Molecular characterization of a new hemagglutinin, subtype H14, of influenza A virus

Spatial, temporal, and species variation in prevalence of influenza A viruses in wild migratory birds

Although extensive data exist on avian influenza in wild birds in North America, limited information is available from elsewhere, including Europe. Here, molecular diagnostic tools were employed for high-throughput surveillance of migratory birds, as an alternative to classical labor-intensive methods of virus isolation in eggs. This study included 36,809 samples from 323 bird species belonging to 18 orders, of which only 25 species of three orders were positive for influenza A virus. Information on species, locations, and timing is provided for all samples tested. Seven previously unknown host species for avian influenza virus were identified: barnacle goose, bean goose, brent goose, pink-footed goose, bewick's swan, common gull, and guillemot. Dabbling ducks were more frequently infected than other ducks and Anseriformes; this distinction was probably related to bird behavior rather than population sizes. Waders did not appear to play a role in the epidemiology of avian influenza in Europe, in contrast to the Americas. The high virus prevalence in ducks in Europe in spring as compared with North America could explain the differences in virus–host ecology between these continents. Most influenza A virus subtypes were detected in ducks, but H13 and H16 subtypes were detected primarily in gulls. Viruses of subtype H6 were more promiscuous in host range than other subtypes. Temporal and spatial variation in influenza virus prevalence in wild birds was observed, with influenza A virus prevalence varying by sampling location; this is probably related to migration patterns from northeast to southwest and a higher prevalence farther north along the flyways. We discuss the ecology and epidemiology of avian influenza A virus in wild birds in relation to host ecology and compare our results with published studies. These data are useful for designing new surveillance programs and are particularly relevant due to increased interest in avian influenza in wild birds.

Significant gaps in our knowledge of the ecology of avian influenza in wild migratory birds have become apparent during recent outbreaks of H5N1 highly pathogenic avian influenza, in particular in relation to the risk of virus spread by wild birds. An eight-year surveillance study, which included more than 36,000 wild birds tested for low pathogenic avian influenza, provides new information on host species, prevalence, and temporal and geographical variation of avian influenza in wild migratory birds in Europe. Dabbling ducks harbored nearly all known influenza virus subtypes, with the exception of H13 and H16, which were found primarily in gulls. In contrast to American studies, waders did not play a role in the epidemiology of avian influenza in Europe. This study provides important information on the ecology and epidemiology of avian influenza A virus and could assist in the design of new surveillance studies for high and low pathogenic avian influenza in wild birds.

Characterization of low-pathogenic H5 subtype influenza viruses from Eurasia: implications for the origin of highly pathogenic H5N1 viruses

Highly pathogenic avian influenza (HPAI) H5N1 viruses are now endemic in many Asian countries, resulting in repeated outbreaks in poultry and increased cases of human infection. The immediate precursor of these HPAI viruses is believed to be A/goose/Guangdong/1/96 (Gs/GD)-like H5N1 HPAI viruses first detected in Guangdong, China, in 1996. From 2000 onwards, many novel reassortant H5N1 influenza viruses or genotypes have emerged in southern China. However, precursors of the Gs/GD-like viruses and their subsequent reassortants have not been fully determined. Here we characterize low-pathogenic avian influenza (LPAI) H5 subtype viruses isolated from poultry and migratory birds in southern China and Europe from the 1970s to the 2000s. Phylogenetic analyses revealed that Gs/GD-like virus was likely derived from an LPAI H5 virus in migratory birds. However, its variants arose from multiple reassortments between Gs/GD-like virus and viruses from migratory birds or with those Eurasian viruses isolated in the 1970s. It is of note that unlike HPAI H5N1 viruses, those recent LPAI H5 viruses have not become established in aquatic or terrestrial poultry. Phylogenetic analyses revealed the dynamic nature of the influenza virus gene pool in Eurasia with repeated transmissions between the eastern and western extremities of the continent. The data also show reassortment between influenza viruses from domestic and migratory birds in this region that has contributed to the expanded diversity of the influenza virus gene pool among poultry in Eurasia.

Virus-like particle vaccine induces protective immunity against homologous and heterologous strains of influenza virus

Recurrent outbreaks of highly pathogenic avian influenza virus pose the threat of pandemic spread of lethal disease and make it a priority to develop safe and effective vaccines. Influenza virus-like particles (VLPs) have been suggested to be a promising vaccine approach. However, VLP-induced immune responses, and their roles in inducing memory immune responses and cross-protective immunity have not been investigated. In this study, we developed VLPs containing influenza virus A/PR8/34 (H1N1) hemagglutinin (HA) and matrix (M1) proteins and investigated their immunogenicity, long-term cross-protective efficacy, and effects on lung proinflammatory cytokines in mice. Intranasal immunization with VLPs containing HA induced high serum and mucosal antibody titers and neutralizing activity against PR8 and A/WSN/33 (H1N1) viruses. Mice immunized with VLPs containing HA showed little or no proinflammatory lung cytokines and were protected from a lethal challenge with mouse-adapted PR8 or WSN viruses even 5 months postimmunization. Influenza VLPs induced mucosal immunoglobulin G and cellular immune responses, which were reactivated rapidly upon virus challenge. Long-lived antibody-secreting cells were detected in the bone marrow of immunized mice. Immune sera administered intranasally were able to confer 100% protection from a lethal challenge with PR8 or WSN, which provides further evidence that anti-HA antibodies are primarily responsible for preventing infection. Taken together, these results indicate that nonreplicating influenza VLPs represent a promising strategy for the development of a safe and effective vaccine to control the spread of lethal influenza viruses.

A point mutation at the C terminus of the cytoplasmic domain of influenza B virus haemagglutinin inhibits syncytium formation

The C-terminal sequence of the cytoplasmic tail (CT) of influenza B haemagglutinin (BHA) consists of strictly conserved, hydrophobic amino acids, and the endmost C-terminal amino acid of the CT is Leu. To elucidate the role of this amino acid in the fusion activity of BHA (B/Kanagawa/73), site-specific mutant HAs were created by replacing Leu at this position with Arg, Lys, Ser, Try, Val or Ile or by the deletion of Leu altogether. All mutants were expressed at the cell surface, bound to red blood cells, were cleaved properly into two subunits and could be acylated like the wild-type (wt) HA. The membrane-fusion ability of these mutants was examined with a lipid (R18) and aqueous (calcein) dye-transfer assay and quantified with a syncytium-formation assay. All mutant HAs showed no measurable effect on lipid mixing or fusion-pore formation. However, mutant HAs with a hydrophobic value of the C-terminal amino acid lower than that of Leu had a reduced ability to form syncytia, whereas mutants with a more hydrophobic amino acid (Val or Ile) promoted fusion to the extent of the wt HA. On the other hand, the mutant HA with the deletion of Leu supported full fusion. These results demonstrate that Leu at the endmost portion of the C terminus of the BHA-CT is not essential for BHA-mediated fusion, but that the hydrophobicity of the single amino acid at this position plays an important role in syncytium formation.

An outbreak of highly pathogenic avian influenza subtype H5N1 in broiler breeders, Korea

Highly pathogenic avian influenza (HPAI) was diagnosed in broiler breeders, submitted to the National Veterinary Research and Quarantine Service in South Korea. Grossly, the dead breeders had lesions consistent with HPAI, including pancreatic mottling, splenomegaly, pulmonary edema and congestion, and hemorrhages in the mucosa of the proventriculus, gizzard and small intestine, and on the serosal surface. Microscopically, there were necrotized hepatitis and pancreatitis, lymphocytic meningoencephalitis, myocarditis, and interstitial pneumonia. Influenza viral antigen was demonstrated in areas closely associated with histopathologic lesions. The AI virus was isolated from cecal tonsils, feces, trachea, and kidney of the chickens. The isolated virus was identified as the highly pathogenic H5N1, with a hemagglutinin proteolytic cleavage site deduced amino acid sequences of QREKRKKR/GLFGAGLFGAIAG. In order to determine the pathogenicity of the isolate, eight 6-week-old specific pathogen free chickens were inoculated intravenously with the virus, and all the birds died within 24 hr after inoculation. This is the first report of an outbreak of HPAI in the chickens in South Korea.

Amplification of the entire genome of influenza A virus H1N1 and H3N2 subtypes by reverse-transcription polymerase chain reaction

This study describes the development of a simple RT-PCR method to amplify the whole genome of the influenza A virus based on the amplification of full-length gene segments. Primers were designed based on the conserved regions of both the 5'-end and the 3'-end of each gene segment. After optimizing the duration and temperature of denaturing, annealing, and extension, these primers could amplify all of the full-length gene segments. To test the accuracy of the method, all amplicons were subjected to DNA sequencing with an autosequencer. Eighteen strains of influenza A virus which belonged to H1N1 or H3N2 subtypes were tested. All eight segments of both subtypes were successfully amplified in all tested strains. Using a newly developed reverse-transcriptase (RT), primers and PCR running conditions, this study established a protocol to amplify the entire genome of the influenza A virus. This method provides a tool which can be used for the amplification of all genes of the H1N1 and H3N2 subtypes of influenza A virus prior to analysis of their sequences, and to construct expression plasmids for further study.

A new approach to an influenza live vaccine: modification of the cleavage site of hemagglutinin

A promising approach to reduce the impact of influenza is the use of an attenuated, live virus as a vaccine. Using reverse genetics, we generated a mutant of strain A/WSN/33 with a modified cleavage site within its hemagglutinin, which depends on proteolytic activation by elastase. Unlike the wild-type, which requires trypsin, this mutant is strictly dependent on elastase. Both viruses grow equally well in cell culture. In contrast to the lethal wild-type virus, the mutant is entirely attenuated in mice. At a dose of 10(5) plaque-forming units, it induced complete protection against lethal challenge. This approach allows the conversion of any epidemic strain into a genetically homologous attenuated virus.

Characterization of a novel influenza A virus hemagglutinin subtype (H16) obtained from black-headed gulls

In wild aquatic birds and poultry around the world, influenza A viruses carrying 15 antigenic subtypes of hemagglutinin (HA) and 9 antigenic subtypes of neuraminidase (NA) have been described. Here we describe a previously unidentified antigenic subtype of HA (H16), detected in viruses circulating in black-headed gulls in Sweden. In agreement with established criteria for the definition of antigenic subtypes, hemagglutination inhibition assays and immunodiffusion assays failed to detect specific reactivity between H16 and the previously described subtypes H1 to H15. Genetically, H16 HA was found to be distantly related to H13 HA, a subtype also detected exclusively in shorebirds, and the amino acid composition of the putative receptor-binding site of H13 and H16 HAs was found to be distinct from that in HA subtypes circulating in ducks and geese. The H16 viruses contained NA genes that were similar to those of other Eurasian shorebirds but genetically distinct from N3 genes detected in other birds and geographical locations. The European gull viruses were further distinguishable from other influenza A viruses based on their PB2, NP, and NS genes. Gaining information on the full spectrum of avian influenza A viruses and creating reagents for their detection and identification will remain an important task for influenza surveillance, outbreak control, and animal and public health. We propose that sequence analyses of HA and NA genes of influenza A viruses be used for the rapid identification of existing and novel HA and NA subtypes.

Influence of acylation sites of influenza B virus hemagglutinin on fusion pore formation and dilation

The cytoplasmic tail (CT) of hemagglutinin (HA) of influenza B virus (BHA) contains at positions 578 and 581 two highly conserved cysteine residues (Cys578 and Cys581) that are modified with palmitic acid (PA) through a thioester linkage. To investigate the role of PA in the fusion activity of BHA, site-specific mutagenesis was performed with influenza B virus B/Kanagawa/73 HA cDNA. All of the HA mutants were expressed on Cos cells by an expression vector. The membrane fusion ability of the HA mutants at a low pH was quantitatively examined with lipid (octadecyl rhodamine B chloride) and aqueous (calcein) dye transfer assays and with the syncytium formation assay. Two deacylation mutants lacking a CT or carrying serine residues substituting for Cys578 and Cys581 promoted full fusion. However, one of the single-acylation-site mutants, C6, in which Cys581 is replaced with serine, promoted hemifusion but not pore formation. In contrast, four other single-acylation-site mutants that have a sole cysteine residue in the CT at position 575, 577, 579, or 581 promoted full fusion. The impaired pore-forming ability of C6 was improved by amino acid substitution between residues 578 and 582 or by deletion of the carboxy-terminal leucine at position 582. Syncytium-forming ability, however, was not adequately restored by these mutations. These facts indicated that the acylation was not significant in membrane fusion by BHA but that pore formation and pore dilation were appreciably affected by the particular amino acid sequence of the CT and the existence of a single acylation site in CT residue 578.

Phylogenetic analysis of neuraminidase gene of H9N2 influenza viruses prevalent in chickens in China during 1995-2002

The neuraminidase (NA) genes of 12 H9N2 influenza virus strains isolated from diseased chickens in different farms in mainland China during 1995-2002 were amplified and sequenced. Amino acids at hemadsorbing (HB) site of these isolates are different from those of A/quail/Hong Kong/G1/97-like viruses and A/chicken/Korea/96-like viruses. Neuraminidases of the 12 strains had a deletion of 3 amino acid residues at positions 63-65 as compared to that of A/turkey/Wisconsin/189/66, while those of Korea and Pakistan H9N2 isolates had no deletion. Phylogenetic analyses showed NA gene of these isolates belonged to that of A/duck/Hong Kong/Y280/97-like virus lineage. NA gene of the H9N2 viruses isolated in Korea and Pakistan belonged to lineage different from those of the 12 isolates. The present results indicate that the NA of H9N2 strains isolated in mainland China during the past 8 years were well preserved and the geographical distribution play a significant role in the evolution of the H9N2 influenza viruses.

Sequence similarities and evolutionary relationships of influenza virus A hemagglutinins

This study brings the analysis of amino acid sequences of hemagglutinin (HA) from the influenza virus A that can infect a wide variety of birds and mammals. 191 sequences belonging to all known 15 HA subtypes were compared. The emphasis was given on functional sites (receptor-binding cavity with its right and left edges) and degree of their conservation in each subtype. Three evolutionary trees of 15 avian HA representatives were constructed: one tree based on the alignment of the entire HA sequences and two trees based on the alignment of HA1 and HA2 chains, respectively. The results have shown that, despite low degree of sequence similarity among the 191 sequences of HA1 subunit, the active site is well conserved, and that there are only marginal differences in the clustering of the individual HA subtypes between the two subunit trees. In this respect, the subtype H9 seems to be the most fluctuating example. The proposals of the probable avian HAs that could be the closest relatives to human (mammalian) HAs were also provided for several HA subtypes.

Receptor binding and membrane fusion in virus entry: the influenza hemagglutinin

Hemagglutinin (HA) is the receptor-binding and membrane fusion glycoprotein of influenza virus and the target for infectivity-neutralizing antibodies. The structures of three conformations of the ectodomain of the 1968 Hong Kong influenza virus HA have been determined by X-ray crystallography: the single-chain precursor, HA0; the metastable neutral-pH conformation found on virus, and the fusion pH-induced conformation. These structures provide a framework for designing and interpreting the results of experiments on the activity of HA in receptor binding, the generation of emerging and reemerging epidemics, and membrane fusion during viral entry. Structures of HA in complex with sialic acid receptor analogs, together with binding experiments, provide details of these low-affinity interactions in terms of the sialic acid substituents recognized and the HA residues involved in recognition. Neutralizing antibody-binding sites surround the receptor-binding pocket on the membrane-distal surface of HA, and the structures of the complexes between neutralizing monoclonal Fabs and HA indicate possible neutralization mechanisms. Cleavage of the biosynthetic precursor HA0 at a prominent loop in its structure primes HA for subsequent activation of membrane fusion at endosomal pH (Figure 1). Priming involves insertion of the fusion peptide into a charged pocket in the precursor; activation requires its extrusion towards the fusion target membrane, as the N terminus of a newly formed trimeric coiled coil, and repositioning of the C-terminal membrane anchor near the fusion peptide at the same end of a rod-shaped molecule. Comparison of this new HA conformation, which has been formed for membrane fusion, with the structures determined for other virus fusion glycoproteins suggests that these molecules are all in the fusion-activated conformation and that the juxtaposition of the membrane anchor and fusion peptide, a recurring feature, is involved in the fusion mechanism. Extension of these comparisons to the soluble N-ethyl-maleimide-sensitive factor attachment protein receptor (SNARE) protein complex of vesicle fusion allows a similar conclusion.

Pandemic threat posed by avian influenza A viruses

Influenza pandemics, defined as global outbreaks of the disease due to viruses with new antigenic subtypes, have exacted high death tolls from human populations. The last two pandemics were caused by hybrid viruses, or reassortants, that harbored a combination of avian and human viral genes. Avian influenza viruses are therefore key contributors to the emergence of human influenza pandemics. In 1997, an H5N1 influenza virus was directly transmitted from birds in live poultry markets in Hong Kong to humans. Eighteen people were infected in this outbreak, six of whom died. This avian virus exhibited high virulence in both avian and mammalian species, causing systemic infection in both chickens and mice. Subsequently, another avian virus with the H9N2 subtype was directly transmitted from birds to humans in Hong Kong. Interestingly, the genes encoding the internal proteins of the H9N2 virus are genetically highly related to those of the H5N1 virus, suggesting a unique property of these gene products. The identification of avian viruses in humans underscores the potential of these and similar strains to produce devastating influenza outbreaks in major population centers. Although highly pathogenic avian influenza viruses had been identified before the 1997 outbreak in Hong Kong, their devastating effects had been confined to poultry. With the Hong Kong outbreak, it became clear that the virulence potential of these viruses extended to humans.

Change in receptor-binding specificity of recent human influenza A viruses (H3N2): a single amino acid change in hemagglutinin altered its recognition of sialyloligosaccharides

Human H3N2 influenza A viruses were known to preferentially bind to sialic acid (SA) in alpha2,6Gal linkage on red blood cells (RBC). However, H3N2 viruses isolated in MDCK cells after 1992 did not agglutinate chicken RBC (CRBC). Experiments with point-mutated hemagglutinin (HA) of A/Aichi/51/92, one of these viruses, revealed that an amino acid change from Glu to Asp at position 190 (E190D) was responsible for the loss of ability to bind to CRBC. A/Aichi/51/92 did not agglutinate CRBC treated with alpha2, 3-sialidase, suggesting that SAalpha2,3Gal on CRBC might not inhibit the binding of the virus to SAalpha2,6Gal on CRBC. However, the virus agglutinated derivatized CRBC resialylated with SAalpha2, 6Galbeta1,4GlcNAc. These findings suggested that the E190D change might have rendered the HA able to distinguish sialyloligosaccharides on the derivatized CRBC containing the SAalpha2,6Galbeta1,4GlcNAc sequence from those on the native CRBC.

Production and evaluation criteria of specific monoclonal antibodies to the hemagglutinin of the H7N2 subtype of avian influenza virus

To enhance the rapidity in diagnosing the spread of avian influenza virus (AIV) in chicken layer flocks, studies were initiated to develop more sensitive and specific immunological and molecular methods for the detection of AIV. In this study, the purification of the hemagglutinin protein (H) from field isolates of H7N2, the production of monoclonal antibodies (MAbs), and their evaluation as diagnostic reagents are reported. Hybridomas were generated by fusion of SP2/0-Ag14 myelomas and spleen cells from immunized mice. Hybridomas secreting antibodies specific for the H protein were assayed by an ELISA and cloned using limiting dilution. The MAbs produced were characterized by hemagglutination inhibition (HI), immunohistochemistry (IHC), indirect fluorescent antibody assay (IFA), Western blots, and IFA flow cytometry using various AIV subtypes (i.e., H4N2, H5N3, H7N2). Of the various MAbs assayed, 6 had consistent and reproducible results in each of the assays used. The results obtained in this investigation enhanced the usage of the MAbs to viral H protein in the surveillance of AIV in chickens.

Influenza A viruses lacking sialidase activity can undergo multiple cycles of replication in cell culture, eggs, or mice

Influenza A viruses possess both hemagglutinin (HA), which is responsible for binding to the terminal sialic acid of sialyloligosaccharides on the cell surface, and neuraminidase (NA), which contains sialidase activity that removes sialic acid from sialyloligosaccharides. Interplay between HA receptor-binding and NA receptor-destroying sialidase activity appears to be important for replication of the virus. Previous studies by others have shown that influenza A viruses lacking sialidase activity can undergo multiple cycles of replication if sialidase activity is provided exogenously. To investigate the sialidase requirement of influenza viruses further, we generated a series of sialidase-deficient mutants. Although their growth was less efficient than that of the parental NA-dependent virus, these viruses underwent multiple cycles of replication in cell culture, eggs, and mice. To understand the molecular basis of this viral growth adaptation in the absence of sialidase activity, we investigated changes in the HA receptor-binding affinity of the sialidase-deficient mutants. The results show that mutations around the HA receptor-binding pocket reduce the virus's affinity for cellular receptors, compensating for the loss of sialidase. Thus, sialidase activity is not absolutely required in the influenza A virus life cycle but appears to be necessary for efficient virus replication.

Proteolytic processing of Marburg virus glycoprotein

Processing of the transmembrane glycoprotein (GP) of Marburg virus involved the conversion of an endo H-sensitive, ER-specific form into an endo H-resistant, Golgi-specific precursor that was cleaved into GP(1) and GP(2). Cleavage was mediated by furin or another subtilisin-like endoprotease with similar substrate specificity as indicated by mutational analysis of the cleavage site and inhibition using peptidyl chloromethylketones. Mature GP consisted of disulfide-linked GP(1) and GP(2) subunits.

Baculovirus-derived hemagglutinin vaccines protect against lethal influenza infections by avian H5 and H7 subtypes

Baculoviruses were engineered to express hemagglutinin (HA) genes of recent avian influenza (AI) isolates of the H5 and H7 subtypes. The proteins were expressed as either intact (H7) or slightly truncated versions (H5). In both cases purified HA proteins from insect cell cultures retained hemagglutination activity and formed rosettes in solution, indicating proper folding. Although immunogenic in this form, these proteins were more effective when administered subcutaneously in a water-in-oil emulsion. One or two-day-old specific pathogen free (SPF) White Rock chickens, free of maternal AI antibodies, responded with variable serum HI titers, but in some cases the titers were comparable to those achieved using whole virus preparations. Vaccination of three-week-old chickens with 1.0 microg of protein per bird generated a more consistent serum antibody response with an average geometric mean titer (GMT) of 121 (H5) and 293 (H7) at 21 days postvaccination. When challenged with highly pathogenic strains of the corresponding AI subtypes, the vaccinated birds were completely protected against lethal infection and in some cases exhibited reduced or no cloacal shedding at 3 days postinfection. Vaccine protocols employing these recombinant HA proteins will not elicit an immune response against internal AI proteins and thus will not interfere with epidemiological surveys of natural influenza infections in the field.

Coinfection of wild ducks by influenza A viruses: distribution patterns and biological significance

Coinfection of wild birds by influenza A viruses is thought to be an important mechanism for the diversification of viral phenotypes by generation of reassortants. However, it is not known whether coinfection is a random event or follows discernible patterns with biological significance. In the present study, conducted with viruses collected throughout 15 years from a wild-duck population in Alberta, Canada, we identified three discrete distributions of coinfections. In about one-third of the events, which involved subtypes of viruses that appear to be maintained in this duck reservoir, coinfection occurred at rates either close to or significantly lower than one would predict from rates of single-virus infection. Apparently, the better adapted an influenza A virus is to an avian population, the greater is its ability to prevent coinfections. Conversely, poorly adapted, nonmaintained viruses were significantly overrepresented as coinfectants. Rarely encountered subtypes appear to represent viruses whose chances of successfully infiltrating avian reservoirs are increased by coinfection. Mallards (Anas platyrhynchos) and pintails (A. acuta) were significantly more likely to be infected by a single influenza A virus than were the other species sampled, but no species was significantly more likely to be coinfected. These observations provide the first evidence of nonrandom coinfection of wild birds by influenza A viruses, suggesting that reassortment of these viruses in a natural population does not occur randomly. These results suggest that even though infections may occur in a species, all subtypes are not maintained by all avian species. They also suggest that specific influenza A virus subtypes are differentially adapted to different avian hosts and that the fact that a particular subtype is isolated from a particular avian species does not mean that the virus is maintained by that species.

Oligosaccharides in the stem region maintain the influenza virus hemagglutinin in the metastable form required for fusion activity

The influenza A virus hemagglutinin (HA) has three conserved oligosaccharides located in the stem region at asparagine residues 12, 28, and 478. The biological role of these oligosaccharides has been investigated by mutational analysis of HA of fowl plague virus that was expressed from a simian virus 40 vector in the presence of ammonium chloride for protection from acid denaturation in the trans-Golgi network. Resistance to endoglycosidase H and cleavage of HA into the subunits HA1 and HA2 have been analyzed as markers for intracellular transport. Cell surface exposure has been determined by hemadsorption following neuraminidase treatment, by immunofluorescence staining, and by fluorescence-activated cell sorter analysis. When all three stem oligosaccharides were removed, transport was almost completely blocked. When two of the three stem oligosaccharides, particularly those at asparagine residues 12 and 28, were missing, HA was transported to the surface but showed extremely low fusion activity. With mutants lacking one stem oligosaccharide, fusion was reduced to a lesser extent. Removal of stem oligosaccharides resulted also in an increase in the pH optimum required for fusion. On the other hand, no reduction in fusion activity was observed when oligosaccharides in the head region of the HA spike were removed. These results indicate that the conserved oligosaccharides in the stem stabilize HA in the form susceptible to the conformational change necessary for fusion.

The role of acidic residues in the "fusion segment" of influenza A virus hemagglutinin in low-pH-dependent membrane fusion

To clarify the role of acidic amino acid residues in the "fusion segment" of hemagglutinin (HA) of influenza A virus (H1N1) in pH-dependent membrane fusion, we have constructed and expressed five mutant HA cDNAs in CV-1 cells by SV40-HA virus vectors (SVHA). Fusion activities of the five mutant HAs were examined by lipid mixing and polykaryon formation assays. In spite of the substitution of Gly and Lys for the acidic residues, all the mutants were found to retain their low-pH-dependent fusion activity by lipid mixing assay. Although SVHA-G19(HA(2)19D-->G), -K11 (HA(2)11E-->K) and -K19(HA(2)19D-->K) induced polykaryon formation at low pH as wild type HA did, SVHA-G11(HA(2)11E-->G) induced limited polykaryon formation and SVHA-G11,19 (HA(2)11E-->G, 19D-->G) did not. The substitution of Gly for Glu at position 11 inhibited widening of the initial fusion pore. However, Lys mutants induced the formation of an initial fusion pore and widened it at low pH where Lys residues might have positive charges. These results suggest that the neutralization of the charges on acidic residues in the "fusion segment" at low pH is not important for interaction of the "fusion segment" with the target lipid bilayer or for triggering the membrane fusion.

Mutations at palmitylation sites of the influenza virus hemagglutinin affect virus formation

The carboxy terminus of the hemagglutinin (HA) of influenza A viruses contains three cysteine residues which are highly conserved among HA subtypes. It has previously been shown for the H2, H3, and H7 subtypes of HA that these cysteine residues are modified by the covalent attachment of palmitic acid. In order to study the role of the acylated cysteines in the formation of infectious influenza viruses, we introduced mutations into the HA of influenza A/WSN/33 virus (H1 subtype) by reverse-genetics techniques. We found that the cysteine at position 563 of the cytoplasmic tail is required for infectious-particle formation. The cysteine at position 560 can be changed to alanine or tyrosine to yield virus strains that are attenuated in cell cultures. The change from cysteine at position 553 to serine or alanine does not significantly alter the phenotype of the virus. The requirement for a cysteine at position 563 suggests a functional role for palmitylation of the cytoplasmic tail. This interpretation is further supported by experiments in which two or more of the cysteine residues were mutated, eliminating potential palmitylation sites. None of these double or triple mutations resulted in infectious virus. Selection of revertants of the attenuated cysteine-to-tyrosine mutant (mutation at position 560) always resulted in reversion to cysteine rather than to other amino acids. Although our data indicate a biological role for the conserved cysteine residues in the cytoplasmic tail of the HA of influenza viruses, we cannot exclude the possibility that structural constraints in the cytoplasmic tail of the HA--rather than altered palmitylation--are the determining factors for infectious-particle formation.

Deduced amino acid sequences of the haemagglutinin of H5N1 avian influenza virus isolates from an outbreak in turkeys in Norfolk, England

The deduced amino acid sequences of the haemagglutinins of avian influenza viruses, isolated from an outbreak in turkeys in Norfolk, England in 1991/92, were determined by PCR amplification and cycle sequencing. Both the highly pathogenic and avirulent isolates had the same cleavage site sequence with multiple-basic amino acids, which normally would be expected only for the former. Clones derived by plaque picking from the highly pathogenic isolate ranged from low to very high pathogenicity in vivo and these, and the original isolates, showed nucleotide and amino acid variation at one or more of five possible sites, none of which were at the cleavage site. None of these site variations correlated with pathogenicity, suggesting that the factor responsible for the suppression of the expected effects of the multiple-basic amino acid haemagglutinin cleavage site in the avirulent isolate may not have been part of the haemagglutinin amino acid sequence.

The hemagglutinins of duck and human H1 influenza viruses differ in sequence conservation and in glycosylation

We determined the deduced amino acid sequences of two H1 duck influenza A virus hemagglutinins (HAs) and found that the consensus sequence of the HA, determined directly from virus recovered from the intestinal tract, remains unchanged through many generations of growth in MDCK cells and chicken embryos. These two duck viruses differ from each other by 5 amino acids and from A/Dk/Alberta/35/1976 (F. J. Austin, Y. Kawaoka, and R. G. Webster, J. Gen. Virol. 71:2471-2474, 1990) by 9 and 12 amino acids, most of which are in the HA1 subunit. They are antigenically similar to each other but different from the Alberta virus. We compared these H1 duck HAs with the HAs of human isolates to identify structural properties of this viral glycoprotein that are associated with host range. By comparison to the human H1 HAs, the duck virus HA sequences are highly conserved as judged by the small fraction of nucleotide differences between strains which result in amino acid substitutions. However, the most striking difference between these duck and human HAs is in the number and distribution of glycosylation sites. Whereas duck and swine viruses have four and five conserved glycosylation sites per HA1 subunit, none of which are on the tip of the HA, all human viruses have at least four additional sites, two or more of which are on the tip of the HA. These findings stress the role of glycosylation in the control of host range and suggest that oligosaccharides on the tip of the HA are important to the survival of H1 viruses in humans but not in ducks or swine.

A study of the advantages and limitations of immunoblotting procedures for the detection of antibodies against influenza virus

An immunoblotting procedure was used to determine the specificity and examine some of the properties of antibodies produced following infection of mice with influenza virus or inoculation with noninfectious material with Alhydrogel or complete Freund's adjuvant. The noninfectious material used was beta-propiolactone-inactivated influenza virus and a preparation (HANA) enriched for the surface glycoproteins, hemagglutinin (HA) and neuraminidase (NA). When influenza viral proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under nonreducing conditions, each of the anti-viral antisera tested exhibited strong binding. Under reducing conditions, however, much weaker binding was observed especially towards the HA1 subunit of HA. This was particularly apparent with antisera raised to virus or HANA in the absence of adjuvant. A panel of monoclonal antibodies directed to HA also bound well to viral HA separated by SDS-PAGE under nonreducing conditions but failed to recognize epitopes on HA1 separated under reducing conditions. These results suggest that when HA is reduced and immobilized on a solid support, it does not display the conformational features essential for the integrity of all epitopes. The immunoblotting procedure was also used to determine the isotype of anti-viral antibody directed against individual viral proteins and to detect matrix protein 2 (M2) in purified influenza virions and influenza-infected cells using antisera raised to a synthetic peptide representing a sequence within the M2 protein.

Role of conserved glycosylation sites in maturation and transport of influenza A virus hemagglutinin

The role of three N-linked glycans which are conserved among various hemagglutinin (HA) subtypes of influenza A viruses was investigated by eliminating the conserved glycosylation (cg) sites at asparagine residues 12 (cg1), 28 (cg2), and 478 (cg3) by site-directed mutagenesis. An additional mutant was constructed by eliminating the cg3 site and introducing a novel site 4 amino acids away, at position 482. Expression of the altered HA proteins in eukaryotic cells by a panel of recombinant vaccinia viruses revealed that rates and efficiency of intracellular transport of HA are dependent upon both the number of conserved N-linked oligosaccharides and their respective positions on the polypeptide backbone. Glycosylation at two of the three sites was sufficient for maintenance of transport of the HA protein. Conserved glycosylation at either the cg1 or cg2 site alone also promoted efficient transport of HA. However, the rates of transport of these mutants were significantly reduced compared with the wild-type protein or single-site mutants of HA. The transport of HA proteins lacking all three conserved sites or both amino-terminally located sites was temperature sensitive, implying that a polypeptide folding step had been affected. Analysis of trimer assembly by these mutants indicated that the presence of a single oligosaccharide in the stem domain of the HA molecule plays an important role in preventing aggregation of molecules in the endoplasmic reticulum, possibly by maintaining the hydrophilic properties of this domain. The conformational change observed after loss of all three conserved oligosaccharides also resulted in exposure of a normally mannose-rich oligosaccharide at the tip of the large stem helix that allowed its conversion to a complex type of structure. Evidence was also obtained suggesting that carbohydrate-carbohydrate interactions between neighboring oligosaccharides at positions 12 and 28 influence the accessibility of the cg2 oligosaccharide for processing enzymes. We also showed that terminal glycosylation of the cg3 oligosaccharide is site specific, since shifting of this site 4 amino acids away, to position 482, yielded an oligosaccharide that was arrested in the mannose-rich form. In conclusion, carbohydrates at conserved positions not only act synergistically by promoting and stabilizing a conformation compatible with transport, they also enhance trimerization and/or folding rates of the HA protein.

A H1 hemagglutinin of a human influenza A virus with a carbohydrate-modulated receptor binding site and an unusual cleavage site

Two receptor binding variants of the influenza virus A/Tübingen/12/85 (H1N1) were separated by their different plaque formation in MDCK cells. Hemagglutination of variant I was restricted to red blood cells of guinea pigs, whereas variant II also hemagglutinated chicken cells. The variants differed also in their ability to bind to alpha 2,6-linked sialic acid. Evidence is presented that this difference is determined by a complex carbohydrate side chain at asparagine131 near the receptor binding site which is absent in variant II. With both variants, the arginine found at the cleavage site of all other human isolates analyzed so far was replaced by lysine.

Characterization of a new avian-like influenza A virus from horses in China

In March 1989 a severe outbreak of respiratory disease occurred in horses in the Jilin and Heilongjiang provinces of Northeast China that caused up to 20% mortality in some herds. An influenza virus of the H3N8 subtype was isolated from the infected animals and was antigenically and molecularly distinguishable from the equine 2 (H3N8) viruses currently circulating in the world. The reference strain A/Equine/Jilin/1/89 (H3N8) was most closely related to avian H3N8 influenza viruses. Sequence comparisons of the entire hemagglutinin (HA), nucleoprotein (NP), neuraminidase (NA), matrix (M), and NS genes along with partial sequences of the three polymerase (PB1, PB2, PA) genes suggest that six of the eight gene segments (PA, HA, NP, NA, M, NS) are closely related to avian influenza viruses. Since direct sequence analysis can only provide a crude measure of relationship, phylogenetic analysis was done on the sequence information. Phylogenetic analyses of the entire HA, NP, M, and NS genes and of partial sequences of PB1, PB2, and PA indicated that these genes are of recent avian origin. The NP gene segment is closely related to the gene segment found in the newly described H14 subtype isolated from ducks in the USSR. The A/Equine/Jilin/1/89 (H3N8) influenza virus failed to replicate in ducks, but did replicate and cause disease in mice on initial inoculation and on subsequent passaging caused 100% mortality. In ferrets, the virus caused severe influenza symptoms. A second outbreak of influenza in horses in Northeast China occurred in April 1990 in the Heilongjiang province with 48% morbidity and no mortality. The viruses isolated from this outbreak were antigenically indistinguishable from those in the 1989 outbreak and it is probable that the reduced mortality was due to the immune status of of the horses in the region. No influenza was detected in horses in Northern China in the spring, summer, or fall of 1991 and no influenza has been detected in horses in adjacent areas. Our analysis suggests that this new equine influenza virus in horses in Northeast China is the latest influenza virus in mammals to emerge from the avian gene pool in nature and that it may have spread to horses without reassortment. The appearance of this new equine virus in China emphasizes the potential for whole avian influenza viruses to successfully enter mammalian hosts and serves as a model and a warning for the appearance of new pandemic influenza viruses in humans.(ABSTRACT TRUNCATED AT 250 WORDS)

Evolution and ecology of influenza A viruses

In this review we examine the hypothesis that aquatic birds are the primordial source of all influenza viruses in other species and study the ecological features that permit the perpetuation of influenza viruses in aquatic avian species. Phylogenetic analysis of the nucleotide sequence of influenza A virus RNA segments coding for the spike proteins (HA, NA, and M2) and the internal proteins (PB2, PB1, PA, NP, M, and NS) from a wide range of hosts, geographical regions, and influenza A virus subtypes support the following conclusions. (i) Two partly overlapping reservoirs of influenza A viruses exist in migrating waterfowl and shorebirds throughout the world. These species harbor influenza viruses of all the known HA and NA subtypes. (ii) Influenza viruses have evolved into a number of host-specific lineages that are exemplified by the NP gene and include equine Prague/56, recent equine strains, classical swine and human strains, H13 gull strains, and all other avian strains. Other genes show similar patterns, but with extensive evidence of genetic reassortment. Geographical as well as host-specific lineages are evident. (iii) All of the influenza A viruses of mammalian sources originated from the avian gene pool, and it is possible that influenza B viruses also arose from the same source. (iv) The different virus lineages are predominantly host specific, but there are periodic exchanges of influenza virus genes or whole viruses between species, giving rise to pandemics of disease in humans, lower animals, and birds. (v) The influenza viruses currently circulating in humans and pigs in North America originated by transmission of all genes from the avian reservoir prior to the 1918 Spanish influenza pandemic; some of the genes have subsequently been replaced by others from the influenza gene pool in birds. (vi) The influenza virus gene pool in aquatic birds of the world is probably perpetuated by low-level transmission within that species throughout the year. (vii) There is evidence that most new human pandemic strains and variants have originated in southern China. (viii) There is speculation that pigs may serve as the intermediate host in genetic exchange between influenza viruses in avian and humans, but experimental evidence is lacking. (ix) Once the ecological properties of influenza viruses are understood, it may be possible to interdict the introduction of new influenza viruses into humans.

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.

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.

New aspects of influenza viruses

Influenza virus infections continue to cause substantial morbidity and mortality with a worldwide social and economic impact. The past five years have seen dramatic advances in our understanding of viral replication, evolution, and antigenic variation. Genetic analyses have clarified relationships between human and animal influenza virus strains, demonstrating the potential for the appearance of new pandemic reassortants as hemagglutinin and neuraminidase genes are exchanged in an intermediate host. Clinical trials of candidate live attenuated influenza virus vaccines have shown the cold-adapted reassortants to be a promising alternative to the currently available inactivated virus preparations. Modern molecular techniques have allowed serious consideration of new approaches to the development of antiviral agents and vaccines as the functions of the viral genes and proteins are further elucidated. The development of techniques whereby the genes of influenza viruses can be specifically altered to investigate those functions will undoubtedly accelerate the pace at which our knowledge expands.

Influenza A virus transfectants with chimeric hemagglutinins containing epitopes from different subtypes

Influenza virus transfectants with chimeric hemagglutinins were constructed by using a ribonucleoprotein transfection method. Transfectants W(H1)-H2 and W(H1)-H3 contained A/WSN/33(H1N1) (WSN) hemagglutinins in which the six-amino-acid loop (contained in antigenic site B) was replaced by the corresponding structures of influenza viruses A/Japan/57(H2N2) and A/Hong Kong/8/68(H3N2) (HK), respectively. Serological analysis indicated that the W(H1)-H3 transfectant virus reacted with antibodies against both the WSN and HK viruses in hemagglutination inhibition and plaque neutralization assays. Furthermore, mice immunized with W(H1)-H3 transfectant virus produced antibodies to the WSN and HK viruses. The results demonstrate that influenza virus transfectants can be engineered to express epitopes of different subtypes on their hemagglutinins.

Amantadine selection of a mutant influenza virus containing an acid-stable hemagglutinin glycoprotein: evidence for virus-specific regulation of the pH of glycoprotein transport vesicles

Mutants of influenza Rostock virus (H7N1 subtype) were selected for resistance to amantadine hydrochloride at concentrations of the antiviral drug known to affect the function of the virus M2 transmembrane protein. Sequence analysis revealed that three mutants had no changes in M2 but contained a lysine to isoleucine substitution in the hemagglutinin (HA) membrane glycoprotein at position 58 of HA2. The mutant viruses were found to fuse membranes at a pH value 0.7 lower than wild type and to exhibit changes in the conformation of their HAs specifically at the lower pH. The homologous lysine to isoleucine substitution was introduced by site-specific mutagenesis into the HA of X-31 influenza virus (H3 subtype), which was expressed by using vaccinia virus recombinants. The expressed HA also mediated membrane fusion and changed in conformation at a pH value 0.7 lower than wild type. These results indicate that increased acid stability of the HA obviates the consequences of the inhibition of M2 function by amantadine and provide further evidence for the role of M2 in regulating the pH of vesicles involved in glycoprotein transport to the cell surface.

New viruses and new disease: mutation, evolution and ecology

Given the extraordinarily high mutation rate of viruses, particularly those with RNA genomes, it is not surprising that new viruses are continually evolving. However, the symptomatology of old viral diseases has remained stable for centuries. The combination of genetic and ecological factors that constrain as well as facilitate the emergence of new viruses is analyzed.

Comparison of complete amino acid sequences and receptor-binding properties among 13 serotypes of hemagglutinins of influenza A viruses

We determined the sequences of 7 serotypes (H4, H6, H8, H9, H11, H12, and H13) of hemagglutinin (HA) genes, which have not been reported so far. The coding regions consisted of 1692 nucleotides in H4, 1698 in H6, 1695 in H8, 1680 in H9, 1695 in H11, 1692 in H12, and 1698 in H13, and specified 564, 566, 565, 560, 565, 564, and 566 amino acids, respectively. By comparison of amino acid sequences, 13 HA serotypes could be divided into two families, i.e., an H1 group (H1, H2, H5, H6, H8, H9, H11, H12, and H13) and an H3 group (H3, H4, H7, and H10). The relationship was essentially similar to that reported by Air from the comparison of 80 amino-terminal amino acid sequence of 12 HA serotypes (G.M. Air, 1981, Proc. Natl. Acad. Sci. USA 78, 7639-7643). Though a considerable amino acid sequence difference exists between certain HA serotypes, several amino acid residues in fusion peptides (HA2(1-11)) and receptor-binding sites (HA1(98), -134, -138, -153, -183, and -195) were shown to be conserved among the 13 HA serotypes. Human H1 and avian H3, H4, H8, and H10 viruses preferentially bound NeuAc alpha 2,3Gal sequences, whereas human H2 and H3 and avian H6 and H9 viruses bound NeuAc alpha 2,6Gal sequences, although the amino acid residues at position 226 of human H2 and avian H6 and H9 serotype HAs are glutamine. These results show that the amino acid residue at position 226 is not necessarily a determinant of receptor specificity for all serotypes.