B.K. virus haemagglutinin.

Among the widely applied buffered media, the HSAG (hepes-salt-albumin-gelatin) medium at pH 5.75--6.25 was found to be the most favourable for B.K. virus haemagglutinin titration. The optimum temperature was at 4 degrees C. The haemagglutinin was not affected by temperatures up to 37 degrees C, pHs between 5.5 and 9.5, and NaCl concentrations between 0.063 M and 2.56 M. When incubated at 56 degrees C, the haemagglutinin shows a time and pH dependent decline in titre. No significant time dependent titre fall occurred at 56 degrees C if NaCl molarity was varied between 1.31 and 2.56.     

Structure and stability of Ricinus communis haemagglutinin.

The molecular properties of the haemagglutinin of Ricinus communis (RCA I or RCA 120) were evaluated by analytical ultracentrifugation, light-scattering, c.d. and fluorescence. The native molecule had a fairly expanded structure (f/f0 = 1.43) and dissociated into two subunits of equal size in 6 M-guanidinium chloride. This native structure was stable in alkali (up to pH 11) and resistant to thermal denaturation at neutrality. A pH-triggered change in the haemagglutinin conformation was observed and characterized by analytical ultracentrifugation, c.d. and fluorescence between pH 7 and 4.5, the range in which its affinity for galactosides decreased [Yamasaki, Absar & Funatsu (1985) Biochim, Biophys. Acta 828, 155-161]. These results are discussed in relation to those reported in the literature for other lectins and more especially ricin, for which a pH-dependent conformation transition has been observed in the same range of low pH.     

Boar seminal zinc-precipitable protein and the haemagglutinin.

About 30% of boar seminal plasma nitrogen is maximally precipitated at room temperature by 6 to 10 mM zinc in citrate solution at pH 8. A rise in the total nitrogen precipitated by 1 to 6 mM zinc is accompanied by a fall in the haemagglutinin titre of the supernatant fluid. At 6 mM zinc addition, 95% of the haemagglutinin is precipitated, but much of this is recoverable by re-solution of the zinc precipitate. Protein profile studies by gel-filtration chromatography of the zinc precipitate solution reveals a mixture of proteins, some of which are not by themselves zinc-precipitable.     

Specific structural alteration of the influenza haemagglutinin by amantadine.

Amantadine hydrochloride specifically blocks the release of virus particles from H7 influenza virus infected cells. This appears to be the direct consequence of an amantadine induced change in the haemagglutinin (HA) to its low pH conformation. The effect is indirect and mediated via interaction of the drug with the M2 protein since mutants altered in this component alone are insensitive to amantadine. The timing of drug action, some 15-20 min after synthesis, and its coincidence with proteolytic cleavage indicates that the modifications to HA occur late during transport but prior to insertion into the plasma membrane. Reversal by mM concentrations of amines and 0.1 microM monensin indicates that amantadine action causes a reduction in intravesicular pH which triggers the conformational change in HA. We conclude, therefore, that the function of M2 inhibited by amantadine is involved in counteracting the acidity of vesicular compartments of the exocytic pathway in infected cells and is important in protecting the structural integrity of the acid-sensitive glycoprotein.     

An overview of influenza haemagglutinin and neuraminidase

This is an overview of the structures of influenza virus haemagglutinin and neuraminidase membrane glycoproteins with particular reference to antibody recognition and antigenic variation.     

Location of haemagglutinin in bacterial cells of Fusobacterium necrophorum subsp. necrophorum.

The location of haemagglutinin (HA) of Fusobacterium necrophorum subsp. necrophorum VPI 2891 strain was investigated by immunofluorescence, confocal laser scan microscopy and immunoelectron microscopy. The immunofluorescence study demonstrated the fluorescence specific for the HA on the bacterial cells and confocal laser scan microscopy indicated similar fluorescence around the cross section of the bacterial cell. The immunoelectron microscopic study also revealed that the protein A-gold conjugates were located around the bacterial surfaces. These findings suggest that HA is one of the components of the cell surfaces of F. necrophorum subsp, necrophorum.     

Characterization of the Renibacterium salmoninarum haemagglutinin

Water-extracted proteins from nine geographically diverse strains of Renibacterium salmoninarum, all of which agglutinated rabbit erythrocytes and rainbow trout spermatozoa, were compared by SDS-PAGE. Extracts from eight strains, including the type strain, ATCC 33209, were similar, containing a major protein of 57 kDa and a minor protein of 58 kDa. The SDS-PAGE protein profile of the Char strain did not contain the 58 kDa protein. A non-agglutinating strain, MT-239, which was also non-hydrophobic, did not produce any water-extractable protein. Immunoblot reactions with rabbit antiserum prepared against whole cells of the type strain demonstrated that the water-extracted haemagglutinins from the various strains were antigenically related. When purified by polyacrylamide gel zone electrophoresis, the haemagglutinin from R. salmoninarum ATCC 33209 formed a doublet band with molecular masses of 57 and 58 kDa, similar to the previously described F antigen. The water-extracted haemagglutinin agglutinated salmonid spermatozoa, was degraded by protease K and trypsin, and was shown to self-assemble onto the cell surface.     

Immune recognition of influenza virus haemagglutinin

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

Electron microscopy of the low pH structure of influenza virus haemagglutinin.

Influenza virus haemagglutinin mediates infection of cells by fusion of viral and endosomal membranes, triggered by low pH which induces a conformational change in the protein. We report studies of this change by electron microscopy, neutron scattering, sedimentation and photon correlation on X-31 (H3N2) haemagglutinin, both intact and bromelain cleaved, in various assemblies. HAs in all preparations showed a thinning at low pH, and a marked elongation which was removed on tryptic digestion, revealing altered features in the remaining stem portion of the molecule. A tentative model of the change is proposed, with reference to the known X-ray structure at neutral pH, in which major changes occur in the stem tertiary structure, while the top portion is only affected in its quaternary structure.     

Purification of haemagglutinin and neuraminidase from influenza virus strain 3QB and isolation of a peptide from an antigenic region of haemagglutinin

Methods were developed for the purification of the surface, membrane-bound glycoproteins haemagglutinin and neuraminidase of influenza virus strain 3QB, in antigenically active forms. The methods employed in the purification included selective removal of the neuraminidase with the proteinase, bromelain, and subsequent disruption of the residual virus particle with the detergent Sarkosyl to release the haemagglutinin. Using techniques for proteolytic digestion of intact, native proteins an antigenically active peptide was isolated from the purified haemagglutinin, the surface glycoprotein against which the major antigenic response is directed. The amino acid composition of this peptide was determined. This was a 16-residue peptide with amino-terminal isoleucine and composition Ile1 Val1 Asx2 Thr1 Ser2 Glx2 Pro1 Gly3 Ala1 Leu1 Lys1.     

Cloning and sequence analysis of theMaackia amurensis haemagglutinin cDNA

Maackia amurensis haemagglutinin (MAH) is a leguminous lectin which preferentially binds to a cluster of sialylatedO-linked carbohydrate chains (Konami Y, Yamamoto K, Osawa T, Irimura T (1994)FEBS Lett 342:334–38). In the present study a 950 bp cDNA clone encoding MAH was isolated from a cDNA library constructed from germinatedMaackia amurensis seeds. From the nucleotide sequence, MAH was predicted to consist of 285 amino acid residues containing a signal peptide of 29 amino acids. The results also confirmed our previous findings from the amino acid sequence analysis, which indicated that two highly conserved amino acid residues in all other well-known leguminous lectins were replaced in MAH. These residues were lysine-105 and aspartic acid-135. The corresponding amino acid residues in other leguminous lectins were glycine and asparagine, respectively. These differences were due to the presence of nucleotides AAA and GAT in place of AAT/C and GGA/T.Abbreviations MAH Maackia amurensis haemagglutinin.     

A new mannose-resistant haemagglutinin in Klebsiella

Strains of Klebsiella of the species (or 'patho-bio-sero-geogroups') Kl. atlantae, Kl. edwardsii and Kl. rhinoscleromatis produced neither haemagglutinins (HAs) nor fimbriae; strains of Kl. ozaenae were HA- but some produced type-6 fimbriae; and strains of Kl. pneumoniae (sensu stricto) and Kl. aerogenes that produced the mannose-sensitive HA (MS-HA) formed type-1 fimbriae. Most strains of Kl. aerogenes produced, in addition, one or both of the mannose-resistant HAs, MR/K-HA or MR/P-HA. The former, associated with type-3 fimbriae, was produced by 95%, and the latter by 57%, of the Kl. aerogenes strains. Some of the properties of the MR/P-HA, apparently a non-fimbrial HA not previously recognised in Klebsiella, are described.     

A new mannose-resistant haemagglutinin in Klebsiella

Strains of Klebsiella of the species (or 'patho-bio-sero-geogroups') Kl. atlantae, Kl. edwardsii and Kl. rhinoscleromatis produced neither haemagglutinins (HAs) nor fimbriae; strains of Kl. ozaenae were HA^- but some produced type-6 fimbriae; and strains of Kl. pneumoniae ( sensu stricto ) and Kl. aerogenes that produced the mannose-sensitive HA (MS-HA) formed type-1 fimbriae. Most strains of Kl. aerogenes produced, in addition, one or both of the mannose-resistant HAs, MR/K-HA or MR/P-HA. The former, associated with type-3 fimbriae, was produced by 95%, and the latter by 57%, of the Kl. aerogenes strains. Some of the properties of the MR/P-HA, apparently a non-fimbrial HA not previously recognised in Klebsiella , are described.     

The influenza virus haemagglutinin gene: cloning and characterisation of a double-stranded DNA copy.

A protocol has been developed for the synthesis of a double-stranded DNA (dsDNA) copy of the influenza virus RNA genome segment which codes for the major surface antigen, haemagglutinin (HA). This dsDNA copy was inserted, after digestion with S1 nuclease and poly (dC) tailing with terminal transferase, into poly(dG)-tailed, PstI-cut, pBR322 DNA, and used to transform E. coli RR1. Tetracycline-resistant bacterial colonies were screened for the presence of plasmid containing the copied HA gene by testing their ability to hybridise to a specific, 32P-labelled, single-stranded DNA probe. Four cloned hybrid plasmids, containing DNA complementary to the HA gene of the influenza strain 29C (a laboratory derivative of influenza A/NT/60/68 (1)) were analysed by restriction enzyme mapping. Each contained a dsDNA insert equivalent to a full length copy of the HA gene. The nucleotide sequence of a selected restriction fragment from the DNA inserted in one of these cloned plasmids (C89) was determined. The amino acid sequence deduced from these data agreed with the amino acid sequence determined for the corresponding region of HA from the influenza strain A/Mem/102/72, another member of the Hong Kong subtype, identifying the inserted dsDNA of C89 as an authentic copy of the influenza HA gene.     

Studies on the structure of the haemagglutinin

The biosynthesis of the haemagglutinin glycoproteins of infectious influenza virus particles involves proteolytic cleavage of the primary translation products and the amino acid sequences at the two sites of processing are presented. In addition, details of the primary structure of the haemagglutinin of A/Japan/305/57 (H2N1) are reported and compared with information available for haemagglutinins of other subtypes.     

Immune receptor repertoire for influenza haemagglutinin

An extensive analysis was made of receptor specificity and gene usage in the neutralising antibody (mAb) and Class II-restricted T cell responses to influenza haemagglutinin (HA) following natural infection of MHC (H-2^k or H-2^d) congenic mice with X31 virus (H3N2 subtype). Despite the diversity of available antigenic sites on the HA1 subunit, there was strikingimmunodominance in the mAb response as deduced by sequencing the HA genes of escape mutants and the corresponding antibody H and L chain gene rearrangements. Similarly, Class II restricted T cell responses of individual donors focused on a single antigenic site, or immunodominant peptide; and PCR sequence analysis of T cell receptor () gene usage indicated that T cell memory was derived from asingle progenitor cell. Focusing of the immune repertoire to limited regions of the HA molecule during a primary viral infection may be a significant factor in immune pressure for antigenic variation.     

The structure of a membrane fusion mutant of the influenza virus haemagglutinin.

The haemagglutinin glycoprotein (HA) of influenza virus specifically mediates fusion of the viral and host cell endosomal membranes at the acidic pH of endosomes. The HAs from mutant viruses with raised fusion pH optima contain amino acid substitutions in regions of the HA structure thought to be involved in the fusion process [Daniels et al. (1985b) Cell, 40, 431-439]. We have determined the neutral pH crystal structure of one such mutant, HA2 112 Asp----Gly. A water molecule appears to partially replace the aspartate side chain, and no changes are observed in the surrounding structure. It appears that four intra-chain hydrogen bonds that stabilize the location of the N-terminus of HA2 are lost in the mutant, resulting in a local destabilization that facilitates the extrusion of the N-terminus at higher pH.     

Cell surface influenza haemagglutinin can mediate infection by other animal viruses.

We have used filter-grown Madin-Darby canine kidney (MDCK) cells to explore the mechanism by which influenza virus facilitates secondary virus infection. Vesicular stomatitis virus (VSV) and Semliki Forest virus (SFV) infect only through the basolateral surface of these polarized epithelial cells and not through the apical surface. Prior infection with influenza virus rendered the cell susceptible to infection by VSV or SFV through either surface. The presence of both a permissive and a restrictive surface for virus entry in the same cell allowed us to determine how the influenza infection enhanced the subsequent infection of a second virus. Biochemical and morphological evidence showed that influenza haemagglutinin on the apical surface serves as a receptor for the superinfecting virus by binding to its sialic acid-bearing envelope proteins. Influenza virus also facilitates secondary virus infection in non-epithelial cells; baby hamster kidney cells (BHK-21), which are normally resistant to infection by the coronavirus (mouse hepatitis virus MHV-A59), could be infected via the haemagglutinin-sialic acid interaction. Facilitation of secondary virus infection requires only the sialic acid-binding properties of the haemagglutinin since the uncleaved haemagglutinin could also mediate virus entry.