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.     

Intracellular Cleavage of Human Influenza A Virus Hemagglutinin and Its Inhibition

Replication of human influenza A viruses and proteolytic cleavage of the viral glycoprotein HA0 HA1/2 were studied in passaged cultures of epithelial cells of the serous membrane of human large intestine (CACO-2 line), dog kidney cells (MDCK), and monkey kidney cells (CV-1). Cleavage of the viral glycoprotein HA0, synthesis of activated virions, multicycle virus infection, and effective production of viral foci under an agarose overlayer were found in CACO-2 cells. By pulse–chase labeling of viral glycoproteins, testing the sensitivity to endoglycosidase-H of the viral glycoproteins HA0 and HA1/2 synthesized, and inhibiting the HA0 proteolysis with brefeldin A, the HA0 HA1/2 proteolysis was established to occur in the late stages of intracellular transport in the trans-Golgi and plasma membrane areas of the cells. Proteolysis of the viral glycoprotein HA0 in CACO-2 cells was suppressed by aprotinin, a natural inhibitor of serine proteinases. Unlike MDCK and CV-1 cells resistant to apoptosis induced by influenza virus, CACO-2 cells retained their viability for 2-3 days after infection with human influenza A virus.     

Interaction of influenza A virus M1 matrix protein with caspases

In this investigation, an ability of influenza A virus M1 matrix protein to bind intracellular caspases, the key enzymes of cell apoptosis, has been examined. Protein–protein binding on polystyrene plates and polyvinyl pyrrolidone membrane was employed for this purpose. Under a comparative study of caspases-3, -6, -7, -8 influenza virus M1 protein specifically bound caspase-8 and weakly bound caspase-7. Using a computer analysis of the N-terminal region of M1 protein, a site similar to the anti-caspase site of baculovirus p35 protein, which inhibits caspases and displays antiapoptotic activity, was identified. These results are in good agreement with the supposition that influenza virus M1 protein is involved in a caspase-8-mediated apoptosis pathway in influenza virus infected cells.     

Identification of the Protease-Binding Domain in the N-Terminal Region of Influenza Virus A Matrix Protein M1

A region responsible for protease binding by influenza virus A matrix protein M1 was identified. Trypsin binding was observed with the N-proximal 9-kDa fragment obtained by cleaving M1 with formic acid. The binding was inhibited by monoclonal antibodies (mAb) to region 46–70 of M1 and by an antiserum to region 21–45, whereas mAb to the middle and C-terminal regions had no effect. Thus, the protease-binding domain was mapped to the N-terminal part of M1.     

NS1 Protein of Influenza A Virus Down-Regulates Apoptosis

Wild-type (WT) influenza A/PR/8/34 virus and its variant lacking the NS1 gene (delNS1) have been compared for their ability to mediate apoptosis in cultured cells and chicken embryos. Cell morphology, fragmentation of chromatin DNA, and caspase-dependent cleavage of the viral NP protein have been used as markers for apoptosis. Another marker was caspase cleavage of the viral M2 protein, which was also found to occur in an apoptosis-specific manner. In interferon (IFN)-competent host systems, such as MDCK cells, chicken fibroblasts, and 7-day-old chicken embryos, delNS1 virus induced apoptosis more rapidly and more efficiently than WT virus. As a consequence, delNS1 virus was also more lethal for chicken embryos than WT virus. In IFN-deficient Vero cells, however, apoptosis was delayed and developed with similar intensity after infection with both viruses. Taken together, these data indicate that the IFN antagonistic NS1 protein of influenza A viruses has IFN-dependent antiapoptotic potential.     

Biochemical mechanisms of fluorine action

Biochemical mechanisms of fluorine ion action accounting for the biological role and significance of fluorine for vital activity of the organism are investigated. Results of these investigations are generalized. This trace element is shown to participate at least in two vitally important systems of the organism: the adenylate cyclase system which accounts for the cell response to neuroendocrinological information and the immune protection system providing antimicrobic resistance. Available data permit considering that cytotoxic fluorine action is based on the ability to hinder protein synthesis in eukaryotes and to stimulate peroxidation processes of biomembrane lipids. Inorganic fluorine compounds are recommended to be used with the treatment-and-prophylactic purpose for certain pathologic states, associated with its insufficient or excessive arrival into the organism.     

Induced expression of <Emphasis Type="Italic">Serratia marcescens</Emphasis> ribonuclease III gene in transgenic <Emphasis Type="Italic">Nicotiana tabacum</Emphasis> L. cv. SR1 tobacco plants

Transgenic Nicotiana tabacum L. cv. SR1 plants, characterized by an increase in the level of dsRNA-specific hydrolytic activity after induction by wounding, were obtained. The Solanum lycopersicum anionic peroxidase gene promoter (new for plant genetic engineering) was for the first time used for the induced expression of the target Serratia marcescens RNase III gene. Upon infection with the tobacco mosaic virus (TMV), the transgenic plants of the obtained lines did not differ significantly from the control group in the level of TMV capsid protein accumulation. In general, no delay in the development of the infection symptoms was observed in transgenic plants as compared with the control group. The obtained transgenic plants represent a new model for the study of the biological role of endoribonucleases from the RNase III family, including in molecular mechanisms of resistance to pathogens.     

Influenza virus proteins: preparation of a soluble M1 polypeptide by means of a stepwise deproteination of virions

Layer by layer uncoating of influenza A and B viruses with non-ionic detergent (NP-40) at fixed pH was developed. Treatment of virions with NP-40 at neutral or alkaline pH solubilized the lipoprotein envelope and the surface glycopolypeptides HA1 and HA2, but the internal core structures containing matrix protein M1 remained. Exposition of the cores in acidic media (pH 4,5 and lower) selectively solubilized protein M1 and released viral ribonucleoprotein (RNP). The resulting M1 sedimented in a glycerol gradient with a coefficient of 2.8 S and most probably exists as a monomer of 27,000 Da polypeptide. Neutralization of protein M1 with Tris-HC1 at pH 7.0 did not cause aggregation of M1 polypeptides. The described method of viron layer by layer uncoating with non-ionic detergent at fixed pH is suitable for isolation of subvirus structures and individual viral proteins.     

Antiviral activity of proteinase inhibitors in cultured cells infected with alpha-viruses

The ability of synthetic inhibitors of trypsin-like (TLCK) and chymotrypsin-like (TPCK) proteinases and natural antiproteinase oligopeptides of animal (aprotinin) and microbial (enzistatin) origin to suppress multicycle replication of different alpha viruses (Semliki, Sindbis, Venezuelan equine encephalomyelitis viruses) in cultured cells was studied. Antiviral activity was found to be induced by TPCK and aprotinin (Gordox). These compounds were shown to reduce virus yield 100-fold and to prevent the involvement of cells into infection process. The mechanisms of antiviral activity and chemotherapeutic possibilities of antiproteinase compounds are discussed.