RNP template of vesicular stomatitis virus regulates transcription and replication functions

How does the polymerase of non-segmented negative strand RNA viruses commit to transcription or genome replication?

The Mononegavirales, or non-segmented negative-sense RNA viruses (nsNSVs), includes significant human pathogens, such as respiratory syncytial virus, parainfluenza virus, measles virus, Ebola virus, and rabies virus. Although these viruses differ widely in their pathogenic properties, they are united by each having a genome consisting of a single strand of negative-sense RNA. Consistent with their shared genome structure, the nsNSVs have evolved similar ways to transcribe their genome into mRNAs and replicate it to produce new genomes. Importantly, both mRNA transcription and genome replication are performed by a single virus-encoded polymerase. A fundamental and intriguing question is: how does the nsNSV polymerase commit to being either an mRNA transcriptase or a replicase? The polymerase must become committed to one process or the other either before it interacts with the genome template or in its initial interactions with the promoter sequence at the 3´ end of the genomic RNA. This review examines the biochemical, molecular biology, and structural biology data regarding the first steps of transcription and RNA replication that have been gathered over several decades for different families of nsNSVs. These findings are discussed in relation to possible models that could explain how an nsNSV polymerase initiates and commits to either transcription or genome replication.

Structures and Mechanisms of Nonsegmented, Negative-Strand RNA Virus Polymerases

The nonsegmented, negative-strand RNA viruses (nsNSVs), also known as the order Mononegavirales, have a genome consisting of a single strand of negative-sense RNA. Integral to the nsNSV replication cycle is the viral polymerase, which is responsible for transcribing the viral genome, to produce an array of capped and polyadenylated messenger RNAs, and replicating it to produce new genomes. To perform the different steps that are necessary for these processes, the nsNSV polymerases undergo a series of coordinated conformational transitions. While much is still to be learned regarding the intersection of nsNSV polymerase dynamics, structure, and function, recently published polymerase structures, combined with a history of biochemical and molecular biology studies, have provided new insights into how nsNSV polymerases function as dynamic machines. In this review, we consider each of the steps involved in nsNSV transcription and replication and suggest how these relate to solved polymerase structures.

Identification and characterization of short leader and trailer RNAs synthesized by the Ebola virus RNA polymerase

Transcription of non-segmented negative sense (NNS) RNA viruses follows a stop-start mechanism and is thought to be initiated at the genome’s very 3’-end. The synthesis of short abortive leader transcripts (leaderRNAs) has been linked to transcription initiation for some NNS viruses. Here, we identified the synthesis of abortive leaderRNAs (as well as trailer RNAs) that are specifically initiated opposite to (anti)genome nt 2; leaderRNAs are predominantly terminated in the region of nt ~ 60–80. LeaderRNA synthesis requires hexamer phasing in the 3’-leader promoter. We determined a steady-state NP mRNA:leaderRNA ratio of ~10 to 30-fold at 48 h after Ebola virus (EBOV) infection, and this ratio was higher (70 to 190-fold) for minigenome-transfected cells. LeaderRNA initiation at nt 2 and the range of termination sites were not affected by structure and length variation between promoter elements 1 and 2, nor the presence or absence of VP30. Synthesis of leaderRNA is suppressed in the presence of VP30 and termination of leaderRNA is not mediated by cryptic gene end (GE) signals in the 3’-leader promoter. We further found different genomic 3’-end nucleotide requirements for transcription versus replication, suggesting that promoter recognition is different in the replication and transcription mode of the EBOV polymerase. We further provide evidence arguing against a potential role of EBOV leaderRNAs as effector molecules in innate immunity. Taken together, our findings are consistent with a model according to which leaderRNAs are abortive replicative RNAs whose synthesis is not linked to transcription initiation. Rather, replication and transcription complexes are proposed to independently initiate RNA synthesis at separate sites in the 3’-leader promoter, i.e., at the second nucleotide of the genome 3’-end and at the more internally positioned transcription start site preceding the first gene, respectively, as reported for Vesicular stomatitis virus.

The RNA polymerase (RdRp) of Ebola virus (EBOV) initiates RNA synthesis at the 3’-leader promoter of its encapsidated, non-segmented negative sense (NNS) RNA genome, either at the penultimate 3’-end position of the genome in the replicative mode or more internally (position 56) at the transcription start site (TSS) in its transcription mode. Here we identified the synthesis of abortive replicative RNAs that are specifically initiated opposite to genome nt 2 (termed leaderRNAs) and predominantly terminated in the region of nt ~ 60–80 near the TSS. The functional role of abortive leaderRNA synthesis is still enigmatic; a role in interferon induction could be excluded. Our findings indirectly link leaderRNA termination to nucleoprotein (NP) availability for encapsidation of nascent replicative RNA or to NP removal from the template RNA. Our findings further argue against the model that leaderRNA synthesis is a prerequisite for each transcription initiation event at the TSS. Rather, our findings are in line with the existence of distinct replicase and transcriptase complexes of RdRp that interact differently with the 3’-leader promoter and intiate RNA synthesis independently at different sites (position 2 or 56 of the genome), mechanistically similar to another NNS virus, Vesicular stomatitis virus.

Several residues within the N-terminal arm of vesicular stomatitis virus nucleoprotein play a critical role in protecting viral RNA from nuclease digestion

The nucleoprotein (N) of vesicular stomatitis virus (VSV) plays a central role in transcription and replication by encapsidating genome RNA to form a nucleocapsid as the template for the RNA synthesis. Using minigenome system we evaluated the roles of 21 amino acids of the N-terminal arm of N in forming functional N-RNA templates and found that three triple-amino-acid substitutions (TVK4-6A3, RII7-9A3, and VIV13-15A3) and one single-amino-acid substitution (R7A) resulted in RNA synthesis loss. But all the mutants maintain the ability to oligomerize N, interact with P, and encapsidate viral RNA for template formation. Further analysis showed that the nucleocapsid formed by these mutants failed to protect RNA from nuclease digestion. Then, we found that only recombinant viruses containing R7A could be recovered. Our results show that the several amino acids within the N-terminal arm of N contribute to the template function beyond its role in RNA encapsidation and viral growth.

Importance of hydrogen bond contacts between the N protein and RNA genome of vesicular stomatitis virus in encapsidation and RNA synthesis

Vesicular stomatitis virus (VSV) genomic RNA encapsidated by the nucleocapsid (N) protein is the template for transcription and replication by the viral polymerase. We analyzed the 2.9-A structure of the VSV N protein bound to RNA (T. J. Green, X. Zhang, G. W. Wertz, and M. Luo, Science 313:357-360, 2006) and identified amino acid residues with the potential to interact with RNA via hydrogen bonds. The contributions of these interactions to N protein function were investigated by individually substituting the residues with alanine and assaying the effect of these mutations on N protein expression, on the ability of the N protein to interact with the phosphoprotein (P), and on its ability to encapsidate RNA and generate templates that can support transcription and RNA replication. These studies identified individual amino acids critical for N protein function. Nine nucleotides are associated with each N monomer and contorted into two quasi-helices within the N protein RNA binding cavity. We found that N protein residues that formed hydrogen bond contacts with the nucleotides in quasi-helix 2 were critical to the encapsidation of RNA and the production of templates that can support RNA synthesis. Individual hydrogen bond interactions between the N protein and the nucleotides of quasi-helix 1 were not essential for ribonucleoprotein (RNP) template function. Residue R143 forms a hydrogen bond with nucleotide 9, the nucleotide that extends between N monomers. R143A mutant N protein failed to encapsidate RNA and to support RNA synthesis and suppressed wild-type N protein function. These studies show a direct correlation between viral RNA synthesis and N protein residues structurally positioned to interact with RNA.

Insertion of enhanced green fluorescent protein in a hinge region of vesicular stomatitis virus L polymerase protein creates a temperature-sensitive virus that displays no virion-associated polymerase activity in vitro

The RNA-dependent RNA polymerase of viruses belonging to the order Mononegavirales is part of a large multifunctional L protein that also catalyzes viral mRNA capping and cap methylation. The L protein of this diverse group of agents displays six blocks of conserved sequences. The precise relationship between these conserved regions and individual functions is largely unknown, except for "domain" VI that clearly encodes a viral mRNA cap methylase. The L protein of morbilliviruses (family Paramyxoviridae) was reported to tolerate insertion of the enhanced green fluorescent protein (EGFP) in a region just upstream of domain VI. Recombinant viruses with this insertion grow well in cell culture but are highly attenuated in animal hosts. We show here that the L protein of vesicular stomatitis virus (VSV), the prototype of the Rhabdoviridae family, also tolerates insertion of EGFP at a similar site. The modified protein (L(EGFP)) and the resultant recombinant virus both demonstrated a sharp temperature-sensitive phenotype for polymerase activity, with reduced activity at 37 degrees C and no activity at 37.5 degrees C. Neither translation nor methylation of mutant virus transcripts was affected at 37 degrees C. Curiously, mutant virus grown at permissive temperature contained about threefold-less L protein than the wild-type virus did and displayed no virion-associated polymerase activity in vitro. These findings support the notion that a flexible "hinge" region separates the cap methylase domain of L proteins from upstream functions and open up a number of avenues for studies of L-protein function in the more-tractable VSV model system.

Single-amino-acid alterations in a highly conserved central region of vesicular stomatitis virus N protein differentially affect the viral nucleocapsid template functions

The nucleocapsid protein (N) of vesicular stomatitis virus and other rhabdoviruses plays a central role in the assembly and template functions of the viral N-RNA complex. The crystal structure of the viral N-RNA complex suggests that the central region of the N protein interacts with the viral RNA. Sequence alignment of rhabdovirus N proteins revealed several highly conserved regions, one of which spanned residues 282 to 291 (GLSSKSPYSS) in the central region of the molecule. Alanine-scanning mutagenesis of this region suggested that replacement of the tyrosine residue at position 289 (Y289) with alanine resulted in an N-RNA template that is nonfunctional in viral genome replication and transcription. To establish the molecular basis of this defect, our further studies revealed that the Y289A mutant maintained its interaction with other N protein molecules but that its interactions with the P protein or with the viral RNA were defective. Replacement of Y289 with other aromatic, polar, or large amino acids indicated that the hydrophobic and aromatic nature of this position in the N protein is functionally important and that a larger aromatic residue is less favorable. Interestingly, we have observed that several single-amino-acid substitutions in this highly conserved region of the molecule rendered the nucleocapsid template nonfunctional in transcription without adversely affecting the replication functions. These results suggest that the structure of the N protein and the resulting N-RNA complex, in part, regulate the viral template functions in transcription and replication.

Overproduction of double-stranded RNA in vesicular stomatitis virus-infected cells activates a constitutive cell-type-specific antiviral response

In a companion paper (D. Ostertag, T. M. Hoblitzell-Ostertag, and J. Perrault, J. Virol. 81:492-502, 2007), we provided indirect evidence that cell-type-specific growth restriction of the vesicular stomatitis virus (VSV) polR mutants may be due to enhanced production of double-stranded RNA (dsRNA). We show here that polR growth in mouse L-929 cells was rescued by vaccinia virus coinfection and that sole expression of the vaccinia virus dsRNA-binding E3L protein, via coinfection with an engineered VSV minigenome, also restored polR growth. Expression of dsRNA-binding protein NS1A or NS1B from influenza virus, but not C protein from Sendai virus, which does not bind dsRNA, likewise effected polR rescue. The N-terminal dsRNA-binding domain of NS1A, only 73 amino acids in length, but not a full-size mutant NS1A lacking dsRNA-binding activity, restored polR growth. Both key aspects of polR growth restriction, namely inhibition of genome replication and release of low-infectivity virus particles, were countered by expression of the dsRNA-binding proteins. We tested the effects of overproducing dsRNA in wild-type VSV infections by coinfecting cells with a VSV recombinant expressing the sense strand of the enhanced green fluorescent protein gene (VSV-GFP) and one expressing the antisense strand (VSV-PFG). These coinfections mimicked all aspects of polR restriction, including host range, lack of effect on transcription, reduced virus particle infectivity, and insensitivity to inhibition of host gene transcription or dsRNA-activated protein kinase activity. We conclude that, for some cell types, overproduction of dsRNA during VSV infection triggers an immediate and constitutive host cell antiviral effector response independent of interferon induction or signaling.

Cell-type-specific growth restriction of vesicular stomatitis virus polR mutants is linked to defective viral polymerase function

Vesicular stomatitis virus polR mutants synthesize defective RNA replication products in vitro and display growth restriction in some cultured cells (J. L. Chuang, R. L. Jackson, and J. Perrault, Virology 229:57-67, 1997). We show here that a recombinant virus carrying the polR N protein mutation (R179H) yielded approximately 100-fold- and approximately 40-fold-lower amounts of infectious virus than the wild type in mouse L-929 and rat 3Y1 cells, respectively, but only approximately 3-fold less in hamster BHK cells. Virus genome accumulation was inhibited 6- to 10-fold in restricting cells, but transcription was not affected. No defect in encapsidation of replication products was detected, but virus protein accumulation was reduced two- to threefold in both restricting and nonrestricting cells. polR virus particles released from the latter were 5- to 10-fold less infectious than the wild type but showed no difference in protein composition. Phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2alpha) was enhanced approximately 3-fold in polR versus wild-type virus-infected L-929 cells, but neither inhibition of host gene transcription nor inhibition of double-stranded RNA (dsRNA)-activated protein kinase showed significant effects on restriction. Conditioned medium studies revealed no evidence for secretion of antiviral factors from restricting cells. We conclude that the block in polR growth is due to the combined effect of reduced genome replication and lower infectivity of released virus particles and may be due to overproduction of dsRNA. An accompanying paper (D. Ostertag, T. M. Hoblitzell-Ostertag, and J. Perrault, J. Virol. 81:503-513, 2007) provides compelling evidence for the role of dsRNA in this unique restriction phenomenon.

Genetic comparison of the rhabdoviruses from animals and plants

There are more than 160 viral species in the Rhabdovidae family, most of which can be grouped into one of the six genera including Vesiculovirus, Lyssavirus, Ephemerovirus, Novirhabdovirus, Cytorhabdovirus, and Nucleorhabdovirus. These viruses are not only morphologically similar but also genetically related. Analysis of viral genes shows that rhabdoviruses are more closely related to each other than to viruses in other families. With the development of reverse genetics, the functions of many cis- and trans-elements important in the process of viral transcription and replication have been clearly defined such as the leader, trailer, and the intergenic sequences. Furthermore, it has been shown that there are two entry sites for the RNA-dependent RNA polymerase: 3' entry for leader synthesis and RNA replication, and direct entry at the N gene start sequence for transcription of the monocistronic mRNAs.

Viral DNA polymerase scanning and the gymnastics of Sendai virus RNA synthesis

mRNA synthesis from nonsegmented negative-strand RNA virus (NNV) genomes is unique in tht the genome RNA is embedded in an N protein assembly (the nucleocapsid) and the viral RNA polymerase does not dissociate from the template after release of each mRNA, but rather scans the genome RNA for the next gene-start site. A revised model for NNV RNA synthesis is presented, in which RNA polymerase scanning plays a prominent role. Polymerase scanning of the template is known to occur as the viral transcriptase negotiates gene junctions without falling off the template.

Transcription and replication of nonsegmented negative-strand RNA viruses

The nonsegmented negative-strand (NNS) RNA viruses of the order Mononegavirales include a wide variety of human, animal, and plant pathogens. The NNS RNA genomes of these viruses are templates for two distinct RNA synthetic processes: transcription to generate mRNAs and replication of the genome via production of a positive-sense antigenome that acts as template to generate progeny negative-strand genomes. The four virus families within the Mononegavirales all express the information encoded in their genomes by transcription of discrete subgenomic mRNAs. The key feature of transcriptional control in the NNS RNA viruses is entry of the virus-encoded RNA-dependent RNA polymerase at a single 3' proximal site followed by obligatory sequential transcription of the linear array of genes. Levels of gene expression are primarily regulated by position of each gene relative to the single promoter and also by cis-acting sequences located at the beginning and end of each gene and at the intergenic junctions. Obligatory sequential transcription dictates that termination of each upstream gene is required for initiation of downstream genes. Therefore, termination is a means to regulate expression of individual genes within the framework of a single transcriptional promoter. By engineering either whole virus genomes or subgenomic replicon derivatives, elements important for signaling transcript initiation, 5' end modification, 3' end polyadenylation, and transcription termination have been identified. Although the diverse families of NNS RNA virus use different sequences to control these processes, transcriptional termination is a common theme in controlling gene expression and overall transcriptional regulation is key in controlling the outcome of viral infection. The latest models for control of replication and transcription are discussed.

Transcriptional control of the RNA-dependent RNA polymerase of vesicular stomatitis virus

The nonsegmented negative strand (NNS) RNA viruses include some of the mosr problematic human, animal and plant pathogens extant: for example, rabies virus, Ebola virus, respiratory syncytial virus, the parainfluenza viruses, measles and infectious hemapoietic necrosis virus. The key feature of transcriptional control in the NNS RNA viruses is polymerase entry at a single 3' proximal site followed by obligatory sequential transcription of the linear array of genes. The levels of gene expression are primarily regulated by their position on the genome. The promoter proximal gene is transcribed in greatest abundance and each successive downstream gene is synthesized in progressively lower amounts due to attenuation of transcription at each successive gene junction. In addition, NNS RNA virus gene expression is regulated by cis-acting sequences that reside at the beginning and end of each gene and the intergenic junctions. Using vesicular stomatitis virus (VSV), the prototypic NNS, many of these control elements have been identified.The signals for transcription initiation and 5' end modification and for 3' end polyadenylation and termination have been elucidated. The sequences that determine the ability of the polymerase to slip on the template to generate polyadenylate have been identified and polyadenylation has been shown to be template dependent and integral to the termination process. Transcriptional termination is a key element in control of gene expression of the negative strand RNA viruses and a means by which expression of individual genes may be silenced or regulated within the framework of a single transcriptional promoter. In addition, the fundamental question of the site of entry of the polymerase during transcription has been reexamined and our understanding of the process altered and updated. The ability to engineer changes into infectious viruses has confirmed the action of these elements and as a consequence, it has been shown that transcriptional control is key to controlling the outcome of a viral infection. Finally, the principles of transcriptional regulation have been utilized to develop a new paradigm for systematic attenuation of virulence to develop live attenuated viral vaccines.

Transcription and replication initiate at separate sites on the vesicular stomatitis virus genome

The RNA-dependent RNA polymerase of the nonsegmented negative-strand RNA viruses carries out two distinct RNA synthetic processes: transcription of monocistronic, capped, and polyadenylated subgenomic messenger RNAs, and replication by means of the synthesis of a full-length positive-sense copy of the genome. The template for both processes is the negative-sense genomic RNA tightly encapsidated by the viral nucleocapsid protein. By applying UV transcriptional mapping to engineered variants of vesicular stomatitis virus, we discovered that, in infected cells, transcription and replication are controlled by initiation at different positions on the viral genome.

Strawberry crinkle virus, a Cytorhabdovirus needing more attention from virologists

Summary Taxonomic relationship: A member of nonsegmented, negative-sense, single-stranded RNA viruses of the genus Cytorhabdovirus (type member: Lettuce necrotic yellows virus), family Rhabdoviridae, order Mononegavirales. Members of the family Rhabdoviridae can infect vertebrates, invertebrates and plants. Physical properties: Virions are bacilliform, 74-88 nm in diameter and 163-383 nm in length with surface projections probably composed of trimers of the glycoprotein G, occurring in the cytoplasm in either the coated or the uncoated form (Fig. 1). The nucleocapsid is enclosed in a host-derived envelope. Within the virion, the SCV genome consists of a single negative-sense single-stranded RNA molecule of approximately 13 kb. Viral proteins: The SCV genome encodes at least five proteins: the nucleocapsid (N) protein (45 kDa), the matrix (M) protein (77 kDa), the nonstructural protein [Ns, 55 kDa, also known as phosphoprotein (P)], the glycoprotein (G, 23 kDa) and the large (L) protein. Hosts: The natural host range of SCV is limited to species of the genus Fragaria L. Experimental hosts include Physalis pubescens L., P. floridana Rydb., Nicotiana occidentalis, N. glutinosa L. and N. clevelandi Gray. SCV also replicates in its insect vectors Chaetosiphon fragaefolii Cockerell and C. jacobi Hille Ris Lamberts. When injected as purified virus, SCV replicates in aphids Hyperomyzus lactucae (L.), Macrosiphon euphorbiae Thomas, Myzus ornatus Laing, Megoura viciae Buckton, and Acyrthosiphoa pisum (Harris).

Identification of a minimal size requirement for termination of vesicular stomatitis virus mRNA: implications for the mechanism of transcription

The nonsegmented negative-strand RNA (NNS) viruses have a single-stranded RNA genome tightly encapsidated by the viral nucleocapsid protein. The viral polymerase transcribes the genome responding to specific gene-start and gene-end sequences to yield a series of discrete monocistronic mRNAs. These mRNAs are not produced in equimolar amounts; rather, their abundance reflects the position of the gene with respect to the single 3'-proximal polymerase entry site. Promoter-proximal genes are transcribed in greater abundance than more distal genes due to a localized transcriptional attenuation at each gene junction. In recent years, the application of reverse genetics to the NNS viruses has allowed an examination of the role of the gene-start and gene-end sequences in regulating mRNA synthesis. These studies have defined specific sequences required for initiation, 5' modification, termination, and polyadenylation of the viral mRNAs. In the present report, working with Vesicular stomatitis virus, the prototypic Rhabdovirus, we demonstrate that a gene-end sequence must be positioned a minimal distance from a gene-start sequence for the polymerase to efficiently terminate transcription. Gene-end sequences were almost completely ignored in transcriptional units less than 51 nucleotides. Transcriptional units of 51 to 64 nucleotides allowed termination at the gene-end sequence, although the frequency with which polymerase failed to terminate and instead read through the gene-end sequence to generate a bicistronic transcript was enhanced compared to the observed 1 to 3% for wild-type viral mRNAs. In all instances, failure to terminate at the gene end prevented initiation at the downstream gene start site. In contrast to this size requirement, we show that the sequence between the gene-start and gene-end signals, or its potential to adopt an RNA secondary structure, had only a minor effect on the efficiency with which polymerase terminated transcription. We suggest three possible explanations for the failure of polymerase to terminate transcription in response to a gene-end sequence positioned close to a gene-start sequence which contribute to our emerging picture of the mechanism of transcriptional regulation in this group of viruses.

Replication of paramyxoviruses

Molecular studies on the replication of paramyxoviruses have undergone a revolution in recent years due to the development of techniques that permit the manipulation of their genomes as cDNA. This has led to new information on the structure-function organization of the viral proteins involved in genome expression, as well as dissection of the cis-acting template sequences that regulate transcription and replication. Studies using recombinant viruses have also provided new insights into the role of the accessory proteins (V, C, M1/M2) in both for virus growth in cultured cells and pathogenesis in animals.

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.

Isolation and characterization of vesicular stomatitis virus PoIR revertants: polymerase readthrough of the leader-N gene junction is linked to an ATP-dependent function

The switch from transcription to replication of the VSV genome is coupled to assembly of nascent chains and involves an unspecified change in the P-L polymerase complex when it reaches the leader-N gene junction. PoIR VSV mutants, in contrast to wild-type virus, read through this first gene junction at high frequency without concurrent assembly, and they show altered ATP requirements for transcription in vitro. The mutation(s) responsible for the poIR phenotype segregates to the N-RNA template fraction. We report here that both poIR1 and poIR2 mutants display severe growth restriction in mouse L cells but not in BHK cells. Four of six poIR1 revertant viruses, originating from rare plaques on L cells, showed wild-type characteristics for growth, readthrough of leader-N gene junction, and ATP utilization, while two showed partial and quantitatively parallel coreversion of all properties. Sequence analysis of N and P genes of poIR mutants and revertants provided proof that a single mutation in the N protein, Arg179 to His, is responsible for the poIR phenotype. PoIR1, but not poIR2, also displayed a phenotypically silent GA-to-GG change in the N-P intergenic dinucleotide sequence Five of six revertants retained the poIR1 N protein mutation and showed no change in their P gene. We conclude that the L protein likely contains second-site suppressors of the poIR phenotype, and we propose that the switch from transcription to replication is modulated by an ATP-dependent interaction between the template-associated N protein and the L subunit of the P L polymerase complex.

Characterization of the components and activity of Sonchus yellow net rhabdovirus polymerase

Sonchus yellow net virus (SYNV) is the best-characterized member of a group of plant rhabdoviruses that replicate in the host cell nucleus. Using a recently developed method for partial purification of active SYNV polymerase by salt extraction of nuclei from infected plant tissue (J. D. O. Wagner et al, J. Virol. 70:468-477, 1996), we have identified the nucleocapsid (N), M2, and L proteins as polymerase complex components (based on copurification with the polymerase activity and by coimmunoprecipitation assays). Furthermore, the L protein was shown by antibody inhibition analysis to be a functional component of the polymerase. A second complex of M2 and L proteins, thought to be a precursor to the polymerase complex, was also identified. In addition, we conducted a detailed characterization of SYNV RNA synthesis in vitro. The results demonstrate that the RNAs are transcribed sequentially, beginning with the N mRNA and followed successively by the remaining five mRNAs in the order of their genome organization. Gene expression conforms to a cascade pattern, with synthesis of the 3'-proximal N mRNA occurring at the highest level, followed by consecutively lower levels of transcription from each subsequent gene. The reaction conditions favor transcription over minus-sense RNA replication, which, we posit, is inhibited near specific signal sequences located on the antigenomic template. The results support the concept that the mechanism of transcription is highly conserved among diverse rhabdoviruses and are compatible with a unified model for the regulation of genomic and antigenomic RNA synthesis.

Initiation of vesicular stomatitis virus mutant polR1 transcription internally at the N gene in vitro

The vesicular stomatitis virus (VSV) polymerase is thought to initiate transcription of its genome by first copying a small leader RNA complementary to the 3' end of the template. The polR VSV mutants, in contrast to wild-type virus, frequently read through the leader termination site during transcription in vitro. To shed light on polymerase termination and reinitiation events at the crucial leader-N gene junction, we employed RNase protection assays to precisely measure molar ratios of leader, N, and readthrough transcript accumulation in vitro. Wild-type virus synthesized essentially equimolar amounts of leader and N transcripts, but, unexpectedly, the polR1 mutant yielded about twice as much N mRNA as leader (ratio of 1.9 +/- 0.1). Primer extension assays ruled out an increase in abortive N transcript synthesis for polR1. Transcription entailed multiple rounds of synthesis, with transcript ratios remaining the same after 0.5 or 2 h of synthesis, ruling out a significant contribution from polymerases "pre-positioned" at the N gene. No significant degradation of either leader or N transcripts was observed after incubating purified products with virions. Our data lead us to conclude that transcription can initiate internally at the N gene, at least in the case of polR1 VSV. We propose, however, that productive internal initiation of transcription is a fundamental property of the VSV polymerase and that of related viruses. A model postulating two distinct polymerase complexes, one for leader synthesis and one for internal initiation, is presented.

Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus

Preceding and following each gene of respiratory syncytial virus (RSV) are two conserved sequences, the gene-start (GS) and gene-end (GE) motifs, respectively, which are thought to be transcription signals. The functions and boundaries of these signals and the process of sequential transcription were analyzed with cDNA-encoded RNA analogs (minigenomes) of nonsegmented negative-sense RSV genomic RNA. Two minigenomes were used. The monocistronic RSV-CAT minigenome consists of the chloramphenicol acetyltransferase (CAT) translational open reading frame (ORF) bordered by the GS and GE motifs and flanked by the 3' leader and 5' trailer extragenic regions of genomic RNA. The dicistronic RSV-CAT-LUC minigenome is a derivative of RSV-CAT into which the ORF for luciferase (LUC), bordered by GS and GE motifs, was inserted downstream of the CAT gene with an intergenic region positioned between the two genes. Each minigenome was synthesized in vitro and transfected into RSV-infected cells, where it was replicated and transcribed to yield the predicted polyadenylated subgenomic mRNA(s). The only RSV sequences required for efficient transcription and RNA replication were the 44-nucleotide 3' leader region, the last 40 nucleotides of the 5' trailer region, and the 9- to 10-nucleotide GS and 12- to 13-nucleotide GE motifs. The GS and GE motifs functioned as self-contained, transportable transcription signals which could be attached to foreign sequences to direct their transcription into subgenomic mRNAs. Removal of the GS motif greatly reduced transcription of its gene, and the requirement for this element was particularly strict for the gene in the downstream position. Ablation of the promoter-proximal GS signal was not associated with increased antigenome synthesis. Consistent with its proposed role in termination and polyadenylation, removal of the CAT GE signal in RSV-CAT resulted in the synthesis of a nonpolyadenylated CAT mRNA, and in RSV-CAT-LUC the same mutation resulted in readthrough transcription to yield a dicistronic CAT-LUC mRNA. The latter result showed that a downstream GS signal is not recognized for reinitiation by the polymerase if it is already engaged in mRNA synthesis; instead, it is recognized only if the polymerase first terminates transcription at an upstream termination signal. This result also showed that ongoing transcription did not open the downstream LUC gene for internal polymerase entry. Removal of both the GS and GE signals of the upstream CAT gene in RSV-CAT-LUC silenced expression of both genes, confirming that independent polymerase entry at an internal gene is insignificant. Remarkably, whereas both genes were silent when the CAT GS and GE signals were both absent, restoration of the CAT GE signal alone restored a significant level (approximately 10 to 12% of the wild-type level) of synthesis of both subgenomic mRNAs. This analysis identified a component of sequential transcription that was independent of the promoter-proximal GS signal and appeared to involve readthrough from the leader region.

Constitutive phosphorylation of the vesicular stomatitis virus P protein modulates polymerase complex formation but is not essential for transcription or replication

As a subunit of both the P-L polymerase complex and the P-N assembly complex, the vesicular stomatitis virus (VSV) P protein plays a pivotal role in transcription and replication of the viral genome. Constitutive phosphorylation of this protein is currently thought to be essential for formation of the P-L complex. We recently identified the three relevant phosphate acceptor sites in the VSV Indiana serotype P protein (R. L. Jackson, D. Spadafora, and J. Perrault, Virology 214:189-197, 1995). We now report the effects of substituting Ala at these acceptor sites on transcription reconstitution in vitro and replication of defective interfering virus (DI) templates in vivo. The singly substituted S60A, T62A, and S64A mutants and the doubly substituted S60A/T62A and T62A/S64A mutants, all of which retain some constitutive phosphorylation, were nearly as active as the wild type in both assays. Surprisingly, the nonphosphorylated S60A/S64A protein was also active in transcription (> or = 28%)) and replication (> or = 50%) under optimal conditions. However, this mutant was much less active in in vitro transcription (< or = 5% of wild type) at low P concentrations (<27 nM). In addition, S60A/S64A required higher concentrations of L protein than did the wild type for optimal DI replication in vivo. DI replication efficiency and intracellular accumulation of L, P, and N proteins in the transfected system were very similar to those in VSV-infected cells. We conclude that P protein constitutive phosphorylation is not essential for VSV RNA synthesis per se but likely plays an important role in vivo in facilitating P multimerization and possibly P-L complex formation.

Transcription elongation factor of respiratory syncytial virus, a nonsegmented negative-strand RNA virus

RNA synthesis by the paramyxovirus respiratory syncytial virus, a ubiquitous human pathogen, was found to be more complex than previously appreciated for the nonsegmented negative-strand RNA viruses. Intracellular RNA replication of a plasmid-encoded "minigenome" analog of viral genomic RNA was directed by coexpression of the N, P, and L proteins. But, under these conditions, the greater part of mRNA synthesis terminated prematurely. This difference in processivity between the replicase and the transcriptase was unanticipated because the two enzymes ostensively shared the same protein subunits and template. Coexpression of the M2 gene at a low level of input plasmid resulted in the efficient production of full-length mRNA and, in the case of a dicistronic minigenome, sequential transcription. At a higher level, coexpression of the M2 gene inhibited transcription and RNA replication. The M2 mRNA contains two overlapping translational open reading frames (ORFs), which were segregated for further analysis. Expression of the upstream ORF1, which encoded the previously described 22-kDa M2 protein, was associated with transcription elongation. A model involving this protein in the balance between transcription and replication is proposed. ORF2, which lacks an assigned protein, was associated with inhibition of RNA synthesis. We propose that this activity renders nucleocapsids synthetically quiescent prior to incorporation into virions.

Nucleoprotein phosphorylated on both serine and threonine is preferentially assembled into the nucleocapsids of measles virus

The nucleoprotein (N) in the nucleocapsids of measles virus (MV) has different conformation and antigenicity than the free N-protein in MV-infected cells. These two forms of N-protein have identical methionine-containing tryptic peptides. The free N-protein contains 4 phosphorylated tryptic peptides. However, the nucleocapsid-associated N-protein has an additional phosphorylated peptide not found in the free N-protein. The free N-protein is phosphorylated only on serine residues, whereas the nucleocapsid-associated N-protein is phosphorylated on both serine and threonine residues. The MV N-protein expressed from a cloned gene in primate cells is also phosphorylated on both serine and threonine residues. These results suggest that cellular kinases phosphorylate the MV N-protein, and N-protein with phosphorylated serine and threonine is preferentially assembled into the viral nucleocapsids.

The hypervariable C-terminal tail of the Sendai paramyxovirus nucleocapsid protein is required for template function but not for RNA encapsidation

The paramyxovirus nucleocapsid proteins (NPs) are relatively well conserved, except for the C-terminal 20% (or ca. 100 amino acids), referred to as the tail. We have examined whether this hypervariable tail is required for genome synthesis, both in vitro, where synthesis is predominantly from the input templates, and in vivo, where multiple rounds of amplification occur. In these viruses, genome synthesis and assembly of the nascent chain are coupled. We find that the tail is required in vivo but not in vitro. Closer examination of the in vivo system showed that the tailless NP could encapsidate the genome chain but that amplification did not occur. We interpret these results as indicating that the tail is not required for RNA assembly but is required for the template to function in RNA synthesis. Relatively small deletions within the conserved N-terminal 80% of the protein, on the other hand, rendered the protein nonfunctional in either system. The possible functions of the tail in RNA synthesis are discussed.

Stepwise phosphorylation of vesicular stomatitis virus P protein by virion-associated kinases and uncoupling of second step from in vitro transcription

Transcription-competent cores of vesicular stomatitis virus (VSV) contain two tightly bound protein kinase activities capable of phosphorylating the viral P protein (Beckes and Perrault, Virology 184, 383-386, 1991). We examined here the specificity of these kinases for the P protein substrate and their activity during the in vitro transcription process. Conditions favoring the VSVK1 kinase activity resulted in phosphorylation of the P1 species predominantly whereas conditions favoring VSVK2, or transcription conditions, led to an increase in the proportion of the faster migrating P2 and P3 species. A minimum of 2 mol phosphate/mol P protein was incorporated in 1 hr under optimal transcription conditions. Pulse-chase experiments revealed that the VSVK2 activity converted phosphorylated P1 to P2/P3 species. Most or all of the sites modified by VSVK1 (serines only) mapped to the 78 amino acid-long N-terminal fragment of the P protein; additional serine acceptor sites of undetermined location were also phosphorylated under VSVK2 conditions. Pretreatment of virion cores with 5'-p-fluorosulfonylbenzoyl adenosine had little or no effect on P1 phosphorylation but inhibited P1 to P2/P3 conversion nearly completely, with no effect on subsequent transcription. Likewise, the addition of cell extracts had relatively little effect on P1 phosphorylation but strongly inhibited the appearance of P2/P3, without affecting concurrent transcription. We conclude that phosphorylation of the P protein during transcription in vitro is a two-step process carried out by two distinct kinase activities, but only the first step may be essential for viral mRNA synthesis.

Nucleotide sequences of the 3' leader and 5' trailer regions of human respiratory syncytial virus genomic RNA

The nucleotide sequences of the 3' extracistronic (leader) and 5' extracistronic (trailer) regions were determined for genomic RNA (vRNA) of human respiratory syncytial virus (RSV) strain A2. To sequence the 3' leader region, vRNA was extracted from purified virions, size-selected, polyadenylated, copied into cDNA, amplified by the polymerase chain reaction, cloned, and sequenced. The 3' leader sequence is 44 nt, which is somewhat shorter than its counterparts (50 to 70 nt) in other nonsegmented negative-strand viruses sequenced to date. The 5' trailer region was mapped and sequenced in part directly by dideoxynucleotide sequencing of vRNA. The sequence was confirmed and completed by analysis of cDNA clones derived from vRNA. The 5' trailer sequence is 155 nt in length, which is substantially longer than its counterparts (40 to 70 nt) in other nonsegmented negative-strand viruses. Ten of the 11 terminal nt of the 3' leader and 5' trailer regions were complementary. Among the other paramyxoviruses, the terminal 5 to 16 nt of the leader and trailer regions are highly conserved, but the corresponding RSV sequences were identical to the others only for the terminal 2 nt of each end. Surprisingly, the termini of the RSV leader and trailer regions were in somewhat better agreement with those of the rhabdoviruses vesicular stomatitis virus and rabies virus, sharing identity for the first 3 or 4 nt.

Two distinct protein kinase activities in vesicular stomatitis virions phosphorylate the NS transcription factor

Two vesicular stomatitis virion proteins, NS and M, are phosphorylated in vivo before packaging and in vitro during the transcription process carried out with disrupted virions. Phosphorylation of NS is thought to be essential for transcription but which of the many acceptor sites is or are involved in this function and which protein kinase(s) is responsible still need to be resolved. We recently reported that the virion-associated kinase which modifies M protein is most likely a different enzyme than that phosphorylating NS (Beckes et al., Virology 169, 161-171 1989). Here we present additional evidence for the presence of distinct enzymes modifying M vs NS substrates and also show that at least two distinct kinase activities modify NS protein. Each of the three activities displayed different optimum reaction conditions, phosphate donor preferences, and sensitivity to inhibition by N-ethylmaleimide.

Rescue of a Sendai virus DI genome by other parainfluenza viruses: implications for genome replication

Using a defective interfering Sendai virus stock (DIH4) freed of nondefective helper virus, we found that the closely related parainfluenza viruses 1 and 3 could substitute for the Sendai virus helper in replicating DIH4, creating chimeric nucleocapsids. The morbillivirus measles and the rhabdovirus VSV could not substitute. When DIH4 is incubated intracellularly for 5 days in the absence of help, the ability of PIV3 to rescue DIH4 at this time depended on fresh Sendai virus polymerase. The PIV3 polymerase apparently can only copy the chimeric template, but not that wrapped in the homologous Sendai NP protein. These results suggest that the cis-acting RNA sequences important for genome replication, e.g., the promoter and the encapsidation site, have been conserved among these viruses, but that the interactions between the polymerase and the template protein NP are unique for each virus.

Gene expression of nonsegmented negative strand RNA viruses

Nonsegmented negative strand RNA viruses comprise major human and animal pathogens in nature. This class of viruses is ubiquitous and infects vertebrates, invertebrates, and plants. Our laboratory has been working on the gene expression of two prototype nonsegmented negative strand RNA viruses, vesicular stomatitis virus (a rhabdovirus) and human parainfluenza virus 3 (a paramyxovirus). An RNA-dependent RNA polymerase (L and P protein) is packaged within the virion which faithfully copies the genome RNA in vitro and in vivo; this enzyme complex, in association with the nucleocapsid protein (N), is also involved in the replication process. In this review, we have presented up-to-date information of the structure and function of the RNA polymerases of these two viruses, the mechanisms of transcription and replication, and the role of host proteins in the life-cycle of the viruses. These detailed studies have led us to a better understanding of the roles of viral and cellular proteins in the viral gene expression.

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.

Redistributive properties of the vesicular stomatitis virus polymerase

The template for transcription of the vesicular stomatitis virus (VSV) genome consists of a negative-strand RNA (approximately 11 kb) tightly associated with approximately 1250 copies of the nucleocapsid or N protein (N-RNA template). The interaction between the virion-associated polymerase and this template was probed with a novel assay using purified N-RNA complexes added to detergent-disrupted uv-irradiated standard virions or unirradiated defective interfering (DI) particles. In contrast to the well-known stability of assembled cellular transcription complexes, the VSV polymerase copied exogenously added templates efficiently and yielded products indistinguishable from control virus transcription. Addition of uv-irradiated N-RNA templates to unirradiated virus effectively competed for transcription of endogenous template indicating that most or all of the polymerase can freely redistribute. Furthermore preincubation of virus and added templates at high ionic strength to solubilize L and NS polymerase proteins did not release additional active enzyme for redistribution. Pretranscription of virus also had little or no effect on redistributed activity indicating that polymerase complexes are capable of multiple rounds of synthesis beginning at the 3' end promoter. Unexpectedly, titration with saturating amounts of added N-RNA showed that active polymerase complexes are only in slight excess relative to template in standard or DI particles despite the large surplus of packaged L and NS polypeptides. Moreover, added standard virus templates competed equally well for the redistributing polymerase from DI particles or standard virus indicating no significant polymerase-binding preference for interfering templates. These findings bear important implications regarding mechanisms of VSV transcription and replication.

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.

Modified model for the switch from Sendai virus transcription to replication

RNase mapping was used to estimate the levels of unencapsidated Sendai virus plus-strand RNAs which cross the leader-NP junction relative to NP mRNA. Significant amounts of leader readthrough RNAs were found in Z strain-infected cells, similar to that described for the polR mutant of vesicular stomatitis virus, even though this strain is considered wild type. The levels of the readthrough RNAs detected fell sharply when progressively longer probes were used, unlike that of NP mRNA. These studies suggest that polymerases which read through the first junction terminate shortly afterwards in the absence of concurrent assembly of the nascent chain, whereas those which reinitiate at NP continue efficiently to the next junction. Reinitiation appears to be necessary to convert the polymerase to a mode in which elongation is independent of concurrent assembly. Concurrent assembly appears to be required not only for the polymerase to read through the junction efficiently, but also for it to continue elongation between junctions.

Phosphorylation of vesicular stomatitis virus M protein: evidence for a second virion-associated protein serine kinase activity

The vesicular stomatitis virus (VSV) NS and M proteins are not only phosphorylated in vivo but are also further modified by the virion-associated protein kinase(s) concomitantly with the in vitro transcription process. Although NS phosphorylation is necessary for this transcription, no function has yet been ascribed for M protein phosphorylation. We show here that all phosphates added to M protein in vitro mapped to the trypsin-sensitive N-terminal basic domain (residues 1-43). The major site(s) (approximately 93%) corresponded to one or more of three serine residues within the first 17 amino acids. Nearly 1 mol phosphate/mol protein was added in vitro under optimal conditions suggesting that only one of these three candidate serine residues corresponds to the major site. This same M protein domain is thought to play an important role in virus RNA synthesis by inhibiting transcription. We show here that in vitro phosphorylation did not appear to affect this function. Two critical serine residues in the VSV NS protein were previously reported to be phosphorylated during in vitro transcription (D. Chattopadhyay and A. K. Banerjee, 1987, Cell 49, 407-414). The sequence flanking these NS serines is very acidic while that of all three candidate phosphoserines in the M protein is very basic. We therefore predict that at least two distinct serine-specific kinase activities are packaged in virions, one specific for M and one specific for NS.

Altered ATP utilization by the poIR mutants of vesicular stomatitis virus maps to the N-RNA template

In a continuation of previous efforts to study the modified ATP requirements for RNA synthesis by poIR mutants of vesicular stomatitis virus (VSV), we have used a novel reconstitution assay to show that it is the template moiety of the mutants, not the polymerase proteins, which governs both the increased utilization of the ATP analog, beta, gamma-imido ATP (AMP-PMP), and the loss of a positive cooperativity-like response to varying ATP concentrations. Assays utilized uv-irradiated virus as a source of polymerase proteins and purified N-RNA as templates. Homologous and heterologous transcriptase reactions were carried out with wild-type (wt) virus and each of the two independently isolated poIR mutants. We show that in the presence of wt N-RNA template, substitution of AMP-PNP for ATP resulted in only approximately 5% of control RNA synthesis regardless of which source of polymerase was used. Furthermore, all reactions containing wt N-RNA template responded to varying ATP concentrations with a concave, upward-shaped Lineweaver-Burke plot generally indicative of positive cooperativity effects. In contrast, all reactions which utilized N-RNA templates from the poIR mutants showed an increased utilization of AMP-PNP (greater than 20%) and a more characteristic Michaelis-Menten response to changing ATP concentrations. These findings strongly support the notion that the template-associated nucleocapsid protein modulates the utilization of an ATP site which is directly or indirectly involved in VSV RNA synthesis.

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.

Differential effect of ATP concentration on synthesis of vesicular stomatitis virus leader RNAs and mRNAs

Cleavage of the beta-gamma bond of ATP is required for wild-type (wt) vesicular stomatitis virus transcription in vitro. Recent findings have established that a domain-specific phosphorylation of the virus NS protein is necessary for activity. We report here that RNA synthesis catalyzed by purified standard wt virions responded cooperatively to various ATP concentrations, with half-maximal activity at approximately 500 microM. In contrast, mutant polR1 standard virions and wt defective interfering particles both showed conventional Michaelis-Menten kinetic profiles with Km values of approximately 143 and approximately 133 microM, respectively. The former synthesize readthrough products of the leader-N gene junction in addition to plus-strand leader RNA and mRNAs, whereas the latter synthesize only minus-strand leader RNA. The cooperative response of wt virus products, however, was specific to mRNAs; the small fraction of the total products corresponding to plus-strand leader approximated Michaelis-Menten behavior. Since the unique phenotype of the polR mutants correlates with the synthesis of replicationlike products in vitro, the affected ATP-requiring function most likely regulates both transcription and replication. We suggest that this mutated function involves phosphorylation of viral proteins.

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.

Continuing coevolution of virus and defective interfering particles and of viral genome sequences during undiluted passages: virus mutants exhibiting nearly complete resistance to formerly dominant defective interfering particles

We quantitatively analyzed the interference interactions between defective interfering (DI) particles and mutants of cloned vesicular stomatitis virus passaged undiluted hundreds of times in BHK-21 cells. DI particles which predominated at different times in these serial passages always interfered most strongly (and very efficiently) with virus isolated a number of passages before the isolation of the DI particles. Virus isolated at the same passage level as the predominant DI particles usually exhibited severalfold resistance to these DI particles. Virus mutants (Sdi- mutants) isolated during subsequent passages always showed increasing resistance to these DI particles, followed by decreasing resistance as new DI particles arose to predominate and exert their own selective pressures on the virus mutant population. It appears that such coevolution of virus and DI particle populations proceeds indefinitely through multiple cycles of selection of virus mutants resistant to a certain DI particle (or DI particle class), followed by mutants resistant to a newly predominant DI particle, etc. At the peak of resistance, virus mutants were isolated which were essentially completely resistant to a particular DI particle; i.e., they were several hundred thousand-fold resistant, and they formed plaques of normal size and numbers in the presence of extremely high multiplicities of the DI particle. However, they were sensitive to interference by other DI particles. Recurring population interactions of this kind can promote rapid virus evolution. Complete sequencing of the N (nucleocapsid) and NS (polymerase associated) genes of numerous Sdi- mutants collected at passage intervals showed very few changes in the NS protein, but the N gene gradually accumulated a series of stable nucleotide and amino acid substitutions, some of which correlated with extensive changes in the Sdi- phenotype. Likewise, the 5' termini (and their complementary plus-strand 3' termini) continued to accumulate extensive base substitutions which were strikingly confined to the first 47 nucleotides. We also observed addition and deletion mutations in noncoding regions of the viral genome at a level suggesting that they probably occur at a high frequency throughout the genome, but usually with lethal or debilitating consequences when they occur in coding regions.

RNA virus genomes hybridize to cellular rRNAs and to each other

In this communication we show that the RNA genomes of vesicular stomatitis, Sindbis, and reoviruses can specifically hybridize under stringent conditions to the large rRNAs present in HeLa cell cytoplasmic extracts. In addition, we show that some virus genome RNAs can also hybridize to each other. On the basis of our previous detailed studies identifying specific regions of hybridization between the poliovirus genome and 28S rRNA, we suggest that a similar phenomenon of "patchy complementary" may be responsible for the interactions described here (M. A. McClure and J. Perrault, Nucleic Acids Res. 13:6797-6816, 1985). The possible biological implications of these cross-reacting hybridizations and practical considerations in the use of viral probes for diagnosis are discussed.

Poliovirus genome RNA hybridizes specifically to higher eukaryotic rRNAs

The RNA genome of poliovirus hybridizes to 28S and 18S rRNAs of higher eukaryotes under stringent conditions. The hybridization detected by Northern blot analyses is specific since little or no signal was detected for yeast or prokaryotic rRNAs or other major cellular RNAs. Southern blot analysis of DNA clones of mouse rRNA genes leads us to conclude that several regions of 28S rRNA, and at least one region in 18S rRNA, are involved in the hybridization to polio RNA, and that G/C regions are not responsible for this phenomenon. We have precisely mapped one of these hybridizing regions in both molecules. Computer analysis confirms that extensive intermolecular base-pairing (81 out of 104 contiguous bases in the rRNA strand) could be responsible for this one particular site of interaction (polio genome, bases 5075-5250; 28S rRNA, bases 1097-1200). We discuss the possible functional and/or evolutionary significance of this novel type of interaction.

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.