Mechanism of antigenic variation in an individual epitope on influenza virus N9 neuraminidase.

Monoclonal antibodies which inhibit influenza virus neuraminidase (NA) and which therefore indirectly neutralize virus infectivity bind to epitopes located on the rim of the active-site crater. The three-dimensional structure of one of these epitopes, recognized by monoclonal antibody NC41, has previously been determined (W. R. Tulip, J. N. Varghese, R. G. Webster, G. M. Air, W. G. Laver, and P. M. Colman, Cold Spring Harbor Symp. Quant. Biol. 54:257-263, 1989). Nineteen escape mutants of influenza virus A/tern/Australia/G70c/75 (N9) NA selected with NC41 were sequenced. A surprising restriction was seen in the sequence changes involved. Ten mutants had a Ser-to-Phe change at amino acid 372, and six others had mutations at position 367. No escape mutants with changes at 369 or 370 were found, although these mutations were selected with other antibodies and rendered the epitope unrecognizable by antibody NC41. Another N9 NA, from A/ruddy turnstone/NJ/85, which differs by 14 amino acids from the tern virus NA, still bound antibody NC41. Epitope mapping by selecting multiple escape mutants with antibody NC41 thus identified only three of the five polypeptide loops on NA that contact the antibody. Escape mutants selected sequentially with three different monoclonal antibodies showed three sequence changes in two loops of the NC41 epitope. The multiple mutants were indistinguishable from wild-type virus by using polyclonal rabbit antiserum in double immunodiffusion tests, but NA inhibition titers were fourfold lower. The results suggest that although the NC41 epitope contains 22 amino acids, only a few of these are so critical to the interaction with antibody that a single sequence change allows selection of an escape mutant. In that case, the variety of amino acid sequence changes which can lead to polyclonal selection of new epidemic viruses during antigenic drift might be very limited.     

Three-dimensional structure of neuraminidase of subtype N9 from an avian influenza virus

Neuraminidases from different subtypes of influenza virus are characterized by the absence of serological cross-reactivity and an amino acid sequence homology of approximately 50%. The three-dimensional structure of the neuraminidase antigen of subtype N9 from an avian influenza virus (A/tern/Australia/G70c/75) has been determined by X-ray crystallography and shown to be folded similarly to neuraminidase of subtype N2 isolated from a human influenza virus. This result demonstrates that absence of immunological cross-reactivity is no measure of dissimilarity of polypeptide chain folding. Small differences in the way in which the subunits are organized around the molecular fourfold axis are observed. Insertions and deletions with respect to subtype N2 neuraminidase occur in four regions, only one of which is located within the major antigenic determinants around the enzyme active site.     

Refined atomic structures of N9 subtype influenza virus neuraminidase and escape mutants

The crystal structure of the N9 subtype neuraminidase of influenza virus was refined by simulated annealing and conventional techniques to an R-factor of 0.172 for data in the resolution range 6.0 to 2.2 A. The r.m.s. deviation from ideal values of bond lengths is 0.014 A. The structure is similar to that of N2 subtype neuraminidase both in secondary structure elements and in their connections. The three-dimensional structures of several escape mutants of neuraminidase, selected with antineuraminidase monoclonal antibodies, are also reported. In every case, structural changes associated with the point mutation are confined to the mutation site or to residues that are spatially immediately adjacent to it. The failure of antisera to cross-react between N2 and N9 subtypes may be correlated with the absence of conserved, contiguous surface structures of area 700 A2 or more.     

Sequence and structure alignment of paramyxovirus hemagglutinin-neuraminidase with influenza virus neuraminidase.

A model is proposed for the three-dimensional structure of the paramyxovirus hemagglutinin-neuraminidase (HN) protein. The model is broadly similar to the structure of the influenza virus neuraminidase and is based on the identification of invariant amino acids among HN sequences which have counterparts in the enzyme-active center of influenza virus neuraminidase. The influenza virus enzyme-active site is constructed from strain-invariant functional and framework residues, but in this model of HN, it is primarily the functional residues, i.e., those that make direct contact with the substrate sialic acid, which have identical counterparts in neuraminidase. The framework residues of the active site are different in HN and in neuraminidase and appear to be less strictly conserved within HN sequences than within neuraminidase sequences.     

Molecular modeling of sialyloligosaccharide fragments into the active site of influenza virus N9 neuraminidase

Molecular modeling studies have been carried out to investigate the interactions between substrate sialyloligosaccharide (SOS) fragments bearing different glycosidic linkages and influenza virus N9 neuraminidase, a surface glycoprotein of influenza virus subtype N9. The studies revealed that the allowed orientation for sialic acid (SA) is less than 1% in the Eulerian space at the active site. The active site of this enzyme has enough space to accommodate various SOS fragments, NeuNAcalpha(2-3)Gal, NeuNAcalpha(2-6)Gal, NeuNAcalpha(2-8)NeuNAc and NeuNAcalpha(2-9)NeuNAc, but on specific conformations. In the bound conformation, among these substrates there exists a conformational similarity leading to a structural similarity, which may be an essential requirement for the cleavage activity of the neuraminidases irrespective of the type of glycosidic linkage.     

Antigenic variation in visna virus.

Two antigenic variants of visna virus were isolated sequentially from a single sheep inoculated with a plaque-purified strain of virus designated 1514. The genetically stable variants, LV1-1 and LV1-4, are of two classes: LV1-1 is partially neutralized by antibody to the inoculum strain 1514, while LV1-4 is not neutralized by antibody to 1514. The genetic mechanism responsible for generating the antigenic variants was investigated by comparing the chymotryptic and tryptic maps of the envelope glycoprotein gp135 and core polypeptides (p30, p16, p14), and by comparing the pattern of large oligonucleotides produced by digestion of the RNAs by T1 ribonuclease. We show that only the peptide maps of gp135 differ among strains, that the number of peptide fragments altered is small and that gp135 is the polypeptide that elicits neutralizing antibody. The maps of the RNAs are identical. We conclude that mutation in the glycoprotein gene rather than recombination is more probably responsible for antigenic variation, and speculate on the special aspects of visna virus replication relevant to this phenomenon.     

Antigenic variation of influenza A virus nucleoprotein detected with monoclonal antibodies.

Monoclonal antibodies were used to study antigenic variation in the nucleoprotein of influenza A viruses. We found that the nucleoprotein molecule of the WSN/33 strain possesses at least five different determinants. Viruses of other influenza A virus subtypes showed antigenic variation in these nucleoprotein determinants, although changes in only one determinant were detected in H0N1 and animal strains. The nucleoprotein of human strains isolated from 1933 through 1979 could be divided into six groups, based on their reactivities with monoclonal antibodies; these groups did not correlate with any particular hemagglutinin or neuraminidase subtype. Our results indicate that antigenic variation in the nucleoproteins of influenza A viruses proceeds independently of changes in the viral surface antigens and suggest that point mutations and genetic reassortment may account for nucleoprotein variability.     

Refined crystal structure of the influenza virus N9 neuraminidase-NC41 Fab complex.

The crystal structure of the complex between neuraminidase from influenza virus (subtype N9 and isolated from an avian source) and the antigen-binding fragment (Fab) of monoclonal antibody NC41 has been refined by both least-squares and simulated annealing methods to an R-factor of 0.191 using 31,846 diffraction data in the resolution range 8.0 to 2.5 A. The resulting model has a root-mean-square deviation from ideal bond-length of 0.016 A. One fourth of the tetrameric complex comprises the crystallographic model, which has 6577 non-hydrogen atoms and consists of 389 protein residues and eight carbohydrate residues in the neuraminidase, 214 residues in the Fab light chain, and 221 residues in the heavy chain. One putative Ca ion buried in the neuraminidase, and 73 water molecules, are also included. A remarkable shape complementarity exists between the interacting surfaces of the antigen and the antibody, although the packing density of atoms at the interface is somewhat looser than in the interior of a protein. Similarly, there is a high degree of chemical complementarity between the antigen and antibody, mediated by one buried salt-link, two solvated salt-links and 12 hydrogen bonds. The antibody-binding site on neuraminidase is discontinuous and comprises five chain segments and 19 residues in contact, whilst 33 neuraminidase residues in eight segments have 899 A2 of surface area buried by the interaction (to a 1.7 A probe), including two hexose units. Seventeen residues in NC41 Fab lying in five of the six complementarity determining regions (CDRs) make contact with the neuraminidase and 36 antibody residues in seven segments have 916 A2 of buried surface area. The interface is more extensive than those of the three lysozyme-Fab complexes whose crystal structures have been determined, as judged by buried surface area and numbers of contact residues. There are only small differences (less than 1.5 A) between the complexed and uncomplexed neuraminidase structures and, at this resolution and accuracy, those differences are not unequivocal. The main-chain conformations of five of the CDRs follow the predicted canonical structures. The interface between the variable domains of the light and heavy chains is not as extensive as in other Fabs, due to less CDR-CDR interaction in NC41. The first CDR on the NC41 Fab light chain is positioned so that it could sterically hinder the approach of small as well as large substrates to the neuraminidase active-site pocket, suggesting a possible mechanism for the observed inhibition of enzyme activity by the antibody.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigenicity of the N8 influenza A virus neuraminidase: existence of an epitope at the subunit interface of the neuraminidase.

To locate antigenic epitopes on the N8 neuraminidase (NA), we generated a panel of 97 monoclonal antibodies (MAbs), 66 of which inhibited NA activity (NI antibodies). Three groups of NI MAbs were identified from their different reactivities with escape mutants. Group 1 antibodies recognized the peptide loop containing residues 344 to 346, which appears to be an immunodominant region on the rim of the enzyme center of the N8 NA. Group 2 antibodies recognized a novel epitope containing residues 150, 199, 367, 399, and 400 (N2 numbering). From the location of these residues on the three-dimensional structure of the N8 NA, the epitope appears to be located at the interface of two adjacent monomers in the tetrameric NA, one contributing residues 150 and 199 and the other contributing residues 367 and 399 to 400. The available evidence indicates that the MAbs of this group react with the NA only after it is fully assembled. The third group of antibodies recognized the peptide loops containing residues 367 and 399 to 400. All of the amino acid substitutions in N8 escape mutants which affect the NI activity of antibodies were located in the peptide loops known to form epitopes in the N2 and N9 subtypes, indicating that antigenic regions in the NA head inducing NI antibodies appear to be similar among different subtypes of influenza A viruses. The MAbs used in this study will be valuable in studying the role of each N8 NA epitope in host immune defense systems and in the kinetics analysis of the biosynthesis of the enzyme.     

Purification of neuraminidase from influenza virus on an immunosorbent

A procedure for isolation of neuraminidase from influenza virus using the nonionic detergent Triton x-100 was developed. To achieve further purification, the protein mixture was passed through a Sepharose column packed with immobilized antibodies against hemagglutinin. The neuraminidase preparation thus obtained fully retained its enzymatic and antigenic properties and during electrophoretic separation under denaturating conditions gave one protein band.     

Identification of critical contact residues in the NC41 epitope of a subtype N9 influenza virus neuraminidase

We have examined amino acids on influenza virus neuraminidase (NA) subtype N9 (A/tern/Australia/G70c/75) which are in contact with monoclonal antibody NC41 to analyze individual interactions important for antibody recognition. The crystal structure of NA complexed with NC41 Fab¹ shows antibody contacts at 19 amino acid residues on the NA surface which are localized on five polypeptide loops surrounding the enzyme active site. Fifteen mutant NA genes were constructed to encode a protein which contained a single amino acid substitution and these were tested for effects of the replacement on NC41 binding. Our data revealed that NAs with changes at 368, 400, and 434 completely lost NC41 recognition. NAs with side chains replaced at residues 346 and 373 exhibited binding reduced to less than 50% of wild-type binding. Changes in seven other contacting residues, including substituted side chains which differed considerably from wild-type NA in size and charge, had no significant effect on NC41 binding. These results indicate that only a few of the many residues which make up an epitope are crucial for interaction and provide the critical contacts required for antibody recognition. This implies that antibody escape mutants are selected only if they contain changes at these crucial sites, or changes which introduce bulky side chains that sterically prevent antibody attachment. © 1993 Wiley-Liss, Inc.     

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.     

抗体选择压作用下H9N2亚型禽流感病毒NA基因的变异

将LG1株H9N2亚型禽流感病毒在带有抗LG1株母源抗体的鸡胚中分4个独立系列连续传40代后,有3个系列从10～20代起在NA基因的#99位发生了可稳定遗传的碱基"G"到"A"的突变,并使氨基酸由蛋氨酸变为异亮氨酸;有2个系列从20～30代起在#473位发生了可稳定遗传的由"A"到"G"的碱基突变,导致相应的氨基酸由天冬酰胺变为丝氨酸,另一个传代系列在50代时也发生了同样的突变。在无抗体的鸡胚上的2个独立对照系列同样传了80代,在这2个位点没有发生突变,表明这2个突变与抗体的选择压相关。在抗LG1母源抗体阳性鸡胚的连续40代传代过程中,NA基因在有抗体组的四个传代系列碱基的非同义突变(NS)与同义突变(S)比为4.6(32/7),而在无抗体组NS/S比为2.0(16/8)。有抗体组NS/S值显著高于无抗体组,也显示出抗体的选择压作用。     

The neuraminidase of influenza virus

It is the enzyme neuraminidase, projecting from the surface of influenza virus particles, which allows the virus to leave infected cells and spread in the body. Antibodies which inhibit the enzyme limit the infection, but antigenic variation of the neuraminidase renders it ineffective in a vaccine. This article describes the crystal structure of influenza virus neuraminidase, information about the active site which may lead to development of specific and effective inhibitors of the enzyme, and the structure of epitopes (antigenic determinants) on the neuraminidase. The 3-dimensional structure of the epitopes was obtained by X-ray diffraction methods using crystals of neuraminidase complexed with monoclonal antibody Fab fragments. Escape mutants, selected by growing virus in the presence of monoclonal antibodies to the neuraminidase, possess single amino acid sequence changes. The crystal structure of two mutants showed that the change in structure was restricted to that particular sidechain, but the change in the epitope was sufficient to abolish antibody binding even though it is known in one case that 21 other amino acids on the neuraminidase are in contact with the antibody.     

Steps in maturation of influenza A virus neuraminidase.

We have studied the maturation of the influenza A virus neuraminidase (NA), using monoclonal antibodies (MAbs) with different conformational specificities against the head domains of the N8 NA. The results obtained with radioimmunoprecipitation, together with previously published information, suggest the following steps in maturation of this molecule. First, the folding of the nascent NA leads to formation of the epitope recognized by MAb N8-10, a step that depends on the formation of intramolecular disulfide bonds. Second, monomers form dimers by an intermolecular disulfide linkage in the stalk, with a t1/2 of 2.5 min. Third, the epitope recognized by MAb N8-82 appears after dimerization, suggesting that oligomeric NAs may undergo conformational change with a t1/2 of 8 min. Finally, a tetramer-specific epitope recognized by MAb N8-4 appears on the NA with a t1/2 of 13 min. Epitope detection by MAb N8-4 was inhibited by tunicamycin treatment, suggesting that glycosylation of this molecule is required for proper tetramerization. Each of these proposed steps occurs in the endoplasmic reticulum of host cells, as demonstrated by treatment of virus-infected cells with brefeldin A or carbonyl cyanide m-chlorophenylhydrazine; subsequently, tetrameric NA is transported to the Golgi apparatus, where oligosaccharide processing is completed. Our findings also provide a possible explanation--lack of a functionally active conformation--for the absence of enzymatic function by NA monomers.     

Binding affinity of influenza virus N9 neuraminidase with Fab fragments of monoclonal antibodies NC10 and NC41

Sedimentation equilibrium centrifugation has been applied to determine the affinity and stoichiometry of the interaction between Fab fragments, derived from monoclonal antibodies NC10 and NC41, with influenza virus neuraminidase N9 isolated from either tern or whale. Although the two neuraminidase epitopes recognized by NC10 and NC41 Fab overlap, crystal-lographic studies have shown that the modes of binding of each Fab are different. The sedimentation equilibrium experiments described here reveal that the binding affinities are also different, with NC10 Fab binding more strongly to each neuraminidase. Furthermore, comparison of the affinity of binding of each antibody fragment reveals a stronger interaction with tern neuraminidase than with whale neuraminidase. Although the respective epitopes recognized by each antibody on the two antigens are similar, this technique shows that they do nevertheless possess sufficient differences to affect significantly the binding of antibody.