Nonvirion protein of novirhabdovirus suppresses apoptosis at the early stage of virus infection

Viral hemorrhagic septicemia virus (VHSV) and infectious hematopoietic necrosis virus (IHNV) are members of the genus Novirhabdovirus within the Rhabdoviridae family, which can cause severe hemorrhagic disease in fresh- and saltwater fish worldwide. These viruses carry an additional nonvirion (NV) gene, which codes for the nonstructural NV protein that has been implicated to play a role in viral pathogenesis. To determine the precise biological function of this NV gene and its gene product, we generated NV-deficient and NV knockout recombinant VHSVs, using reverse genetics. Comparisons of the replication kinetics and markers for virus-induced apoptosis indicated that the NV-deficient and NV knockout mutant viruses induce apoptosis earlier in cell culture than the wild-type recombinant VHSV. These results suggest that the NV protein has an antiapoptotic function at the early stage of virus infection. Furthermore, we created a chimeric VHSV, in which the NV gene of VHSV was replaced by the IHNV NV gene, which was capable of suppressing apoptosis in cell culture. These results show that the NV protein of other members of Novirhabdovirus can restore the NV protein function. In this study, we also investigated the kinetics of VHSV replication during a single round of viral replication and examined the mechanism of VHSV-induced apoptosis. Our results show that VHSV infection induced caspases 3, 8 and 9 in cell culture.     

Caspase cleavage of the nonstructural protein NS1 mediates replication of Aleutian mink disease parvovirus

Virus-induced apoptosis of infected cells can limit both the time and the cellular machinery available for virus replication. Hence, many viruses have evolved strategies to specifically inhibit apoptosis. However, Aleutian mink disease parvovirus (ADV) is the first example of a DNA virus that not only induces apoptosis but also utilizes caspase activity to facilitate virus replication. To determine the function of caspase activity during ADV replication, virus-infected cell lysates or purified ADV proteins were incubated with various purified caspases. Caspases cleaved the major nonstructural protein of ADV (NS1) at two caspase recognition sequences, whereas ADV structural proteins could not be cleaved. Importantly, the NS1 products could be identified in ADV-infected cells but were not present in infected cells pretreated with caspase inhibitors. By mutating putative caspase cleavage sites (D to E), we mapped the two cleavage sites to amino acid residues NS1:227 (INTD downward arrow S) and NS1:285 (DQTD downward arrow S). Replication of ADV containing either of these mutations was reduced 10(3)- to 10(4)-fold compared to that of wild-type virus, and a construct containing both mutations was replication defective. Immunofluorescent studies revealed that cleavage was required for nuclear localization of NS1. The requirement for caspase activity during permissive replication suggests that limitation of caspase activation and apoptosis in vivo may be a novel approach to restricting virus replication.     

Cells lacking NF-kappaB or in which NF-kappaB is not activated vary with respect to ability to sustain herpes simplex virus 1 replication and are not susceptible to apoptosis induced by a replication-incompetent mutant virus

Earlier we reported that NF-kappaB is activated by protein kinase R (PKR) in herpes simplex virus 1-infected cells. Here we report that in PKR(-/-) cells the yields of wild-type virus are 10-fold higher than in PKR(+/+) cells. In cells lacking NF-kappaB p50 (nfkb1), p65 (relA), or both p50 and p65, the yields of virus were reduced 10-fold. Neither wild-type nor mutant cells undergo apoptosis following infection with wild-type virus. Whereas PKR(+/+) and NF-kappaB(+/+) control cell lines undergo apoptosis induced by the d120 (Deltaalpha4) mutant of HSV-1, the mutant PKR(-/-) and NF-kappaB(-/-) cell lines were resistant. The evidence suggests that the stress-induced apoptosis resulting from d120 infection requires activation of NF-kappaB and that this proapoptotic pathway is blocked in cells in which NF-kappaB is not activated or absent. Activation of NF-kappaB in the course of viral infection may have dual roles of attempting to curtain viral replication by rendering the cell susceptible to apoptosis induced by the virus and by inducing the synthesis of proteins that enhance viral replication.     

Influenza A virus NS1 protein activates the PI3K/Akt pathway to mediate antiapoptotic signaling responses

Recently we have shown that influenza A virus infection leads to activation of the phosphatidylinositol 3-kinase (PI3K)/Akt pathway and that this cellular reaction is dependent on the expression of the viral nonstructural protein 1 (NS1). These data also suggested that PI3K activation confers a virus-supporting activity at intermediate stages of the infection cycle. So far it is not known which process is regulated by the kinase that supports virus replication. It is well established that upon infection with influenza A virus, the expression of the viral NS1 keeps the induction of beta interferon and the apoptotic response within a tolerable limit. On a molecular basis, this activity of NS1 has been suggested to preclude the activation of cellular double-stranded RNA receptors as well as impaired modulation of mRNA processing. Here we present a novel mode of action of the NS1 protein to suppress apoptosis induction. NS1 binds to and activates PI3K, which results in the activation of the PI3K effector Akt. This leads to a subsequent inhibition of caspase 9 and glycogen synthase-kinase 3beta and limitation of the virus-induced cell death program. Thus, NS1 not only blocks but also activates signaling pathways to ensure efficient virus replication.     

Caspase 3 activation is essential for efficient influenza virus propagation

Apoptosis is a hallmark event observed upon infection with many viral pathogens, including influenza A virus. The apoptotic process is executed by a proteolytic system consisting of a family of cysteinyl proteases, termed caspases. Since the consequences of apoptosis induction and caspase activation for the outcome of an influenza virus infection are not clear, we have addressed this issue by interfering with expression or function of a major virus-induced apoptosis effector, caspase 3. Surprisingly, influenza virus propagation was strongly impaired in the presence of an inhibitor that blocks caspase 3 and in cells where caspase 3 was partially knocked down by small interfering RNAs. Consistent with these findings, poor replication efficiencies of influenza A viruses in cells deficient for caspase 3 could be boosted 30-fold by ectopic expression of the protein. Mechanistically, the block in virus propagation appeared to be due to retention of the viral RNP complexes in the nucleus, preventing formation of progeny virus particles. Our findings indicate that caspase 3 activation during the onset of apoptosis is a crucial event for efficient influenza virus propagation.     

Influenza A virus NS1 protein‐induced JNK activation and apoptosis are not functionally linked

Expression of the influenza A virus (IAV) nonstructural protein (NS1) results in the activation of c‐Jun N‐terminal kinase (JNK). Both NS1 and JNK are involved in apoptosis induction. To investigate their interrelationship, we stably expressed a tamoxifen inducible NS1 oestrogen receptor fusion‐protein (NS1ERT) in mammalian cells. Upon tamoxifen stimulation, NS1ERT‐expressing cells partially rescued the attenuated replication of NS1‐deficient IAVs and also inhibited interferon up‐regulation, confirming the functional competence of NS1ERT. Tamoxifen‐induced NS1ERT created a cytopathic phenotype and led to the activation of JNK and apoptosis. Induction of NS1F103SERT mutant failed to activate JNK, but induced apoptosis, whereas the induction of NS1M106IERT led to JNK phosphorylation, but not apoptosis, indicating that JNK activation and apoptosis induction are not functionally linked. Further mutational analysis highlighted that apoptosis induction is a function of the C‐terminal effector domain of NS1. Finally, IAVs encoding mutant NS1 revealed a modulating effect of NS1 on apoptosis induction in a genuine infection. With respect to apoptogenicity, an NS1 mutant virus that results in a super activation of JNK behaves similarly to the JNK nonactivating virus expressing NS1F103S, thus confirming that NS1‐mediated JNK activation and apoptosis induction are also functionally independent from each other in vivo.     

Critical role for voltage-dependent anion channel 2 in infectious bursal disease virus-induced apoptosis in host cells via interaction with VP5

Infectious bursal disease (IBD) is an acute, highly contagious, and immunosuppressive avian disease caused by IBD virus (IBDV). Although IBDV-induced host cell apoptosis has been established, the underlying molecular mechanism is still unclear. We report here that IBDV viral protein 5 (VP5) is a major apoptosis inducer in DF-1 cells by interacting with the voltage-dependent anion channel 2 (VDAC2) in the mitochondrion. We found that in DF-1 cells, VP5-induced apoptosis can be completely abolished by 4,4'-diisothiocyanatostibene-2,2'-disulfonic acid (DIDS), an inhibitor of VDAC. Furthermore, knockdown of VDAC2 by small interfering RNA markedly inhibits IBDV-induced apoptosis associated with decreased caspase-9 and -3 activation and cytochrome c release, leading to increased IBDV growth in host cells. Thus, VP5-induced apoptosis during IBDV infection is mediated by interacting with VDAC2, a protein that appears to restrict viral replication via induction of cell death.     

Hepatitis C virus NS5A and subgenomic replicon activate NF-kappaB via tyrosine phosphorylation of IkappaBalpha and its degradation by calpain protease

Hepatitis C virus nonstructural protein 5A (NS5A) has been implicated in the HCV antiviral resistance, replication, and transactivation of cellular gene expression. We have recently shown that HCV NS5A activates NF-kappaB via oxidative stress (22). In this study, we investigate the molecular mechanism(s) of NF-kappaB activation in response to oxidative stress induced by NS5A protein. In contrast to the classic Ser32,36 phosphorylation of IkappaBalpha, we report here that tyrosine phosphorylation of IkappaBalpha at Tyr42 and Tyr305 residues is induced by the HCV NS5A and the subgenomic replicons in the NF-kappaB activation process. Use of IkappaBalpha-Tyr42,305 double mutant provided the evidence for their key role in the activation of NF-kappaB. Activation of NF-kappaB was blocked by a series of tyrosine kinase inhibitors but not by IkappaB kinase inhibitor BAY 11-7085. More specifically, a ZAP-70 knock-out cell line expressing NS5A and other nonstructural proteins respectively prevented the NF-kappaB activation, indicating the involvement of ZAP-70 as a probable tyrosine kinase in the activation process. Evidence is also presented for the possible role of calpain proteases in the NS5A-induced IkappaBalpha degradation. These studies collectively define an alternate pathway of NF-kappaB activation by NS5A alone or in the context of the HCV subgenomic replicon. Constitutive activation of NF-kappaB by HCV has implications in the chronic liver disease including hepatocellular carcinoma associated with HCV infection.     

trans-Complementation of yellow fever virus NS1 reveals a role in early RNA replication.

Mutational analysis of the nonstructural protein 1 (NS1) of yellow fever virus (YF) has implicated it in viral RNA replication. To further explore this observation, we sought a method for uncoupling NS1 function from NS1 expression and processing as part of the large YF polyprotein. Here we describe a strategy for providing NS1 in trans, utilizing a noncytopathic Sindbis virus vector. Replication of a defective YF genome containing a large in-frame deletion of NS1 was dependent on functional expression of NS1. Recovered mutant virus was shown to contain the deletion and was neutralized by YF-specific antiserum. Complemented mutant virus increased in titer with kinetics similar to those of parental YF 17D but peaked at lower titers. trans-complementation has allowed us to derive high-titer, helper-free stocks of YF defective in NS1 with which to further characterize the role of this gene product in RNA replication. The first cycles of RNA replication were analyzed by using a sensitive strand-specific RNase protection assay. We document these events for mutant and wild-type viruses in the presence or absence of complementation. These data strongly suggest a role for NS1 prior to or at initial minus-strand synthesis.     

Nonstructural proteins of respiratory syncytial virus suppress premature apoptosis by an NF-kappaB-dependent, interferon-independent mechanism and facilitate virus growth

The two nonstructural (NS) proteins NS1 and NS2 of respiratory syncytial virus (RSV) are abundantly expressed in the infected cell but are not packaged in mature progeny virions. We found that both proteins were expressed early in infection, whereas the infected cells underwent apoptosis much later. Coincident with NS protein expression, a number of cellular antiapoptotic factors were expressed or activated at early stages, which included NF-kappaB and phosphorylated forms of protein kinases AKT, phosphoinositide-dependent protein kinase, and glycogen synthase kinase. Using specific short interfering RNAs (siRNAs), we achieved significant knockdown of one or both NS proteins in the infected cell, which resulted in abrogation of the antiapoptotic functions and led to early apoptosis. NS-dependent suppression of apoptosis was observed in Vero cells that are naturally devoid of type I interferons (IFN). The siRNA-based results were confirmed by the use of NS-deleted RSV mutants. Early activation of epidermal growth factor receptor (EGFR) in the RSV-infected cell did not require NS proteins. Premature apoptosis triggered by the loss of NS or by apoptosis-promoting drugs caused a severe reduction of RSV growth. Finally, recombinantly expressed NS1 and NS2, individually and together, reduced apoptosis by tumor necrosis factor alpha, suggesting an intrinsic antiapoptotic property of both. We conclude that the early-expressed nonstructural proteins of RSV boost viral replication by delaying the apoptosis of the infected cell via a novel IFN- and EGFR-independent pathway.     

Regulation of minute virus of mice NS1 replicative functions by atypical PKClambda in vivo

Minute virus of mice NS1 protein is a multifunctional phosphoprotein endowed with a variety of enzymatic and regulatory activities necessary for progeny virus particle production. To regulate all of its different functions in the course of a viral infection, NS1 has been proposed to be modulated by posttranslational modifications, in particular, phosphorylation. Indeed, it was shown that the NS1 phosphorylation pattern is altered during the infectious cycle and that the biochemical profile of the protein is dependent on the phosphorylation state of the polypeptide. Moreover, in vitro approaches have identified members of the protein kinase C (PKC) family, in particular, atypical PKC, as regulators of viral DNA replication through the phosphorylation of NS1 residues T435 and S473, thereby activating the protein for DNA unwinding activities. In order to substantiate these findings in vivo, we produced NS1 in the presence of a dominant-negative PKClambda mutant and characterized the purified protein in vitro. The NS1 protein produced under these conditions was found to be only partially phosphorylated and as a consequence to be deficient for viral DNA replication. However, it could be rescued for this viral function by treatment with recombinant activated PKClambda. Our data clearly demonstrate that NS1 is a target for PKClambda phosphorylation in vivo and that this modification is essential for the helicase activity of the viral polypeptide. In addition, the phosphorylation of NS1 at residues T435 and S473 appeared to occur mainly in the nucleus, providing further evidence for the involvement of PKClambda which, unlike PKCzeta, accumulates in the nuclear compartment of infected cells.     

Replication of modified vaccinia virus Ankara in primary chicken embryo fibroblasts requires expression of the interferon resistance gene E3L

Highly attenuated modified vaccinia virus Ankara (MVA) serves as a candidate vaccine to immunize against infectious diseases and cancer. MVA was randomly obtained by serial growth in cultures of chicken embryo fibroblasts (CEF), resulting in the loss of substantial genomic information including many genes regulating virus-host interactions. The vaccinia virus interferon (IFN) resistance gene E3L is among the few conserved open reading frames encoding viral immune defense proteins. To investigate the relevance of E3L in the MVA life cycle, we generated the deletion mutant MVA-DeltaE3L. Surprisingly, we found that MVA-DeltaE3L had lost the ability to grow in CEF, which is the first finding of a vaccinia virus host range phenotype in this otherwise highly permissive cell culture. Reinsertion of E3L led to the generation of revertant virus MVA-E3rev and rescued productive replication in CEF. Nonproductive infection of CEF with MVA-DeltaE3L allowed viral DNA replication to occur but resulted in an abrupt inhibition of viral protein synthesis at late times. Under these nonpermissive conditions, CEF underwent apoptosis starting as early as 6 h after infection, as shown by DNA fragmentation, Hoechst staining, and caspase activation. Moreover, we detected high levels of active chicken alpha/beta IFN (IFN-alpha/beta) in supernatants of MVA-DeltaE3L-infected CEF, while moderate IFN quantities were found after MVA or MVA-E3rev infection and no IFN activity was present upon infection with wild-type vaccinia viruses. Interestingly, pretreatment of CEF with similar amounts of recombinant chicken IFN-alpha inhibited growth of vaccinia viruses, including MVA. We conclude that efficient propagation of MVA in CEF, the tissue culture system used for production of MVA-based vaccines, essentially requires conserved E3L gene function as an inhibitor of apoptosis and/or IFN induction.