Although some viruses, particularly the herpes viruses, may never be eliminated from the body, others like influenza A, regularly reinfect humans and boost waning crossreactive CD8+ T-cell immunity. Prolonged T-cell memory is found for viruses that are unlikely to be re-encountered and which do not persist in the host genome, indicating that CD8+ T-cell memory might be independent of continued (or sporadic) antigenic exposure. A feature of virus-specific CD8+ T-cell memory is that antigen-specific cytotoxic T-lymphocyte precursors (CTLp) are greatly increased and remain high throughout life. The idea that persistence of the inducing antigen is essential is based on experiments in which adoptively transferred CD8+ memory T cells could not be detected for more than a few weeks in naive recipient mice without secondary challenge. Here we show that restimulation of such chimaeric mice with an inducing Sendai virus antigen increases the clonal burst size more than 7-fold within 8 days, making memory CTLp easier to detect in the longer term. We find that Sendai-virus-specific CTLp are maintained for > 250 days in irradiated uninfected recipients, including reconstituted beta 2-microglobulin-/- mice. To determine whether a source of viral peptide can persist after primary infection, we gave Sendai-virus-specific Thy1.1+ memory spleen cells to naive mice that had been minimally depleted of Thy1.2+ T cells, or to comparable recipients that had recovered from infection with Sendai virus or influenza virus. Although antibody against Sendai virus was never found in the naive recipients, Sendai-virus-specific CD8+ memory T cells were maintained equally well in each case for > 100 days after cell transfer. We find no evidence for persisting depots of viral protein that might feed into the endogenous processing pathway and maintain virus-specific CD8+ T-cell memory.
Paramyxoviruses are the leading cause of respiratory disease in children. Several paramyxoviruses possess a surface glycoprotein, the hemagglutinin-neuraminidase (HN), that is involved in attachment to sialic acid receptors, promotion of fusion, and removal of sialic acid from infected cells and progeny virions. Previously we showed that Newcastle disease virus (NDV) HN contained a pliable sialic acid recognition site that could take two states, a binding state and a catalytic state. Here we present evidence for a second sialic acid binding site at the dimer interface of HN and present a model for its involvement in cell fusion. Three different crystal forms of NDV HN now reveal identical tetrameric arrangements of HN monomers, perhaps indicative of the tetramer association found on the viral surface.
Paramyxovirus infects cells by initially attaching to a sialic acid-containing cellular receptor and subsequently fusing with the plasma membrane of the cells. Hemagglutinin-neuraminidase (HN) protein, which is responsible for virus attachment, interacts with the fusion protein in a virus type-specific manner to induce efficient membrane fusion. To elucidate the mechanism of HN-promoted membrane fusion, we characterized a series of Newcastle disease virus HN proteins whose surface residues were mutated. Fusion promotion activity was substantially altered in only the HN proteins with a mutation in the first or sixth  sheet. These regions overlap the large hydrophobic surface of HN; thus, the hydrophobic surface may contain the fusion promotion domain. Furthermore, a comparison of the HN structure crystallized alone or in complex with 2-deoxy-2,3-dehydro-N-acetylneuraminic acid revealed substantial conformational changes in several loops within or near the hydrophobic surface. Our results suggest that the binding of HN protein to the receptor induces the conformational change of residues near the hydrophobic surface of HN protein and that this change triggers the activation of the F protein, which initiates membrane fusion.
We recently reported the first crystal structure of a paramyxovirus hemagglutinin-neuraminidase (HN) from Newcastle disease virus. This multifunctional protein is responsible for binding to cellular sialyl-glycoconjugate receptors, promotion of fusion through interaction with the second viral surface fusion (F) glycoprotein, and processing progeny virions by removal of sialic acid from newly synthesized viral coat proteins. Our structural studies suggest that HN possesses a single sialic acid recognition site that can be switched between being a binding site and a catalytic site. Here we examine the effect of mutation of several conserved amino acids around the binding site on the hemagglutination, neuraminidase, and fusion functions of HN. Most mutations around the binding site result in loss of neuraminidase activity, whereas the effect on receptor binding is more variable. Residues E401, R416, and Y526 appear to be key for receptor binding. The increase in fusion promotion seen in some mutants that lack receptor binding activity presents a conundrum. We propose that in these cases HN may be switched into a fusion-promoting state through a series of conformational changes that propagate from the sialic acid binding site through to the HN dimer interface. These results further support the single-site model and suggest certain residues to be important for the triggering of fusion.Viruses belonging to the family Paramyxoviridae are major causative agents for respiratory illnesses in humans, particularly in children. Members of the Paramyxovirinae subfamily include the human parainfluenza viruses (PIVs), mumps viruses, Newcastle disease virus (NDV), Sendai virus, and simian virus 5. Infection of host cells by paramyxoviruses is accomplished by the interaction of two surface glycoproteins, hemagglutinin-neuraminidase (HN) and the fusion (F) protein. HN possesses both the receptor recognition of sialic acid at the termini of host glycoconjugates and neuraminidase activity to hydrolyze sialic acid from progeny virion particles to prevent viral self-aggregation (14,23,24). In addition to these activities, HN has been shown to promote fusion through its interaction with the F protein, which involves residues from the stalk and the globular head region of HN (1,2,8,26,31,34), thereby allowing the entry of viral RNA.Recently, we determined the first crystal structure of the globular head region of the Newcastle disease virus HN (6). HN displays the six-bladed -propeller fold typical of other sialidases/neuraminidases, whose structures are known (5, 7, 9, 35). Two crystal forms of the dimeric HN molecule were determined: a pH 6.5 hexagonal crystal form that would only grow in the presence of the inhibitor 2-deoxy-2,3-dehydro-Nacetyl-neuraminic acid (Neu5Ac2en) and a pH 4.6 orthorhombic crystal form grown in the absence of ligand but into which ligands could be soaked. The association of monomers in these two forms is very different, suggesting a flexible interface between the monomers that may have functional significanc...
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