Is the gene pool of influenza viruses in shorebirds and gulls different from that in wild ducks?

Origin and evolutionary pathways of the H1 hemagglutinin gene of avian, swine and human influenza viruses: cocirculation of two distinct lineages of swine virus

The nucleotide sequences of the HA1 domain of the H1 hemagglutinin genes of A/duck/Hong Kong/36/76, A/duck/Hong Kong/196/77, A/sw/North Ireland/38, A/sw/Cambridge/39 and A/Yamagata/120/86 viruses were determined, and their evolutionary relationships were compared with those of previously sequenced hemagglutinin (H1) genes from avian, swine and human influenza viruses. A pairwise comparison of the nucleotide sequences revealed that the genes can be segregated into three groups, the avian, swine and human virus groups. With the exception of two swine strains isolated in the 1930s, a high degree of nucleotide sequence homology exists within the group. Two phylogenetic trees constructed from the substitutions at the synonymous site and the third codon position showed that the H1 hemagglutinin genes can be divided into three host-specific lineages. Examination of 21 hemagglutinin genes from the human and swine viruses revealed that two distinct lineages are present in the swine population. The swine strains, sw/North Ireland/38 and sw/Cambridge/39, are clearly on the human lineage, suggesting that they originate from a human A/WSN/33-like variant. However, the classic swine strain, sw/Iowa/15/30, and the contemporary human viruses are not direct descendants of the 1918 human pandemic strain, but did diverge from a common ancestral virus around 1905. Furthermore, previous to this the above mammalian viruses diverged from the lineage containing the avian viruses at about 1880.

Wild ducks are the reservoir for only a limited number of influenza A subtypes

Analysis of cloacal samples collected from 12,321 wild ducks in Alberta, Canada, from 1976 to 1990 showed influenza A infections to be seasonal, with prevalences increasing as the population became increasingly more dense. Viruses with 3 haemagglutinin (H3, H4, and H6) and 3 neuraminidase subtypes (N2, N6, and N8) were found consistently to infect both adult and juvenile ducks each year, indicating that wild ducks may be a reservoir for these viruses. In contrast, viruses with 7 haemagglutinin (H2, H5, H7, H8, H9, H11, and H12) and 3 neuraminidase subtypes (N1, N3, and N4) were not found for prolonged periods during the study; when they were found, they primarily infected juveniles at moderate levels. Whilst wild ducks appear to perpetuate some influenza A viruses, they apparently do not act as a reservoir for all such viruses.

Recent advances in avian virology

Selected, recent research on the following avian diseases, and their causative viruses, has been reviewed: chicken anaemia, infectious bursal disease, turkey rhinotracheitis, avian nephritis, fowlpox, influenza, infectious bronchitis and turkey enteritis.

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.

Host range determination and functional mapping of the nucleoprotein and matrix genes of influenza viruses using monoclonal antibodies

Construction and comparison of phylogenetic trees, the standard approach to determining the host-specific lineage of influenza A virus genes is tedious and expensive. In this study, panels of monoclonal antibodies (Mabs) produced against the matrix proteins (M1) of A/WSN and A/PR/8/34 and the nucleoprotein (NP) of A/WSN were assessed for their value in identifying the hosts of origin of the M1 and NP genes in influenza virus isolates and in mapping the proteins' functional domains. Using ELISA against a broad spectrum of reference viruses, we found two Mabs against the NP (150/4 and 469/6) to be useful in determining host-specific lineage. Comparative sequence analysis placed five amino acids within the antigenic domains recognized by Mab 150/4 and two amino acids within the domains recognized by 469/6. One Mab against the NP (5/1) recognized a conserved epitope that is present on each of the 36 influenza A viruses tested. This epitope may be a type-specific determinant for influenza A viruses and an RNA binding site. Monoclonal antibodies to M1 did not discriminate among species, but they did contribute information to the construction of a functional map of M1. These results demonstrate that Mabs to defined protein epitopes can provide useful information on the molecular epidemiology of influenza viruses.

Reassortants with equine 1 (H7N7) influenza virus hemagglutinin in an avian influenza virus genetic background are pathogenic in chickens

Reassortants possessing the hemagglutinin (HA) gene from A/Equine/London/1416/73 (H7N7) [Eq/Lond] and five or more genes from A/Chicken/Pennsylvania/1370/83 (H5N2) [Ck/Penn] were lethal in chickens. This result demonstrates that horses can maintain influenza viruses whose HAs are capable of promoting virulence. Thus, reassortment of equine and avian influenza virus genes could generate viruses that might be lethal in domestic poultry.

Replication of avian influenza viruses in humans

Volunteers inoculated with avian influenza viruses belonging to subtypes currently circulating in humans (H1N1 and H3N2) were largely refractory to infection. However 11 out of 40 volunteers inoculated with the avian subtypes, H4N8, H6N1, and H10N7, shed virus and had mild clinical symptoms: they did not produce a detectable antibody response. This was presumably because virus multiplication was limited and insufficient to stimulate a detectable primary immune response. Avian influenza viruses comprise hemagglutinin (HA) subtypes 1-14 and it is possible that HA genes not so far seen in humans could enter the human influenza virus gene pool through reassortment between avian and circulating human viruses.

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

Two influenza A viruses whose hemagglutinin (HA) did not react with any of the reference antisera for the 13 recognized HA subtypes were isolated from mallard ducks in the USSR. Antigenic analysis by hemagglutination inhibition and double immunodiffusion tests showed that the HAs of these viruses are similar to each other but distinct from the HAs of other influenza A viruses. Nucleotide sequence analysis showed that these HA genes differ from each other by only 21 nucleotides. However, they differ from all other HA subtypes at the amino acid level by at least 31% in HAI. Thus, we propose that the HAs of these viruses [A/Mallard/Gurjev/263/82 (H14N5) and A/Mallard/Gurjev/244/82 (H14N6) belong to a previously unrecognized subtype, and are designated H14. Unlike any other HAs of influenza viruses, the H14 HAs contained lysine at the cleavage site between HA1 and HA2 instead of arginine. Experimental infection of domestic poultry and ferrets with A/Mallard/Gurjev/263/82 (H14N5) showed that the virus is avirulent for these animals. Based on comparative sequence analysis of different HA genes, it is suggested that differences of 30% or more at the amino acid level in HA1 constitute separate subtypes. Phylogenetic analysis of representatives of each HA subtype showed that H14 is one of the most recently diverged lineages while H8 and H12 branched off early during the evolution of the HA subtypes. These latter two subtypes (H8 and H12) have been isolated very infrequently in recent years, suggesting that these old subtypes may be disappearing from the influenza reservoirs in nature.

Derivation of the nucleoproteins (NP) of influenza A viruses isolated from marine mammals

The nucleoprotein (NP) genes of influenza viruses were sequenced from a variety of virus isolates derived from marine mammals: whales from the Pacific and Atlantic oceans, seal and gull from the Western Atlantic, and a tern from the Caspian Sea. In comparison to published NP sequences, we found pairs of NPs derived from avian and marine mammal isolates to be closely related, e.g., the gull-whale and mallard-seal pairs from the Atlantic Coast of the USA and the tern-Pacific Ocean whale pair of the Eastern Hemisphere. Our analysis suggests that influenza viruses have been independently introduced into marine mammals from avian sources for each of our three examples. Furthermore, the closeness of the relationship in these avian-mammalian NP pairs indicates that the introductions are relatively recent. The sequences of these marine mammal NPs are avian-like and can be clearly distinguished from human NPs. Our results provide further support of interspecies transmission of influenza A viruses from the avian host reservoir directly to mammalian hosts.

Evolution of the nucleoprotein gene of influenza A virus

Nucleotide sequences of 24 nucleoprotein (NP) genes isolated from a wide range of hosts, geographic regions, and influenza A virus serotypes and 18 published NP gene sequences were analyzed to determine evolutionary relationships. The phylogeny of NP genes was determined by a maximum-parsimony analysis of nucleotide sequences. Phylogenetic analysis showed that NP genes have evolved into five host-specific lineages, including (i) Equine/Prague/56 (EQPR56), (ii) recent equine strains, (iii) classic swine (H1N1 swine, e.g., A/Swine/Iowa/15/30) and human strains, (iv) gull H13 viruses, and (v) avian strains (including North American, Australian, and Old World subgroups). These NP lineages match the five RNA hybridization groups identified by W. J. Bean (Virology 133:438-442, 1984). Maximum nucleotide differences among the NPs was 18.5%, but maximum amino acid differences reached only 10.8%, reflecting the conservative nature of the NP protein. Evolutionary rates varied among lineages; the human lineage showed the highest rate (2.54 nucleotide changes per year), followed by the Old World avian lineage (2.17 changes per year) and the recent equine lineage (1.22 changes per year). The per-nucleotide rates of human and avian NP gene evolution (1.62 x 10(-3) to 1.39 x 10(-3) changes per year) are lower than that reported for human NS genes (2.0 x 10(-3) changes per year; D. A. Buonagurio, S. Nakada, J. D. Parvin, M. Krystal, P. Palese, and W. M. Fitch, Science 232:980-982, 1986). Of the five NP lineages, the human lineage showed the greatest evolution at the amino acid level; over a period of 50 years, human NPs have accumulated 39 amino acid changes. In contrast, the avian lineage showed remarkable conservatism; over the same period, avian NP proteins changed by 0 to 10 amino acids. The specificity of the H13 NP in gulls and its distinct evolutionary separation from the classic avian lineage suggests that H13 NPs may have a large degree of adaptation to gulls. The presence of avian and human NPs in some swine isolates demonstrates the susceptibility of swine to different virus strains and supports the hypothesis that swine may serve as intermediates for the introduction of avian influenza virus genes into the human virus gene pool. EQPR56 is relatively distantly related to all other NP lineages, which suggests that this NP is rooted closest to the ancestor of all contemporary NPs. On the basis of estimation of evolutionary rates from nucleotide branch distances, current NP lineages are at least 100 years old, and the EQPR56 NP is much older.(ABSTRACT TRUNCATED AT 400 WORDS)

Isolation of Candida albicans and halophilic Vibrio spp. from aquatic birds in Connecticut and Florida

Halophilic vibrios were recovered from feces of six types of aquatic birds (gulls, pelicans, Canada geese, swans, egrets, cormorants) from Connecticut and/or Florida shorelines. Candida albicans was isolated from gulls and Canada geese in Connecticut and from gulls and cormorants in Florida.

Evolutionary pathways of the PA genes of influenza A viruses

Nucleotide sequences of the PA genes of influenza A viruses, isolated from a variety of host species, were analyzed to determine the evolutionary pathways of these genes and the host specificity of the genes. Results of maximum parsimony analysis of the nucleotide sequences indicate at least five lineages for the PA genes. Those from human strains represent a single lineage, whereas the avian genes appear to have evolved as two lineages--one comprising genes from many kinds of birds (e.g., chickens, turkeys, shorebirds, and ducks) and the other comprising only genes from gulls. H3N2 swine influenza virus PA genes are closely related to the currently circulating duck virus PA gene. By contrast, the H1N1 swine and equine virus PA genes appear to have evolved along independent lineages. Comparison of predicted amino acid sequences disclosed 10 amino acid substitutions in the PA proteins of all avian and H3N2 swine viruses that distinguished them from human viruses. The H1N1 swine viruses seem to be chimeras between human and avian viruses and they contain 8 amino acids not shared by other viruses. The equine viruses also appear to show their own amino acid substitutions. These findings indicate that the PA genes of influenza A viruses have evolved in different pathways defined by apparently unique amino acid substitutions and host specificities. They also indicate that influenza A viruses have been transmitted from avian to mammalian species.

Antigenic and molecular characterization of subtype H13 hemagglutinin of influenza virus

Influenza A viruses with subtype H13 hemagglutinin display an unusual host range. Although common in shorebirds, they are very rare or absent in wild ducks; additionally, H13 viruses have been isolated from a whale. To study the molecular basis for this host range, we have determined the complete nucleotide sequences of the hemagglutinin genes of three H13 influenza viruses from different species or geographical areas: A/gull/Maryland/77, A/gull/Astrachan (USSR)/84, and A/pilot whale/Maine/84. Based on the deduced amino acid sequences, H13 hemagglutinin shares the basic structure of other type A hemagglutinin subtypes such as H3, but has clearly diverged from other completely sequenced subtypes. Unique features of H13 hemagglutinin include the occurrence, near the receptor binding pocket, of residues Arg/Lys-227 and Trp-229 (H3 numbering); the significance of these are unknown. The sequence of the HA1-HA2 cleavage site resembles those of avirulent avian influenza viruses. The whale H13 hemagglutinin is similar to those from gulls, supporting the hypothesis that influenza viruses from avian sources can enter marine mammal populations but are probably not permanently maintained there. Antigenic analysis using a panel of monoclonal antibodies suggests that, like other subtypes, H13 viruses are heterogeneous, with different antigenic variants predominating in the eastern versus the western hemispheres.

What is the potential of avirulent influenza viruses to complement a cleavable hemagglutinin and generate virulent strains?

A large pool of avirulent influenza viruses are maintained in the wild ducks and shorebirds of the world, but we know little about their potential to become virulent. It is well established that the hemagglutinin (HA) is pivitol in determining virulence and that a constellation of other genes is also necessary (R. Rott, M. Orlich, and C. Scholtissek, 1976, J. Virol. 19, 54-60). The question we are asking here is the ability of avirulent influenza viruses to provide the gene constellation that will complement the HA from a highly virulent virus and for the reassortant to be virulent. Reassortant influenza viruses were prepared between ultraviolet treated A/Chicken/Pennsylvania/1370/83 (H5N2) [Ck/Penn] and influenza viruses from natural reservoirs. These viruses included examples of the predominant subtypes in wild ducks, shorebirds, and domestic poultry. Attention was given to the influenza viruses from live poultry markets, for it is possible that these establishments may be important in mixing of influenza genes from different species and the possible transmission to domestic and mammalian species. The reassortants were genotyped by partial sequencing of each gene and were tested for virulence in chickens. Each of the reassortants contained the hemagglutinin and matrix (M) genes from Ck/Penn and a majority of genes from the viruses from natural reservoirs indicating a preferential association between the HA and M genes. The reassortants containing multiple genes from wild ducks and a cleavable HA were avirulent indicating that the gene pool in ducks may not have a high potential to provide genes that are potentially virulent. In contrast, a disproportionate number of viruses from shorebirds and all avirulent H5N2 influenza viruses from city markets provided a gene constellation that in association with cleavable H5 HA were highly virulent in chickens. An evolutionary tree based on oligonucleotide mapping established that the H5N2 influenza viruses from birds in city markets are closely related.

Two subtypes of nucleoproteins (NP) of influenza A viruses

The nucleoprotein (NP) genes of nine influenza A virus strains isolated from different species have been sequenced and the deduced amino acid sequences have been compared to published NP sequences and sequences in press. Two "subtypes" of NPs can clearly be defined, one "subtype" comprises the NPs found with all tested human and one porcine strain, and another "subtype" comprises the NPs found with all tested avian and equine, and some porcine strains and a mink virus. There are no significant differences between these two groups concerning secondary structure predictions. Pig viruses were the only ones whose NP can belong to the one or the other "subtype." Therefore, pigs can be regarded as "mixing vessels," where the two independently evolving reservoirs of influenza A viruses can meet for the creation of new pandemic strains by reassortment.

Distinct lineages of influenza virus H4 hemagglutinin genes in different regions of the world

To understand the determinants of influenza virus evolution, phylogenetic relationships were determined for nine hemagglutinin (HA) genes of the H4 subtype. These genes belong to a set of viruses isolated from several avian and mammalian species from various geographic locations around the world between 1956 and 1985. We found that the HA gene of the H4 subtype is 1738 nucleotides in length and is predicted to encode a polypeptide of 564 amino acids. The connecting peptide, which is removed from the precursor polypeptide by peptidases to yield the mature HA1 and HA2 polypeptides, contains only one basic amino acid. This type of connecting peptide is a feature of all avian avirulent HAs. On the basis of pairwise nucleotide sequence homology comparisons the genes can be segregated into two groups: influenza virus genes isolated in North America and those isolated from other parts of the world. A high degree of homology exists between pairs of genes from viruses of similar geographic origin. The nucleotide sequences within a group differ by 1.5 to 10.6%; in contrast, between groups the differences range from 15.8 to 19.4%. An evolutionary tree for the nine sequences suggests that North American isolates have diverged extensively from those circulating in other parts of the world. Geographic barriers which determine flyway outlay may prevent the gene pools from extensive mixing. The lack of correlation between date of isolation and evolutionary distance suggests that different H4 HA genes cocirculate in a fashion similar to avian H3 HA genes (H. Kida et al., 1987, Virology 159, 109-119) and influenza C genes (D. Buonagurio et al., 1985, Virology 146, 221-232) implying the absence of selective pressure by antibody that would give a significant advantage to antigenic variants. In contrast to avian influenza virus genes, human influenza virus genes evolve rapidly under the selective pressure of antibody.