Neuraminidase gene from the early Asian strain of human influenza virus, A/RI/5-/57 (H2N2)

A perspective on the 2009 A/H1N1 influenza pandemic in Mexico

In this article, we provide a chronological description of the 2009 H1N1 influenza pandemic in Mexico from the detection of severe respiratory disease among young adults in central Mexico and the identification of the novel swine-origin influenza virus to the response of Mexican public health authorities with the swift implementation of the National Preparedness and Response Plan for Pandemic Influenza. Furthermore, we review some features of the 2009 H1N1 influenza pandemic in Mexico in relation to the devastating 1918-1920 influenza pandemic and discuss opportunities for the application of mathematical modeling in the transmission dynamics of pandemic influenza. The value of historical data in increasing our understanding of past pandemic events is highlighted.

The impact of vaccines and vaccinations: Challenges and opportunities for modelers

This review focuses on how infectious diseases and their prevention and control by development of vaccines and widespread vaccination has shaped evolution of human civilization and of the animals and plants that humans depend on for food, labor and companionship. After describing major infectious diseases and the current status for control by vaccination, the barriers to infection and the attributes of innate and acquired immunity contributing to control are discussed. The evolution in types of vaccines is presented in the context of developing technologies and in improving adjuvants to engender enhanced vaccine efficacy. The special concerns and needs in vaccine design and development are discussed in dealing with epidemics/pandemics with special emphasis on influenza and current global problems in vaccine delivery.

Effect of neuraminidase inhibitor-resistant mutations on pathogenicity of clade 2.2 A/Turkey/15/06 (H5N1) influenza virus in ferrets

The acquisition of neuraminidase (NA) inhibitor resistance by H5N1 influenza viruses has serious clinical implications, as this class of drugs can be an essential component of pandemic control measures. The continuous evolution of the highly pathogenic H5N1 influenza viruses results in the emergence of natural NA gene variations whose impact on viral fitness and NA inhibitor susceptibility are poorly defined. We generated seven genetically stable recombinant clade 2.2 A/Turkey/15/06-like (H5N1) influenza viruses carrying NA mutations located either in the framework residues (E119A, H274Y, N294S) or in close proximity to the NA enzyme active site (V116A, I117V, K150N, Y252H). NA enzyme inhibition assays showed that NA mutations at positions 116, 117, 274, and 294 reduced susceptibility to oseltamivir carboxylate (IC(50)s increased 5- to 940-fold). Importantly, the E119A NA mutation (previously reported to confer resistance in the N2 NA subtype) was stable in the clade 2.2 H5N1 virus background and induced cross-resistance to oseltamivir carboxylate and zanamivir. We demonstrated that Y252H NA mutation contributed for decreased susceptibility of clade 2.2 H5N1 viruses to oseltamivir carboxylate as compared to clade 1 viruses. The enzyme kinetic parameters (V(max), K(m) and K(i)) of the avian-like N1 NA glycoproteins were highly consistent with their IC(50) values. None of the recombinant H5N1 viruses had attenuated virulence in ferrets inoculated with 10(6) EID(50) dose. Most infected ferrets showed mild clinical disease signs that differed in duration. However, H5N1 viruses carrying the E119A or the N294S NA mutation were lethal to 1 of 3 inoculated animals and were associated with significantly higher virus titers (P<0.01) and inflammation in the lungs compared to the wild-type virus. Our results suggest that highly pathogenic H5N1 variants carrying mutations within the NA active site that decrease susceptibility to NA inhibitors may possess increased virulence in mammalian hosts compared to drug-sensitive viruses. There is a need for novel anti-influenza drugs that target different virus/host factors and can limit the emergence of resistance.

Rapid detection of influenza A neuraminidase subtypes by cDNA amplification coupled to a simple DNA enzyme immunoassay

A newly developed colorimetric method, DNA enzyme immunoassay (DEIA), was applied to the detection of neuraminidase subtypes N1 and N2 of influenza A viruses. Reverse transcription and polymerase chain reaction with universal primers were used for genomic amplification of H1N1, H2N2, and H3N2 strains. Following amplification, an aliquot of the PCR product was hybridized to biotinylated DNA sequences (N1/N2 probes) immobilized on microtiter wells. The hybridization event was revealed by monoclonal antibodies to double stranded DNA in a standard ELISA reaction. The assay described here was able to distinguish accurately between the two neuraminidase subtypes of human influenza A viruses. It is a simple and rapid method facilitating the handling of a large number of samples and therefore seems to be easily applicable to diagnostic laboratories.

Three-dimensional structure of the neuraminidase of influenza virus A/Tokyo/3/67 at 2.2 A resolution

An atomic model of the tetrameric surface glycoprotein neuraminidase of influenza virus A/Tokyo/3/67 has been built and refined based on X-ray diffraction data at 2.2 A resolution. The crystallographic residual is 0.21 for data between 6 and 2.2 A resolution and the r.m.s. deviations from ideal geometry are 0.02 A for bond lengths and 3.9 degrees for bond angles. The model includes amino acid residues 83 to 469, four oligosaccharide structures N-linked at asparagine residues 86, 146, 200 and 234, a single putative Ca2+ ion site, and 85 water molecules. One of the oligosaccharides participates in a novel crystal contact. The folding pattern is a beta-sheet propeller as described earlier and details of the intramolecular interactions between the six beta-sheets are presented. Strain-invariant residues are clustered around the propeller axis on the upper surface of the molecule where they line the wall of a cavity into which sialic has been observed to bind. Strain-variable residues implicated in binding to antibodies surround this site.

Detection and identification of human influenza viruses by the polymerase chain reaction

A series of oligonucleotide primers are described which hybridize to conserved regions of influenza virus cDNA and prime DNA synthesis in Taq polymerase catalyzed amplification reactions (PCR). Primers were designed to hybridize as nested pairs and, following a two-step amplification, produce uniquely sized DNA fragments diagnostic for viral type and subtype. Influenza A and B matrix-protein genes and the influenza C haemagglutinin gene were targets for the type-specific primers. Subtype-specific primers targeted conserved sequences within the three haemagglutinin or two neuraminidase subtypes of different human influenza isolates. The utility of this method was demonstrated using computer search methods and by accurately amplifying DNA from a variety of influenza A, B, and C strains. Type-specific primer sets showed a broad type specificity and amplified DNA from viral strains of unknown sequence. Restriction mapping and DNA sequencing showed that fragments amplified in this manner derived from the input template, confirming the accuracy of the method and demonstrating how PCR can be used to quickly derive sufficient sequence information for analysis of viral relatedness. Subtyping primers were able to distinguish accurately between the three haemagglutinin (H1, H2, H3) and two neuraminidase (N1, N2) alleles of human influenza A isolates. Again DNA was amplified from viruses of unknown sequence confirming that most of these primer sets may prove useful as broad range subtyping reagents. In order to simplify the work associated with analysis of many samples, we have also devised a rapid method for the isolation of viral RNA and synthesis of cDNA. Using this 'mini-prep' technique, it is possible to detect, amplify, and identify picogram quantities of influenza virus in a single day, confirming that PCR provides a useful alternative to existing methods of influenza detection.

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%.

Molecular cloning and analysis of the N5 neuraminidase subtype from an avian influenza virus

The neuraminidase (NA) gene from the prototype N5 influenza virus, A/Shearwater/Australia/72, has been cloned and completely sequenced. An open reading frame of 1404 bp (468 amino acids) is flanked by 20-bp 5'- and 31-bp 3'-untranslated regions. The deduced amino acid sequence of the N5 gene was compared with sequences from N2, N1, N7, N8, and N9 subtypes. One hundred thirteen amino acid residues (24%) are completely conserved across subtypes and include active site residues, cysteines, potential glycosylation sites, and certain glycines which suggests that these subtypes share a common ancestor and adopt the same 3-D conformation. Three groups can be assigned from amino acid homologies: (i) N5, N8, N1; (ii) N7, N9; and (iii) N2 where the percentage identity within groups is 55-68% and between groups is 40-46%, the N5-N8 pair bearing the closest identity (68%). Phylogenetic analysis suggests that these groups diverged concurrently.

On the tertiary structure of the extracellular domains of the epidermal growth factor and insulin receptors

Alignment of the sequences, the identification of conserved residue patterns and secondary structure predictions indicate that the extra-cellular regions of the human and Drosophila epidermal growth factor (EGF), c-erb-B2 and human insulin receptors each contain two large, homologous domains (L) which are probably comprised of at least four short alpha-helices followed by turns of conserved length and beta-strands. In the human and Drosophila EGF and c-erb-B2 receptors these homologous domains are each followed by a series of smaller cystine-rich domains (S) to give a gene-duplicated structure of L1S11S12S13L2S21S22S23. In the human insulin receptor, the second series of cystine domains is replaced by a different sequence. These duplicated structures are probably organised as a pseudo-symmetrical dimer. There are two 'hyper-variable' regions, one at the end of the large domains and one in the cystine-rich sequences, which are candidates for hormone or growth-factor binding.

Heterogeneity of neuraminidase genetic information in an H1N2 reassortant influenza virus [X-7 (F1)]. Brief report

cDNA clones of the neuraminidase gene from the reassortant influenza virus X-7 (F 1) have different sequences. Some clones are more closely related to A/Tokyo/67 neuraminidase than to the A/RI/5+/57 NA gene from which the NA of X-7 (F 1) was derived.

Molecular analyses of the hemagglutinin genes of H5 influenza viruses: origin of a virulent turkey strain

Comparative sequence analysis of the hemagglutinin (HA) genes of a highly virulent H5N8 virus isolated from turkeys in Ireland in 1983 and a virus of the same subtype detected simultaneously in healthy ducks showed only four amino acid differences between these strains. Partial sequencing of six of the other genes and antigenic similarity of the neuraminidases established the overall genetic similarity of these two viruses. Comparison of the complete sequence of two H5 gene sequences and partial sequences of other virulent and avirulent H5 viruses provides evidence for at least two different lineages of H5 influenza virus in the world, one in Europe and the other in North America, with virulent and avirulent members in each group. In vivo studies in domestic ducks showed that all of the H5 viruses that are virulent in chickens and turkeys replicate in the internal organs of ducks but did not produce any disease signs. Additionally, both viruses isolated from turkeys and ducks in Ireland were detected in the blood. These studies provide the first conclusive evidence for the possibility that fully virulent influenza viruses in domestic poultry can arise directly from viruses in wild aquatic birds. Studies on the cleavability of the HA of virulent and avirulent H5 viruses showed that the principles established for H7 viruses (F. X. Bosch, M. Orlich, H. D. Klenk, and R. Rott, 1979, Virology 95, 197-207; F. X. Bosch, W. Garten, H. D. Klenk, and R. Rott, 1981, Virology 113, 725-735) also apply to the H5 subtype. These are (1) only the HAs of virulent influenza viruses were cleaved in tissue culture in the absence of trypsin and (2) virulent H5 influenza viruses contain a series of basic amino acids at the cleavage site of the HA, whereas avirulent strains contain only a single arginine with the exception of the avirulent Chicken/Pennsylvania virus. Thus, a series of basic amino acids at the cleavage site probably forms a recognition site for the enzyme(s) responsible for cleavage.

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.

Identification of defects in the neuraminidase gene of four temperature-sensitive mutants of A/WSN/33 influenza virus

Four influenza (A/WSN/33) mutants, temperature sensitive (ts) for neuraminidase (NA) (Sugiura et al., 1972, 1975) were analyzed. All four ts mutants were found to be defective at the nonpermissive temperature (39.5 degrees) both in enzymatic activity and in transport to the cell surface. Upon shift down to the permissive temperature (33 degrees), enzymatic activity and transport to the cell surface were both restored suggesting that the mutational defect is reversible. Comparative sequence analysis of the NA gene from ts mutants, their revertants and wild type WSN viruses revealed that in each case single point mutations causing amino acid substitutions were associated with the ts defect. The positions of each point mutation when mapped in the three-dimensional structure of NA varied. However, all four amino acid substitutions were located in beta-sheet strands of the head region. Several other amino acid changes not essential for the ts phenotype were found in each mutant NA. The nonessential changes were localized either in the stalk region or in the loop structures of the head, but none in the beta-sheet strands. Because both enzymatic activity and transport of NA were affected in all four mutants, we propose that the mutational phenotype is caused by a change in overall conformation rather than a localized change in the sialic acid binding site.

Examination of folding patterns for predicting protein topologies

From the prediction of protein secondary structures, formation energies may be estimated for each incipient nucleus of the folding process. The averaging which may be performed on large families of distantly related proteins improves the accuracy of measurement of these energies and the efficiency of the prediction of the different steps involved in the protein folding (secondary structures, domain boundaries, topologies, etc.) and allows the description of new folding patterns.

The neuraminidases of the virulent and avirulent A/Chicken/Pennsylvania/83 (H5N2) influenza A viruses: sequence and antigenic analyses

To define the sequence changes that occurred in an avian influenza virus neuraminidase (NA) during the evolution of virulence, we have studied the NA of the virulent and avirulent A/Chick/Penn/83 (H5N2) influenza viruses. A comparison of the deduced amino acid sequence from these viruses shows that the virulent strain, which evolved from the avirulent by the accumulation of point mutations (Bean et al., 1985), acquired four amino acid changes in the NA: one in the transmembrane segment, one in the stalk, and two in the head. A comparison of the deduced amino acid sequences with those of the human N2 NAs indicates a 20-amino acid deletion in the stalk of the Chick/Penn/83 NA. Antigenic analysis of the NAs from the avirulent and virulent Chick/Penn/83 virus shows they are antigenically very closely related, but can be distinguished with two monoclonal antibodies at a site which probably involves at least one of the amino acid changes in the NA head. Antigenic analysis also shows the Chick/Penn/83 NAs are closely related to the NAs of other N2 avian influenza viruses isolated between 1965 and 1984, supporting previous studies which indicate a relative antigenic stability of the NA among avian N2 influenza viruses. The Chick/Penn/83 NAs are the first N2 NA genes of an avian virus to be sequenced. These NAs are antigenically closely related to the 1957 human N2 NAs, and show a high degree of amino acid sequence homology with the prototype 1957 human N2 NA. These data give further support to the view that the 1957 human H2N2 viruses were at least partially derived from an avian source.

Location of antigenic sites on the three-dimensional structure of the influenza N2 virus neuraminidase

Sequence analysis of the neuraminidase (NA) genes of influenza virus X-7(F1) and of 12 variants selected with monoclonal antibodies has been used to define in physical terms the antigenic structure of this NA, which was operationally established by R. G. Webster, L. E. Brown, and W. G. Laver (1984, Virology 135, 30-42). X-7(F1) is a reassortant virus containing the NA of the early Asian (H2N2) isolate A/RI/5+/57, and the results of antigenic and sequence analysis of X-7(F1) and of variants selected with monoclonal antibodies have been combined with a similar analysis of the A/Tokyo/3/67 NA (H2N2, M. R. Lentz, G. M. Air, W. G. Laver, and R. G. Webster (1984), Virology 135, 257-265) to obtain a model of antibody binding to N2 NAs. The selection process was biased, however, since only those monoclonal antibodies which inhibited NA activity could be used to select variants. Most of the changes in the variants selected with monoclonal antibodies occur in those parts of the polypeptide chain which encircle the enzyme active site pocket in the three-dimensional structure (P. M. Colman, J. N. Varghese, and W. G. Laver (1983), Nature (London) 303, 41-44). The results suggest that in general the antibody binds to a site on the NA which includes those amino acid side chains which are altered in monoclonal variants. There are, however, several aspects of the antigen-antibody interaction which are not easily explained, and which will probably only be fully elucidated by X-ray crystallographic analysis of NA-antibody complexes.

Sequence of the neuraminidase gene of an avian influenza A virus (A/parrot/ulster/73, H7N1)

The complete sequence of the neuraminidase (NA) gene of the influenza A strain A/parrot/ Ulster /73 ( H7N1 ) has been determined after reverse transcribing and cloning it into the pBR322 plasmid, followed by subcloning into M13 vectors and sequencing with dideoxynucleotide chain terminators. The gene consists of 1458 nucleotides and codes for a protein of 469 amino acids. The neuraminidase has seven potential glycosylation sites. According to the molecular weight as determined by electrophoretic migration in polyacrylamide gel all of these sites might carry a carbohydrate side chain. When the parrot Ulster NA was compared with two other N1 neuraminidases, those of the human PR8 and WSN strains, deletions in the stalk region of 15 amino acids for PR8 NA and of 16 amino acids for WSN NA were apparent. No further rearrangements were found within N1 neuraminidases. Although the parrot Ulster strain was isolated 40 years after the two human strains, the base sequence homology of their NA genes is still 83 or 82%, respectively.

Nucleotide sequence of the influenza virus A/USSR/90/77 neuraminidase gene

The complete nucleotide sequence of the N1 neuraminidase gene of influenza virus A/USSR/90/77 was determined. Comparison of its predicted amino acid sequence with other N1 and N2 neuraminidases indicates that the N1 neuraminidases share most of the antigenic determinants mapped on the N2 neuraminidase but display at least one additional potentially antigenic region probably as a result of intersubtypic differences in glycosylation.

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).

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.

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.

Structure of the influenza virus glycoprotein antigen neuraminidase at 2.9 A resolution

The influenza virus neuraminidase glycoprotein is a tetramer with a box-shaped head, 100 X 100 X 60 A, attached to a slender stalk. The three-dimensional structure of neuraminidase heads shows that each monomer is composed of six topologically identical beta-sheets arranged in a propeller formation. The tetrameric enzyme has circular 4-fold symmetry stabilized in part by metal ions bound on the symmetry axis. Sugar residues are attached to four of the five potential glycosylation sequences, and in one case contribute to the interaction between subunits in the tetramer.

Structure of the catalytic and antigenic sites in influenza virus neuraminidase

The catalytic sites of influenza virus neuraminidase are located on the upper corners of the box-shaped tetramer that forms the head of the molecule. Antigenic determinants form a nearly-continuous surface across the top of the monomer encircling the catalytic site. Approximately the same number of amino acid sequence changes occurred in these determinants between the years 1968 and 1975 as occurred in the antigenic sites of influenza virus haemagglutinin in the same period.

Chemical and antigenic characterization of the carbohydrate side chains of an Asian (N2) influenza virus neuraminidase

The Pronase-released neuraminidase heads from the Asian influenza virus A/Tokyo/3/67 contain four oligosaccharide units attached at asparagine residues 86, 146, 200, and 234. Chemical analysis of the isolated tryptic, chymotryptic, or thermolytic glycopeptides shows that the oligosaccharide side chains attached at residues 86 and 200 are essentially of the oligomannoside (simple or Type II) variety containing two residues of N-acetylglucosamine, five residues of mannose, and less than molar ratios of galactose and fucose. The carbohydrate side chains attached at residues 146 and 234 are of the N-acetyllactosamine (complex or Type I) type and contain N-acetylglucosamine, mannose, galactose, and fucose. The complex oligosaccharide unit at residue 146 is unusual in that it also contains N-acetylgalactosamine, a sugar residue rarely found in N-glycosidically linked carbohydrates. Antigenic analysis of these four isolated glycopeptides showed that only the N-acetyllactosamine oligosaccharide unit at asparagine residue 146 was capable of binding to antibodies raised against uninfected chick chorioallantoic membranes and is hence antigenically related to chick embryo host antigen.

The disulphide bonds of an Asian influenza virus neuraminidase

The arrangement of the disulphide bonds in the pronase-released neuraminidase heads of the Asian influenza virus A/Tokyo/3/67 have been examined by cyanogen bromide fragmentation, enzymic digestion and diagonal peptide mapping. There are 9 intrachain disulphide bridges and one interchain bridge which links pairs of monomers at the distal end of the stalk region of the neuraminidase tetramer. The disulphide bond arrangements of the remaining 3 half-cystine residues in the membrane-embedded stalk region of the neuraminidase were not examined.