This variation is caused by sequence changes in the genes coding these antigens and this article summarizes recent information on the structure of the HA and NA, the way in which these glycoproteins vary and the effects of the changes on the antigenic properties of the virus.

Antigenic structure of the hemagglutinin of influenza virus B/Hong Kong/8/73 as determined from gene sequence analysis of variants selected with monoclonal antibodies

Antigenic variation among influenza B viruses is different from that of influenza A in several ways. Antigenic shift has not been observed, distinct antigenic variants of influenza B cocirculate, and antigenically similar viruses have been isolated many years apart. To study the mechanism of antigenic drift in influenza B viruses, monoclonal antibodies were used to select antigenic variants of B/Hong Kong/8/73 virus hemagglutinin (HA). Analyses of the nucleotide sequences of the HA gene of B/Hong Kong/8/73 and the eight variants identified specific regions of the influenza B HA molecule involved in antigenicity, and enabled antigenic mapping data to be correlated with the structure of the protein. The altered amino acids in the variants, when compared to the HA of A/Aichi/2/68, were found in two of the four antigenic regions previously identified for type A viruses. In addition, four of the eight variants showed multiple nucleotide changes some of which gave rise to double amino acid changes. In addition, in the present study monoclonal antibodies which belong to the same antigenic group recognize amino acid changes in regions corresponding to antigenic sites A and B of the H3 HA. These results are in contrast to those obtained with HA variants of A/Memphis/1/71 virus. In the influenza A studies only single amino acid changes were found and these correlated well with the three-dimensional structure as determined by D. C. Wiley, I. A. Wilson, and J. J. Skehel, (1981, Nature (London) 289, 366-373); monoclonal antibodies which recognized one region did not recognize any of the other antigenic sites. Our results suggest that although the basic three-dimensional structure of the influenza B HA may be similar to that of A viruses, the B HA molecule may be folded in a more compact manner so that antigenic sites A and B are in closer proximity to each other than in the H3 structure.

Antigenic structure of the influenza B virus hemagglutinin: nucleotide sequence analysis of antigenic variants selected with monoclonal antibodies

We report here the complete nucleotide sequence of the hemagglutinin (HA) gene of influenza B virus B/Oregon/5/80 and, through comparative sequence analysis, identify amino acid substitutions in the HA1 polypeptide responsible for the antigenic alterations in laboratory-selected antigenic variants of this virus. The complete nucleotide sequence of the B/Oregon/5/80 HA gene was established by a combination of chemical sequencing of a full-length cDNA clone and dideoxy sequencing of the virion RNA. The nucleotide sequence is very similar to previously reported influenza B virus HA gene sequences and differs at only nine nucleotide positions from the B/Singapore/222/79 HA gene (Verhoeyen et al., Nucleic Acids Res. 11:4703-4712, 1983). The nucleotide sequences of the HA1 portions of the HA genes of 18 laboratory-selected antigenic variants were determined by the dideoxy method. Comparison of the deduced amino acid sequences of the parental and variant HA1 polypeptides revealed 16 different amino acid substitutions at nine positions. All amino acid substitutions resulted from single-point mutations, and no double mutants were detected, demonstrating that as in the influenza A viruses, single amino acid substitutions are sufficient to alter the antigenicity of the HA molecule. Many of the amino acid substitutions in the variants occurred at positions also observed to change in natural drift strains. The substitutions appear to identify at least two immunodominant regions which correspond to proposed antigenic sites A and B on the influenza A virus H3 HA.

Is virulence of H5N2 influenza viruses in chickens associated with loss of carbohydrate from the hemagglutinin?

The A/Chick/Penn/83 (H5N2) influenza virus that appeared in chickens in Pennsylvania in April 1983 and subsequently became virulent in October 1983, was examined for plaque-forming ability and cleavability of the hemagglutinin (HA) molecule. The avirulent virus produced plaques and cleaved the HA only in the presence of trypsin. In contrast, the virulent virus produced plaques and cleaved the HA precursor into HA1 and HA2 in the presence or absence of trypsin. The apparent molecular weight of the HA1 from the avirulent virus was higher than that from the virulent virus, but when the viruses were grown in the presence of tunicamycin, the molecular weights of HA were indistinguishable. Two of nine monoclonal antibodies to the HA of the avirulent virus indicate that there is at least one epitope on the HA that is different between the virulent and avirulent viruses. The amino acid sequences of the HAs from the two viruses were compared by sequencing their respective HA gene. The nucleotide sequence coding for the processed HA polypeptide contained 1641 nucleotides specifying a protein of 547 amino acids. The amino acid sequences of the virulent and avirulent viruses were indistinguishable through the connecting peptide region, indicating that the difference in cleavability of the H5 HA is not directly attributed to the amino acid sequence of the connecting peptide. Four of seven nucleotide changes resulted in amino acid changes at residues 13, 69, and 123 of HA1 and at residue 501 of the HA2 polypeptide. Since there were no deletions or insertions in the amino acid sequence of the virulent or avirulent viruses, the possibility exists that the difference in molecular weight is due to loss of a carbohydrate side chain in the virulent strain. The amino acid change in the virulent strain at residue 13 is the only mutation that could affect a glycosylation site and this is in the vicinity of the connecting peptide. It is postulated that the loss of this carbohydrate may permit access of an enzyme that recognizes the basic amino acid sequences and results in cleavage activation of the HA in the virulent virus.

Utilization of sequence libraries on a 16-bit mini computer with particular reference to high speed searching

An interactive menu driven system of programmes written in Fortran and designed to utilize the three main nucleotide sequence libraries and one amino acid sequence library was developed to run on a small 16-bit mini computer with limited main memory and mass storage. The software uses a minimum of system function calls and should be transportable with minimal rewriting to micro computers. Software has also been written to create secondary data bases containing the nucleotide triplet values (4(3) classes) derived from the sequence libraries. Using this secondary set, a given sequence and its reversed complement, once reduced to their trinucleotide values, can be compared to all sequences present in the libraries in about forty minutes on a PDP 11/10 mini computer using the correlation statistic. Because the statistic in this case may not be assumed to be normally distributed, we have termed it a quasi correlation coefficient (Qr).

Influenza B virus genome: complete nucleotide sequence of the influenza B/lee/40 virus genome RNA segment 5 encoding the nucleoprotein and comparison with the B/Singapore/222/79 nucleoprotein

The complete nucleotide sequence of a cloned full-length DNA copy of genome RNA segment 5 of influenza B/Lee/40 virus has been determined. The genome segment is 1841 nucleotides in length and is capable of coding for a nucleoprotein (NP) of 560 amino acids. Comparison with the only other known sequence of an influenza B virus nucleoprotein gene (B/Singapore/222/79) indicates striking homology. Only 113 nucleotide substitutions are present between the two strains in their protein coding region and these lead to only 22 amino acid substitutions between nucleoproteins of identical polypeptide chain length. Assuming a common lineage, this reflects a calculated rate of amino acid sequence divergence of 0.1% per year. Like its influenza A virus counterpart, the influenza B/Lee/40 nucleoprotein is a basic protein with a relatively even distribution of its charged residues. The remarkable conservation of nucleoprotein primary structure over a 39-year period probably reflects both selection for performance of specific functions and protection from antigenic selection by the host immune system.

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.

Construction and characterization of an infectious vaccinia virus recombinant that expresses the influenza hemagglutinin gene and induces resistance to influenza virus infection in hamsters

A DNA copy of the influenza virus hemagglutinin gene, derived from influenza virus A/Jap/305/57 (H2N2) was inserted into the genome of vaccinia virus under the control of an early vaccinia virus promoter. Tissue culture cells infected with the purified recombinant virus synthesized influenza hemagglutinin, which was glycosylated and transported to the cell surface where it could be cleaved with trypsin into HA1 and HA2 subunits. Rabbits and hamsters inoculated intradermally with recombinant virus produced circulating antibodies that inhibited hemagglutination by influenza virus. Furthermore, vaccinated hamsters achieved levels of antibody similar to those obtained upon primary infection with influenza virus and were protected against respiratory infection with the A/Jap/305/57 influenza virus.

Electron microscopy of influenza haemagglutinin-monoclonal antibody complexes

The molecular locations of antibody binding sites on the haemagglutinin of influenza virus X-31 were investigated by electron microscopy of haemagglutinin-monoclonal antibody complexes. Evidence was obtained for different sites of binding of different antibodies and direct correspondence was observed between these sites and the locations of antigenic sites A, B, and E (D. C. Wiley, I. A. Wilson, and J. J. Skehel (1981). Nature (London) 289, 373-378) defined by determining the amino acids recognized by the specific antibodies.

Hemagglutinin of swine influenza virus: a single amino acid change pleiotropically affects viral antigenicity and replication

The complete nucleotide sequence has been obtained of the H1 hemagglutinin (HA) gene of a high-yielding (H) mutant of the A/NJ/11/76(H1N1) strain of swine influenza virus in studies of a viral reassortant (X-53a) bearing this gene. This determination has permitted comparison with human influenza H1N1 prototype viruses A/WSN/33 and A/PR/8/34, with which 80% and 94% amino acid homology was found between HA1 and HA2, respectively. Partial sequences have been determined for other viral reassortants containing either H or L (low-yielding phenotype) genes derived from A/NJ/11/76. Sequence of the HA1 region of an L mutant prototype was virtually completed and differed from that of the H mutant by only four amino acid changes. Sequence analysis of four other viruses was restricted to regions of the HA with which monoclonal antibodies capable of distinguishing L and H mutants are presumed to react. Therefore, changes in these sequences are relevant to changes in viral phenotype. Change at residue 155 from Gly to Glu is associated with change from L to H HA phenotype. This site, structurally equivalent to amino acid 158 on the Wiley et al. HA model [Wiley, D. C., Wilson, I. A. & Skehel, J. J. (1981) Nature (London) 289, 373-378] is near the tip of the HA monomer adjacent to the proposed receptor binding site and therefore credibly could influence both viral antigenicity and replication. Because both L and H variants exist in nature and because revertants may be selected in the laboratory as replication variants in the absence of immunoselection, these studies provide evidence for fortuitous antigenic change in association with change in biological function, which is determined by a single base change.

Evolution of the influenza virus neuraminidase gene during drift of the N2 subtype

The complete genetic information for the neuraminidase (NA) gene of influenza virus A/Bangkok/1/79 has been cloned by in vitro synthesis of dsDNA, insertion into pBR322 plasmid, and transformation of Escherichia coli. The nucleotide sequence of the NA gene has been determined by the Maxam and Gilbert method. It is 1466 nucleotides long and contains a single open reading frame with a coding capacity for 469 amino acids. When compared to the NA genes of the N2 strains A/Victoria/3/75, A/Udorn/72, A/NT/60/68, and A/RI/5-/57, 90% of the nucleotide positions and 87% of the amino acid positions remained invariant. Forty-two nucleotide changes and 14 amino acid changes accumulated in the period 1975-1979, but the general structure of the protein appeared to remain constant.

Assessment of secondary-structure prediction of proteins. Comparison of computerized Chou-Fasman method with others

A method predicting protein secondary structure from sequence information could be assessed for its real efficiency by applying it to a number of proteins which lie completely outside a given data set. This type of test is performed for the three methods of Chou and Fasman (Adv. Enzymol. 47 (1978) 45-148), Robson and co-workers (J. Mol. Biol. 120 (1978) 97-120) and Lim (J. Mol. Biol. 88 (1974) 873-894) by using data of 19 proteins for the former two methods and 11 proteins for the method of Lim. The prediction abilities of these methods turn out to be of almost the same level, but unexpectedly low: their average scores are commonly less than 55% measured by the three-state assessment (alpha, beta and coil) or less than 45% measured by the four-state assessment (alpha, beta, turn and coil). This level of accuracy is more than 20% lower than that of current expectations as summarized by Schulz and Schirmer (Principles of Protein Structure (1979) Ch. 6, Springer, New York). A joint prediction attempted with the simultaneous usage of the three prediction methods did not improve the results. Causes and implications of the unsatisfactory results are discussed. In this study, computer programs were prepared for the methods of Chou and Fasman and of Robson and co-workers. While difficulties arose in the course of the computerization of the Chou-Fasman method, the prediction algorithm was arranged in a fully automatic form with optimization of the original rules as well as introduction of a modified treatment for solving the overlap among initially predicted regions of the secondary structures. Large discrepancies observed between the original results and those obtained by the computerized method are examined.

Antigenicity and evolution amongst recent influenza viruses of H1N1 subtype

The sequence of the HA1 subunit region of the haemagglutinin gene of influenza A/USSR/90/77, and A/Brazil/11/78, A/Lackland/3/78, A/England/333/80 and A/India/6263/80 was determined by dideoxy-sequencing methods using total virion RNA and specific oligonucleotide primers for reverse transcriptase. These 1977-1980 strains share a minimum of 85% amino acid sequence homology with influenza A/PR/8/34. Most of the surface amino acid substitutions which occurred during the evolution of A/PR/8/34 to A/USSR/90/77 and subsequently in the 1978-1980 strains are located in the 4 antigenic sites previously defined by an analysis of laboratory-selected mutants of A/PR/8/34. We deduce an evolutionary pathway for the 1977-80 strains and suggest their different epidemic properties may be a consequence of only a few amino acid changes.

Antigenic drift in influenza virus H3 hemagglutinin from 1968 to 1980: multiple evolutionary pathways and sequential amino acid changes at key antigenic sites

Surveys of the antigenic properties of a wide range of variants of the H3N2 (Hong Kong) influenza virus subtype have revealed complex patterns of variants cocirculating during each of the main epidemic eras of the subtype. We determined hemagglutinin (HA) gene sequences for 14 isolates chosen to give the wildest possible spread of variant types. The addition of these data to existing HA gene sequence information for other variants provides a comprehensive picture of HA gene evolution during antigenic drift among H3N2 subtype viruses. The data reveal the existence of multiple evolutionary pathways during at least one period of development of the subtype and strikingly demonstrate that amino acid changes are limited to a small number of locations on the HA molecule during antigenic drift. The occurrence of sequential amino acid changes at key positions within these variable regions suggests that the HA structure has remained constant during subtype evolution so that only limited possibilities remain for further antigenic drift among H3N2 viruses.

Sequence of the hemagglutinin gene from influenza virus A/Seal/Mass/1/80

A double-strand DNA copy of the influenza virus A/Seal/Mass/1/80 (H7N7) [seal] hemagglutinin (HA) gene was cloned into the plasmid pAT153/PvuII/8 and sequenced to deduce the primary amino acid sequence. The gene is 1731 nucleotides long and codes for a protein of 560 amino acids with a nonglycosylated molecular weight of 62098 Da. The deduced amino acid sequence displays similarities to all other sequenced hemagglutinins by retaining six of seven potential glycosylation sites, showing conversation in the number and position of cysteine residues, conservation in the fusion and anchor peptides, and conservation in the putative receptor site of the molecule. However, three features of the primary amino acid sequence could be distinguished from the H7 amino acid sequence of A/fowl plague/Rostock/34 (FPV), another avian H7 influenza virus which does not produce disease in mammals. First, the seal HA sequence has three fewer amino acids in the connecting peptide region of the HA than FPV. This lack of multiple basic amino acids in the connecting peptide is similar to that found in avirulent H7 avian strains and to mammalian serotypes H1, H2, and H3. Second, the seal HA has gained four additional proline residues, all in HA1, as compared to FPV. These residues may alter the tertiary structure of the HA and ultimately contribute to the biological features of this virus. Third, the seal HA has lost a potential carbohydrate attachment site at residue 149 which lies at the tip of the HA structure. The loss of this carbohydrate could alter the seal HAs interaction with host cell receptors.

Evolution of the nucleotide sequence of influenza virus RNA segment 7 during drift of the H3N2 subtype

The complete genetic information contained in the influenza virus RNA segment 7 of the A/Bangkok/1/79 (H3N2) strain has been cloned by in vitro synthesis of the complementary dsDNA and its insertion into plasmid pBR322. The nucleotide sequence of the viral RNA segment has been determined from the cDNA insert. It is 1027 nucleotides long, and contains two open reading frames, as shown for other influenza virus strains. When compared with the previously published sequence for the A/Udorn/72 (H3N2) strain, 15 nucleotide exchanges are observed, most of them silent mutations, and only two causing amino acid changes in each of the M1 and M2 protein sequences.

Complete nucleotide sequence of the influenza B/Singapore/222/79 virus hemagglutinin gene and comparison with the B/Lee/40 hemagglutinin

The complete nucleotide sequence of the hemagglutinin (HA) gene of the human type B influenza virus B/Singapore/222/79 is presented. Comparison with the only other known sequence of a B hemagglutinin (B/Lee/40) shows that antigenic drift in type B HA genes is essentially the same as already observed within the influenza A H3 subtype, i.e., an accumulation of point mutations. The main difference is that the apparent evolution is significantly slower, most likely due to the cumulative effect of a lower occurrence in the population (slower evolution) and/or less immunological pressure. There is a striking cluster of changes at positions 127 until 137 of the HA1 subunit which may represent one of the antigenic sites of the molecule.

Single amino acid substitutions in influenza haemagglutinin change receptor binding specificity

The haemagglutinin (HA) glycoproteins of influenza virus membranes are responsible for binding viruses to cells by interacting with membrane receptor molecules which contain sialic acid (for review see ref. 1). This interaction is known to vary in detailed specificity for different influenza viruses (see, for example, refs 2-4) and we have attempted to identify the sialic acid binding site of the haemagglutinin by comparing the amino acid sequences of haemagglutinins with different binding specificities. We present here evidence that haemagglutinins which differ in recognizing either NeuAc alpha 2 leads to 3Gal- or NeuAc alpha 2 leads to 6Gal- linkages in glycoproteins also differ at amino acid 226 of HA1. This residue is located in a pocket on the distal tip of the molecule, an area previously proposed from considerations of the three-dimensional structure of the haemagglutinin to be involved in receptor binding.

Sequential mutations in hemagglutinins of influenza B virus isolates: definition of antigenic domains

Comparative analysis of the amino acid sequences of hemagglutinins (HAs) of influenza B/Lee/40, B/Md/59, and B/HK/73 viruses has allowed examination of the molecular basis of antigenic variation in type B viruses. As seen with influenza type A viruses, antigenic drift in influenza B viruses proceeds mostly through the accumulation of amino acid substitutions within the HA1 portion of the HA molecule. However, the rate of variation observed among the influenza B virus HAs appears to be significantly lower than the observed rate of variation among influenza A virus HAs. The overall rate of amino acid change in the HA1s of the influenza B viruses studied is 2% per 10 years, whereas the HA1s of H3 influenza A viruses vary by 9.2% per 10 years. The sequences of the influenza B HAs were also examined in relation to the three-dimensional model for the A/Aichi/2/68 HA. When the primary amino acid sequences are compared, it appears that most of the important structural features of the type A HAs--such as the sialic acid binding site, the disulfide linkages, and the stem structure of the trimer--are conserved in the influenza B virus HAs. Regions are also identified where extensive amino acid substitutions have occurred among the three antigenically distinct influenza B virus HAs. The locations of these areas in the B HA structure correspond to antigenic regions proposed for the A virus HAs. In addition, modulation of antigenic regions in B virus HAs may also occur through amino acid deletions and variation in glycosylation sites.

Complete sequence of the Rous sarcoma virus env gene: identification of structural and functional regions of its product

The amino-terminal amino acid sequences of gp85 and gp37, the envelope glycoproteins of Rous sarcoma virus (RSV), were determined. Alignment of these sequences with the amino acid sequence predicted from the complete nucleotide sequence of the Prague strain of RSV, subgroup C (PR-C), has allowed us to delineate the env gene-coding region of this virus. The coding sequences for gp85 and gp37 have been placed in an open reading frame that extends from nucleotide 5045 to nucleotide 6862 and predict sizes of 341 amino acids (36,962 molecular weight) for gp85 and 198 amino acids (21,566 molecular weight) for gp37. Carbohydrate makes a significant contribution to the observed molecular weights of these polypeptides--the amino acid sequence contains 14 potential glycosylation sites (Asn-X-Ser/Thr) in gp85 and two in gp37. Experiments aimed at estimating the number of carbohydrate side chains yielded results consistent with most or all of these sites being occupied. Although an initiation codon is located early (codon 4) in the open reading frame, it is likely that splicing yields an mRNA on which translation initiates at the same AUG as that of the gag gene to produce a nascent polypeptide in which gp85 is preceded by a 62-amino-acid-long leader peptide. This leader contains the hydrophobic sequence (signal sequence) necessary for translocation across the endoplasmic reticulum and is completely removed from the env gene product during translation. The polyprotein precursor, Pr95env, is cleaved to gp85 and gp37 at the carboxyl side of the basic sequence:-Arg-Arg-Lys-Arg-. gp85 is attached through a disulphide linkage to gp37, and although the positions of the cysteines involved in this linkage are not known, the presence of a 27-amino-acid-long hydrophobic region at the carboxy-terminus of gp37 is consistent with its role as a membrane anchor for the viral glycoprotein complex. The location of host range variable regions with respect to the possible tertiary structure of the complex is discussed.

Influenza virus hemagglutinin expression is polarized in cells infected with recombinant SV40 viruses carrying cloned hemagglutinin DNA

Primary cell cultures of African Green monkey kidney (AGMK) contain polarized epithelial cells in which influenza virus matures predominantly at the apical surfaces above tight junctions. Influenza virus glycoproteins were found to be localized at the same membrane domain from which the virus budded. When polarized primary AGMK cells were infected with recombinant SV40 viruses containing DNA coding for either an influenza virus H1 or H2 subtype hemagglutinin (HA), the HA proteins were preferentially expressed at the apical surface in a manner identical to that observed in influenza virus-infected cells. Thus, cellular mechanisms for sorting membrane glycoproteins recognize some structural feature of the HA glycoprotein itself, and other viral proteins are not necessary for this process.

On the insertion of proteins into membranes

Recent data concerning the primary structure and the interactions of proteins with membranes suggest the existence of two classes of integral membrane proteins. In the first class, the polypeptide chain crosses the membrane only once. The membrane penetrating fragment is markedly hydrophobic and contains several positive charges on its C-terminal border. In the second class, the protein is folded in a complex fashion within the membrane and the knowledge of its amino acid sequence is not sufficient to predict the manner in which the protein interacts with the membrane.

Sequential mutations in the NS genes of influenza virus field strains

The complete nucleotide sequences of the NS genes from three human influenza viruses, A/FM/1/47 (H1N1), A/FW/1/50 (H1N1), and A/USSR/90/77 (H1N1), were determined. Only five single-base differences were found within the sequences of the A/FW/1/50 and A/USSR/90/77 NS genes, thus confirming earlier data suggesting that the 1977 H1N1 viruses are closely related to virus strains that were circulating around 1950. Comparison of all three sequences with those from A/PR/8/34 and A/Udorn/72 viruses illustrates that these genes (with the exception of that of the A/USSR/90/77 strain) evolve through cumulative base changes along a single common lineage. A nucleotide sequence variation of approximately 2.2 to 3.4% per 10 years was determined for the NS gene segments. Extensive size variation was also observed among the NS1 proteins of the various human viruses. The A/FM/1/47 NS1 protein, which consists of 202 amino acids, is 15% shorter than the A/Udorn/72 NS1 protein, which consists of 237 amino acids.

Antigenic and amino acid sequence variations in the haemagglutinins of type A influenza viruses recently isolated from human subjects

Since 1978, influenza A viruses with different antigenic properties have been isolated in many countries, even though little influenza activity has been recorded. In the present paper, the antigenic properties of viruses representative of isolates from each year since 1979 are compared, and the amino acid sequences of their haemagglutinins are described in detail. The reults give an indication of the extent and nature of variation in influenza A viruses during this period.