Immunization with live nonpathogenic H5N3 duck influenza virus protects chickens against highly pathogenic H5N1 virus.

Development of an effective, broadly-active and safe vaccine for protection of poultry from H5N1 highly pathogenic avian influenza viruses (HPAIVs) remains an important practical goal. In this study we used a low pathogenic wild aquatic bird virus isolate А/duck/Moscow/4182/2010 (H5N3) (dk/4182) as a live candidate vaccine. We compared this virus with four live 1:7 reassortant anti-H5N1 candidate vaccine viruses with modified hemagglutinin from either A/Vietnam/1203/04 (H5N1) or A/Kurgan/3/05 (H5N1) and the rest of the genes from either H2N2 cold-adapted master strain A/Leningrad/134/17/57 (rVN-Len and rKu-Len) or H6N2 virus A/gull/Moscow/3100/2006 (rVN-gull and rKu-gull). The viruses were tested in parallel for pathogenicity, immunogenicity and protective effectiveness in chickens using aerosol, intranasal and oral routes of immunization. All five viruses showed zero pathogenicity indexes in chickens. Viruses rVN-gull and rKu-gull were immunogenic and protective, but they were insufficiently attenuated and caused significant mortality of 1-day-old chickens. The viruses with cold-adapted backbones (rVN-Len and rKu-Len) were completely nonpathogenic, but they were significantly less immunogenic and provided lower protection against lethal challenge with HPAIV A/Chicken/Kurgan/3/05 (H5N1) as compared with three other vaccine candidates. Unlike other four viruses, dk/4182 was both safe and highly immunogenic in chickens of any age regardless of inoculation route. Single administration of 106 TCID50 of dk/4182 virus via drinking water provided complete protection of 30-days-old chickens from 100 LD50 of the challenge virus. Our results suggest that low pathogenic viruses of wild aquatic birds can be used as safe and effective live poultry vaccines against highly pathogenic avian viruses.

Influenza A virus proteins NS1 and hemagglutinin along with M2 are involved in stimulation of autophagy in infected cells.

The NS1 protein of influenza A virus is known to downregulate apoptosis early in infection in order to support virus replication (O. P. Zhirnov, T. E. Konakova, T. Wolff, and H. D. Klenk, J. Virol. 76:1617-1625, 2002). In the present study, we analyzed the development of autophagy, another mechanism to protect cells from degradation that depends on NS1 expression. To this end, we compared autophagy in cells infected with wild-type (WT) influenza virus and virus lacking the NS1 gene (delNS1 virus). The results show that in WT-infected cells but not in delNS1 virus-infected cells, synthesis of the autophagy marker LC3-II, the lipidated form of microtubule light chain-associated protein LC3, is stimulated and that LC3-II accumulates in a perinuclear zone enriched with double-layered membrane vesicles characteristic of autophagosomes. Transfection experiments revealed that NS1 expressed alone was unable to upregulate autophagy, whereas hemagglutinin (HA) and M2 were. Proteolytic cleavage of HA increased autophagy. Taken together, these observations indicate that NS1 stimulates autophagy indirectly by upregulating the synthesis of HA and M2. Thus, it appears that NS1, besides downregulating apoptosis, is involved in upregulation of autophagy and that it supports the survival of infected cells by both mechanisms.

[Evolution and infection biology of new influenza A viruses with pandemic potential]. / Evolution und Infektionsbiologie neuer Influenza-A-Viren mit pandemischem Potenzial.

Wild aquatic birds are natural hosts for a large variety of influenza A viruses. Occasionally, viruses are transmitted from this reservoir to other species, such as chickens, pigs, and man, and may then cause devastating outbreaks in domestic poultry or give rise to human influenza pandemics. The H5N1-, H7N7-, H9N2-, and H2N2-viruses are considered to have high pandemic potential, because of their pathogenicity in humans and because of the lack of immune protection in the human population. However, the unexpected outbreak of the H1N1 pandemic in 2009 demonstrates that the reliability of such predictions is limited. Host specificity, pathogenicity, and transmissibility are polygenic traits that depend on the interactions of viral proteins with host factors, among which receptor specificity and fusion activity of the hemagglutinin, nuclear transport of the polymerase, and interferon antagonism of the NS1 protein are of particular importance.

[Pathogenic effect of pandemic influenza virus H1N1 under replication in cultures of human cells].

The propagation of the pandemic influenza virus H1N1 in cultures of bronchial (Calu-3) and intestinal (Caco-2) differentiated epithelial cells of human origin was studied. The canine epithelial cell lines, MDCK-H and MDCK-2, were comparatively tested. The two human cell lines were found to be highly sensitive to the influenza pandemic strains A/Hamburg/05/09 and A/Moscow/501/2011 and maintained their replication without addition of trypsin to culture medium. Virus strains of seasonal influenza H1N1, such as A/Moscow/450/2003, A/Memphis/14/96, and laboratory strain A/PR/8/34, multiplied in these human cells in similar manner. The intracellular cleavage HA0-->HA1+HA2 by the host virus-activating protease (IAP) occurred in both human cell lines under infection with each influenza virus H1N1 including pandemic ones. Comparatively, this cleavage of all influenza H1N1 virus strains appeared to be either undetectable or low-detectible in MDCK-H and MDCK-2, respectively, thereby implying low levels of active IAP in these cells. Multiplication of pandemic and seasonal influenza H1N1 viruses in Calu-3 and Caco-2 cells caused cytopathic effect, which was accompanied with low autophagy and apoptosis events. These data allow recommending human cell lines, Calu-3 and Caco-2, for optimized isolation and passaging of clinical strains of Influenza pandemic viruses H1N1.

A new approach to an influenza live vaccine: modification of the cleavage site of hemagglutinin.

A promising approach to reduce the impact of influenza is the use of an attenuated, live virus as a vaccine. Using reverse genetics, we generated a mutant of strain A/WSN/33 with a modified cleavage site within its hemagglutinin, which depends on proteolytic activation by elastase. Unlike the wild-type, which requires trypsin, this mutant is strictly dependent on elastase. Both viruses grow equally well in cell culture. In contrast to the lethal wild-type virus, the mutant is entirely attenuated in mice. At a dose of 10(5) plaque-forming units, it induced complete protection against lethal challenge. This approach allows the conversion of any epidemic strain into a genetically homologous attenuated virus.

[Aprotinin-induced inhibition of pandemic influenza virus A(H1N1) reproduction].

Infectivity of pandemic influenza virus A(H1N1) infectivity is shown to be activated through proteolytic cleavage of hemagglutinin HA0 --> HA1 + HA2 during virus propagation in the human intestinal cell line Caco-2 and chicken embryonated eggs. Injection of aprotinin, a natural serine protease inhibitor, into the liquid culture or allantoic cavity of chicken embryos inhibited the proteolysis of the viral HA0 and suppressed the proteolytic activation of the synthesized virus and its multicycle replication. These data allow aprotinin to be recommended as an antiviral drug for the treatment of swine influenza in humans.

[NP gene of pandemic H1N1 virus attenuates virulence of mouse-adapted human influenza virus].

The authors studied a possible role of the caspase cleavage motif located in the nucleoprotein (NP) of pandemic influenza virus H1N1 in the regulation of viral virulence properties. A reverse genetics method was used to obtain chimeric seasonal-like mouse-adapted influenza virus hvA/PE/8/34 (H1N10) carrying either the NP gene of wild type pandemic virus with incomplete caspase motif ETGC or mutated pandemic NP with natural caspase cleavage site of human type ETDG. The wild-type NP gene of the pandemic virus was found to poorly fit to the gene pattern of closely related seasonal-like hvA/PR/8/34 virus (H1N1) and did not rescue mature virus production whereas a mutated NP with human-type caspase cleavage site maintained gene fitness, giving rise to a chimeric virus. The generated chimeric virus hvA/PR/8/34 carrying the mutated pandemic NP successfully replicated in the murine lung, but was attenuated and did not reach the virulence level of seasonal-like mouse-adapted virus hvA/PR/8/34. The findings indicate that the NP caspase cleavage site plays a role in viral adaptation and viral virulence in mammals.

Recognition of viral glycoproteins by influenza A-specific cross-reactive cytolytic T lymphocytes.

Two populations of cytolytic T lymphocytes (CTL) generated after influenza A virus infection can be distinguished into one with specificity for the sensitizing hemagglutinin type and a second with cross-reactivity for antigens induced by other type-A influenza viruses. The molecules carrying the antigenic determinants recognized by the cross-reactive CTL were studied. In L-929 cells abortively infected with fowl plague virus, matrix (M) protein synthesis is specifically inhibited, whereas the envelope glycoproteins, hemagglutinin and neuraminidase, are synthesized and incorporated into the plasma membrane. These target cells were lysed by cross-reactive CTL. The envelope proteins of type A/Victoria virus were separated from the other virion components and reconstituted into lipid vesicles that lacked M protein that subsequently were used to prepare artificial target cells. Target-cell formation with vesicles was achieved by addition of fusion-active Sendai virus. These artificial target cells were also susceptible to lysis by cross-reactive CTL. In contrast to previous observations that suggested that the M protein of influenza viruses is recognized by these effector cells, we present evidence that the antigencic determinants induced by the viral glycoproteins are recognized.

[Integration of influenza A virus NSP gene into baculovirus genome and its expression in insect cells].

Segment NS in all human influenza A viruses and in the part of avian and animal ones was found to contain an additional (beside NS1 and NEP) long open reading frame (ORF) enabling to code a polypeptide of 18-26 kD in different strains. This ORF, in contrast to the NS1 and NEP, locates in positive sense orientation in the negative polarity genomic NS RNA segment and the encoded protein is referred NSP (Negative Strand Protein). Here, the NSP gene of human influenza A/WSN/33 (H1N1) virus was inserted into genomic DNA of baculovirus (insect nuclear polyhedrosis virus) and insect H5 cells (ovary cell line of Trichoplusia ni) were infected with the obtained chimeric virus. The NSP gene appeared to express 19 kD polypeptide which was intracellularly stable and accumulated predominantly in the cytoplasm of infected H5 cells. These data indicate that the NSP gene possesses sense sequence which is able to direct a physiological synthesis of stable protein in eukaryotic cells.

Maturation of the trans-Golgi network protease furin: compartmentalization of propeptide removal, substrate cleavage, and COOH-terminal truncation.

We have cloned a bovine cDNA encoding the trans-Golgi network (TGN) protease furin and expressed it via recombinant vaccinia viruses to investigate intracellular maturation. Pulse-chase labeling reveals that the 104-kD pro-furin bearing high mannose N-glycans is rapidly processed into the 98-kD protease whose N-glycans remain sensitive to endoglycosidase H for a certain period of time. Furthermore, in the presence of brefeldin A, pro-furin cleavage occurs. From these data we conclude that the ER is the compartment of propeptide removal. Studies employing the ionophore A23187 and DTT show that autocatalysis is Ca2+ dependent and that it does not occur under reducing conditions. Pro-furin produced under these conditions never gains endo H resistance indicating that it is retained in the ER. Coexpression of furin with the fowl plague virus hemagglutinin in the presence of brefeldin A and monensin reveals that furin has to enter the Golgi region to gain substrate cleaving activity. N-glycans of furin are sialylated proving its transit through the trans-Golgi network. A truncated form of furin is found in supernatants of cells. Truncation is inhibited in the absence of Ca2+ ions and in the presence of acidotropic agents indicating that it takes place in an acidic compartment of cells. Comparative analysis with furin expressed from cDNA reveals that the truncated form prevails in preparations of biologically active, endogenous furin obtained from MDBK cells. This observation supports the concept that secretion of truncated furin is a physiological event that may have important implications for the processing of extracellular substrates.

Recovery of infectious Ebola virus from complementary DNA: RNA editing of the GP gene and viral cytotoxicity.

To study the mechanisms underlying the high pathogenicity of Ebola virus, we have established a system that allows the recovery of infectious virus from cloned cDNA and thus permits genetic manipulation. We created a mutant in which the editing site of the gene encoding envelope glycoprotein (GP) was eliminated. This mutant no longer expressed the nonstructural glycoprotein sGP. Synthesis of GP increased, but most of it accumulated in the endoplasmic reticulum as immature precursor. The mutant was significantly more cytotoxic than wild-type virus, indicating that cytotoxicity caused by GP is down-regulated by the virus through transcriptional RNA editing and expression of sGP.

[Site-directed modification of caspase cleavage site regions in avian influenza virus proteins].

A reverse genetics approach was applied to generate variants of avian influenza virus A/FPV/Ro/34 (H7N1) containing mutations in the caspase cleavage sites of NP and M2 proteins. Mutation Gly16 --> Asp in avian virus NP made this protein (NPgd) sensitive to caspases, like human virus NP, and permitted its cleavage in infected cells. Mutant recombinant virus NPgd was able to replicate and stably carried Gly --> Asp mutation during passages in cultured cells, chicken eggs, and chickens. This variant was found to have significantly decreased virulence for chickens comparatively to wild type recombinant virus (wtr). Virus variants characterized by deletion Gly16 in NP (NPdel) and mutated caspase cleavage site VDVDD87 --> VNVND87 in M2 (M2nn) protein were shown to lack intracellular caspase-dependent cleavage of NP and M2, respectively, and to retain their ability to replicate in different hosts. Variant NPdel, like wide type virus, displayed a high chicken virulence whereas M2nn, like NPgd one, was found to possess a low virulent phenotype. The findings suggest that the mutations altering natural caspase cleavage motifs in NP and M2 do not restrict virus replication ability but can significantly reduce the virulent potential of the mutant viruses. Recombinant virus variants with altered caspase cleavage motifs could be proposed as a matrix for the design of live recombinant vaccines.

Replication of Marburg virus in human endothelial cells. A possible mechanism for the development of viral hemorrhagic disease.

Marburg and Ebola virus, members of the family Filoviridae, cause a severe hemorrhagic disease in humans and primates. The disease is characterized as a pantropic virus infection often resulting in a fulminating shock associated with hemorrhage, and death. All known histological and pathophysiological parameters of the disease are not sufficient to explain the devastating symptoms. Previous studies suggested a nonspecific destruction of the endothelium as a possible mechanism. Concerning the important regulatory functions of the endothelium (blood pressure, anti-thrombogenicity, homeostasis), we examined Marburg virus replication in primary cultures of human endothelial cells and organ cultures of human umbilical cord veins. We show here that Marburg virus replicates in endothelial cells almost as well as in monkey kidney cells commonly used for virus propagation. Our data support the concept that the destruction of endothelial cells resulting from Marburg virus replication is a possible mechanism responsible for the hemorrhagic disease and the shock syndrome typical of this infection.

Intravirion cohesion of matrix protein M1 with ribonucleocapsid is a prerequisite of influenza virus infectivity.

Influenza virus has two major structural modules, an external lipid envelope and an internal ribonucleocapsid containing the genomic RNA in the form of the ribonucleoprotein (RNP) complex, both of which are interlinked by the matrix protein M1. Here we studied M1-RNP cohesion within virus exposed to acidic pH in vitro. The effect of acidification was dependent on the cleavage of the surface glycoprotein HA. Acidic pH caused a loss of intravirion RNP-M1 cohesion and activated RNP polymerase activity in virus with cleaved HA (HA1/2) but not in the uncleaved (HA0) virus. The in vitro acidified HA1/2 virus rapidly lost infectivity whereas the HA0 one retained infectivity, following activation by trypsin, suggesting that premature activation and release of the RNP is detrimental to viral infectivity. Rimantadine, an inhibitor of the M2 ion channel, was found to protect the HA1/2 virus interior against acidic disintegration, confirming that M2-dependent proton translocation is essential for the intravirion RNP release and suggesting that the M2 ion channel is only active in virions with cleaved HA. Acidic treatment of both HA0 and HA1/2 influenza viruses induces formation of spikeless bleb-like protrusion of ~ 25 nm in diameter on the surface of the virion, though only the HA1/2 virus was permeable to protons and permitted RNP release. It is likely that this bleb corresponds to the M2-enriched and M1-depleted focus arising from pinching off of the virus during the completion of budding. Cooperatively, the data suggest that the influenza virus has an asymmetric structure where the M1-mediated organization of the RNP inside the virion is a prerequisite for infectious entry into target cell.

Host cell proteases controlling virus pathogenicity.

The majority of viral glycoproteins that undergo post-translational proteolysis are cleaved by ubiquitous intracellular proteases; however, a minority are cleaved by secreted proteases available only in a few host systems. The interplay of viral glycoproteins and cellular proteases may have a pivotal role in the spread of infection, host range and pathogenicity.

Structural characterization and membrane binding properties of the matrix protein VP40 of Ebola virus.

The matrix protein VP40 of Ebola virus is believed to play a central role in viral assembly as it targets the plasma membrane of infected cells and subsequently forms a tightly packed layer on the inner side of the viral envelope. Expression of VP40 in Escherichia coli and subsequent proteolysis yielded two structural variants differing by a C-terminal truncation 114 amino acid residues long. As indicated by chemical cross-linking studies and electron microscopy, the larger polypeptide was present in a monomeric form, whereas the truncated one formed hexamers. When analyzed for their in vitro binding properties, both constructs showed that only monomeric VP40 efficiently associated with membranes containing negatively charged lipids. Membrane association of truncated, hexameric VP40 was inefficient, indicating a membrane-recognition role for the C-terminal part. Based on these observations we propose that assembly of Ebola virus involves the formation of VP40 hexamers that is mediated by the N-terminal part of the polypeptide.

Polymer-bound 6' sialyl-N-acetyllactosamine protects mice infected by influenza virus.

To develop a mouse model for testing receptor attachment inhibitors of human influenza viruses, the human clinical virus isolate in MDCK cells A/NIB/23/89M (H1N1) was adapted to mice by serial passaging through mouse lungs. The adaptation enhanced the viral pathogenicity for mice, but preserved the virus receptor binding phenotype, preferential binding to 2-6-linked sialic acid receptors and low affinity for 2-3-linked receptors. Sequencing of the HA gene of the mouse-adapted virus A/NIB/23/89-MA revealed a loss of the glycosylation sites in positions 94 and 163 of HA1 and substitutions 275Asp-->Gly in HA1 and 145Asn-->Asp in HA2. The four mouse strains tested differed significantly in their sensitivity to A/NIB/23/89-MA with the sensitivity increasing in the order of BALB/cJCitMoise, C57BL/6LacSto, CBA/CaLacSto and A/SnJCitMoise strains. Testing of protective efficacy of the polyacrylamide conjugate bearing Neu5Acalpha2-6Galbeta1-4GlcNAc trisaccharide under conditions of lethal or sublethal virus infection demonstrated a strong protective effect of this preparation. In particular, aerosol treatment of mice with the polymeric attachment inhibitor on 24-110 h after infection completely prevented mortality in sensitive animals and lessened disease symptoms in more resistant mouse strains.

Processing and localisation of a GPI-anchored Plasmodium falciparum surface protein expressed by the baculovirus system.

We describe the expression, in insect cells using the baculovirus system, of two protein fragments derived from the C-terminus of merozoite surface protein 1(MSP-1) of the human malaria parasite Plasmodium falciparum, and their glycosylation and intracellular location. The transport and intracellular localisation of the intact C-terminal MSP-1 fragment, modified by addition of a signal sequence for secretion, was compared with that of a similar control protein in which translation of the GPI-cleavage/attachment site was abolished by insertion of a stop codon into the DNA sequence. Both proteins could only be detected intracellularly, most likely in the endoplasmic reticulum. This lack of transport to the cell surface or beyond, was confirmed for both proteins by immunofluorescence with a specific antibody and characterisation of their N-glycans. The N-glycans had not been processed by enzymes localised in post-endoplasmic reticulum compartments. In contrast to MSP-1, the surface antigen SAG-1 of Toxoplasma gondii was efficiently transported out of the endoplasmic reticulum of insect cells and was located, at least in part, on the cell surface. No GPI-anchor could be detected for either of the MSP-1 constructs or SAG-1, showing that the difference in transport is a property of the individual proteins and cannot be attributed to the lack of a GPI-anchor. The different intracellular location and post-translational modification of recombinant proteins expressed in insect cells, as compared to the native proteins expressed in parasites, and the possible implications for vaccine development are discussed.