NA Proteins of Influenza A Viruses H1N1/2009, H5N1, and H9N2 Show Differential Effects on Infection Initiation,Virus Release,and Cell-Cell Fusion

Two surface glycoproteins of influenza virus, haemagglutinin (HA) and neuraminidase (NA), play opposite roles in terms of their interaction with host sialic acid receptors. HA attaches to sialic acid on host cell surface receptors to initiate virus infection while NA removes these sialic acids to facilitate release of progeny virions. This functional opposition requires a balance. To explore what might happen when NA of an influenza virus was replaced by one from another isolate or subtype, in this study, we generated three recombinant influenza A viruses in the background of A/PR/8/34 (PR8) (H1N1) and with NA genes obtained respectively from the 2009 pandemic H1N1 virus, a highly pathogenic avian H5N1 virus, and a lowly pathogenic avian H9N2 virus. These recombinant viruses, rPR8-H1N1NA, rPR8-H5N1NA, and rPR8-H9N2NA, were shown to have similar growth kinetics in cells and pathogenicity in mice. However, much more rPR8-H5N1NA and PR8-wt virions were released from chicken erythrocytes than virions of rPR8-H1N1NA and rPR8-H9N2NA after 1 h. In addition, in MDCK cells, rPR8-H5N1NA and rPR8-H9N2NA infected a higher percentage of cells, and induced cell-cell fusion faster and more extensively than PR8-wt and rPR8-H1N1NA did in the early phase of infection. In conclusion, NA replacement in this study did not affect virus replication kinetics but had different effects on infection initiation, virus release and fusion of infected cells. These phenomena might be partially due to NA proteins’ different specificity to α2-3/2-6-sialylated carbohydrate chains, but the exact mechanism remains to be explored.     

Biophysical Measurement of the Balance of Influenza A Hemagglutinin and Neuraminidase Activities

The interaction of influenza A viruses with the cell surface is controlled by the surface glycoproteins hemagglutinin (HA) and neuraminidase (NA). These two glycoproteins have opposing activities: HA is responsible for binding the host receptor (sialic acid) to allow infection, and NA is responsible for cleaving the receptor to facilitate virus release. Several studies have demonstrated that compatible levels of HA and NA activity are required for a virus to replicate efficiently. This is consequently of great interest for determining virus transmissibility. The concurrent role of these two proteins in receptor binding has never been directly measured. We demonstrate a novel biophysical approach based on bio-layer interferometry to measure the balance of the activities of these two proteins in real time. This technique measures virus binding to and release from a surface coated with either the human-like receptor analog α2,6-linked sialic acid or the avian-like receptor analog α2,3-linked sialic acid in both the presence and absence of NA inhibitors. Bio-layer interferometry measurements were also carried out to determine the effect of altering HA receptor affinity and NA stalk length on receptor binding.     

Adaptation of influenza A viruses to cells expressing low levels of sialic acid leads to loss of neuraminidase activity

Influenza A viruses possess two virion surface proteins, hemagglutinin (HA) and neuraminidase (NA). The HA binds to sialyloligosaccharide viral receptors, while the NA removes sialic acids from the host cell and viral sialyloligosaccarides. Alterations of the HA occur during adaptation of influenza viruses to new host species, as in the 1957 and 1968 influenza pandemics. To gain a better understanding of the contributions of the HA and possibly the NA to this process, we generated cell lines expressing reduced levels of the influenza virus receptor determinant, sialic acid, by selecting Madin-Darby canine kidney cells resistant to a lectin specific for sialic acid linked to galactose by alpha(2-3) or alpha(2-6) linkages. One of these cell lines had less than 1/10 as much N-acetylneuraminic acid as its parent cell line. When serially passaged in this cell line, human H3N2 viruses lost sialidase activity due to a large internal deletion in the NA gene, without alteration of the HA gene. These findings indicate that NA mutations can contribute to the adaptation of influenza A virus to new host environments and hence may play a role in the transmission of virus across species.     

Transport of influenza virus neuraminidase (NA) to host cell surface is regulated by ARHGAP21 and Cdc42 proteins

Influenza virus neuraminidase (NA) is transported to the virus assembly site at the plasma membrane and is a major viral envelope component that plays a critical role in the release of progeny virions and in determination of host range restriction. However, little is known about the host factors that are involved in regulating the intracellular and cell surface transport of NA. Here we identified the Cdc42-specific GAP, ARHGAP21 differentially expressed in host cells infected with influenza A virus using cDNA microarray analysis. Furthermore, we have investigated the involvement of Rho family GTPases in NA transport to the cell surface. We found that expression of constitutively active or inactive mutants of RhoA or Rac1 did not significantly affect the amount of NA that reached the cell surface. However, expression of constitutively active Cdc42 or depletion of ARHGAP21 promoted the transport of NA to the plasma membranes. By contrast, cells expressing shRNA targeting Cdc42 or overexpressing ARHGAP21 exhibited a significant decrease in the amount of cell surface-localized NA. Importantly, silencing Cdc42 reduced influenza A virus replication, whereas silencing ARHGAP21 increased the virus replication. Together, our results reveal that ARHGAP21- and Cdc42-based signaling regulates the NA transport and thereby impacts virus replication.     

Receptor recognition mechanism of human influenza A H1N1 (1918), avian influenza A H5N1 (2004), and pandemic H1N1 (2009) neuraminidase

Influenza A neuraminidase (NA) is a target for anti-influenza drugs. The function of this enzyme is to cleave a glycosidic linkage of a host cell receptor that links sialic acid (Sia) to galactose (Gal), to allow the virus to leave an infected cell and propagate. The receptor is an oligosaccharide on the host cell surface. There are two types of oligosaccharide receptor; the first, which is found mainly on avian epithelial cell surfaces, links Sia with Gal by an α2,3 glycosidic linkage; in the second, found mainly on human epithelial cell surfaces, linkage is via an α2,6 linkage. Some researchers believe that NAs from different viruses show selectivity for each type of linkage, but there is limited information available to confirm this hypothesis. To see if the linkage type is more specific to any particular NA, a number of NA-receptor complexes of human influenza A H1N1 (1918), avian influenza A H5N1 (2004), and a pandemic strain of H1N1 (2009) were constructed using homology modeling and molecular dynamics simulation. The results show that the two types of receptor analogues bound to NAs use different mechanisms. Moreover, it was found that a residue unique to avian virus NA is responsible for the recognition of the Siaα2,3Gal receptor, and a residue unique to human virus NA is responsible for the recognition of Siaα2,6Gal. We believe that this finding could explain how NAs of different virus origins always possess some unique residues.     

Study of specific oligosaccharide structures related with swine flu (H1N1) and avian flu, and tamiflu as their remedy

The infection of pandemic influenza viruses such as swine flu (H1N1) and avian flu viruses to the host cells is related to the following two factors: First, the surface protein such as HA (hemagglutinin) and NA (neuraminidase) of the influenza virus. Second, the specific structure of the oligosaccharide [sialic acid(alpha2-6) galactose(beta1-4)glucose or sialic acid(alpha2-3)galactose(beta1-4)glucose] on the host cell. After recognizing the specific structure of the oligosaccharide on the surface of host cells by the surface protein of the influenza virus, the influenza virus can secrete sialidase and cleave the sialic acid attached on the final position of the specific structure of the oligosaccharide on the surface of host cells. Tamiflu (oseltamivir), known as a remedy of swine flu, has a saccharide analog structure, especially the sialic acid analog. Tamiflu can inhibit the invasion of influenza viruses (swine flu and avian flu viruses) into the host cells by competition with sialic acid on the terminal position of the specific oligosaccharide on the surface of the host cell. Because of the emergence of Tamiflu resistance, the development of new potent anti-influenza inhibitors is needed. The inhibitors with positive-charge groups have potential as antiviral therapeutics, and the strain specificity must also be resolved.     

Influenza A virus neuraminidase protein interacts with Hsp90, to stabilize itself and enhance cell survival

Neuraminidase protein (NA) of influenza A virus (IAV) is popularly known for its sialidase function to assist in the release of progeny virus. However, involvement of NA in other stages of the IAV life cycle also indicates its multifunctional nature and necessity to interact with other host proteins. Here, we report a host protein—heat shock protein 90 (Hsp90), as a novel interacting partner of IAV NA. A classical yeast two-hybrid screen was conducted to identify a new host interacting partner for NA and the interaction was further validated by coimmunoprecipitation from cells, transiently expressing both proteins and also from IAV-infected cells. Confocal imaging showed that both proteins colocalized in the cytoplasm in transfected host cells. Interestingly, increased levels of NA in the presence of Hsp90 was observed, which tends to decrease if adenosine triphosphatase activity of Hsp90 is inhibited using 17-N-allylamino-17-demethoxygeldanamycin (17AAG). This establishes viral NA as a client protein of host chaperone Hsp90 contributing toward NA's stability via the NA-Hsp90 interaction. This is the first report showing the interaction of NA with Hsp90 and its role in stabilizing viral NA thus preventing it from degradation. Enhanced cell survival in the presence of this interaction was also observed, thus suggesting the requirement of stable viral NA, post-IAV infection, for efficient virus production in infected mammalian cells.     

Role of neuraminidase in the morphogenesis of influenza B virus.

When ts7, a temperature-sensitive (ts) mutant of influenza B/Kanagawa/73 virus, infected MDCK cells at the nonpermissive temperature (37.5 degrees C), infectious virus was produced at very low levels compared with the yield at the permissive temperature (32 degrees C) and hemagglutinating activity and enzymatic activity of neuraminidase (NA) were negligible. However, viral protein synthesis and transport of hemadsorption-active hemagglutinin to the cell surface were not affected. When the cell lysate was treated with bacterial NA, hemagglutinating activity was recovered but infectivity was not, even after further treatment with trypsin. It was found that ts7 was defective in transport of NA to the cell surface and formation of virus particles. Analysis of the genomes of non-ts recombinants obtained by crossing ts7 and UV-inactivated B/Lee showed that ts7 had the ts mutation only in RNA segment 6 coding for NA and the glycoprotein NB. Nucleotide sequence analysis of the RNA segment revealed that ts7 had four amino acid changes in the NA molecule but not in NB. We suggest that assembly or budding of influenza B virus requires the presence of NA at the plasma membrane, unlike influenza A virus.     

Surface expression of influenza virus neuraminidase, an amino-terminally anchored viral membrane glycoprotein, in polarized epithelial cells.

We have investigated the site of surface expression of the neuraminidase (NA) glycoprotein of influenza A virus, which, in contrast to the hemagglutinin, is bound to membranes by hydrophobic residues near the NH2-terminus. Madin-Darby canine kidney or primary African green monkey kidney cells infected with influenza A/WSN/33 virus and subsequently labeled with monoclonal antibody to the NA and then with a colloidal gold- or ferritin-conjugated second antibody exhibited specific labeling of apical surfaces. Using simian virus 40 late expression vectors, we also studied the surface expression of the complete NA gene (SNC) and a truncated NA gene (SN10) in either primary or a polarized continuous line (MA104) of African green monkey kidney cells. The polypeptides encoded by the cloned NA cDNAs were expressed on the surface of both cell types. Analysis of [3H]mannose-labeled polypeptides from recombinant virus-infected MA104 cells showed that the products of cloned NA cDNA comigrated with glycosylated NA from influenza virus-infected cells. Both the complete and the truncated glycoproteins were found to be preferentially expressed on apical plasma membranes, as detected by immunogold labeling. These results indicate that the NA polypeptide contains structural features capable of directing the transport of the protein to apical cell surfaces and the first 10 amino-terminal residues of the NA polypeptide are not involved in this process.     

Characterization of a neuraminidase-deficient influenza a virus as a potential gene delivery vector and a live vaccine

We recently identified a packaging signal in the neuraminidase (NA) viral RNA (vRNA) segment of an influenza A virus, allowing us to produce a mutant virus [GFP(NA)-Flu] that lacks most of the NA open reading frame but contains instead the gene encoding green fluorescent protein (GFP). To exploit the expanding knowledge of vRNA packaging signals to establish influenza virus vectors for the expression of foreign genes, we studied the replicative properties of this virus in cell culture and mice. Compared to wild-type virus, GFP(NA)-Flu was highly attenuated in normal cultured cells but was able to grow to a titer of >10(6) PFU/ml in a mutant cell line expressing reduced levels of sialic acid on the cell surface. GFP expression from this virus was stable even after five passages in the latter cells. In intranasally infected mice, GFP was detected in the epithelial cells of nasal mucosa, bronchioles, and alveoli for up to 4 days postinfection. We attribute the attenuated growth of GFP(NA)-Flu to virion aggregation at the surface of bronchiolar epithelia. In studies to test the potential of this mutant as a live attenuated influenza vaccine, all mice vaccinated with >/==" BORDER="0">10(5) PFU of GFP(NA)-Flu survived when challenged with lethal doses of the parent virus. These results suggest that influenza virus could be a useful vector for expressing foreign genes and that a sialidase-deficient virus may offer an alternative to the live influenza vaccines recently approved for human use.     

Role of phosphatidylserine exposure and sugar chain desialylation at the surface of influenza virus-infected cells in efficient phagocytosis by macrophages

HeLa cells infected with influenza A virus undergo typical caspase-dependent apoptosis and are efficiently phagocytosed by mouse peritoneal macrophages in a manner mediated by the membrane phospholipid phosphatidylserine, which is translocated to the surface of virus-infected cells during apoptosis. However, the extent of phagocytosis is not always parallel with the level of phosphatidylserine externalization. Here we examined the involvement of influenza virus neuraminidase (NA) in efficient phagocytosis of virus-infected cells. HeLa cells infected with an influenza virus strain expressing temperature-sensitive NA underwent apoptosis and produced viral proteins, including the defective NA, at a non-permissive temperature to almost the same extent as cells infected with the wild-type virus. The cells were, however, phagocytosed by macrophages with reduced efficiency. In addition, phagocytosis of cells infected with the wild-type virus was severely inhibited when the cells had been maintained in the presence of the NA inhibitor zanamivir. On the other hand, the binding of sialic acid-recognizing lectins to the cell surface declined after infection with the wild-type virus. The decrease in the extent of lectin binding was greatly attenuated when cells were infected with the mutant virus or when wild-type virus-infected cells were maintained in the presence of zanamivir. These results indicate that sugar chains are desialylated by NA at the surface of virus-infected cells. We conclude that the presence of both phosphatidylserine and asialoglycomoieties on the cell surface is required for efficient phagocytosis of influenza virus-infected cells by macrophages.     

Force Spectroscopy Shows Dynamic Binding of Influenza Hemagglutinin and Neuraminidase to Sialic Acid

The influenza A virus infects target cells through multivalent interactions of its major spike proteins, hemagglutinin (HA) and neuraminidase (NA), with the cellular receptor sialic acid (SA). HA is known to mediate the attachment of the virion to the cell, whereas NA enables the release of newly formed virions by cleaving SA from the cell. Because both proteins target the same receptor but have antagonistic functions, virus infection depends on a properly tuned balance of the kinetics of HA and NA activities for viral entry to and release from the host cell. Here, dynamic single-molecule force spectroscopy, based on scanning force microscopy, was employed to determine these bond-specific kinetics, characterized by the off rate k_off, rupture length x_β and on rate k_on, as well as the related free-energy barrier ΔG and the dissociation constant K_D. Measurements were conducted using surface-immobilized HA and NA of the influenza A virus strain A/California/04/2009 and a novel, to our knowledge, synthetic SA-displaying receptor for functionalization of the force probe. Single-molecule force spectroscopy at force loading rates between 100 and 50,000 pN/s revealed most probable rupture forces of the protein-SA bond in the range of 10–100 pN. Using an extension of the widely applied Bell-Evans formalism by Friddle, De Yoreo, and co-workers, it is shown that HA features a smaller x_β, a larger k_off and a smaller ΔG than NA. Measurements of the binding probability at increasing contact time between the scanning force microscopy force probe and the surface allow an estimation of K_D, which is found to be three times as large for HA than for NA. This suggests a stronger interaction for NA-SA than for HA-SA. The biological implications in regard to virus binding to the host cell and the release of new virions from the host cell are discussed.     

The cytoplasmic tail of influenza A virus neuraminidase (NA) affects NA incorporation into virions, virion morphology, and virulence in mice but is not essential for virus replication.

In this study, we investigated the role of the conserved neuraminidase (NA) cytoplasmic tail residues in influenza virus replication. Mutants of influenza A virus (A/WSN/33 [H1N1]) with deletions of the NA cytoplasmic tail region were generated by reverse genetics. The resulting viruses, designated NOTAIL, contain only the initiating methionine of the conserved six amino-terminal residues. The mutant viruses grew much less readily and produced smaller plaques than did the wild-type virus. Despite similar levels of NA cell surface expression by the NOTAIL mutants and wild-type virus, incorporation of mutant NA molecules into virions was decreased by 86%. This reduction resulted in less NA activity per virion, leading to the formation of large aggregates of progeny mutant virions on the surface of infected cells. A NOTAIL virus containing an additional mutation (Ser-12 to Pro) in the transmembrane domain incorporated three times more NA molecules into virions than did the NOTAIL parent but approximately half of the amount incorporated by the wild-type virus. However, aggregation of the progeny virions still occurred at the cell surface. All NOTAIL viruses were attenuated in mice. We conclude that the cytoplasmic tail of NA is not absolutely essential for virus replication but exerts important effects on the incorporation of NA into virions and thus on the aggregation and virulence of progeny virus. In addition, the relative abundance of long filamentous particles formed by the NOTAIL mutants, compared with the largely spherical wild-type particles, indicates a role for the NA cytoplasmic tail in virion morphogenesis.     

A Mutant Influenza Virus That Uses an N1 Neuraminidase as the Receptor-Binding Protein

In the vast majority of influenza A viruses characterized to date, hemagglutinin (HA) is the receptor-binding and fusion protein, whereas neuraminidase (NA) is a receptor-cleaving protein that facilitates viral release but is expendable for entry. However, the NAs of some recent human H3N2 isolates have acquired receptor-binding activity via the mutation D151G, although these isolates also appear to retain the ability to bind receptors via HA. We report here the laboratory generation of a mutation (G147R) that enables an N1 NA to completely co-opt the receptor-binding function normally performed by HA. Viruses with this mutant NA grow to high titers even in the presence of extensive mutations to conserved residues in HA''s receptor-binding pocket. When the receptor-binding NA is paired with this binding-deficient HA, viral infectivity and red blood cell agglutination are blocked by NA inhibitors. Furthermore, virus-like particles expressing only the receptor-binding NA agglutinate red blood cells in an NA-dependent manner. Although the G147R NA receptor-binding mutant virus that we characterize is a laboratory creation, this same mutation is found in several natural clusters of H1N1 and H5N1 viruses. Our results demonstrate that, at least in tissue culture, influenza virus receptor-binding activity can be entirely shifted from HA to NA.     

Characterization of a temperature-sensitive influenza B virus mutant defective in neuraminidase.

ts5, a temperature-sensitive mutant of influenza B virus, belongs to one of seven recombination groups. When the mutant infected MDCK cells at the nonpermissive temperature (37.5 degrees C), infectious virus was produced at very low levels compared with the yield at the permissive temperature (32 degrees C) and hemagglutinating and enzymatic activities were undetectable. However, viral protein synthesis and transport of hemagglutinin (HA) and neuraminidase (NA) to the cell surface were not affected. The NA was found as a monomer within cells even at 32 degrees C, in contrast to wild-type virus NA, existing mostly as an oligomer, but the mutant had oligomeric NA, like the wild-type virus. Its enzymatic activity was more thermolabile than that of wild-type virus. Despite the low yield, large aggregates of progeny virus particles were found to accumulate on the cell surface at the nonpermissive temperature, and these aggregates were broken by treatment with bacterial neuraminidase, with the concomitant appearance of hemagglutinating activity, suggesting that NA prevents the aggregation of progeny virus by removal of neuraminic acid from HA and cell receptor, allowing its release from the cells. Further treatment with trypsin resulted in the recovery of infectivity. When bacterial NA was added to the culture early in infection, many hemagglutinable infectious virus was produced. We also suggest that the removal of neuraminic acid from HA by NA is essential for the subsequent cleavage of HA by cellular protease. Nucleotide sequence analysis of RNA segment 6 revealed that ts5 encoded five amino acid changes in the NA molecule but not in NB.     

Macrophage Receptors for Influenza A Virus: Role of the Macrophage Galactose-Type Lectin and Mannose Receptor in Viral Entry

Although sialic acid has long been recognized as the primary receptor determinant for attachment of influenza virus to host cells, the specific receptor molecules that mediate viral entry are not known for any cell type. For the infection of murine macrophages by influenza virus, our earlier study indicated involvement of a C-type lectin, the macrophage mannose receptor (MMR), in this process. Here, we have used direct binding techniques to confirm and characterize the interaction of influenza virus with the MMR and to seek additional macrophage surface molecules that may have potential as receptors for viral entry. We identified the macrophage galactose-type lectin (MGL) as a second macrophage membrane C-type lectin that binds influenza virus and is known to be endocytic. Binding of influenza virus to MMR and MGL occurred independently of sialic acid through Ca²⁺-dependent recognition of viral glycans by the carbohydrate recognition domains of the two lectins; influenza virus also bound to the sialic acid on the MMR. Multivalent ligands of the MMR and MGL inhibited influenza virus infection of macrophages in a manner that correlated with expression of these receptors on different macrophage populations. Influenza virus strain A/PR/8/34, which is poorly glycosylated and infects macrophages poorly, was not recognized by the C-type lectin activity of either the MMR or the MGL. We conclude that lectin-mediated interactions of influenza virus with the MMR or the MGL are required for the endocytic uptake of the virus into macrophages, and these lectins can thus be considered secondary or coreceptors with sialic acid for infection of this cell type.Infection of host cells by influenza virus is initiated by attachment of virus to sialic acid residues on the host cell surface through the receptor-binding site at the distal tip of the viral hemagglutinin (HA) (43). After attachment, the virus is internalized by endocytosis, and acidification of the endosome triggers a conformational change in viral HA that results in fusion of the viral envelope and host cell membrane (34). At the cell surface, sialic acid residues are commonly found at the termini of oligosaccharide chains that are attached in O or N linkage to cell surface proteins; they are also an essential component of acidic glycosphingolipids (gangliosides) that are present in all mammalian cell membranes. Although the abundance of sialic acid on mammalian cells provides influenza virus with multiple potential receptors, virus attachment does not always lead to virus entry (5, 8, 46). Furthermore, sialic acid-independent infection of Madin-Darby canine kidney (MDCK) cells by influenza virus has been reported (35). The specific host cell molecules that serve as functional receptors (or coreceptors) for the infectious entry of influenza virus have yet to be defined.We have studied the infectious entry of influenza virus into macrophages (Mφ), which represents an early event in recognition of the virus by the innate immune system (23, 44). After intranasal infection of mice, influenza virus replicates productively in cells of the respiratory epithelium. Mφ are also infected and viral proteins are produced, but replication is abortive and no live progeny are released (32); infection of Mφ is thus a dead-end for the virus leading to a reduction in viral load. In addition, influenza virus infection of Mφ stimulates production and release of proinflammatory cytokines and alpha/beta interferon (28), which may assist in further limiting viral replication and spread within the respiratory tract. Depletion of airway Mφ from mice prior to intranasal influenza virus infection leads to increased virus titers in the lung, attesting to the important role of Mφ in early host defense against the virus (38, 44).We observed in a previous study (30) that influenza A virus strains differed in their ability to infect murine Mφ, strains carrying a more highly glycosylated hemagglutinin (HA) molecule being more efficient at infecting Mφ than less glycosylated strains, although binding of viruses to the Mφ cell surface was equivalent. Our investigation of this phenomenon indicated involvement of the Mφ mannose receptor MMR (CD206), a C-type lectin, in infectious viral entry (29, 30). The involvement of other receptors was not excluded, and our subsequent observation that influenza virus can infect the RAW 264.7 Mφ cell line, which does not express the MMR, indeed points to the existence of other routes of infectious entry of the virus into Mφ.In the present study we used direct binding methods to confirm and characterize the interaction of influenza virus with the MMR and to seek additional Mφ surface molecules that may have potential as receptors for viral entry. We identify the Mφ galactose-type lectin (MGL) as a second Mφ membrane C-type lectin that binds influenza virus and investigate its involvement in the infectious process.     

Class II MHC-restricted T cell determinants processed from either endosomes or the cytosol show similar requirements for host protein transport but different kinetics of presentation.

We have studied the role of APC protein transport in presentation of class II MHC-restricted T cell determinants of influenza virus glycoproteins that have distinct Ag processing requirements. Two I-Ed-restricted epitopes were analyzed: hemagglutinin (HA) 111-119, which is processed by the exogenous/endocytic pathway, and neuraminidase (NA) 79-93, which has a requirement for cytosolic processing. NA 79-93 is presented from infectious but not non-replicative virus under ordinary conditions. This requirement for viral biosynthesis could be bypassed by using a soluble inhibitor of NA,2,3-dehydro-2-deoxy-N-acetyl neuraminic acid (DDAN), to facilitate cytosolic introduction of virus. APC exposed to UV virus/DDAN present HA and NA determinants derived directly from proteins of the input virus particles. This allows presentation of both endocytically and cytosolically processed epitopes in the same experiment using noninfectious virus. The inhibitor brefeldin A (BFA) was used to interrupt host protein transport at various times relative to virus/DDAN addition. We observed that BFA added simultaneously with virus blocked recognition of NA 79-93 but not HA 111-119. This distinction was found to be based upon different expression kinetics of the HA and NA determinants. Expression of NA 79-93 required 6 to 9 h, whereas HA 111-119 was presented by 1 h after Ag addition. When APC were incubated with BFA at intervals before virus addition, presentation of HA 111-119 was also blocked as a function of time. Data indicate that about 5 h of BFA treatment is needed to deplete host protein pools required for presentation of I-Ed-restricted T cell determinants processed from either endosomes or the cytosol.     

甲型流感病毒蛋白和遗传物质在宿主细胞质内顺向转运过程及其机制

流感病毒的蛋白和基因组在宿主细胞内能否正确地转运到相关部位,直接影响到病毒颗粒的形态发生。流感病毒跨膜蛋白(HA、NA和M2)主要通过宿主细胞的运输膜泡实现转运,而宿主细胞的蛋白转运机器参与了这一过程。新合成的流感病毒核糖核蛋白复合物(vRNPs)出核后,通过与活化的Rab11相结合,聚集于邻近微管组织中心(MTOC)的胞内体。然后以运输小膜泡的形式,沿着MTOC的微管网络向细胞膜方向转运。跨膜蛋白和基因组在细胞质内的转运受一些宿主因子的调控,如ARHGAP21和小G蛋白Cdc42能够调节NA蛋白向细胞膜转运,Rab11协助vRNPs从MTOC向细胞膜转运。文中主要讨论新合成的流感病毒跨膜蛋白和遗传物质在宿主细胞质内的顺向转运(Anterograde transport)过程与调控。