RNA synthesis by vesicular stomatitis virus and a small plaque mutant: effects of cycloheximide

A vesiculovirus showing a steepened transcription gradient and dominant trans-repression of virus transcription

Vesicular stomatitis virus (VSV) is a prototype nonsegmented, negative-sense virus used to examine viral functions of a broad family of viruses, including human pathogens. Here we demonstrate that S(2) VSV, an isolate with a small plaque phenotype compared to other Indiana strain viruses, has a transcription defect resulting in an altered pattern and rapid decline of transcription. The S(2) VSV transcription gradient is dominant over the wild-type transcription in a coinfection. This is the first characterization of an altered gradient of transcription not dependent on RNA template sequence or host response and may provide insight into new approaches to viral attenuation.

Interaction of chandipura virus N and P proteins: identification of two mutually exclusive domains of N involved in interaction with P

The nucleocapsid protein (N) and the phosphoprotein (P) of nonsegmented negative-strand (NNS) RNA viruses interact with each other to accomplish two crucial events necessary for the viral replication cycle. First, the P protein binds to the aggregation prone nascent N molecules maintaining them in a soluble monomeric (N(0)) form (N(0)-P complex). It is this form that is competent for specific encapsidation of the viral genome. Second, the P protein binds to oligomeric N in the nucleoprotein complex (N-RNA-P complex), and thereby facilitates the recruitment of the viral polymerase (L) onto its template. All previous attempts to study these complexes relied on co-expression of the two proteins in diverse systems. In this study, we have characterised these different modes of N-P interaction in detail and for the first time have been able to reconstitute these complexes individually in vitro in the chandipura virus (CHPV), a human pathogenic NNS RNA virus. Using a battery of truncated mutants of the N protein, we have been able to identify two mutually exclusive domains of N involved in differential interaction with the P protein. An unique N-terminal binding site, comprising of amino acids (aa) 1-180 form the N(0)-P interacting region, whereas, C-terminal residues spanning aa 320-390 is instrumental in N-RNA-P interactions. Significantly, the ex-vivo data also supports these observations. Based on these results, we suggest that the P protein acts as N-specific chaperone and thereby partially masking the N-N self-association region, which leads to the specific recognition of viral genome RNA by N(0).

Initiation of encapsidation as evidenced by deoxycholate-treated Nucleocapsid protein in the Chandipura virus life cycle

Encapsidation of nascent genome RNA into an RNase-resistant form by nucleocapsid protein, N is a necessary step in the rhabdoviral life cycle. However, the precise mechanism for viral RNA specific yet processive encapsidation remains elusive. Using Chandipura virus as a model system, we examined RNA binding specificity of N protein and dissected the biochemical steps involved in the rhabdoviral encapsidation process. Our analysis suggested that N protein in its monomeric form specifically binds to the first half of the leader RNA in a 1:1 complex, whereas, oligomerization imparts a broad RNA binding specificity. We also observed that viral P protein and dissociating detergent deoxycholate, both were able to maintain N in a monomeric form and thus promote specific RNA recognition. Finally, use of a minigenome length RNA in an in vitro encapsidation assay revealed the monomeric N and not its oligomeric counterpart, to be the true encapsidating unit. Based on our observations, we propose a model to explain encapsidation that involves two discrete biochemically separable steps, initiation and elongation.

Leader RNA binding ability of Chandipura virus P protein is regulated by its phosphorylation status: a possible role in genome transcription-replication switch

The molecular events associated with the transcriptive and replicative cycle of negative-stranded RNA viruses are still an enigma. We took Chandipura virus, a member of the Rhabdoviridae family, as our model system to demonstrate that Phosphoprotein P, besides Nucleocapsid protein N, also acts as a leader RNA-binding protein in its unphosphorylated form, whereas CKII-mediated phosphorylation totally abrogates its RNA-binding ability. However, interaction between P protein and leader RNA can be distinguished from N-mediated encapsidation of viral sequences. Furthermore, P protein bound to leader chain can successively recruit N protein on RNA while itself being replaced. We also observed that the accumulation of phosphorylation null mutant of P protein in cells results in enhanced genome RNA replication with concurrent increase in the viral yield. All these results led us to propose a model explaining viral transcription-replication switch where Phosphoprotein P acts as a modulator of genome transcription and replication by its ability to bind to the nascent leader RNA in its unphosphorylated form, promoting read-through of the transcription termination signals and initiating nucleocapsid assembly on the nascent RNA chain.

Role of the virus nucleoprotein in the regulation of lymphocytic choriomeningitis virus transcription and RNA replication

The prototypic arenavirus lymphocytic choriomeningitis virus (LCMV) has a bisegmented negative-strand RNA genome. Each segment carries two viral genes in opposite orientation and separated by an intergenic region (IGR). The RNA-dependent RNA polymerase (RdRp) L of LCMV produces subgenomic mRNA and full-length genomic and antigenomic RNA species in two different processes termed transcription and replication, respectively. It is widely accepted that intracellular nucleoprotein (NP) levels regulate these two processes. Intracellular NP levels increase during the course of the infection, resulting in the unfolding of secondary RNA structures within the IGR. Structure-dependent transcription termination at the IGR is thereby attenuated, promoting replication of genome and antigenome RNA species. To test this hypothesis, we established a helper-virus-free minigenome (MG) system where intracellular synthesis of an S segment analogue from a plasmid is driven by RNA polymerase I. Cotransfection with two additional plasmids expressing the minimal viral trans-acting factors L and NP under control of RNA polymerase II allowed for RNA synthesis mediated by the intracellularly reconstituted LCMV polymerase. Both processes, transcription and replication, were strictly dependent on NP. However, both were equally enhanced by incrementally increasing amounts of NP up to levels in the range of those in LCMV-infected cells. Our data are consistent with a central role for NP in transcription and replication of the LCMV genome, but they do not support the participation of NP levels in balancing the two processes.

Virus promoters determine interference by defective RNAs: selective amplification of mini-RNA vectors and rescue from cDNA by a 3' copy-back ambisense rabies virus

Typical defective interfering (DI) RNAs are more successful in the competition for viral polymerase than the parental (helper) virus, which is mostly due to an altered DI promoter composition. Rabies virus (RV) internal deletion RNAs which possess the authentic RV terminal promoters, and which therefore are transcriptionally active and can be used as vectors for foreign gene expression, are poorly propagated in RV-infected cells and do not interfere with RV replication. To allow DI-like amplification and high-level gene expression from such mini-RNA vectors, we have used an engineered 3' copy-back (ambisense) helper RV in which the strong replication promoter of the antigenome was replaced with the 50-fold-weaker genome promoter. In cells coinfected with ambisense helper virus and mini-RNAs encoding chloramphenicol acetyltransferase (CAT) and luciferase, mini-RNAs were amplified to high levels. This was correlated with interference with helper virus replication, finally resulting in a clear predominance of mini-RNAs over helper virus. However, efficient successive passaging of mini-RNAs and high-level reporter gene activity could be achieved without adding exogenous helper virus, revealing a rather moderate degree of interference not precluding substantial HV propagation. Compared to infections with recombinant RV vectors expressing CAT, the availability of abundant mini-RNA templates led to increased levels of CAT mRNA such that CAT activities were augmented up to 250-fold, while virus gene transcription was kept to a minimum. We have also exploited the finding that internal deletion model RNAs behave like DI RNAs and are selectively amplified in the presence of ambisense helper virus to demonstrate for the first time RV-supported rescue of cDNA after transfection of mini-RNA cDNAs in ambisense RV-infected cells expressing T7 RNA polymerase.

Increased expression of the N protein of respiratory syncytial virus stimulates minigenome replication but does not alter the balance between the synthesis of mRNA and antigenome

A popular model for RNA synthesis by nonsegmented negative-strand RNA viruses is that transcription and RNA replication are executed by the same polymerase complex and that there is a dynamic balance between the two processes that is mediated by the nucleocapsid N protein. According to this model, transcription occurs until sufficient soluble N protein accumulates to initiate encapsidation of the nascent RNA product, which somehow switches the polymerase into a readthrough replicative mode. This model was examined for respiratory syncytial virus (RSV) using a reconstituted transcription and RNA replication system that involves a minireplicon and viral proteins that are expressed intracellularly from transfected plasmids. Preliminary experiments showed that reconstituted RNA replication was highly productive, such that on average each molecule of plasmid-supplied minigenome that became encapsidated was amplified 10- to 50-fold. N protein was increased on its own or in concert with the phosphoprotein P and in the presence or absence of the M2 ORF1 transcription elongation factor. The maximum level of N and P protein expression achieved from plasmids equalled or exceeded that obtained in RSV-infected cells. Increased levels of N protein stimulated RNA replication. This is consistent with the idea that RNA replication is dependent on the availability of N protein for encapsidation, which is one postulate of the model. The M2 ORF1 protein had no detectable effect on RNA replication under the various conditions of expression of N and P, which confirmed and extended previous results. However, there was no evidence of a significant switch in positive-sense RNA synthesis from transcription (synthesis of mRNAs) to RNA replication (synthesis of antigenome). The synthesis of positive-sense antigenome and mRNA appeared to occur at a fixed ratio, with mRNA being by far the more abundant product.

Expression and purification of vesicular stomatitis virus N-P complex from Escherichia coli: role in genome RNA transcription and replication in vitro

The nucleocapsid protein (N) and phosphoprotein (P) genes of vesicular stomatitis virus (VSV), Indiana serotype, were coexpressed in Escherichia coli BL21(DE3) by using the expression vector pET-3a. The coexpression resulted in the formation of N-P complex. The purified N-P complex was found to inhibit transcription in vitro mediated by viral ribonucleoprotein (RNP) complex in a dose-dependent manner. However, addition of uninfected mammalian cell extracts together with the N-P complex to the transcribing RNP resulted in the synthesis of full-length negative-strand genome RNA. These results indicate that the N-P complex regulated transcription and a cellular factor(s) in combination with the N-P complex may switch the RNA polymerase from transcription to replication mode.

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.

Temperature-sensitivity of the replication of rabies virus (HEP-flury strain) in BHK-21 cells. I. Alteration of viral RNA synthesis at the elevated temperature

We investigated the nature of temperature sensitivity of the HEP strain of rabies virus. After initial incubation for appropriate period (more than 12 hr) at the permissive temperature (36-37 degrees), incubation temperature of the rabies virus infected cultures was shifted to a nonpermissive temperature (39.5-40.5 degrees). Upon the upshift, virion production was ceased, but the rate of viral RNA synthesis was greatly increased and reached almost 10 times that of 36 degrees-infection within 8-10 hr, and then the activity quickly decreased together with the onset of accelerated CPE. Little or no 42S genome-sized RNA was produced at the elevated temperature, and almost all RNAs produced in large amounts seemed to be viral mRNAs and were shown to be functional in t he cell-free translation system. Consistent with these observations, the viral ribonucleoprotein complex isolated from the temperature-upshifted culture was associated with relatively large amounts of small sized RNAs, which might reflect their increased transcriptive activity. These observations suggest that the viral RNA polymerase itself is not temperature-sensitive and the temperature-induced defect may reside in the regulatory factor which plays a role in turning on the synthesis of viral genome-sized RNA.

Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs

Replication and amplification of RNA genomes of defective interfering (DI) particles of vesicular stomatitis virus (VSV) depend on the expression of viral proteins and have until now been attained only in cells coinfected with helper VSV. In the work described in this report, we used a recombinant vaccinia virus-T7 RNA polymerase expression system to synthesize individual VSV proteins in cells transfected with plasmid DNAs that contain cDNA copies of the VSV genes downstream of the T7 RNA polymerase promoter. In this way, we were able to examine the ability of VSV proteins, individually and in combination, to support DI particle RNA replication. VSV proteins were synthesized soon after transfection in amounts that depended on the amount of input plasmid DNA and at rates that remained constant for at least 16 h after transfection. When cells expressing the nucleocapsid protein (N), the phosphoprotein (NS), and the large polymerase protein (L) of VSV were superinfected with the DI particles, rapid and efficient replication and amplification of DI particle RNA was observed. Omission of any one of the three viral proteins abrogated the replication. The maximum levels of DI particle RNA replication that were achieved in the system exceeded those seen with wild-type helper VSV by 8- to 10-fold and were observed at molar L:NS:N protein ratios of approximately 1:200:200. This replication system can be used for analysis of structure-function relationships of VSV proteins that are involved in RNA replication and has potential for use in the identification of RNA sequences in the viral genome that control transcription and replication of VSV RNA.

The 1:1 N-NS protein complex of vesicular stomatitis virus is essential for efficient genome replication

We studied the effect pH had on the N-NS protein complex to determine its role in vesicular stomatitis virus (VSV) genome replication, as we had previously shown that VSV genome replication in vitro requires the interaction of the viral N and NS proteins into a 1:1 complex. A previous report showed that the growth of VSV in L cells was sensitive to the pH of the environment (M. Fiszman, J. B. Leaute, C. Chany, and M. Girard, J. Virol. 13:801-808, 1974). We hypothesized that low pH might disrupt the N-NS protein complex, and so we investigated the molecular events leading to inhibition of viral RNA replication in vitro from extracts that were prepared from VSV-infected cells incubated at pH 6.6. We found that viral genome RNA synthesis in vitro was reduced when infected cells were maintained at pH 6.6. Through immunoprecipitation analysis of the viral soluble protein pool, we found that a complex that usually exists between the N and NS proteins at pH 7.4 was altered in extracts from infected cells maintained at pH 6.6, and this was responsible for the observed effects on viral replication. The effect of low pH on the N-NS protein complex could not be abolished by increasing the concentration of the altered complex, indicating that the effects is more than simply a decrease in the level of the protein complex in the cell. Our data provide additional evidence that the 1:1 N-NS protein complex, and not the N protein alone, serves as the substrate for viral RNA replication in vivo.

Measles virus synthesizes both leaderless and leader-containing polyadenylated RNAs in vivo

The minus-sense RNA genome of measles virus serves as a template for synthesizing plus-sense RNAs of genomic length (antigenomes) and subgenomic length [poly(A)+ RNAs]. To elucidate how these different species are produced in vivo, RNA synthesized from the 3'-proximal N gene was characterized by Northern RNA blot and RNase protection analyses. The results showed that measles virus produced three size classes of plus-sense N-containing RNA species corresponding to monocistronic N RNA, bicistronic NP RNA, and antigenomes. Unlike vesicular stomatitis virus, measles virus does not produce a detectable free plus-sense leader RNA. Instead, although antigenomes invariably contain a leader sequence, monocistronic and bicistronic poly(A)+ N-containing RNAs are synthesized either without or with a leader sequence. We cloned and characterized a full-length cDNA representing a product of the latter type of synthesis. mRNAs and antigenomes appeared sequentially and in parallel with leaderless and leader-containing RNAs. These various RNA species accumulated concurrently throughout infection. However, cycloheximide preferentially inhibited accumulation of antigenomes and leader-containing RNA but not leaderless and subgenomic RNAs late in infection, suggesting that synthesis of the former RNA species requires a late protein function or a continuous supply of structural proteins or both. These results reveal a previously undescribed mechanism for RNA synthesis in measles virus.

Resolution of multiple complexes of phosphoprotein NS with nucleocapsid protein N of vesicular stomatitis virus

The interaction of the nucleocapsid protein N and the phosphoprotein NS of vesicular stomatitis virus (VSV) was studied, free of other viral proteins, by transcription from SP6 vectors, followed by translation in a rabbit reticulocyte lysate. N-NS complex formation depended strongly on cotranslation of the two proteins; when N and NS were mixed following separate translation of each, very little complex formation occurred. Conditions were found under which at least six N-NS complexes were separated from each other by electrophoresis in a nondenaturing gel system, and the following findings were made. (i) These complexes fell into two groups; complexes 1 through 5 all had a stoichiometry of two molecules of N to one molecule of NS, whereas N-NS complex 6 had an equimolar ratio of the two proteins. (ii) N-NS complexes 1 through 5 predominated at lower concentrations of NS relative to N, but N-NS complex 6 was the major or sole product when NS was equimolar to or in excess of N. (iii) The two sets of complexes were formed by two distinct types of interactions of NS with N. The formation of N-NS complexes 1 through 5 was abolished by the removal of as few as 11 amino acid residues from the basic, highly conserved carboxy-terminal domain of NS, which is essential for the binding of NS to the N-RNA template of VSV. In contrast, formation of complex 6 was unaffected by removal of as many as 62 of the carboxy-terminal amino acids of NS, a region encompassing both the terminal basic domain and an adjacent domain which is required for VSV RNA polymerase function. The significance of these observations for the mechanism of VSV genome replication is discussed.

Early steps in the assembly of vesicular stomatitis virus nucleocapsids in infected cells

The assembly of nucleocapsids is an essential step in the replicative cycle of vesicular stomatitis virus (VSV). In this study, we have examined the early events of vesicular stomatitis virus nucleocapsid assembly in BHK-21 cells. Nuclease-resistant intracellular nucleocapsids were isolated at various stages of assembly and analyzed for RNA and protein contents. The smallest ribonucleoprotein complex formed during nucleocapsid assembly contains the 5'-terminal 65 nucleotides of nascent viral RNA complexed with the viral proteins N and NS. Elongation of the assembling nucleocapsids proceeds unidirectionally towards the 3' terminus by the sequential addition of viral proteins which incrementally protect short stretches of the growing RNA chain. Pulse-chase studies show that the assembling nucleocapsids can be chased into full-length nucleocapsids which are incorporated into mature virions. Our results also suggest an involvement of the cytoskeletal framework during nucleocapsid assembly.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

MHV nucleocapsid synthesis in the presence of cycloheximide and accumulation of negative strand MHV RNA

We have found that genomic RNA synthesis is inhibited by cycloheximide in cells infected with mouse hepatitis virus, strain A59 (MHV-A59), in agreement with previously published results (Sawicki, S.G. and Sawicki, D.L. (1986) J. Virol, 57, 328-334). In the present study, the fate of the residual genomic RNA synthesized in the presence of cycloheximide was determined. Nearly all of the genomic RNA synthesized in the presence of drug was incorporated into nucleocapsid structures, suggesting that even in the absence of protein synthesis, genomic RNA synthesis and encapsidation are coupled in MHV-infected cells. Sufficient free nucleocapsid N protein was available for this purpose, since the pool of soluble N protein was determined to decay with a half-life of approximately one hour. Negative strand RNA is the template for the synthesis of both genomic and subgenomic positive strand RNA, and would be predicted to accumulate primarily during the early phases of the lytic cycle. In agreement with this prediction, negative strand RNA accumulated during the first 5-6 h of infection, with little additional accumulation occurring over the next 2.5 h. In marked contrast, positive strand RNA increased 5-6-fold over the same 2.5 h period. These results, taken in conjunction with published data, suggest that negative strand RNA is synthesized during the early period of the infectious cycle and is stable in infected cells and also suggest that treatment with cycloheximide at late times does not inhibit positive strand RNA synthesis indirectly by blocking the formation of negative strand templates.

Vesicular stomatitis virus N and NS proteins form multiple complexes

The vesicular stomatitis virus nucleocapsid protein, N, associated specifically with the viral phosphoprotein, NS, in an in vitro system which supported vesicular stomatitis virus RNA replication. Essentially all the N protein was found complexed with NS. In addition, multiple forms of the N-NS complex were detected which differed in their sedimentation properties and ratios of N to NS.

Coronavirus minus-strand RNA synthesis and effect of cycloheximide on coronavirus RNA synthesis

The temporal sequence of coronavirus plus-strand and minus-strand RNA synthesis was determined in 17CL1 cells infected with the A59 strain of mouse hepatitis virus (MHV). MHV-induced fusion was prevented by keeping the pH of the medium below pH 6.8. This had no effect on the MHV replication cycle, but gave 5- to 10-fold-greater titers of infectious virus and delayed the detachment of cells from the monolayer which permitted viral RNA synthesis to be studied conveniently until at least 10 h postinfection. Seven species of poly(A)-containing viral RNAs were synthesized at early and late times after infection, in nonequal but constant ratios. MHV minus-strand RNA synthesis was first detected at about 3 h after infection and was found exclusively in the viral replicative intermediates and was not detected in 60S single-stranded form in infected cells. Early in the replication cycle, from 45 to 65% of the [3H]uridine pulse-labeled RF core of purified MHV replicative intermediates was in minus-strand RNA. The rate of minus-strand synthesis peaked at 5 to 6 h postinfection and then declined to about 20% of the maximum rate. The addition of cycloheximide before 3 h postinfection prevented viral RNA synthesis, whereas the addition of cycloheximide after viral RNA synthesis had begun resulted in the inhibition of viral RNA synthesis. The synthesis of both genome and subgenomic mRNAs and of viral minus strands required continued protein synthesis, and minus-strand RNA synthesis was three- to fourfold more sensitive to inhibition by cycloheximide than was plus-strand synthesis.

Role of the nucleocapsid protein in regulating vesicular stomatitis virus RNA synthesis

We describe experiments with two monoclonal antibodies to the vesicular stomatitis virus (VSV) nucleocapsid protein N with strikingly different characteristics. Antibody 1 binds to nucleocapsids and probably the pool of free (unbound) N protein; it inhibits transcription in vitro, and when microinjected into cells, protects the cells against VSV. Antibody 2 binds poorly to nucleocapsids, does not inhibit transcription, but when microinjected into cells, binds selectively to the free N and delays the appearance of progeny virus. We have confirmed these results by analyzing the effect of these antibodies on in vitro genomic RNA synthesis. The results of both the in vivo and in vitro experiments show that the replication of the VSV genome is controlled by the availability of the nucleocapsid protein, even when the polymerase has access to the host factors and multiple phosphorylated forms of the NS protein thought to be involved in genomic RNA synthesis.

Ultrastructural localization of L and NS enzyme subunits on vesicular stomatitis virus RNPs using gold sphere-staphylococcal protein A-monospecific IgG conjugates

Colloidal gold spheres were coated with staphylococcal protein A and were used to determine the location of NS and L proteins on vesicular stomatitis virus (VSV) ribonucleoprotein (RNP) complexes using monospecific anti-NS and anti-L IgG preparations. Conjugates using either anti-NS or anti-L demonstrated that these enzyme subunits were uniformly distributed along the entire length of the RNP complex. Under saturating conditions of IgG concentrations, it was observed that there were at least 60-70 molecules of NS protein and 30-35 molecules of L protein labeled per RNP complex.

Assignment of the temperature-sensitive lesion in the replication mutant A1 of vesicular stomatitis virus to the N gene

The replication defect in the temperature-sensitive mutant A1 of the New Jersey serotype (Hazelhurst subtype) of vesicular stomatitis virus was confirmed by the absence of intracellular nucleocapsids in infected cells incubated at the restrictive temperature. After preamplification, the relative yield of the A1 N protein accumulated intracellularly after 1 h of incubation at the restrictive temperature was decreased by 50% that of the wild-type or revertant A1 N protein. This difference was not as apparent in pulse-chase experiments. The functional lesion in A1 was correlated with a structural alteration in the N protein on the basis of the thermolability of the template activity of the A1 N protein-RNA complex in in vitro transcription reactions and the covariance of this phenotype with the temperature-sensitive phenotype in a spontaneous A1 revertant. This correlation was consistent with a direct role of the N protein in replication and allowed the assignment of the N gene to complementation group A.

Isolation and characterization of canine distemper virus-specific RNA

Ten species of virus-specific RNA were detected in Vero cells infected with the FXNO strain of canine distemper virus (CDV). The largest RNA was the genome-sized RNA and the nine smaller species were polyadenylated RNAs. Similar results were obtained for nine other strains of CDV. The molecular weights of these ten RNAs were determined to be 4.61 X 10(6), 2.46 X 10(6), 1.52 X 10(6), 1.32 X 10(6), 1.19 X 10(6), 1.07 X 10(6), 0.77 X 10(6), 0.65 X 10(6), 0.58 X 10(6), and 0.48 X 10(6). By in vitro translation of the polyadenylated RNAs in a rabbit reticulocyte lysate system, three different proteins which probably correspond to H, NP, and M were synthesized from the fraction containing RNAs 7, 8, 9, and 10.

ATP dependence of vesicular stomatitis virus transcription initiation and modulation by mutation in the nucleocapsid protein

We recently reported that vesicular stomatitis virus pol R mutants contain a template-associated N-protein alteration which allows for efficient readthrough of leader RNA termination sites in vitro (Perrault et al., Cell 35:175-185, 1983). We show here that in vitro RNA synthesis mediated by pol R virions is much more resistant to replacement of ATP by the analog beta,gamma-imido ATP than by wild-type virus (approximately 50% inhibition versus approximately 95%). Characterization of beta,gamma-imido ATP-resistant and control products by size, polyadenylic acid content, frequency of initiation at the 3' end of the template, and readthrough of the leader-N gene junction leads us to conclude the following: (i) most likely, the ATP dependence of the transcription process primarily reflects a requirement for initiation or entry of the polymerase at the 3' end of the template; (ii) this requirement is largely bypassed in the mutant pol R viruses; (iii) the synthesis of small, internally initiated transcripts by wild-type virus is less dependent on ATP than that of leader RNA; and (iv) termination at leader RNA sites is not directly affected when beta,gamma-imido ATP is added before initiation of synthesis. These results are discussed in terms of the possible roles of ATP and the nucleocapsid protein in initiation and termination of vesicular stomatitis virus RNA synthesis.

Characterization of La Crosse virus small-genome transcripts

With restriction fragments from DNA clones of the La Crosse virus S genome segment, the 3' end of the S mRNA was located by S1 nuclease mapping near a polyuridine tract, approximately 100 nucleotides, from the end of the S genome. Genome replication in La Crosse virus-infected cells was abolished by the drug cycloheximide, similar to other negative-strand RNA viruses. However, the synthesis of S mRNA could not be detected in cells pretreated with cycloheximide, suggesting that ongoing protein synthesis is required for La Crosse virus genome transcription and replication. Primer extension experiments in the presence of chain-terminating nucleoside triphosphates demonstrated that the 5' end of the La Crosse virus S mRNA begins 10 to 14 nucleotides before the 3' end of the S genome segment, suggesting that the La Crosse virus S mRNA is initiated on a host primer. A hypothesis consistent with these unexpected findings is presented.

N protein alone satisfies the requirement for protein synthesis during RNA replication of vesicular stomatitis virus

Genomic replication of the negative-strand RNA viruses is dependent upon protein synthesis. To examine the requirement for protein synthesis in replication, we developed an in vitro system that supports the genome replication of defective interfering particles of the negative-strand rhabdovirus vesicular stomatitis virus (VSV), as a function of protein synthesis (Wertz, J. Virol. 46:513-522, 1983). The system consists of defective interfering nucleocapsid templates and an mRNA-dependent reticulocyte lysate to support protein synthesis. We report here an analysis of the requirement for individual viral proteins in VSV replication. Viral mRNAs purified by hybridization to cDNA clones were used to direct the synthesis of individual proteins in the in vitro system. By this method, it was demonstrated that the synthesis of the VSV nucleocapsid protein, N, alone, resulted in the replication of genome-length RNA by both defective interfering intracellular nucleocapsids and virion-derived nucleocapsids. Neither the viral phosphoprotein, NS, nor the matrix protein, M, supported RNA replication. The amount of RNA replication for a given amount of N protein was the same in reactions in which either all of the VSV proteins or only N protein were synthesized. In addition, RNA replication products synthesized in reactions containing only newly made N protein assembled with the N protein to form nucleocapsids. These results demonstrate that the major nucleocapsid protein (N) can by itself fulfill the requirement for protein synthesis in RNA replication and allow complete replication, i.e., initiation and elongation, as well as encapsidation of genome-length progeny RNA.

RNP template of vesicular stomatitis virus regulates transcription and replication functions

Small leader RNAs, copied from the extreme 3' ends of the minus and plus strands of the vesicular stomatitis virus (VSV) genome, are thought to play a central role in the regulation of viral transcription and replication. We describe here a novel class of VSV mutants, denoted pol R, in which termination at leader sites in vitro is specifically suppressed. We have assayed for the presence of leader RNAs and readthrough transcripts in reaction products from standard virion templates (plus leader) and defective interfering particle templates (minus leader). In both cases, mutant virions gave rise to a much higher proportion of readthrough transcripts than wild type (greater than 80% vs approximately 10%). Reconstitution experiments with separated ribonucleoprotein (RNP) templates and polymerase protein fractions revealed, surprisingly, that the N protein moiety of the RNP template was responsible for readthrough. This conclusion was further supported by protein analyses that showed a similar charge change in the N protein of two independently isolated pol R VSV mutants. These results lead us to propose that modification of the N protein may regulate termination at leader RNA sites.

Initiation and replication of vesicular stomatitis virus genome RNA in a cell-free system

A system for studying the in vitro replication of the RNA genomes of both wild-type vesicular stomatitis virus (VSV) and its defective interfering particle MS-T has been developed. After lysolecithin treatment of cells infected with VSV or VSV plus MS-T, a cell-free cytoplasmic extract is prepared which will support VSV mRNA synthesis and the synthesis of the 42S wild-type or 19S MS-T genome RNAs. The genome-length RNAs synthesized in vitro are assembled into RNase-resistant nucleocapsids. The level of 42S RNA synthesis in vitro (6-13% of total RNA synthesis) reflects the level of replication in vivo. Although the extracts of VSV-infected cells can also support the synthesis of VSV proteins, RNA replication is not dependent on de novo protein synthesis but utilizes the preformed soluble proteins present in the infected cell at the time the extract is prepared. The initiation of genomic RNA during in vitro replication can be demonstrated because detergent-disrupted, purified MS-T particles will replicate their RNA when added to either a total cytoplasmic extract from VSV-infected cells or the soluble protein fraction derived from such an extract.

Replication of vesicular stomatitis virus defective interfering particle RNA in vitro: transition from synthesis of defective interfering leader RNA to synthesis of full-length defective interfering RNA

The replication of the RNA of vesicular stomatitis virus (VSV) defective interfering (DI) particles was established in a defined cell-free system. The transition from synthesis of only the DI-leader RNA to replication of the full-length DI RNA was effected in the system by newly synthesized VSV proteins and occurred in the absence of VSV helper virus. Both positive- and negative-polarity full-length DI RNA were synthesized. Furthermore, the products of RNA replication associated with newly synthesized viral proteins to form complexes that were indistinguishable from authentic DI particle nucleocapsids on the basis of buoyant density and resistance to ribonuclease digestion. The DI-leader RNA did not form ribonuclease-resistant structures. We conclude that this in vitro system successfully executes many of the reactions of VSV DI particle replication and assembly.

Cell-free synthesis and assembly of vesicular stomatitis virus nucleocapsids

The association of newly synthesized vesicular stomatitis virus proteins into nucleocapsid structures was examined in a cell-free system that supports concurrent viral protein synthesis, transcription, and RNA replication. The vesicular stomatitis virus proteins synthesized by this system associated with the newly replicated RNA to form structures that banded in CsCl gradients with marker nucleocapsids. In reactions lacking nucleocapsid templates to program RNA synthesis, the newly synthesized proteins did not associate into nucleocapsid structures. The newly synthesized proteins associated with nucleocapsids were analyzed by electrophoresis on polyacrylamide gels containing sodium dodecyl sulfate after separation from non-associated proteins by chromatography on Bio-Gel A15M agarose columns. The results of this analysis showed that newly synthesized L, NS, and N proteins associated into nucleocapsids in the in vitro system. In addition, a small amount of newly synthesized M protein was stably bound to the nucleocapsids. The molar ratio of the associated, newly synthesized proteins was 2:350:1,000:10 (L:NS:N:M). More than 90% of the newly synthesized NS protein that associated with nucleocapsids in vitro was of the NS2 subspecies, as assayed by DEAE-cellulose column chromatography. The stability of the association of the newly synthesized proteins with nucleocapsids in the system mimicked that of the association of viral proteins with nucleocapsids from infected cells as measured by salt sensitivity. These data indicate that nucleocapsids were assembled from newly synthesized proteins within our in vitro system and that the molar ratio of assembled proteins was similar to that observed for virion nucleocapsids.

Synthesis in vitro of full length genomic RNA and assembly of the nucleocapsid of vesicular stomatitis virus in a coupled transcription-translation system

Synthesis of a small amount of 42S RNA in addition to the VSV specific mRNA species was observed in a coupled transcription-translation system containing ribonucleoprotein particles from L cell infected with vesicular stomatitis virus and nuclease-treated ribosomal extract obtained from uninfected HeLa cells. Analysis on a CsCl density gradient showed that the synthesized 42S RNA was associated with newly synthesized by protein as a nucleoprotein of bouyant density of 1.3 g/ml. The 42S RNA and the N protein present in the nucleoprotein were resistant to nuclease and protease, respectively. About 35% of the remaining 65% had a complementary polarity. The evidence presented here demonstrates that both the full length genomic and the complementary RNA are associated with N protein in the in vitro replication process. A template role for the complementary 42S RNA for replication of the genomic RNA is also suggested.

Synthesis of vesicular stomatitis virus negative-strand RNA in vitro: dependence on viral protein synthesis

An in vitro system is described which supports the synthesis of vesicular stomatitis virus (VSV) negative-strand RNA. The major components of this system are (i) an mRNA-dependent rabbit reticulocyte lysate to carry out cell-free protein synthesis, (ii) the five VSV mRNAs to program VSV-specific protein synthesis, and (iii) nucleocapsids containing positive- and negative-strand genome-length RNA. The protein products synthesized in the system in response to addition of saturating amounts of the five VSV mRNA's included polypeptides which comigrated in acrylamide gels with the five VSV proteins. Approximately 200 pmol of protein per ml was synthesized during a 90-min reaction. The RNA products synthesized in the system included all five of the VSV mRNA's and, in addition, negative-strand, genome-sense RNA. All of the negative-strand RNA, which represented 2 to 5% of the total RNA product synthesized in vitro, banded in CsCl at the position of nucleocapsids. All of the mature mRNA's made in the system pelleted in CsCl. This technique allowed a clear separation of negative-strand product from the mRNA products and facilitated further analysis of the negative-strand product. The amount of negative-strand product produced in the system was shown to be a function of the amount of concurrent protein synthesis in the system. An increase in the level of protein synthesis led to an increase in the amount of negative-strand RNA synthesized, whereas inhibition of protein synthesis by cycloheximide resulted in a 70% inhibition of negative-strand synthesis. In contrast to the negative-strand RNA product, the amount of transcriptive product was decreased by 50% in the presence of maximum levels of viral protein synthesis. This inhibition was reversed by adding cycloheximide. Characterization of the negative-strand product by Northern blot analysis demonstrated that negative-strand product was being synthesized which hybridized to all five of the VSV mRNA's and, hence, that product representing all of the VSV cistrons was being made. This in vitro system offers an opportunity to study factors involved in the promotion of VSV genome replication as well as those responsible for the regulation of transcription.

Characterization and mapping of RNase III cleavage sites in VSV genome RNA

Ribonuclease III cleaves the genome RNA of vesicular stomatitis virus (VSV) to yield an array of fragments which range in size from 3.5 to 0.1 x 10(6) daltons under partial digestion conditions. The locations of the RNase III cleavage sites which give rise to these fragments have been ordered relative to the 3' end of the virion RNA by digestion of 3' end-labeled RNA. Based on a map of the cleavage sites we predicted that fragments having the same size could be generated which contain information from each gene. Annealing of individual VSV mRNA probes to Northern blots of the separated RNase III-generated fragments confirmed that fragments having the same size are, in fact, generated which contain information from each coding region of the VSV genome. Analysis of maps of partial digestion products indicates that fragments having the same size arise repeatedly along the 3' half of the genome. The cleavage of VSV RNA by RNase III can be detected only if the nuclease treated molecules are denatured. This suggest that the structure features in VSV RNA which signal cleavage involve areas of higher order RNA structure.

RNA synthesis of vesicular stomatitis virus. X. Transcription and replication by defective interfering particles

In cells coinfected by standard vesicular stomatitis virus (VSV) and defective interfering (DI) T particles, small RNA consisting of 46 nucleotides was synthesized in molar excess over other VSV-specific RNAs. Although its rate of synthesis increased over time, small RNA accumulated linearly, suggesting that the molecule is unstable. In contrast, replication of the genome RNA of DI T particles was relatively constant after 3 h of infection, resulting in the intracellular accumulation of stable genomic and antigenomic RNA of DI T particles. Coinfection of cells with DI T particles and selected temperature-sensitive mutants from all five complementation groups of VSV indicated that the replication of DI genomes was controlled separately from the synthesis of small RNA. Also, when viral RNA replication was inhibited by cycloheximide, small RNA continued to be synthesized as long as there were enough templates present. These results indicate that small RNA is synthesized by the enzyme(s) involved in VSV transcription and that its dependence on RNA replication is due to the requirement for template amplification.

Replicative RNA synthesis and nucleocapsid assembly in vesicular stomatitis virus-infected permeable cells

A permeable-cell system has been developed to study the replication of vesicular stomatitis virus. When vesicular stomatitis virus-infected BHK cells were permeabilized by lysolecithin treatment, they incorporated nucleoside triphosphates into RNA and amino acids into proteins at nearly normal rates. The viral mRNA's synthesized appeared normal in polarity, size distribution, and polyadenylation, and all five viral proteins were synthesized. Replication of the viral genome proceeded, and full-length RNA strands were synthesized in amounts and polarities resembling those found in intact cells. These full-length RNAs associated with viral N proteins to form RNase-resistant nucleocapsids of normal buoyant density. Permeable cells appear to represent ideal hosts for studying vesicular stomatitis virus replication since they closely mimic in vivo conditions while retaining much of the experimental flexibility of current in vitro systems.

Short-lived minus-strand polymerase for Semliki Forest virus

Semliki Forest virus (SFV)-infected BHK-21, Vero, and HeLa cells incorporated [3H]uridine into 42S and 26S plus-strand RNA and into viral minus-strand RNA (complementary to the 42S virion RNA) early in the infectious cycle. Between 3 and 4 h postinfection, the synthesis of minus-strand RNA ceased in these cultures, although the synthesis of plus-strand RNA continued at a maximal rate. At the time of cessation of minus-strand RNA synthesis, two changes in the pattern of viral protein synthesis were detected: a decrease in the translation of nonstructural proteins and an increase in the translation of the viral structural proteins. Addition of cycloheximide and puromycin to cultures of SFV-infected BHK cells actively synthesizing both viral plus- and minus-strand RNA resulted within 15 to 30 min in the selective shutoff of minus-strand RNA synthesis. Removal of the cycloheximide-containing medium led to the resumption of minus-strand synthesis and to an increased rate of viral RNA synthesis. We conclude that the minus-strand polymerase regulates the rate of SFV plus-strand RNA synthesis by determining the number of minus-strand templates and that the synthesis of the minus-strand templates is regulated at the level of translation by a mechanism which utilizes one or more short-lived polymerase proteins.