Adenovirus VAI RNA antagonizes the antiviral action of interferon by preventing activation of the interferon-induced eIF-2 alpha kinase

Interferon-gamma-induced assembly block in the replication cycle of adenovirus 2: augmentation by tumour necrosis factor-alpha

Replication of adenovirus 2 (Ad-2) is inhibited in A 549 cells pretreated with interferon-gamma (IFN-gamma). The antiviral effect is synergistically enhanced by the simultaneous presence of tumor necrosis factor-alpha (TNF-alpha) before infection. Under conditions of strong inhibition of virus progeny formation, viral DNA synthesis and [35S]methionine incorporation into most late viral proteins are only marginally impaired. Pulse chase experiments indicate a partial inhibition of processing of viral proteins. Viral proteins are not degraded and capsomeres accumulate in the inhibitor-treated cells. Capsid formation, on the other hand, is strongly inhibited in the cytokine-treated cells. The inhibition of Ad-2 replication in A 549 cells by IFN-gamma and TNF-alpha is caused, therefore, by a block in the maturation of Ad-2.

Role of the RNA-dependent protein kinase in the regulated expression of genes in transfected cells

The RNA-dependent P1/eIF-2 alpha protein kinase is a highly specific protein-serine/threonine kinase that catalyzes the phosphorylation of the alpha subunit of protein synthesis initiation factor eIF-2. The kinase plays a central role in translational control. The activity of the kinase is regulated by a variety of naturally occurring effector RNAs which bind to the regulatory domain of the enzyme. Certain RNAs are able to activate the eIF-2 alpha kinase activity inherent within protein P1, a process which involves an autophosphorylation of protein P1, whereas other RNAs are able to antagonize the activation process. Translational repression mediated by the kinase may also be disrupted by RNA binding proteins that sequester activator double-stranded RNAs and by site-directed mutants and homologs of the eIF-2 alpha translation factor substrate. The P1/eIF-2 alpha protein kinase is an important regulator of the translation of plasmid-derived mRNAs in transfected eukaryotic cells.

Viral inhibition of the interferon system

In response to interferon (IFN), cells develop an antiviral state in which the replication of a wide spectrum of RNA and DNA viruses is inhibited. Viruses have evolved a variety of mechanisms to inhibit the production and action of the interferons. Interferon action may be blocked by inhibition of the post-receptor signalling pathway, which prevents the expression of a number of proteins with antiviral properties. Other viruses prevent the action of specific, interferon-induced antiviral systems. In particular, the action of the dsRNA-dependent protein kinase (DAI) is inhibited by a variety of different viruses, indicating the fundamental importance of this enzyme to the antiviral response.

Interferon alpha (IFN)-macrophage interactions in human immunodeficiency virus (HIV) infection: role of IFN in the tempo and progression of HIV disease

Components of the host immune response that constrain virus replication and affect long-lasting antiviral immunity following HIV infection are incompletely defined. IFNs are critical participants in host antiviral processes. While IFN induces significant anti-retroviral activities, they also serve as harbingers for poor clinical outcomes. Moreover, monocytes, a major cellular source of IFN and HIV in man, are poor producer cells for IFN following HIV infection. Indeed, HIV infection of monocytes results in a diminished production and induction of IFN. IFN is only produced during cell to cell contact between HIV-infected cells and uninfected PBMC. Analysis of the biologic activity of HIV-induced IFN(s) shows that it poorly restricts HIV replication. Thus, the role of IFN in HIV disease is complex and seemingly paradoxical. The diminished capacity of HIV-infected monocytes to produce IFN and the production of defective IFNs likely reflect specific viral adaptive mechanisms for persistent infection.

Characterization of a vaccinia virus-encoded double-stranded RNA-binding protein that may be involved in inhibition of the double-stranded RNA-dependent protein kinase

The work described in this article identifies a vaccinia virus-encoded protein that may be involved in inhibition of the interferon-induced, double-stranded RNA-dependent protein kinase. Extracts prepared from vaccinia virus (WR strain)-infected cells contain an inhibitor of this kinase. Inhibition was reduced in extracts from which dsRNA-binding proteins had been removed by preadsorption to poly(rI).poly(rC)-Sepharose, suggesting that a dsRNA-binding protein may be involved in kinase inhibition. A single major virus-specific polypeptide of Mr = 25,000 (p25) bound to the poly(rI).poly(rC)-Sepharose. p25 was synthesized in a coupled in vitro transcription/translation system programmed with vaccinia cores, indicating that it is a vaccinia-encoded protein. Synthesis of p25 was detected at early times, by 2 hr post infection, peaked at 5 hours postinfection, and decreased during the late phase of virus replication. In the presence of cytosine arabinoside p25 synthesis did not decrease at late times postinfection. Kinase inhibitory activity accumulated with similar kinetics to p25, both in the presence and absence of cytosine arabinoside. Kinase inhibitory activity copurified with p25, through gel filtration, and Cibacron blue-affinity chromatography. Removal of p25 by precipitation with antiserum to p25 decreased kinase inhibitory activity in extracts prepared from vaccinia virus-infected cells. These results suggest that p25 may be necessary for the specific kinase inhibitory activity detected in vaccinia virus-infected cells.

Repression of the interferon signal transduction pathway by the adenovirus E1A oncogene

The signal transduction pathway initiated by type I interferon (alpha and beta interferons) is inhibited by expression of the adenovirus type 5 E1A oncogene. Cotransfection analyses with the E1A oncogene and an interferon-stimulated reporter gene show that mutations within an amino-terminal domain of the E1A oncoprotein are defective in transcriptional repression. Cotransfection experiments also revealed that the transcriptional repression is mediated through the interferon-stimulated response element (ISRE) found within the promoter of interferon-stimulated genes. Since interferon treatment activates a latent cytoplasmic DNA-binding factor that can recognize the ISRE and subsequently stimulate transcription, the appearance of this factor was analyzed in a cell line that constitutively expresses the E1A oncogene. The DNA binding activity of this transcriptional activator was found to be inhibited in the E1A-expressing cell line. In vitro cytoplasmic mixing experiments with extracts from control and E1A-expressing cells identified a specific component of this multimeric transcription factor to be defective.

Inhibition of interferon-inducible gene expression by adenovirus E1A proteins: block in transcriptional complex formation

Infection with wild-type adenovirus 5, but not with a mutant lacking the E1A gene, prevented the induction by interferon (IFN) alpha of chloramphenicol acetyltransferase (CAT) activity in HeLaM cell lines that had been permanently transfected with chimeric CAT reporter genes driven by the transcriptional regulatory regions of the IFN-responsive genes 561 and 6-16. Similar inhibition of IFN-inducible CAT activity was observed in cells that were cotransfected with the same reporter genes and plasmids expressing either the E1A 289- or 243-amino acid protein. These proteins also prevented the induction of CAT activity by IFN-gamma from a cotransfected HLA-DR alpha-CAT gene. Experiments with E1A mutants mapped the inhibitory activity to amino acid residues 38-65 of these proteins. In a HeLa cell line permanently expressing the E1A 289-amino acid protein, the replication of vesicular stomatitis virus and encephalomyocarditis virus was not inhibited by IFN-alpha, suggesting a global blockade of IFN responses. In accord with this theory, induction of 561, 1-8, and (2'-5')oligoadenylate synthetase mRNAs by IFN was blocked in these cells at the transcriptional level. The observed transcriptional inhibition could be attributed to the lack of formation of the crucial IFN-stimulated gene factor 3 (ISGF3) transcriptional complex. As shown by mobility shift assays, this complex was not formed in the nuclear extracts of IFN-treated adenovirus-infected cells or IFN-treated E1A-producing cells. These nuclear extracts were deficient in both ISGF3 alpha and ISGF3 gamma subunits. However, they did not block the formation of ISGF3 complex from exogenously added components.

The Lang strain of reovirus serotype 1 and the Dearing strain of reovirus serotype 3 differ in their sensitivities to beta interferon

Replication of the Dearing strain of reovirus serotype 3 in mouse L cells was decreased 17- to 100-fold when a saturating dose of beta interferon (1,000 IU/ml) was used. Replication of the Lang strain of reovirus serotype 1 was inhibited only two- to threefold under similar conditions. It therefore appears that closely related strains of reovirus differ in their sensitivities to beta interferon treatment of mouse L cells.

Inhibition of the cellular response to interferons by products of the adenovirus type 5 E1A oncogene

Expression of the E1A oncogene of adenovirus type 5 inhibits the response of interferon (IFN)-inducible constructs to Type I (alpha,beta) and II (gamma) IFNs in transient transfection assays. In human cell lines stably expressing E1A mRNA and protein acquisition of an antiviral state and the induction of a number of genes in response to alpha- and gamma-IFNs is inhibited. A short IFN-stimulable response element (ISRE) present in the 5' flanking region of a number of genes mediates induction by alpha- and gamma-IFNs. In cells expressing E1A there is a substantial reduction in the levels of the ISRE-binding factors E and M, inducible by alpha-IFN, and of factor G, inducible by gamma-IFN. In E1A-expressing cells the E alpha subunit of factor E is activated normally in response to alpha-IFN; the defect is in the production or activation of the E gamma subunit. The inhibitory activity of E1A is lost upon deletion of the CR1 domain. The induction of HLA class II genes by gamma-IFN, which involves a different DNA response element(s), and of beta-IFN mRNA in response to double-stranded RNA are also inhibited by E1A. An essential component(s) of a number of signalling pathways must, therefore, be subject, directly or indirectly, to inhibition by E1A.

Binding of the adenovirus VAI RNA to the interferon-induced 68-kDa protein kinase correlates with function

In human cells infected with adenovirus, the virus-associated RNA VAI blocks the activation of the interferon-induced double-stranded-RNA-dependent 68-kDa protein kinase (p68) and maintains normal levels of protein synthesis at late times after infection. VAI antagonizes the kinase activity by binding to p68. The structure of VAI consists of two long, base-paired stems connected by a complex short stem-loop structure. Previous work using a series of adenovirus mutants showed that the structural determinants of the VAI RNA that are essential for function reside in the central complex short stem-loop structure and adjacent base-paired regions (functional domain); the long duplex regions were found to be dispensable for function. To determine whether binding of VAI to p68 correlates with function and whether the structural determinants that are essential for function are also essential for binding, we studied the interaction of wild-type and several mutant VAI RNAs with p68 in whole cells. The p68-VAI complexes from mutant- and wild-type-infected cells were immunoprecipitated by an anti-p68 monoclonal antibody. The mutant RNAs that functioned efficiently in the cells bound to p68 efficiently in the cells, whereas functionally impaired mutants failed to bind to p68, indicating that the binding of the VAI RNA to p68 correlates well with function. In vitro binding assays with immunopurified p68 confirmed these observations. Secondary-structure analysis of several mutant VAI RNAs suggests that the binding does not depend on the long duplex regions but requires all the elements of the functional domain. We propose that the functional domain and the p68-binding domain of the VAI RNA are identical.

Interferon-induced and double-stranded RNA-activated enzymes: a specific protein kinase and 2',5'-oligoadenylate synthetases

Treatment of cells with interferon (IFN) results in the induction of two double-stranded RNA (dsRNA)-activated enzymes: a specific protein kinase and 2'-5' linked oligoadenylate [pppA(2'p5'A)n referred to as 2-5A] synthetases. The protein kinase, when activated by dsRNA, becomes autophosphorylated and catalyzes and phosphorylation of the protein synthesis initiation factor, eIF2. The 2-5A synthetases, when activated by dsRNA, form 2-5A molecules capable of activating a latent endoribonuclease that degrades RNA. By inhibiting initiation of protein synthesis or by degrading of RNA, these enzymes play key roles in two independent pathways that regulate overall protein synthesis.

The control of interferon-inducible gene expression

The alpha beta interferons (IFNs) transiently induce genes through an IFN-stimulable DNA response element (ISRE). IFN-cell surface receptor interaction triggers the cytoplasmic activation of the complex primary transcription factor E, which on translocation and interaction with the ISRE initiates transcription. Whether E is activated directly through the receptor(s) or through a more classical second message pathway(s) and the roles of additional factors in the alpha beta and gamma IFN responses remain to be established. Meanwhile analysis of mutants has revealed complexity and overlap in the alpha, beta and gamma IFN response pathways and the products of at least two viruses have been shown to inhibit IFN-inducible gene expression.

Regulation of a double-stranded RNA modification activity in human cells

A double-stranded RNA (dsRNA)-specific modification activity from Xenopus oocytes and human cells dsRNA modifier) converts adenosine residues present in dsRNA to inosines. The function of the dsRNA modifier is unknown, although it has been suggested that it may be part of the cellular antiviral response. We investigated the relationship between the activity of the dsRNA modifier, viral infection, and the antiviral response in human cells induced by poly(rI)-poly(rC) [poly(I.C)] treatment. We found, unexpectedly, that treatment of HeLa cells with poly(I.C) or other dsRNA molecules resulted in the dramatic inhibition of the dsRNA modifier. Mixing experiments, reconstruction experiments, and pretreatment of extracts with RNases indicated that inhibition of the dsRNA modifier did not result from the continued presence of a soluble inhibitor such as dsRNA) in the in vitro modification reactions. Treatment of cells with cyclohexamide or dactinomycin simultaneously with the poly(I.C) demonstrated that in vivo inhibition of the dsRNA modifier did not require new transcription or translation. The dsRNA modification activity was also substantially inhibited in cells infected with poliovirus and was slightly inhibited in cells infected with adenovirus. The inhibition of the dsRNA modifier during the antiviral state is thus not consistent with an antiviral function, and instead suggests another cellular function for dsRNA modification.

Regulation of a double-stranded RNA modification activity in human cells

A double-stranded RNA (dsRNA)-specific modification activity from Xenopus oocytes and human cells dsRNA modifier) converts adenosine residues present in dsRNA to inosines. The function of the dsRNA modifier is unknown, although it has been suggested that it may be part of the cellular antiviral response. We investigated the relationship between the activity of the dsRNA modifier, viral infection, and the antiviral response in human cells induced by poly(rI)-poly(rC) [poly(I.C)] treatment. We found, unexpectedly, that treatment of HeLa cells with poly(I.C) or other dsRNA molecules resulted in the dramatic inhibition of the dsRNA modifier. Mixing experiments, reconstruction experiments, and pretreatment of extracts with RNases indicated that inhibition of the dsRNA modifier did not result from the continued presence of a soluble inhibitor such as dsRNA) in the in vitro modification reactions. Treatment of cells with cyclohexamide or dactinomycin simultaneously with the poly(I.C) demonstrated that in vivo inhibition of the dsRNA modifier did not require new transcription or translation. The dsRNA modification activity was also substantially inhibited in cells infected with poliovirus and was slightly inhibited in cells infected with adenovirus. The inhibition of the dsRNA modifier during the antiviral state is thus not consistent with an antiviral function, and instead suggests another cellular function for dsRNA modification.

Antiviral actions of interferon. Interferon-regulated cellular proteins and their surprisingly selective antiviral activities

Considerable progress has been made in the understanding of the molecular biology of the human interferon system. The genes encoding the interferons, their receptors, and the proteins that mediate many of their biological effects have been molecularly cloned and characterized. The availability of complete cDNA clones of components of the interferon systems has contributed significantly to our understanding of both the biology and the biochemistry of the antiviral actions of interferons. At the biological level, the antiviral effects of interferon may be viewed to be virus-type nonspecific. That is, treatment of cells with one type or even subspecies of interferon often leads to the generation of an antiviral state effective against a wide array of different RNA and DNA animal viruses. However, at the biochemical level, the antiviral action of interferon is often virus-type selective. That is, the apparent molecular mechanism which is primarily responsible for the inhibition of virus replication may differ considerably between virus types, and even host cells. For example, the IFN-regulated Mx protein selectively inhibits influenza virus but not other viruses when constitutively expressed in mouse cells. The IFN-regulated 2',5'-oligoadenylate synthetase selectively inhibits EMC and mengo viruses, two picornaviruses, but not viruses of other families when constitutively expressed in transfected cells. Some viruses are typically insensitive to the antiviral effects of interferon, both in cell culture and in intact animals. This lack of sensitivity to IFN may result from a virus-mediated direct antagonism of the interferon system. For example, in the case of adenovirus, the activation of the IFN-regulated RNA-dependent P1/elF-2 protein kinase is blocked by the virus-associated VA RNA. The relative sensitivity to interferon of different animal viruses varies appreciably. All three of the basic components required to measure an antiviral response may play a role in determining the relative effectiveness of the antiviral response: the species of interferon administered; the kind of cell treated; and, the type of virus used to challenge the interferon-treated host cell. Thus, the relative sensitivity to interferon observed for a particular interferon-cell-virus combination is likely the result of the equilibrium between the many agonists and antagonists which contribute to the overall response. That is, the relative sensitivity of a virus to the inhibitory action of IFN is governed by the qualitative nature and quantitative amount of the individual IFN-regulated cell proteins that may collectively contribute to the inhibition of virus replication.(ABSTRACT TRUNCATED AT 400 WORDS)

Cellular response to double-stranded RNA

The study of double-stranded RNA (dsRNA) encompasses a variety of fields. Basic research in this area has contributed to a greater mechanistic understanding of gene induction, tumor cell growth arrest, the establishment of antiviral states, and immunomodulation. Because of the possible clinical value of these molecules, physicians are now exploring the use of synthetic dsRNA to treat patients with cancer, HIV-1 disease, and immune dysfunction. Continued studies of the mechanisms of action of dsRNA are likely to suggest an even wider scope of clinical applications.

Adenovirus inhibition of cellular protein synthesis involves inactivation of cap-binding protein

Adenovirus (Ad) infection results in a marked inhibition of cellular protein synthesis that initiates during the late phase of the viral infectious cycle. We show that the mechanism used for suppression of cellular protein synthesis during cell cycle progression is exploited by Ad to repress host and enhance late viral mRNA translation. Discrimination between cellular and late Ad mRNAs and inhibition of host protein synthesis are shown to involve viral-mediated underphosphorylation of cap-binding protein (CBP) and subsequent inactivation of CBP complex, a large enzymatic complex required for cap-dependent mRNA translation. Late Ad mRNAs, like those of poliovirus, possess the unique ability to translate independent of a normal cap recognition process and do not require the activity of CBP complex. Inhibition of cellular translation by these two viruses is quite similar, except that whereas CBP complex is proteolytically degraded by poliovirus, it is functionally inactivated by Ad.

Adenovirus type 2 VAI RNA transcription by polymerase III is blocked by sequence-specific methylation

Sequence-specific methylation of the promoter and adjacent regions in mammalian genes transcribed by RNA polymerase II leads to the inhibition of these genes. So far, RNA polymerase III-transcribed genes have not been investigated in depth. We therefore studied methylation effects on the RNA polymerase III-transcribed VAI gene of adenovirus type 2 DNA. The VAI gene contains 20 5'-CG-3' dinucleotides, of which 4 (20%) can be methylated by HpaII (5'-CCGG-3') and HhaI (5'-GCGC-3'). Three of these 5'-CG-3' sequences are located close to the internal regulatory region of the VAI segment. An unmethylated, a 5'-CCGG-3'- and 5'-GCGC-3'-methylated, and a 5'-CG-3'-methylated pUC18 construct containing the VAI and VAII regions were transfected into mammalian cells. In many experiments, an inactivating effect of 5'-CCGG-3' and 5'-GCGC-3' DNA methylation on the VAI region was not observed. In contrast, methylation of all 20 5'-CG-3' sequences in the VAI region by a CpG-specific DNA methyltransferase from Spiroplasma species did interfere with VAI transcription. Transcription of the VAI- and VAII- and of the VAI-containing constructs was also shown to be inhibited in an in vitro cell-free transcription system after the constructs had been methylated at the 5'-CCGG-3' and 5'-GCGC-3' sequences or at all 5'-CG-3' sequences. When an oligodeoxyribonucleotide which carried the internal control block A of the VAI region was methylated at three 5'-CG-3' sequences, the formation of a complex with HeLa nuclear proteins was abrogated. The results presented support the notion that the VAI gene transcribed by the DNA-dependent RNA polymerase III is also inactivated by methylation of the decisive 5'-CG-3' sequences.

Recombinant Epstein-Barr virus with small RNA (EBER) genes deleted transforms lymphocytes and replicates in vitro

Strains of Epstein-Barr virus (EBV) with deletions of the small RNA (EBER) genes were made by homologous recombination using the EBV P3HR-1 strain, which has undergone deletion of the essential transforming gene that encodes the EBV nuclear antigen, EBNA-2, and a DNA fragment that was wild type at the EBNA-2 locus but from which the EBER genes had been deleted. Even though the EBER and EBNA-2 genes are separated by 40 kilobases, selection for transforming P3HR-1 recombinants that required a restored EBNA-2 gene resulted in 20% cotransfer of the EBER deletion. EBER-deleted recombinants transformed primary B lymphocytes into lymphoblastoid cell lines (LCLs), which were indistinguishable form LCLs transformed by wild-type EBV in their proliferation, in latency-associated EBV gene expression, and in their permissiveness for EBV replication cycle gene expression. EBER-deleted virus from infected LCL clones could infect and growth-transform primary B lymphocytes. These procedures should be applicable to the construction of other EBV recombinants within 40 kilobases of the EBNA-2 gene. The EBER-deleted EBV recombinants should be useful in further evaluating the role of EBERs in EBV infection.

Activation of the double-stranded RNA-dependent eIF-2 alpha kinase by cellular RNA from 3T3-F442A cells

The interferon induced double-stranded-RNA-dependent eIF-2 alpha kinase has an established role in mediating part of interferons anti-viral effects. Several studies have suggested that it may have additional functions in cells not infected with virus. The mechanism of activation of the kinase and the consequences of its activity in uninfected cells remain to be determined. Our previous results have indicated that the activation (phosphorylation) of this kinase may be an important regulatory signal to the arrest of growth of mouse 3T3-F442A fibroblasts and their subsequent differentiation to adipocytes. We have found that the phosphorylation of the kinase occurred in vivo in the absence of viral infection and in vitro without the addition of dsRNA. We demonstrate here that total cytoplasmic RNA from 3T3-F442A cells contains a regulatory RNA(s) capable of activating dsRNA-dependent eIF-2 alpha kinase. Fractionation of the cytoplasmic RNA by oligo(dT)-cellulose indicated that the regulatory RNA eluted with the poly(A)-rich RNA fraction. It bound tightly to the dsRNA-dependent eIF-2 alpha kinase and was immune-precipitated with its antibodies as a complex of regulatory RNA and dsRNA-dependent eIF-2 alpha kinase. The regulatory RNA activity was further purified by phenol extraction of immune precipitates containing this complex. These findings indicated that the regulatory RNA forms a specific complex with the dsRNA-dependent eIF-2 alpha kinase. The activity of the regulatory RNA was sensitive to the dsRNA-specific RNase VI but not to proteinase K, DNase I or ssRNA-specific RNase T1. The activation of the dsRNA-dependent eIF-2 alpha kinase by regulatory RNA was prevented by addition of a high concentration of poly(I).poly(C). The regulatory RNA was also shown to activate partially purified dsRNA-dependent eIF-2 alpha kinase prepared from rabbit reticulocyte lysates and to inhibit protein synthesis in reticulocyte lysates. Our findings, that cellular RNAs can specifically activate the dsRNA-dependent eIF-2 alpha kinase, are consistent with a physiological role for the dsRNA-dependent eIF-2 alpha kinase and interferon during cell growth and differentiation. The relationship of the regulatory RNA activity to growth and differentiation of 3T3-F442A cells is discussed.

Modified subcellular localization of interferon-induced p68 kinase during encephalomyocarditis virus infection

The double-stranded (ds) RNA-activated protein kinase from human cells is a 68,000 Mr protein (p68 kinase) induced by interferon. When autophosphorylated, p68 kinase catalyzes the phosphorylation of the protein synthesis eukaryotic initiation factor-2, thus mediating inhibition of protein synthesis. The level of p68 kinase is dramatically reduced in nonionic detergent NP-40 extracts, obtained from interferon-treated cells during infection with encephalomyocarditis virus (EMCV) (A. G. Hovanessian, J. Galabru, E. Meurs, C. Buffet-Janvresse, J. Svab and N. Robert, Virology 159, 126-136, 1987). Here we show that such reduction of p68 kinase is in fact due to its reduced NP-40 solubility occurring during EMCV infection. However, p68 kinase can be recovered by extraction with an ionic detergent. Reduced NP-40 extractibility of p68 kinase is dependent on the multiplicity of virus infection and seems to be specific, since other cellular proteins as well as the 100-kDa 2',5'-oligoadenylate synthetase also induced by interferon are not modified. Immunofluorescence studies using specific antibodies demonstrated that p68 kinase which is distributed evenly in the cytoplasm of HeLa cells becomes concentrated around the nuclei after EMCV infection. As a consequence of aggregating around the nuclei, p68 kinase might then resist extraction by NP-40. The aggregated kinase is found to be already activated probably due to binding to the replicative form and/or to replicative intermediates of EMCV RNA. Through this process, the functioning of p68 kinase might be guaranteed by a localized activation in the replication complexes of EMCV.

Interferon selectively inhibits the expression of mitochondrial genes: a novel pathway for interferon-mediated responses

As an approach to identifying genes involved in physiological actions of interferons we used differential probes to screen a cDNA library from mouse L-929 cells treated with interferon alpha/beta. We identified two negatively regulated mRNA species which have been examined by analysis of the corresponding mRNAs and by DNA sequencing. Comparison with the GenBank database showed that these cDNA clones corresponded to mitochondrially encoded genes for cytochrome b and subunit I of cytochrome c oxidase. A further cDNA encompassing three mitochondrial genes was used as a probe to show that a third mRNA, NADH dehydrogenase subunit 5, was also down-regulated by interferon while a fourth, NADH dehydrogenase subunit 6, was unaffected. Expression of cytochrome b was also inhibited in mouse NIH 3T3 cells treated with interferon alpha/beta and in human Daudi lymphoblastoid cells treated with interferon alpha. The ability of interferon to reduce mitochondrial mRNA levels could be blocked by cycloheximide suggesting that these effects are mediated by an interferon-responsive nuclear gene which encodes a product capable of regulating mitochondrial gene expression. Analysis of proteins synthesized in the presence of emetine, a specific inhibitor of cytoplasmic translation, showed that the synthesis of several mitochondrial translation products, including cytochrome b, was reduced after treatment with interferon. Our results reveal a novel effect of interferon on cellular physiology which could have important consequences for understanding the effects of interferons as well as suggesting new mechanisms for the regulation of mitochondrial biogenesis and function.

Tat-responsive region RNA of human immunodeficiency virus 1 can prevent activation of the double-stranded-RNA-activated protein kinase

Transcription from the human immunodeficiency virus type 1 promoter gives rise to short cytoplasmic transcripts of approximately 60 nucleotides as well as to longer mRNAs. These RNAs contain the Tat-responsive region sequence, which is capable of assuming a stem-loop structure and has been implicated in the regulation of both transcription and translation. It has been reported that Tat-responsive region RNA inhibits translation in vitro through activation of an interferon-induced protein kinase, the double-stranded-RNA-activated inhibitor, which phosphorylates eukaryotic initiation factor 2. We show that the activation property is due to double-stranded RNA that often contaminates RNA synthesized in vitro using bacteriophage RNA polymerases. After purification, high concentrations of Tat-responsive region RNA inhibit the activation of double-stranded RNA-activated inhibitor, suggesting that it may serve to protect human immunodeficiency virus type 1 infection from a cellular defense mechanism.

Removal of double-stranded contaminants from RNA transcripts: synthesis of adenovirus VA RNAI from a T7 vector

Bacteriophage RNA polymerases are widely used to synthesize defined RNAs on a large scale in vitro. Unfortunately, the RNA product contains a small proportion of contaminating RNAs, including complementary species, which can lead to errors of interpretation. We cloned the gene encoding Ad2 VA RNAI into a vector containing a T7 RNA polymerase promoter in order to generate large quantities of VA RNA for the study of its interaction with the dsRNA-dependent protein kinase DAI. Exact copies of VA RNAI were synthesized efficiently, but were contaminated with small amounts of dsRNA which activated DAI and confounded interpretation of kinase assays. We therefore developed a method to remove the dsRNA contaminants, allowing VA RNAI and mutants to be tested for their ability to activate or inhibit DAI. This method appears to be generally applicable.

Adenovirus inhibition of cellular protein synthesis is prevented by the drug 2-aminopurine

Adenovirus infection results in the suppression of cellular protein synthesis, but the mechanism has not been established. In this report we demonstrate that the shut-off of cellular protein synthesis by adenovirus is prevented in cells by treatment with the drug 2-aminopurine. Treatment with 2-aminopurine is shown to prevent suppression of cellular translation without disrupting the normal viral block in the transport of cellular mRNAs from the nucleus to the cytoplasm. We show that viral suppression of cellular protein synthesis occurs concomitant with activation of the interferon-induced double-stranded RNA-activated inhibitor (DAI), a protein kinase, and phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha), but that prevention of host cell shut-off by 2-aminopurine occurs without a decrease in kinase activity or a dephosphorylation of eIF-2 alpha. Results are presented that indicate that activation of DAI kinase and phosphorylation of eIF-2 alpha may be required but are not sufficient to achieve inhibition of cellular protein synthesis during adenovirus infection. We suggest that other events, in particular the modification of additional initiation factors, are likely involved in viral inhibition of cellular translation.

Phosphorylation of protein synthesis initiation factor-2. Identification of the site in the alpha-subunit phosphorylated in reticulocyte lysates

The data presented here show that serine-51 of the alpha-subunit of eukaryotic initiation factor eIF-2 is the only residue phosphorylated by the eIF-2 alpha-specific kinases HCR (haem-controlled repressor) and dsI (double-stranded RNA-activated inhibitor) in vitro. This confirms our earlier finding that serine-48 is not labelled by either kinase. Methodology appropriate for the examination of phosphorylation sites in eIF-2 alpha in whole cells and their extracts has been developed, and used to study the site(s) in eIF-2 alpha labelled in reticulocyte lysates. Only serine-51 became phosphorylated under conditions of haem-deficiency or in the presence of double-stranded RNA. No evidence for a second phosphorylation site on the alpha-subunit was obtained with the lysates and conditions used here.

Herpesvirus saimiri U RNAs are expressed and assembled into ribonucleoprotein particles in the absence of other viral genes

Marmoset T lymphocytes transformed by herpesvirus saimiri contain a set of five virally encoded U RNAs called HSUR1 through HSUR5. HSUR genes have been individually transfected into a nonlymphoid, nonsimian cell line (HeLa cells) in the absence of any other coding regions of the herpesvirus saimiri genome. The levels of HSUR1 through HSUR4 in HeLa transient-expression systems are comparable to those found in virally transformed T cells (23 to 91%). In contrast, HSUR5 is expressed at ninefold-higher levels in transfected HeLa cells. Immunoprecipitation experiments show that HSURs expressed in transfected cells bind proteins with Sm determinants and acquire a 5' trimethylguanosine cap structure, as they do in transformed T cells. HSUR1 or HSUR4 particles from transfected HeLa cells migrate between 10S and 15S in velocity gradients, identical to the sedimentation of "monoparticles" produced in virally transformed lymphocytes. We conclude from these transfection experiments that no other herpesvirus saimiri or host-cell-specific gene products appear to be required for efficient expression of the HSUR genes or for subsequent assembly of the viral U RNAs into small nuclear ribonucleoprotein particles. In lymphocytes transformed by herpesvirus saimiri, HSUR small nuclear ribonucleoprotein particles are involved in higher-order complexes that sediment between 20S and 25S. HSUR1, HSUR2, and HSUR5 dissociate from such complexes upon incubation at 30 degrees C, whereas the complex containing HSUR4 is stable to incubation.

Purification and partial characterization of a cellular inhibitor of the interferon-induced protein kinase of Mr 68,000 from influenza virus-infected cells

A number of eukaryotic viruses have evolved mechanisms to downregulate activity of the interferon-induced, double-stranded RNA-activated protein kinase (referred to as P68 based on its Mr of 68,000 in human cells). This control is essential because once activated, the P68 kinase phosphorylates its natural substrate, the alpha subunit of the eukaryotic protein synthesis initiation factor 2 (eIF-2), limiting functional eukaryotic protein synthesis initiation factor 2 available for protein synthesis initiation. We have previously shown that influenza virus encoded a specific mechanism to repress the autophosphorylation and activity of P68. Using in vitro assays for P68 inhibition, we now have purified, to near homogeneity, the P68 repressor from influenza virus-infected cells. The purified product inhibited both the autophosphorylation of P68 as well as phosphorylation of the alpha subunit of eukaryotic protein synthesis initiation factor 2 by the kinase. We tested for both protease and phosphatase activity but found neither activity associated with the purified inhibitor. Surprisingly we found the purified repressor, which had an apparent Mr of approximately 58,000, was a cellular and not a viral-encoded protein. Possible mechanisms by which influenza virus activates this cellular regulator of the protein kinase, thereby minimizing potential antiviral effects of interferon, are discussed.

Resistance to influenza virus and vesicular stomatitis virus conferred by expression of human MxA protein

MxA and MxB are interferon-induced proteins of human cells and are related to the murine protein Mx1, which confers selective resistance to influenza virus. In contrast to the nuclear murine protein Mx1, MxA and MxB are located in the cytoplasm, and their role in the interferon-induced antiviral state was unknown. In this report we show that transfected cell lines expressing MxA acquired a high degree of resistance to influenza A virus. Surprisingly, MxA also conferred resistance to vesicular stomatitis virus. Expression of MxA in transfected 3T3 cells had no effect on the multiplication of two picornaviruses, a togavirus, or herpes simplex virus type 1. Treatment of MxA-expressing cells with antibodies to mouse alpha-beta interferon did not abolish the resistance phenotype. The conclusion that resistance to influenza virus and vesicular stomatitis virus was due to the specific action of MxA is further supported by the observation that transfected 3T3 cell lines expressing the related MxB failed to acquire virus resistance.

Interaction of adenovirus VA RNAl with the protein kinase DAI: nonequivalence of binding and function

Adenovirus VA RNAL maintains protein synthesis by preventing activation of the double-stranded RNA (dsRNA)-dependent protein kinase DAI. There appears to be a single binding site for dsRNA on DAI, and this site is blocked by VA RNAl. VA RNAl binds to purified DAI and can be cross-linked to the enzyme by UV irradiation. To determine the relationship between DAI binding and VA RNAl structure and function, we examined the binding abilities of wild-type and mutant VA RNAs. In several cases, the ability to bind DAI efficiently in vitro did not correlate with function in vivo. Secondary structure analysis suggested that efficient binding requires an apical stem-loop structure, whereas inhibition of DAI activation requires the central domain of the VA RNA molecule. We propose that the duplex stem permits VA RNA to interact with the dsRNA binding site on DAI and inhibits activation by juxtaposing the central domain of the RNA with the enzyme's active site.

The adenovirus L4 100-kilodalton protein is necessary for efficient translation of viral late mRNA species

When screening a number of adenovirus type 5 (Ad5) temperature-sensitive mutants for defects in viral gene expression, we observed that H5ts1-infected 293 cells accumulated reduced levels of newly synthesized viral late proteins. Pulse-labeling and pulse-chase experiments were used to establish that the late proteins synthesized in H5ts1-infected cells under nonpermissive conditions were as stable as those made in Ad5-infected cells. H5ts1-infected cells contained normal levels of viral late mRNAs. Because these observations implied that translation of viral mRNA species was defective in mutant virus-infected cells, the association of viral late mRNAs with polyribosomes was examined during the late phase of infection at a nonpermissive temperature. In Ad5-infected cells, the majority of the viral L2, L3, L4, pIX, and IVa2 late mRNA species were polyribosome bound. By contrast, these same mRNA species were recovered from H5ts1-infected cells in fractions nearer the top of polyribosome gradients, suggesting that initiation of translation was impaired. During the late phase of infection, neither the polyribosome association nor the translation of most viral early mRNA species was affected by the H5ts1 mutation. This lesion, mapped by marker rescue to the L4 100-kilodalton (kDa) nonstructural protein, has been identified as a single base pair substitution that replaces Ser-466 of the Ad5 100-kDa protein with Pro. A set of temperature-independent revertants of H5ts1 was isolated and characterized. Either true reversion of the H5ts1 mutation or second-site mutation of Pro-466 of the H5ts1 100-kDa protein to Thre, Leu, or His restored both temperature-independent growth and the efficient synthesis of viral late proteins. We therefore conclude that the Ad5 L4 100-kDa protein is necessary for efficient initiation of translation of viral late mRNA species during the late phase of infection.

Biosynthesis of reovirus-specified polypeptides. 2-aminopurine increases the efficiency of translation of reovirus s1 mRNA but not s4 mRNA in transfected cells

The effect of 2-aminopurine (2AP), an inhibitor of the RNA-dependent P1/eIF-2 protein kinase, on the expression of the reovirus serotype 1 Lang strain S1 and S4 genes in transfected simian COS cells was examined. In the absence of 2AP, the s4-encoded sigma 3 gene product was expressed about five times more efficiently than the s1-encoded sigma 1 gene product. When COS cells were treated with 2AP, the synthesis of the sigma 1 polypeptide was increased about fivefold compared to that in untreated cells even though s1 mRNA levels were not detectably altered. In contrast to the increased translational efficiency of the s1 mRNA observed in 2AP-treated cells, the translational efficiency of the s4 mRNA was not affected by 2AP treatment. However, the cytoplasmic accumulation of s4 mRNA was transiently decreased by 2AP treatment. These results demonstrate that the expression of the reovirus S1 and S4 genes in transient transfection assays is differentially affected by 2AP. Furthermore, when considered together with the prior observation that the reovirus s1 mRNA is a potent activator of the RNA-dependent protein kinase relative to the s4 mRNA which is a very poor activator, the results are consistent with the suggestion that the differential translational efficiency of the reovirus s1 and s4 mRNAs in vivo may be attributed in part to their differential ability to activate the P1/eIF-2 protein kinase.

Interferon cures cells lytically and persistently infected with African swine fever virus in vitro

Human interferon alpha (IFN-alpha) and interferon gamma (IFN-gamma) inhibit African swine fever (ASF) virus replication in Vero cells. IFN-alpha and IFN-gamma exert a synergistic inhibition. Human tumor necrosis factor (TNF) does not inhibit ASF virus replication in this cell line, but in combination with IFNs it has antiviral enhancing activity. Analysis of the mechanism of inhibition suggests that the action of these cytokines blocks a step that comes prior to DNA replication. The 2'-5' A synthetase activity is induced in Vero cells by treatment with these cytokines and is activated after ASF virus infection. More interesting is the finding that continuous treatment with IFN-alpha cures Vero cells from lytic and persistent infections with ASF virus. A potential application of IFN for the treatment of animals carrying the virus is suggested.

Protein synthesis initiation factor modifications during viral infections: implications for translational control

Infection of tissue culture cells with certain viruses results in the shutoff of host cell protein synthesis. We have examined virally infected cell lysates using two-dimensional gel electrophoresis and immunoblotting to ascertain whether initiation factor protein modifications are correlated with translational repression. Moderate increases in eukaryotic initiation factor (eIF)-2 alpha phosphorylation are detected in reovirus- and adenovirus-infected cells, as reported previously (Samuel et al., 1984; O'Malley et al., 1989). Neither vesicular stomatitis virus, vaccinia virus, frog virus III, rhinovirus, nor encephalomyocarditis virus caused significantly increased 2 alpha phosphorylation. There were no reproducible, significant changes in eIF-4A, eIF-4B, or eIF-2 beta in cells infected by any of these viruses. The cleavage of eIF-4F subunit p220, such as has been previously demonstrated to occur in poliovirus (Etchison et al., 1982) and rhinovirus (Etchison and Fout, 1985), was not detected in any of the other virus infections analyzed.

A novel effect of adenovirus VA RNA1 on cytoplasmic mRNA abundance

Adenovirus VA RNA1 is a small RNA polymerase III transcript that enhances mRNA translation both in transfected cells and during a lytic virus infection. Here we present evidence that VA RNA1 also, in length-dependent manner, increases cytoplasmic mRNA abundance in transient expression assays in 293 cells.

Recent progress in interferon research: molecular mechanisms of regulation, action, and virus circumvention

A complex system of cis regulatory elements exists by which induction of IFN gene expression is initiated in response to a variety of inducers; cis elements also appear to be involved in the down-regulation of IFN production. IFN gene activation or inhibition of expression may be tightly regulated by the specific binding of newly synthesized or modified proteins to be regulatory regions of the IFN genes. IFN itself acts as a potent modulator of multiple cellular activities. By binding to specific cell surface receptors and probable internalization via receptor-mediated endocytosis and transport into the dense chromatin, IFN treatment leads to activation of numerous genes, some of which possess known antiviral or immunoregulatory functions, whereas the function of others remains to be identified. As with the IFN genes themselves, many of the IFN-inducible genes appear to possess complex regulatory mechanisms, including domains for binding of specific trans-acting proteins. To add to this molecular complexity some viruses have successfully developed methods to circumvent, among other mechanisms, the 2',5'-A-mediated system and the P1 protein kinase system.

Permanent cell lines that show temperature-dependent expression of adenovirus virus-associated RNA

Temperature-sensitive COS cells, clone E540, have been stably transformed at a restrictive temperature with plasmid pVA1, which contains the adenovirus type 5 virus-associated (VA) genes in addition to the Neor marker. Transformed cell clones, named EVA cells, contained adenovirus DNA in an integrated form while grown at restrictive temperature but accumulated up to 100 to 200 copies of the input plasmid per cell after temperature shift down. Concomitant with this gene amplification, an accumulation of VA RNA was observed, reaching average concentrations of 10(4) to 10(5) copies per cell. The VA RNA synthesized in EVA cells is functional, as judged by inhibition of in vitro eucaryotic initiation factor-2 phosphorylation and enhancement of reporter gene expression. These EVA cell lines may be of use to study the mechanism of VA RNA function in the absence of adenovirus infection.

Complementation of adenovirus virus-associated RNA I gene deletion by expression of a mutant eukaryotic translation initiation factor

Adenovirus VA RNAs (virus-associated RNAs) are small polymerase III transcripts that are required for efficient initiation of mRNA translation late in adenovirus infection. VAI RNA prevents double-stranded RNA (dsRNA) activation of the interferon-induced protein kinase (DAI kinase). Activation of this kinase results in phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2 alpha) and correlates with inhibition of translation initiation. In this report we show growth complementation of adenoviruses harboring deletions in the VAI gene in cell lines expressing a serine-to-alanine mutant of eIF-2 alpha. This serine-to-alanine mutant is resistant to phosphorylation by DAI kinase. These results directly show that the primary function of VAI RNA in the lytic adenovirus infection is the inhibition of eIF-2 alpha phosphorylation by DAI kinase and identify eIF-2 alpha as the target that mediates the effects of DAI kinase activation. Cells that express a mutant eIF-2 alpha will enable the isolation of specific host-range mutants for other types of viruses that are defective in the ability to inhibit DAI kinase.

The completed sequence of lymphocytic choriomeningitis virus reveals a unique RNA structure and a gene for a zinc finger protein

The arenavirus, lymphocytic choriomeningitis virus (LCMV) has a single-stranded RNA genome composed of a large (L) and a small (S) RNA segment. The completed sequence of LCMV, presented here, reveals a formerly unknown gene (Z) on the L genomic segment. This gene is encoded in the positive or message-sense of the viral genomic RNA, whereas the adjacent gene (L) is in the genome-complementary, or negative sense. The ambisense polarity of the genes on the L RNA reiterates the polarity of genes on the small (S) genomic segment. The Z gene encodes a 10-kDa protein containing a single zinc-finger sequence (Cys2His2). A small RNA representing the message sense of the Z gene is found in infected cells and within virions. In contrast to the known LCMV proteins having structural or enzymatic functions, the predicted Z gene product is most likely to be an RNA-binding protein with a regulatory role. The encapsidation of a message sense Z RNA suggests a role for this gene immediately following virus penetration. The L/Z intergenic region is rich in cytidylic acid (C) and presents an unusual RNA structure. All cDNA clones of the intergenic region differ from each other within a certain poly(C) stretch and lack a 30-base region present in the direct RNA sequence. Finally, the completed sequence establishes that the L RNA 5' end is complementary to its 3' end. The L RNA termini, similar to the S RNA termini, have a small but potentially important asymmetry of sequence. LCMV is the first arenavirus to be completely sequenced.

Mechanism of interferon action. Activation of the human P1/eIF-2 alpha protein kinase by individual reovirus s-class mRNAs: s1 mRNA is a potent activator relative to s4 mRNA

The ability of pure viral and cellular single-strand (ss) RNAs to activate the interferon-induced, double-stranded (ds) RNA-dependent P1/eIF-2 protein kinase purified from human amnion U cells was examined. In addition to the well-established activation of P1 kinase autophosphorylation in vitro by reovirus genome dsRNA, the P1 kinase was also efficiently activated by certain reovirus ssRNAs. The reovirus s1 mRNA was a potent activator of the kinase. By contrast, the reovirus s4 mRNA was a poor activator of the kinase. Likewise, adenovirus VAI RNA, transfer RNA, 5 S ribosomal RNA, and rabbit globin mRNA were not activators or were very poor activators of the purified P1/eIF-2 protein kinase. Analysis of hybrid ssRNAs produced between the reovirus s1 and s4 mRNAs revealed that both the 5' and the 3' portions of the s1 mRNA possessed nucleotide sequences capable of mediating kinase activation. Subsequent deletion analysis of the 5' portion of the s1 mRNA identified a 161-nucleotide region located between positions 416 and 576 which was sufficient for P1 kinase activation. Treatment of reovirus s1 mRNA transcripts with either ssRNA- or dsRNA-specific ribonucleases, but not with heat, destroyed the ability of s1 mRNA transcripts to activate the kinase. These results suggest that P1 kinase autophosphorylation in vitro may be selectively activated by individual ssRNAs in a differential manner, and that a secondary or higher-ordered ssRNA structure(s) may be important in mediating the activation.

Functional dissection of adenovirus VAI RNA

During the course of adenovirus infection, the VAI RNA protects the translation apparatus of host cells by preventing the activation of host double-stranded RNA-activated protein kinase, which phosphorylates and thereby inactivates the protein synthesis initiation factor eIF-2. In the absence of VAI RNA, protein synthesis is drastically inhibited at late times in infected cells. The experimentally derived secondary structure of VAI RNA consists of two extended base-paired regions, stems I and III, which are joined by a short base-paired region, stem II, at the center. Stems I and II are joined by a small loop, A, and stem III contains a hairpin loop, B. At the center of the molecule and at the 3' side, stems II and III are connected by a short stem-loop (stem IV and hairpin loop C). A fourth, minor loop, D, exists between stems II and IV. To determine sequences and domains critical for function within this VAI RNA structure, we have constructed adenovirus mutants with linker-scan substitution mutations in defined regions of the molecule. Cells infected with these mutants were analyzed for polypeptide synthesis, virus yield, and eIF-2 alpha kinase activity. Our results showed that disruption of base-paired regions in the distal parts of the longest stems, I and III, did not affect function, whereas mutations causing structural perturbations in the central part of the molecule containing stem II, the proximal part of stem III, and the central short stem-loop led to loss of function. Surprisingly, one substitution mutant, sub742, although dramatically perturbing the integrity of the structure of this central portion, showed a wild-type phenotype, suggesting that an RNA with an alternate secondary structure is functional. On the basis of sensitivity to single-strand-specific RNases, we can derive a novel secondary structure for the mutant RNA in which a portion of the sequences may fold to form a structure that resembles the central part of the wild-type molecule, which suggests that only the short stem-loop located in the center of the molecule and the adjoining base-paired regions may define the functional domain. These results also imply that only a portion of the VAI RNA structure may be recognized by the host factor(s).

Purification and activation of the double-stranded RNA-dependent eIF-2 kinase DAI

The double-stranded RNA (dsRNA)-dependent protein kinase DAI (also termed dsI and P1) possesses two kinase activities; one is an autophosphorylation activity, and the other phosphorylates initiation factor eIF-2. We purified the enzyme, in a latent form, to near homogeneity from interferon-treated human 293 cells. The purified enzyme consisted of a single polypeptide subunit of approximately 70,000 daltons, retained its dependence on dsRNA for activation, and was sensitive to inhibition by adenovirus VA RNAI. Autophosphorylation required a suitable concentration of dsRNA and was second order with respect to DAI concentration, which suggests an intermolecular mechanism in which one DAI molecule phosphorylates a neighboring molecule. Once autophosphorylated, the enzyme could phosphorylate eIF-2 but seemed unable to phosphorylate other DAI molecules, which implies a change in substrate specificity upon activation. VA RNAI blocked autophosphorylation and activation but permitted the activated enzyme to phosphorylate eIF-2. VA RNAI also blocked the binding of dsRNA to the enzyme. The data are consistent with a model in which activation requires the interaction of two molecules of DAI with dsRNA, followed by intermolecular autophosphorylation of the latent enzyme. VA RNAI would block activation by preventing the interaction between DAI and dsRNA.