Nucleotide sequence and secondary structure of VSV leader RNA and homologous DNA involved in inhibition of DNA-dependent transcription

The Nuclear Matrix Protein SAFA Surveils Viral RNA and Facilitates Immunity by Activating Antiviral Enhancers and Super-enhancers

Pathogen pattern recognition receptors (PRRs) trigger innate immune responses to invading pathogens. All known PRRs for viral RNA have extranuclear localization. However, for many viruses, replication generates dsRNA in the nucleus. Here, we show that the nuclear matrix protein SAFA (also known as HnRNPU) functions as a nuclear viral dsRNA sensor for both DNA and RNA viruses. Upon recognition of viral dsRNA, SAFA oligomerizes and activates the enhancers of antiviral genes, including IFNB1. Moreover, SAFA is required for the activation of super-enhancers, which direct vigorous immune gene transcription to establish the antiviral state. Myeloid-specific SAFA-deficient mice were more susceptible to lethal HSV-1 and VSV infection, with decreased type I IFNs. Thus, SAFA functions as a nuclear viral RNA sensor and trans-activator to bridge innate sensing with chromatin remodeling and potentiate robust antiviral responses.

Specific nucleotides at the 3'-terminal promoter of viral hemorrhagic septicemia virus are important for virulence in vitro and in vivo

Viral hemorrhagic septicemia virus (VHSV), a member of the Novirhabdovirus genus, contains an 11-nucleotide conserved sequence at the terminal 3'- and 5'-untranslated regions (UTRs) that are complementary. To study the importance of nucleotides in the 3'-UTR of VHSV for replication of novirhabdoviruses, we performed site-directed mutagenesis of selected residues at the 3'-terminus and generated mutant viruses using a reverse genetics approach. Assessment of growth kinetics and in vitro real-time cytopathogenicity studies showed that the order of two nucleotides (A4G5) of the 3'-terminus of VHSV directly affects growth kinetics in vitro. The mutant A4G-G5A virus has reduced total positive-strand RNA synthesis efficiency (51% of wild-type) at 48h post-transfection and 70h delay in causing complete cytopathic effect in susceptible fish cells, as compared to the WT-VHSV. Furthermore, when the A4G-G5A virus was used to challenge zebrafish, it exhibited reduced pathogenicity (54% lower end-point mortality) compared to the WT-VHSV. From these studies, we infer that specific residues in the 3'-UTR of VHSV have a promoter function and are essential to modulate the virulence in cells and pathogenicity in fish.

RNAi-mediated immunity provides strong protection against the negative-strand RNA vesicular stomatitis virus in Drosophila

Activation of innate antiviral responses in multicellular organisms relies on the recognition of structural differences between viral and cellular RNAs. Double-stranded (ds)RNA, produced during viral replication, is a well-known activator of antiviral defenses and triggers interferon production in vertebrates and RNAi in invertebrates and plants. Previous work in mammalian cells indicates that negative-strand RNA viruses do not appear to generate dsRNA, and that activation of innate immunity is triggered by the recognition of the uncapped 5' ends of viral RNA. This finding raises the question whether antiviral RNAi, which is triggered by the presence of dsRNA in insects, represents an effective host-defense mechanism against negative-strand RNA viruses. Here, we show that the negative-strand RNA virus vesicular stomatitis virus (VSV) does not produce easily detectable amounts of dsRNA in Drosophila cells. Nevertheless, RNAi represents a potent response to VSV infection, as illustrated by the high susceptibility of RNAi-defective mutant flies to this virus. VSV-derived small RNAs produced in infected cells or flies uniformly cover the viral genome, and equally map the genome and antigenome RNAs, indicating that they derive from dsRNA. Our findings reveal that RNAi is not restricted to the defense against positive-strand or dsRNA viruses but can also be highly efficient against a negative-strand RNA virus. This result is of particular interest in view of the frequent transmission of medically relevant negative-strand RNA viruses to humans by insect vectors.

Monomer and dimer of Chandipura virus unphosphorylated P-protein binds leader RNA differently: implications for viral RNA synthesis

Interaction of the leader RNA with the unphosphorylated P-protein has been proposed to play a key role in the transcription-replication transition of Chandipura virus, a model rhabdovirus. Electrophoretic mobility shift assay with the leader RNA and the unphosphorylated P-protein demonstrated existence of two distinct complexes in vitro. Measurements of stoichiometry indicate the protein monomer/RNA ratio to be 1:1 and 2:1 for faster and slower migrating bands, respectively. We have also observed a concentration-dependent oligomerization of the unphosphorylated P-protein, in sub-micromolar to low micromolar range. Sedimentation velocity, dynamic light scattering and large zone gel filtration experiments suggest a monomer-dimer-tetramer model of association. RNA binding experiments suggest that the two complexes assembled from one molecule of the leader RNA binding to either a protein monomer or a dimer. A truncated RNA consisting of a 3' region of the leader transcript exclusively formed the 1:1 complex, whereas a RNA consisting of only the 5' region forms the 2:1 complex exclusively. RNA binding experiments at different protein concentrations suggest that binding of the RNA comprising the 3' region weakens significantly at higher P(0) concentrations, whereas in contrast the binding of the RNA comprising the 5' region becomes modestly tighter. Implications of two different types of leader RNA-P-protein complexes in viral RNA synthesis are discussed.

The vesicular stomatitis virus matrix protein inhibits glycoprotein 130-dependent STAT activation

Infection of cells by vesicular stomatitis virus (VSV) results in the inhibition of host transcription. We show in this study that infection of HeLa cells with VSV leads to a strongly diminished activation of STAT3 and STAT1 by the inflammatory cytokine IL-6. This effect was mimicked by forced expression of a single viral protein, the matrix (M)-protein of VSV, which blocked STAT activation via chimeric receptors containing the cytoplasmic domain of the IL-6 signal transducer gp130. Western blot analysis revealed that VSV M-protein did not inhibit the nuclear translocation of activated STAT3 but did inhibit its tyrosine phosphorylation. Inhibition of STAT activation was not dependent on tyrosine 759 of the IL-6 signal transducer gp130, suggesting that the inhibitory action of VSV M-protein is not mediated by the induction of the suppressor of cytokine signaling 3. VSV M-protein inhibited gene transcription from cotransfected alpha(2)-macroglobulin or antichymotrypsin promoter/luciferase reporter constructs which contain STAT3-binding sites. However, transcription from a STAT5-dependent construct was not negatively affected. In conclusion, our data suggest that infection by VSV and specifically overexpression of the viral M-protein interferes with an important signaling pathway necessary for triggering antiviral and inflammatory responses.

Cytopathogenesis and inhibition of host gene expression by RNA viruses

Many viruses interfere with host cell function in ways that are harmful or pathological. This often results in changes in cell morphology referred to as cytopathic effects. However, pathogenesis of virus infections also involves inhibition of host cell gene expression. Thus the term "cytopathogenesis," or pathogenesis at the cellular level, is meant to be broader than the term "cytopathic effects" and includes other cellular changes that contribute to viral pathogenesis in addition to those changes that are visible at the microscopic level. The goal of this review is to place recent work on the inhibition of host gene expression by RNA viruses in the context of the pathogenesis of virus infections. Three different RNA virus families, picornaviruses, influenza viruses, and rhabdoviruses, are used to illustrate common principles involved in cytopathogenesis. These examples were chosen because viral gene products responsible for inhibiting host gene expression have been identified, as have some of the molecular targets of the host. The argument is made that the role of the virus-induced inhibition of host gene expression is to inhibit the host antiviral response, such as the response to double-stranded RNA. Viral cytopathogenesis is presented as a balance between the host antiviral response and the ability of viruses to inhibit that response through the overall inhibition of host gene expression. This balance is a major determinant of viral tissue tropism in infections of intact animals.

Overlapping signals for transcription and replication at the 3' terminus of the vesicular stomatitis virus genome

Transcription and replication signals within the negative-sense genomic RNA of vesicular stomatitis virus (VSV) are located at the 3' terminus. To identify these signals, we have used a transcription- and replication-competent minigenome of VSV to generate a series of deletions spanning the first 47 nucleotides at the 3' terminus of the VSV genome corresponding to the leader gene. Analysis of these mutants for their ability to replicate showed that deletion of sequences within the first 24 nucleotides abrogated or greatly reduced the level of replication. Deletion of downstream sequences from nucleotides 25 to 47 reduced the level of replication only to 55 to 70% of that of the parental template. When transcription activity of these templates was measured, the first 24 nucleotides were also found to be required for transcription, since deletion of these sequences blocked or significantly reduced transcription. Downstream sequences from nucleotides 25 to 47 were necessary for optimal levels of transcription. Furthermore, replacement of sequences within the 25 to 47 nucleotides with random heterologous nonviral sequences generated mutant templates that replicated well (65 to 70% of the wild-type levels) but were transcribed poorly (10 to 15% of the wild-type levels). These results suggest that the minimal promoter for transcription and replication could be as small as the first 19 nucleotides and is contained within the 3'-terminal 24 nucleotides of the VSV genome. The sequences from nucleotides 25 to 47 may play a more important role in optimal transcription than in replication. Our results also show that deletion of sequences within the leader gene does not influence the site of transcription reinitiation of the downstream gene.

Inhibition of host RNA polymerase II-dependent transcription by vesicular stomatitis virus results from inactivation of TFIID

During infection with vesicular stomatitis virus (VSV), host-cell mRNA synthesis is inhibited due to shut off of host-cell transcription. The transcriptional activity of nuclear extracts prepared from VSV-infected cells was compared to the activity of nuclear extracts from uninfected cells. An exogenous DNA template was used which contained an adenovirus major late promoter (AdMLP) but lacked upstream activating sequences, so that only basal transcription activity was assayed in these experiments. AdMLP-initiated transcription was decreased by 75% in nuclear extracts from infected cells as early as 3 h p.i. and by >90% by 6 h p.i. Mixing nuclear extracts from uninfected and VSV-infected cells revealed that the inhibition was caused by lack of an active form of a host factor involved in basal transcription rather than by the presence of an excess of inhibitory factor. To determine which transcription factors were lacking from nuclear extracts of infected cells, host transcription initiation factors isolated from uninfected cells by ion-exchange chromatography were added separately to nuclear extracts inactivated by VSV infection. A phosphocellulose column fraction from uninfected cells eluted with 0. 8 M KCl, which contained transcription factor IID (TFIID), overcame the inhibition. The corresponding fraction from infected cells had no detectable activity in a TFIID-dependent in vitro transcription assay. TATA-binding protein (TBP) is the DNA-binding subunit of TFIID and has been shown previously to substitute for TFIID in basal transcription. Purified recombinant TBP also reconstituted the transcription activity of nuclear extracts from infected cells, supporting the idea that TFIID is the target of virus-induced inhibition. Western blot analysis showed that the level of TBP in nuclear extracts or in the 0.8 M KCl column fraction was not changed by VSV infection. These results indicated that VSV infection leads to an inhibition of host transcription by inactivation of TFIID rather than reduction in the level of TFIID.

Estradiol regulates estrogen receptor mRNA stability

Previous studies suggest that post-transcriptional events play an important role in estrogen-induced loss of estrogen receptor expression. The present study shows that treatment of MCF-7 cells with estradiol resulted in a six-fold decrease in estrogen receptor mRNA half-life from 4 h in control cells to 40 min in estradiol treated cells. To determine the role of protein synthesis in the regulation of estrogen receptor mRNA stability, several translational inhibitors were utilized. Pactamycin and puromycin, which prevent ribosome association with mRNA, inhibited the effect of estradiol on receptor mRNA stability, whereas cycloheximide, which has no effect on ribosome association with mRNA, had no effect on estradiol regulation of estrogen receptor mRNA stability. In control cells, the total cellular content of estrogen receptor mRNA was associated with high molecular weight polyribosomes. Treatment with estradiol resulted in a 70% decrease in estrogen receptor mRNA associated with polyribosomes but had no effect on the polyribosome distribution of estrogen receptor mRNA. In an in vitro degradation assay, polyribosomes isolated from estradiol-treated cells degraded ER mRNA faster than polyribosomes isolated from control cells. The nuclease activity associated with the polysome fraction appeared to be Mg2+ independent and inhibited by RNasin. Freeze-thawing and heating at 90 degrees C for 10 min resulted in the loss of nuclease activity. These studies suggest that an estrogen-regulated nuclease activity associated with ribosomes alters the stability of estrogen receptor mRNA.

Migration of vesicular stomatitis virus glycoprotein to the nucleus of infected cells

A new means of direct visualization of the early events of viral infection by selective fluorescence labeling of viral proteins coupled with digital imaging microscopy is reported. The early phases of viral infection have great importance for understanding viral replication and pathogenesis. Vesicular stomatitis virus, the best-studied rhabdovirus, is composed of an RNA genome of negative sense, five viral proteins, and membrane lipids derived from the host cell. The glycoprotein of vesicular stomatitis virus was labeled with fluorescein isothiocyanate, and the labeled virus was incubated with baby hamster kidney cells. After initiation of infection, the fluorescence of the labeled glycoprotein was first seen inside the cells in endocytic vesicles. The fluorescence progressively migrated to the nucleus of infected cells. After 1 h of infection, the virus glycoprotein was concentrated in the nucleus and could be recovered intact in a preparation of purified nuclei. These results suggest that uncoating of the viral RNA occurs close to the nuclear membrane, which would precede transcription of the leader RNA that enters the nucleus to shut off cellular RNA synthesis and DNA replication.

Vesicular stomatitis virus infection induces a nuclear DNA-binding factor specific for the interferon-stimulated response element

Vesicular stomatitis virus (VSV) has a broad host range. It replicates in the cytoplasm and causes rapid cytopathic effects. We show that following VSV infection, a nuclear factor that binds to a select set of interferon-stimulated responsive elements (ISRE) is induced in many cell types. This factor, tentatively called VSV-induced binding protein (VIBP), was estimated to have an approximate molecular mass of 50 kDa and was distinct from known members of the interferon regulatory factor family, that are known to bind to the ISRE. Induction of VIBP required tyrosine kinase activity but did not require cellular transcription. Treatment of cells with cycloheximide, which inhibits translation, only partially inhibited induction of VIBP. However, type I interferons and staurosporine, both of which inhibit VSV transcription, inhibited VIBP induction. Moreover, a double-stranded RNA analog, poly(I)-poly(C) also induced a DNA-binding activity very similar to that of VIBP. These results indicate that a preexisting cellular protein is activated upon VSV infection and that this activation requires primary viral transcripts. The functional activity of VIBP was analyzed in cells stably transfected with a herpesvirus thymidine kinase-luciferase reporter gene that is under control of the ISRE. While activity of the control promoter without ISRE was strongly inhibited following VSV infection (as a result of virus-mediated transcriptional shutdown of the host cell), the inhibition was reversed by the ISRE-containing promoter, albeit partially, which suggests that VSV infection differentially affects transcription of host genes. Although VIBP was induced in all other cells tested, it was not induced in embryonal carcinoma cells after VSV infection, suggesting developmental regulation of VIBP inducibility.

The role of vesicular stomatitis virus matrix protein in inhibition of host-directed gene expression is genetically separable from its function in virus assembly

Recently, the vesicular stomatitis virus matrix (M) protein has been shown to be capable of inhibition of host cell-directed transcription in the absence of other viral components (B. L. Black and D. S. Lyles, J. Virol. 66:4058-4064, 1992). M protein is a major structural protein that is known to play a critical role in virus assembly by binding the helical ribonucleoprotein core of the virus to the cytoplasmic surface of the cell plasma membrane during budding. In this study, two M protein mutants were tested to determine whether the inhibition of host transcription by M protein is an indirect effect of its function in virus assembly or whether it represents an independent function of M protein. The mutant M protein of the conditionally temperature-sensitive (ts) vesicular stomatitis virus mutant, tsO82, was found to be defective in its ability to inhibit host-directed gene expression, as shown by its inability to inhibit expression of a cotransfected target gene encoding chloramphenicol acetyltransferase. The ability of the tsO82 M protein to function in virus assembly was similar to that of wild-type M protein, as shown by its ability to complement the group III ts M protein mutant, tsO23. Another mutant, MN1, which lacks amino acids 4 to 21 of M protein demonstrated that the abilities of M protein to inhibit chloramphenicol acetyltransferase gene expression and to localize to the nucleus were unaffected by deletion of this lysine-rich amino-terminal region but that the ability to function in virus assembly was ablated. Thus, the two M protein mutants examined in this study exhibited complementary phenotypes: tsO82 M protein functioned in virus assembly but was defective in inhibition of host-directed gene expression, while MN1 M protein functioned in inhibiting gene expression but was unable to function in virus assembly. These data demonstrate that the role of M protein in inhibition of host transcription can be separated genetically from its role in virus assembly.

5' sequence of vesicular stomatitis virus N-gene confers selective translation of mRNA

The infection of cells by vesicular stomatitis virus results in the rapid inhibition of host-cell protein synthesis, but not of viral protein synthesis. To determine if this translational selectivity might be conferred by the viral mRNA, we constructed a plasmid (pUCLN beta-4) containing the 5' end of the viral nucleocapsid (N)-gene, including the ribosome binding site, fused in frame with the gene encoding beta-galactosidase, and compared it to a control plasmid (pMC1924) containing the cellular rabbit beta-globin gene 5' end fused with the beta-galactosidase encoding gene. Both plasmids contained identical promoter and 3' nontranslated regions and expressed similar levels of beta-galactosidase in the indicator cell line 293. In cells transfected with either plasmid, viral infection resulted in a approximately 70% decrease in protein synthesis by five hours. The level of beta-galactosidase from cells transfected with pMC1924 also decreased concomitantly with the decrease in total protein synthesis. However, the level of beta-galactosidase from cells transfected with pUCLN beta-4 was not affected by viral infection. Our data suggest that sequences in the 5' end of the viral mRNA allow for the selective translation of the viral message in the presence of an inhibited translational machinery.

Vesicular stomatitis virus matrix protein inhibits host cell-directed transcription of target genes in vivo

Infection by vesicular stomatitis virus (VSV) results in a rapid inhibition of host cell transcription and translation. To determine whether the viral matrix (M) protein was involved in this inhibition of host cell gene expression, an M protein expression vector was cotransfected with a target gene vector, encoding the target gene, encoding chloramphenicol acetyltransferase (CAT). Expression of M protein caused a decrease in CAT activity in a gene dosage-dependent manner, and inhibition was apparent by 12 h posttransfection. The inhibitory effect of M protein was quite potent. The level of M protein required for a 10-fold inhibition of CAT activity was less than 1% of the level of M protein produced during the sixth hour of VSV infection. Northern (RNA) analysis of cotransfected cells showed that expression of M protein caused a reduction in the steady-state level of the vector-encoded mRNAs. Expression of both CAT and M mRNAs was reduced in cells cotransfected with a plasmid encoding M protein, indicating that expression of small amounts of M protein from plasmid DNA inhibits further expression of both M and CAT mRNAs. Nuclear runoff transcription analysis demonstrated that expression of M protein inhibited transcription of the target genes. This is the first report of a viral gene product which is capable of inhibiting transcription in vivo in the absence of any other viral component.

Effects of defective interfering viruses on virus replication and pathogenesis in vitro and in vivo

DI viruses and defective viruses generally are widespread in nature. Laboratory studies show that they can sometimes exert powerful disease-modulating effects (either attenuation or intensification of symptoms). Their role in nature remains largely unexplored, despite recent suggestive evidence for their importance in a number of systems.

E1A-induced enhancer activity of the poly(dG-dT).poly(dA-dC) element (GT element) and interactions with a GT-specific nuclear factor

The alternating sequence poly(dG-dT).poly(dA-dC) is a highly repeated sequence in the eucaryotic genome. We have examined the effect of trans-acting early viral proteins on the ability of the GT element to stimulate transcription of the adenovirus major late promoter (MLP). We find that the GT element alone does not activate expression from the MLP in either the presence or absence of another enhancer element. However, in the presence of the E1A gene products of either adenovirus type 5 or 2, the GT element activated expression from the MLP. The stimulatory activity of the GT element in the presence of E1A had the properties of an enhancer element, and the trans-activating effect on the GT element was additive in conjunction with the E1A-responsive BK virus enhancer. We also have demonstrated that a specific nuclear factor(s) binds to the GT element. However, the E1A protein(s) do not affect the initial factor interaction(s) with the GT element. Overall, our data demonstrate that trans modulation of promoter activity can be mediated through the GT element.

E1A-induced enhancer activity of the poly(dG-dT).poly(dA-dC) element (GT element) and interactions with a GT-specific nuclear factor

The alternating sequence poly(dG-dT).poly(dA-dC) is a highly repeated sequence in the eucaryotic genome. We have examined the effect of trans-acting early viral proteins on the ability of the GT element to stimulate transcription of the adenovirus major late promoter (MLP). We find that the GT element alone does not activate expression from the MLP in either the presence or absence of another enhancer element. However, in the presence of the E1A gene products of either adenovirus type 5 or 2, the GT element activated expression from the MLP. The stimulatory activity of the GT element in the presence of E1A had the properties of an enhancer element, and the trans-activating effect on the GT element was additive in conjunction with the E1A-responsive BK virus enhancer. We also have demonstrated that a specific nuclear factor(s) binds to the GT element. However, the E1A protein(s) do not affect the initial factor interaction(s) with the GT element. Overall, our data demonstrate that trans modulation of promoter activity can be mediated through the GT element.

Negative regulation of the human polyomavirus BK enhancer involves cell-specific interaction with a nuclear repressor

We have examined the cell type-specific regulation of the human BK virus (BKV) enhancer. This enhancer functions efficiently in cis to activate expression from the adenovirus major late promoter in the human kidney cell line, 293, and in a monkey kidney cell line, MK2, but not in the HeLa cell line. In gel retardation migration assays, specific BKV enhancer-protein complexes could be observed by using nuclear extracts prepared from each cell line. Moreover, a unique DNA-protein complex was observed by using the HeLa cell nuclear extracts. By DNase footprint analysis, four binding regions for HeLa cell nuclear proteins were defined within the BKV enhancer repeat region. Two of the protected regions encompassed nuclear factor 1 or CCAAT transcription factor binding sites. These nuclear factor 1 sites also were protected by nuclear proteins from the 293 and MK2 cell lines. The other two protected sites encompassed a region of symmetry which included a sequence similar to the simian virus 40 TC enhancer motif and to a conserved sequence present upstream or within the introns of several cellular genes. These two sites were not protected by either the 293 or MK2 nuclear proteins. Competition studies in transfected cells indicated that the reduced activity of the BKV enhancer in the HeLa cell line was due to negative regulation. Further, we have demonstrated that binding of a nuclear factor(s) to the HeLa cell-specific site is involved in the repression of enhancer activity.

Negative regulation of the human polyomavirus BK enhancer involves cell-specific interaction with a nuclear repressor

We have examined the cell type-specific regulation of the human BK virus (BKV) enhancer. This enhancer functions efficiently in cis to activate expression from the adenovirus major late promoter in the human kidney cell line, 293, and in a monkey kidney cell line, MK2, but not in the HeLa cell line. In gel retardation migration assays, specific BKV enhancer-protein complexes could be observed by using nuclear extracts prepared from each cell line. Moreover, a unique DNA-protein complex was observed by using the HeLa cell nuclear extracts. By DNase footprint analysis, four binding regions for HeLa cell nuclear proteins were defined within the BKV enhancer repeat region. Two of the protected regions encompassed nuclear factor 1 or CCAAT transcription factor binding sites. These nuclear factor 1 sites also were protected by nuclear proteins from the 293 and MK2 cell lines. The other two protected sites encompassed a region of symmetry which included a sequence similar to the simian virus 40 TC enhancer motif and to a conserved sequence present upstream or within the introns of several cellular genes. These two sites were not protected by either the 293 or MK2 nuclear proteins. Competition studies in transfected cells indicated that the reduced activity of the BKV enhancer in the HeLa cell line was due to negative regulation. Further, we have demonstrated that binding of a nuclear factor(s) to the HeLa cell-specific site is involved in the repression of enhancer activity.

Inhibition of adenovirus DNA replication by vesicular stomatitis virus leader RNA

Vesicular stomatitis virus (VSV) leader RNA and a synthetic oligodeoxynucleotide of the same sequence were found to inhibit the replication of adenovirus DNA in vitro. In contrast, the small RNA transcribed by the VSV defective interfering particle DI-011 did not prevent adenovirus DNA replication. The inhibition produced by leader RNA was at the level of preterminal protein (pTP)-dCMP complex formation, the initiation step of adenovirus DNA replication. Initiation requires the adenovirus pTP-adenovirus DNA polymerase complex (pTP-Adpol), the adenovirus DNA-binding protein, and nuclear factor I. Specific replication in the presence of leader RNA was restored when the concentration of adenovirus-infected or uninfected nuclear extract was increased or by the addition of purified pTP-Adpol or HeLa cell DNA polymerase alpha-primase to inhibited replication reactions. Furthermore, the activities of both purified DNA polymerases could be inhibited by the leader sequence. These results suggest that VSV leader RNA is the viral agent responsible for inhibition of adenovirus and possibly cellular DNA replication during VSV infection.

Interferon induction by viruses. XV. Biological characteristics of interferon induction-suppressing particles of vesicular stomatitis virus

A single interferon (IFN) induction-suppressing particle (ISP) of vesicular stomatitis virus (VSV) blocked completely the yield of IFN in a cell otherwise programmed to produce IFN. With mouse L cells as hosts, one lethal hit of UV radiation (D37 = 52.5 ergs/mm2) to the VSV genome sufficed to inactivate ISP activity; however, with "aged" primary chick embryo cells as hosts, it took 198 lethal hits (D37 = 10,395 ergs/mm2). ISP expression in chick cells did not require virus replication or amplified RNA synthesis, but did involve functional virion-associated L protein. ISP in chick cells also were capable of inhibiting, in a multiplicity-dependent manner, the plaquing efficiency of two viruses that require cellular polymerase II (pol II) for replication, e.g., pseudorabies and influenza. The refractory state to IFN inducibility that resulted from infection of chick cells with ISP (VSV tsO5 [UV = 100 hits]) was still extant after 6 days. In contrast, the plaquing efficiency of pseudorabies virus returned to control levels by 5 h after ISP infection. Chick cells infected with UV ISP remained viable, served as hosts for the replication of other viruses, and could be subcultured. Models are presented to account for these contrasting effects. The involvement of viral plus-strand leader RNA as an inhibitor of cellular pol II-dependent RNA synthesis, and the multifunctional activities of the virion-associated L protein, are discussed as possible molecules involved in the action of ISP in chick cells.

Rapid inhibition of processing and assembly of small nuclear ribonucleoproteins after infection with vesicular stomatitis virus

After infection of baby hamster kidney cells with vesicular stomatitis virus (VSV), processing and assembly of small nuclear ribonucleoproteins (snRNP) were rapidly inhibited. The U1 and U2 snRNAs accumulated as precursor species approximately 3 and 10 nucleotides longer, respectively, than the mature RNAs. Alteration in snRNP assembly was noted because the precursor snRNAs were not associated with the U-series RNA-core protein complex in infected cells. However, antibodies specific for the U2 RNA-binding protein, A', were able to precipitate pre-U2 RNAs from VSV-infected cells. These results indicated that precursors to U2 RNA were bound to A' and remained bound during virus infection. Analysis of the synthesis of proteins normally associated with U1 and U2 RNAs indicated that synthesis was unaffected at times when snRNP assembly with core proteins was blocked by the VSV. These findings suggested that the core proteins associate with one another in the absence of the snRNAs in VSV-infected cells. They further suggest a correlation between the inability of the core complex to bind the U-series snRNPs and the failure to process the 3' ends of U1 and U2 RNAs in VSV-infected cells. These effects of VSV on snRNP assembly may be related to the shutoff of host-cell macromolecular synthesis.

Vesicular stomatitis virus in Drosophila melanogaster cells: lack of leader RNA transport into the nuclei and frequent abortion of the replication step

In cultured Drosophila melanogaster cells, vesicular stomatitis virus (VSV) establishes a persistent, noncytopathic infection. No inhibition of host macromolecular synthesis occurs. We studied the synthesis of VSV plus-strand leader RNA, which may be directly involved in vertebrate host synthesis shut-off. Leader RNA accumulated in Drosophila cell cytoplasm, but in low amounts, it was either free or associated to structures larger than the leader RNA-N protein complexes found in vertebrate cells. Only a few leader RNA copies migrated into the cell nucleus; no increase of this transport was observed at any time during the virus cycle. Viral RNAs complementary to the 3' end of the genome and ranging in size from the leader to several hundred nucleotides were found to accumulate in Drosophila cell cytoplasm. Their synthesis was inhibited in the presence of cycloheximide, which blocks all protein synthesis and VSV replication. Correlation between the absence of VSV cytopathogenicity in Drosophila cells and the lack of leader RNA transport into their nuclei is discussed, as well as the possible relationship between the restriction of viral synthesis and the frequent initiation of an abortive replication step.

Rapid inhibition of processing and assembly of small nuclear ribonucleoproteins after infection with vesicular stomatitis virus

After infection of baby hamster kidney cells with vesicular stomatitis virus (VSV), processing and assembly of small nuclear ribonucleoproteins (snRNP) were rapidly inhibited. The U1 and U2 snRNAs accumulated as precursor species approximately 3 and 10 nucleotides longer, respectively, than the mature RNAs. Alteration in snRNP assembly was noted because the precursor snRNAs were not associated with the U-series RNA-core protein complex in infected cells. However, antibodies specific for the U2 RNA-binding protein, A', were able to precipitate pre-U2 RNAs from VSV-infected cells. These results indicated that precursors to U2 RNA were bound to A' and remained bound during virus infection. Analysis of the synthesis of proteins normally associated with U1 and U2 RNAs indicated that synthesis was unaffected at times when snRNP assembly with core proteins was blocked by the VSV. These findings suggested that the core proteins associate with one another in the absence of the snRNAs in VSV-infected cells. They further suggest a correlation between the inability of the core complex to bind the U-series snRNPs and the failure to process the 3' ends of U1 and U2 RNAs in VSV-infected cells. These effects of VSV on snRNP assembly may be related to the shutoff of host-cell macromolecular synthesis.

Inhibition of DNA-dependent transcription by the leader RNA of vesicular stomatitis virus: role of specific nucleotide sequences and cell protein binding

The leader RNA transcript of vesicular stomatitis virus inhibits transcription of the adenovirus major late promoter and virus-associated genes in a soluble HeLa cell transcription system. We examined the specific nucleotide sequence involved and the potential role of leader-protein interactions in this inhibition of RNA polymerase II- and III-directed transcription. Using synthetic oligodeoxynucleotides homologous to regions of the leader RNA molecule, we extend our previous results (B.W. Grinnell and R.R. Wagner, Cell 36:533-543, 1984) that suggest a role for the AU-rich region of the leader RNA or the homologous AT region of a cloned cDNA leader in the inhibition of DNA-dependent transcription. Our results indicate that a short nucleotide sequence (AUUAUUA) or its deoxynucleotide homolog (ATTATTA) appears to be the minimal requirement for the leader RNA to inhibit transcription by both RNA polymerases, but sequences flanking both sides of this region increase the inhibitory activity. Nucleotide changes in the homologous AT-rich region drastically decrease the transcriptional inhibitory activity. Leader RNAs from wild-type virus, but not from a 5'-defective interfering particle, form a ribonuclease-resistant, protease-sensitive ribonucleoprotein complex in the soluble HeLa cell extract. Several lines of evidence suggest that the leader RNA specifically interacts with a 65,000-dalton (65K) cellular protein. In a fractionated cell extract, only those fractions containing this 65K protein could reverse the inhibition of DNA-dependent RNA synthesis by the plus-strand vesicular stomatitis virus leader RNA or by homologous DNA. In studies with synthetic oligodeoxynucleotides homologous to leader RNA sequences, only those oligonucleotides containing the inhibitory sequence were able to bind to a gradient fraction containing the 65K protein.

Regulation of viral transcription by the matrix protein of vesicular stomatitis virus probed by monoclonal antibodies and temperature-sensitive mutants

The ability of the matrix (M) protein of wild-type vesicular stomatitis virus (VSV) to regulate viral transcription was studied with monoclonal antibodies and temperature-sensitive (ts) mutants in complementation group III, the M proteins of which are restricted in transcription inhibition. The marked inhibition of transcription by VSV ribonucleoprotein (RNP) cores complexed with M protein (RNP/M) was reversed by antibody to epitope 1. Antibodies to epitopes 2 and 3 not only failed to reverse the transcription-inhibitory activity of isolated M protein but actually increased M-protein inhibition of transcription in a reconstituted system. Monoclonal antibodies to epitopes 2 and 3 strongly bound to M proteins from all wild-type and ts-mutant virions, but monoclonal antibody to epitope 1 completely failed to bind to the M protein of ts023(III) even though it reacted strongly with M proteins of mutants tsG31(III) and tsG33(III). The M protein of a tsO23 revertant (R11) completely recovered its capacity to inhibit transcription and to bind monoclonal antibody to epitope 1, whereas the M proteins of three other revertants remained restricted in their capacity to inhibit transcription and to bind monoclonal antibody to epitope 1. These studies indicate that exposure of epitope 1 on the surface of M protein is essential for inhibiting transcription by VSV RNP cores.

Inhibition of DNA-dependent transcription by the leader RNA of vesicular stomatitis virus: role of specific nucleotide sequences and cell protein binding

The leader RNA transcript of vesicular stomatitis virus inhibits transcription of the adenovirus major late promoter and virus-associated genes in a soluble HeLa cell transcription system. We examined the specific nucleotide sequence involved and the potential role of leader-protein interactions in this inhibition of RNA polymerase II- and III-directed transcription. Using synthetic oligodeoxynucleotides homologous to regions of the leader RNA molecule, we extend our previous results (B.W. Grinnell and R.R. Wagner, Cell 36:533-543, 1984) that suggest a role for the AU-rich region of the leader RNA or the homologous AT region of a cloned cDNA leader in the inhibition of DNA-dependent transcription. Our results indicate that a short nucleotide sequence (AUUAUUA) or its deoxynucleotide homolog (ATTATTA) appears to be the minimal requirement for the leader RNA to inhibit transcription by both RNA polymerases, but sequences flanking both sides of this region increase the inhibitory activity. Nucleotide changes in the homologous AT-rich region drastically decrease the transcriptional inhibitory activity. Leader RNAs from wild-type virus, but not from a 5'-defective interfering particle, form a ribonuclease-resistant, protease-sensitive ribonucleoprotein complex in the soluble HeLa cell extract. Several lines of evidence suggest that the leader RNA specifically interacts with a 65,000-dalton (65K) cellular protein. In a fractionated cell extract, only those fractions containing this 65K protein could reverse the inhibition of DNA-dependent RNA synthesis by the plus-strand vesicular stomatitis virus leader RNA or by homologous DNA. In studies with synthetic oligodeoxynucleotides homologous to leader RNA sequences, only those oligonucleotides containing the inhibitory sequence were able to bind to a gradient fraction containing the 65K protein.

Characterization of leader-related small RNAs in coronavirus-infected cells: further evidence for leader-primed mechanism of transcription

Mouse hepatitis virus (MHV), a murine coronavirus, replicates in the cytoplasm and synthesizes 7 viral mRNAs containing an identical stretch of leader RNA sequences at the 5'-end of each RNA. The leader-coding sequences at the 5'-end of genomic RNA are at least 72 nucleotides in length and are joined to the viral mRNAs by a unique mechanism. Utilizing a leader-specific cDNA probe, we have detected several free leader RNA species ranging from 70 to 82 nucleotides in length. The predominant leader RNA was approximately 75 nucleotides. In addition, larger distinct leader-containing RNAs were also detected ranging from 130 to 250 nucleotides in length. The 70-82-nucleotide leader-related RNAs were present in both the cytosol and membrane fractions of infected cells. They were also detected only in the small RNA fractions but not associated with the replicative-intermediate RNA. These data suggest that the leader RNAs were associated with the membrane-bound transcription complex but at least part of them were dissociated from the RNA template. We have also identified a temperature-sensitive mutant, which synthesizes only leader RNA but not mRNAs at nonpermissive temperature, indicating that leader RNA synthesis is distinct from the transcription of mRNAs. These data support the leader-primed mechanism for coronavirus transcription and suggest that one or more free leader RNAs are used as primers of mRNA synthesis.

Base mutations in the terminal noncoding regions of the genome of vesicular stomatitis virus isolated from persistent infections of L cells

The 3'-terminal regions of the genomes of vesicular stomatitis virus obtained from two long-term, independently initiated persistent infections of L cells were found to contain several sequence mutations. In contrast to the hypermutability displayed in the 5'-terminal regions of the genomes of viruses obtained from persistent infections of baby hamster kidney (BHK) cells (P. J. O'Hara, F. M. Horodyski, S. T. Nichol, and J. J. Holland, J. Virol. 49, 793-798, 1984), no 5' mutations were detected in viruses from L-cell carrier lines. The absence of detectable defective interfering (DI) particles in the L-cell carrier cultures may account for this difference. Plus-strand leader RNA made by the viruses from persistently infected L cells failed to accumulate from 5 to 8 hr postinfection unlike the accumulation noted for the leader RNA generated by wild-type VSV. Minus-strand leader RNA, on the other hand, accumulated at a similar or increased rate compared to wild type. The relationship of these observations to the processes of host shutoff, viral transcription, and replication are discussed.

The requirement of protein synthesis for VSV inhibition of host cell RNA synthesis

Published ultraviolet (uv) inactivation data and in vitro transcription studies have suggested that vesicular stomatitis virus (VSV) leader RNA was solely responsible for the inhibition of host cell RNA synthesis by this virus. Since no protein product is encoded in leader RNA, this conclusion implied that no protein synthesis should be required for this effect. Therefore, the inhibitory activity of VSV was examined in the presence of the protein synthesis inhibitors, cycloheximide, pactamycin, and emetine. Protein synthesis inhibitors are known not to interfere with VSV primary transcription, but in their presence viral replication and amplification of transcription do not take place. Although at 39 degrees the VSV mutant tsG22 could undergo only primary transcription, maximum inhibition of host cell RNA synthesis took place. However, in the presence of the protein synthesis inhibitors the VSV mutant was no longer able to interfere with host cell RNA synthesis. These results could not be explained by a change in the concentration of intracellular leader RNA which remained unaltered by the drugs. Similar results were also obtained with wild-type VSV in the presence of cycloheximide. Upon removal of the drug, inhibition of host cell RNA synthesis was reestablished in parallel with the restoration of protein synthesis. It is concluded that protein synthesis is required for the inhibitory activity of VSV, presumably because the active inhibitory complex is a nucleoprotein containing leader RNA and either a cellular protein or the viral N protein. The cellular protein would have to be in limiting supply since de novo protein synthesis was required for the inhibition to take place.