Lipid raft microdomains are enriched in sphingomyelin and cholesterol and function as platforms for signal transduction and as the site of budding of several enveloped viruses, including influenza virus. The influenza virus hemagglutinin (HA) glycoprotein, which mediates both viral-cell attachment and membrane fusion, associates intrinsically with lipid rafts. Residues in the HA transmembrane (TM) domain are important for raft association as sequence substitutions in the HA TM domain ablate HA association with rafts (nonraft HA). Cells expressing either WT or nonraft HA cause complete fusion (lipid mixing and content mixing) over widely varying HA expression levels. However, the number of fusion events measured for nonraft HA mutant protein at all HA surface densities was reduced to Ϸ55% of the events for WT HA protein. Mutant influenza viruses were generated that contain the nonraft HA TM domain alterations. Electron microscopy experiments showed that WT HA was distributed at the cell surface in clusters of 200 -280 nm in diameter, whereas nonraft HA was distributed mostly randomly at the plasma membrane. Nonraft HA virus showed reduced budding, contained reduced amounts of HA protein, was greatly reduced in infectivity, and exhibited decreased virus-membrane fusion activity. Cholesterol depletion of virus did not affect the ability of virions to cause either virus-cell lipid mixing or virus-mediated hemolysis, a surrogate for content mixing. Taken together, the data suggest that HA clusters in rafts to provide a sufficient concentration of HA in budding virus to mediate efficient virus-cell fusion.
Peptides derived from heptad repeat regions adjacent to the fusion peptide and transmembrane domains of many viral fusion proteins form stable helical bundles and inhibit fusion specifically. Paramyxovirus SV5 fusion (F) protein‐mediated fusion and its inhibition by the peptides N‐1 and C‐1 were analyzed. The temperature dependence of fusion by F suggests that thermal energy, destabilizing proline residues and receptor binding by the hemagglutinin–neuraminidase (HN) protein collectively contribute to F activation from a metastable native state. F‐mediated fusion was reversibly arrested by low temperature or membrane‐incorporated lipids, and the resulting F intermediates were characterized. N‐1 inhibited an earlier F intermediate than C‐1. Co‐expression of HN with F lowered the temperature required to attain the N‐1‐inhibited intermediate, consistent with HN binding to its receptor stimulating a conformational change in F. C‐1 bound and inhibited an intermediate of F that could be detected until a point directly preceding membrane merger. The data are consistent with C‐1 binding a pre‐hairpin intermediate of F and with helical bundle formation being coupled directly to membrane fusion.
The influenza A virus (IAV) HA protein must be activated by host cells proteases in order to prime the molecule for fusion. Consequently, the availability of activating proteases and the susceptibility of HA to protease activity represents key factors in facilitating virus infection. As such, understanding the intricacies of HA cleavage by various proteases is necessary to derive insights into the emergence of pandemic viruses. To examine these properties, we generated a panel of HAs that are representative of the 16 HA subtypes that circulate in aquatic birds, as well as HAs representative of the subtypes that have infected the human population over the last century. We examined the susceptibility of the panel of HA proteins to trypsin, as well as human airway trypsin-like protease (HAT) and transmembrane protease, serine 2 (TMPRSS2). Additionally, we examined the pH at which these HAs mediated membrane fusion, as this property is related to the stability of the HA molecule and influences the capacity of influenza viruses to remain infectious in natural environments. Our results show that cleavage efficiency can vary significantly for individual HAs, depending on the protease, and that some HA subtypes display stringent selectivity for specific proteases as activators of fusion function. Additionally, we found that the pH of fusion varies by 0.7 pH units among the subtypes, and notably, we observed that the pH of fusion for most HAs from human isolates was lower than that observed from avian isolates of the same subtype. Overall, these data provide the first broad-spectrum analysis of cleavage-activation and membrane fusion characteristics for all of the IAV HA subtypes, and also show that there are substantial differences between the subtypes that may influence transmission among hosts and establishment in new species.
Influenza pandemics require that a virus containing a hemagglutinin (HA) surface antigen previously unseen by a majority of the population becomes airborne-transmissible between humans. Although the HA protein is central to the emergence of a pandemic influenza virus, its required molecular properties for sustained transmission between humans are poorly defined. During virus entry, the HA protein binds receptors and is triggered by low pH in the endosome to cause membrane fusion; during egress, HA contributes to virus assembly and morphology. In 2009, a swine influenza virus (pH1N1) jumped to humans and spread globally. Here we link the pandemic potential of pH1N1 to its HA acid stability, or the pH at which this one-time-use nanomachine is either triggered to cause fusion or becomes inactivated in the absence of a target membrane. In surveillance isolates, our data show HA activation pH values decreased during the evolution of H1N1 from precursors in swine (pH 5.5–6.0), to early 2009 human cases (pH 5.5), and then to later human isolates (pH 5.2–5.4). A loss-of-function pH1N1 virus with a destabilizing HA1-Y17H mutation (pH 6.0) was less pathogenic in mice and ferrets, less transmissible by contact, and no longer airborne-transmissible. A ferret-adapted revertant (HA1-H17Y/HA2-R106K) regained airborne transmissibility by stabilizing HA to an activation pH of 5.3, similar to that of human-adapted isolates from late 2009–2014. Overall, these studies reveal that a stable HA (activation pH ≤ 5.5) is necessary for pH1N1 influenza virus pathogenicity and airborne transmissibility in ferrets and is associated with pandemic potential in humans.
While the molecular mechanism of membrane fusion by the influenza virus hemagglutinin (HA) protein has been studied extensively in vitro, the role of acid-dependent HA protein activation in virus replication, pathogenesis, and transmission in vivo has not been characterized. To investigate the biological significance of the pH of activation of the HA protein, we compared the properties of four recombinant viruses with altered HA protein acid stability to those of wild-type influenza virus A/chicken/Vietnam/C58/04 (H5N1) in vitro and in mallards. Membrane fusion by wild-type virus was activated at pH 5.9. Wild-type virus had a calculated environmental persistence of 62 days and caused extensive morbidity, mortality, shedding, and transmission in mallards. An N114K mutation that increased the pH of HA activation by 0.5 unit resulted in decreased replication, genetic stability, and environmental stability. Changes of ؉0.4 and ؊0.5 unit in the pH of activation by Y23H and K58I mutations, respectively, reduced weight loss, mortality, shedding, and transmission in mallards. An H24Q mutation that decreased the pH of activation by 0.3 unit resulted in weight loss, mortality, clinical symptoms, and shedding similar to those of the wild type. However, the HA-H24 1 Q virus was shed more extensively into drinking water and persisted longer in the environment. The pH of activation of the H5 HA protein plays a key role in the propagation of H5N1 influenza viruses in ducks and may be a novel molecular factor in the ecology of influenza viruses. The data also demonstrate that H5N1 neuraminidase activity increases the pH of activation of the HA protein in vitro.
For decades, hemagglutinin (HA) protein structure and its refolding mechanism have served as a paradigm for understanding protein-mediated membrane fusion. HA trimers are in a high-energy state and are functionally activated by low pH. Over the past decade, HA stability (or the pH at which irreversible conformational changes are triggered) has emerged as an important determinant in influenza virus host range, infectivity, transmissibility, and human pandemic potential. Here, we review HA protein structure, assays to measure its stability, measured HA stability values, residues and mutations that regulate its stability, the effect of HA stability on interspecies adaptation and transmissibility, and mechanistic insights into this process. Most importantly, HA stabilization appears to be necessary for adapting emerging influenza viruses to humans.
The fusion (F) protein of the paramyxovirus SV5 strain W3A causes syncytium formation without coexpression of the SV5 hemagglutinin-neuraminidase (HN) glycoprotein, whereas the F protein of the SV5 strain WR requires coexpression of HN for fusion activity. SV5 strains W3A and WR differ by three amino acid residues at positions 22, 443, and 516. The W3A F protein residues P22, S443, and V516 were changed to amino acids found in the WR F protein (L22, P443, and A516, respectively). Three single-mutants, three double-mutants, and the triple-mutant were constructed, expressed, and assayed for fusion using three different assays. Mutant P22L did not cause fusion under physiological conditions, but fusion was activated at elevated temperatures. Compared with the W3A F protein, mutant S443P enhanced the fusion kinetics with a faster rate and greater extent, and had a lower activation temperature. Mutant V516A had little effect on F protein-mediated fusion. The double-mutant P22L,S443P was capable of causing fusion, suggesting that the two mutations have opposing effects on fusion activation. The WR F protein requires coexpression of HN to cause fusion at 37 degrees C, and does not cause fusion at 37 degrees C when coexpressed with influenza virus hemagglutinin (HA); however, at elevated temperatures coexpression of WR F protein with HA resulted in fusion activation. In the crystal structure of the core trimer of the SV5 F protein (Baker, K. A., Dutch, R. E., Lamb, R.A., and Jardetzky, T. S. (1999). Mol. Cell 3, 309-319), S443 is the last residue (with interpretable electron density) in an extended chain region and the temperature factor for S443 is high, suggesting conformational flexibility at this point. Thus, the presence of prolines at residues 22 and 443 may destabilize the F protein and thereby decrease the energy required to trigger the presumptive conformational change to the fusion-active state.
Currently available drugs for the prevention and treatment of seasonal influenza virus infections are the M2 ion channel blockers (amantadine and rimantadine) and the neuraminidase (NA) inhibitors (oseltamivir and zanamivir) (9). The clinical usefulness of amantadine and rimantadine is limited due to the increasing incidence of adamantane-resistant viruses in the population (3, 11). Moreover, the M2 ion channel blockers inhibit only influenza A virus replication and are associated with neurological side effects. NA inhibitors are favored clinically, since they are effective against all NA subtypes, are well tolerated, and have a higher barrier for resistance (27). However, drug-resistant isolates have been detected in A/H3N2-and A/H5N1-infected patients receiving oseltamivir treatment (10, 16). Even more reason for concern is the recent and worldwide isolation of oseltamivir-resistant A/H1N1 mutants, even among untreated patients (17, 46). Oseltamivir and, to a lesser extent, zanamivir have been stockpiled as part of pandemic preparedness plans and form the cornerstone of the response to the recent outbreak of the swine flu A/H1N1 virus (39, 40). However, it is unclear whether these antivirals will be sufficient to deal with larger influenza epidemics, so there is an urgent need to develop antivirals that act on a novel influenza virus target.An attractive antiviral strategy is to block influenza virus entry into the host cell, a process in which the viral hemagglutinin (HA) plays a key role (42). HA is a trimeric envelope glycoprotein that contains two disulfide-linked polypeptide chains, HA1 and HA2. After attachment of the receptor binding domain in the HA1 subunit to sialic acid-containing cell surface glycans, the virion is internalized by endocytosis. The acidic pH of the endosome leads to an extensive and irreversible conformational change of the HA protein, resulting in exposure of the fusion peptide, which inserts into the endosomal target membrane of the host cell (18). After fusion of the viral and endosomal membranes, the viral ribonucleoproteins are released into the cytosol and transported into the nucleus, where replication occurs (6). Crystallographic studies have provided detailed insight into the processes of HA refolding and extrusion of the fusion peptide (4). The latter is a sequence of hydrophobic amino acids located at the N terminus of the HA2 subunit, which is, in the prefusogenic conformation, sequestered in a pocket of ionizable residues at the monomer interface of the HA trimer (48). In order to exploit the HA protein as an antiviral target, several small-molecule inhibitors that block the acid-induced conformational change of HA have been identified (2,19,21,30,49). For many of these, development has been hindered by their subtype-dependent activities. On the other hand, these diverse fusion inhibitors represent excellent tools to identify the HA amino acid residues involved in the fusion process and/or delineate the structural differences among HA subtypes (36). We report here the i...
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