Homotypic and heterotypic exclusion of vesicular stomatitis virus replication by high levels of recombinant polymerase protein L

Limited interference at the early stage of infection between two recombinant novirhabdoviruses: viral hemorrhagic septicemia virus and infectious hematopoietic necrosis virus

The genome sequence of a hypervirulent novirhabdovirus, viral hemorrhagic septicemia virus (VHSV) French strain 23-75, was determined. Compared to the genome of the prototype Fil3 strain, a number of substitutions, deletions, and insertions were observed. Following the establishment of a plasmid-based minigenome replication assay, recombinant VHSV (rVHSV) was successfully recovered. rVHSV exhibits wild-type-like growth properties in vitro as well as in vivo in rainbow trout. The dispensable role of NV for the novirhabdovirus replication was confirmed by generating rVHSV-DeltaNV, in which the NV gene was deleted. This deletion mutant was shown to be as debilitated as that previously described for infectious hematopoietic necrosis virus (IHNV), a distantly related novirhabdovirus (S. Biacchesi, M. I. Thoulouze, M. Bearzotti, Y. X. Yu, and M. Bremont, J. Virol. 74:11247-11253, 2000). Recombinant VHSV and IHNV expressing tdTomato and GFP(max) reporter genes, respectively, were generated, demonstrating the potential of these rhabdoviruses to serve as viral vectors. Interestingly, rIHNV-GFP(max) could be recovered using the replicative complex proteins of either virus, whereas rVHSV-Tomato could be recovered only by using its own replicative complex, reflecting that the genome signal sequences of VHSV are relatively distant from those of IHNV and do not allow their cross-recognition. Moreover, the use of heterologous protein combinations underlined the importance of strong protein-protein interactions for the formation of a functional ribonucleoprotein complex. The rIHNV-GFP(max) and rVHSV-Tomato viruses were used to simultaneously coinfect cell monolayers. It was observed that up to 74% of the cell monolayer was coinfected by both viruses, demonstrating that a limited interference phenomenon exists during the early stage of primary infection, and it was not mediated by a cellular antiviral protein or by some of the viral proteins.

Inhibition of translation by a short element in the 5' leader of the herpes simplex virus 1 DNA polymerase transcript

Many viruses regulate gene expression, both globally and specifically, to achieve maximal rates of replication. During herpes simplex virus 1 infection, translation of the DNA polymerase (Pol) catalytic subunit is inefficient relative to other proteins of the same temporal class (D. R. Yager, A. I. Marcy, and D. M. Coen., J. Virol. 64:2217-2225, 1990). To investigate the mechanisms involved in the inefficient translation of Pol and to determine whether this inefficient translation could affect viral replication, we performed a mutagenic analysis of the 5' end of the pol transcript. We found that a short sequence ( approximately 55 bases) in the 5' leader of the transcript is both necessary and sufficient to inhibit translation in rabbit reticulocyte lysates and sufficient to inhibit reporter gene translation in transfected cells. RNase structure mapping experiments indicated that the inhibitory element adopts a structure that contains regions of a double-stranded nature, which may interfere with ribosomal loading and/or scanning. Pol accumulated to approximately 2- to 3-fold-higher levels per mRNA in cells infected with a mutant virus containing a deletion of the approximately 55-base inhibitory element than in cells infected with a control virus containing this element. Additionally, the mutant virus replicated less efficiently than the control virus. These results suggest that the inhibitory element regulates Pol translation during infection and that its inhibition of Pol translation is beneficial for viral replication.

Variations in transcription termination signals of human respiratory syncytial virus clinical isolates affect gene expression

Human respiratory syncytial virus (HRSV) has a single-stranded, negative-sense RNA genome with 10 genes encoding 11 proteins. Sequences at the beginning of the HRSV genes are highly conserved; however, the gene end sequences vary around a semiconserved consensus sequence, and the nontranscribed intergenic regions vary in both length and sequence. The regions at the junctions between HRSV genes (the gene end sequence of an upstream gene, intergenic region, and the gene start sequence of a downstream gene) contain elements required for efficient termination of the upstream gene and transcription of the downstream gene. Previous studies have examined variation in the HRSV coding sequences, but none have systematically analyzed the noncoding transcriptional control regions for variability. We determined the gene start and gene end sequences of each of the 10 HRSV genes from 14 clinical isolates for variations from the sequence of the prototype A2 strain. No changes were found in any of the gene start sequences. Eight of the 10 gene end sequences, however, contained variations. Several of these, a U(4)-tract instead of a U(6)- or U(5)-tract at the M and SH gene ends, respectively, (U(4)A) and an A-to-G change at position four in the G gene end (A4G), were predicted to affect termination and were examined for their effects on transcription. The changes were found to inhibit transcriptional termination, resulting in increased polycistronic readthrough and correspondingly reduced initiation of the downstream monocistronic mRNA. Viruses with the A4G variant G gene end sequence produced less F protein than those with A2-like G gene end sequences. Examination of additional G gene end sequences available in GenBank revealed that the observed A4G variation was restricted to one phylogenetic lineage of HRSV. All viruses examined within this lineage possessed this variant G gene end sequence. The data presented show that the gene end sequences of naturally occurring HRSV clinical isolates vary from those of the prototypic A2 strain and that certain of these changes inhibit efficient transcriptional termination and downstream gene expression.

Selective virus resistance conferred by expression of Borna disease virus nucleocapsid components

Persistent viral infections can render host cells resistant to superinfection with closely related viruses by largely uncharacterized mechanisms. We present evidence for superinfection exclusion in brains of Borna disease virus (BDV)-infected rats and in persistently infected Vero cells, and we suggest that acquired resistance to BDV is due to unbalanced intracellular levels of viral nucleocapsid components. We observed that expression of BDV protein P, N, or X rendered human cells resistant to subsequent challenge with BDV but not with other RNA viruses, indicating that incorrect stoichiometry of nucleocapsid components selectively blocked the polymerase activity of incoming viruses. Vero cells containing high levels of an untranslatable BDV-N transcript remained virus susceptible, demonstrating that viral protein rather than RNA mediated resistance. Transient overexpression of BDV-P in persistently infected Vero cells was also remarkably effective against BDV, indicating that the intracellular balance of viral nucleocapsid components could serve as a target for future therapeutic antiviral strategies.

Increased readthrough transcription across the simian virus 5 M-F gene junction leads to growth defects and a global inhibition of viral mRNA synthesis

Recombinant simian virus 5 (rSV5) mutants containing substitutions in the M-F intergenic region were generated to determine the effect of increased readthrough transcription on the paramyxovirus growth cycle. We have previously shown, using an SV5 dicistronic minigenome, that replacement of the 22-base M-F intergenic region with a foreign sequence results in a template (Rep22) that directs very high levels of M-F readthrough transcription. An rSV5 containing the Rep22 substitution grew slower and to final titers that were 50- to 80-fold lower than those of wild-type (WT) rSV5. Cells infected with the Rep22 virus produced very low levels of monocistronic M and F mRNA, consistent with the M-F readthrough phenotype. Surprisingly, Rep22 virus-infected cells also displayed a global decrease in the accumulation of viral mRNA from genes located upstream and downstream of the M-F junction, and overall viral protein synthesis was reduced. Second-site revertants of the Rep22 virus that had regained WT transcription and growth properties contained a single base substitution that increased the M gene end U tract from four to eight residues, suggesting that the growth defects originated from higher-than-normal M-F readthrough transcription. Thus, the primary growth defect for the Rep22 virus appears to be in viral RNA synthesis and not in morphogenesis. A second rSV5 virus (G14), which contained a different foreign M-F intergenic sequence, grew to similar or slightly higher titers than WT rSV5 in some cell types and produced ~1.5- to 2-fold more mRNA and viral protein. The data support the hypothesis that inhibition of Rep22 virus growth is due to increased access by the polymerase to the 5' end of the genome and to the resulting overexpression of L protein. We propose that the elevated naturally occurring M-F readthrough which is characteristic of many paramyxoviruses serves as a mechanism to fine-tune the level of polymerase that is optimal for virus growth.

Phenotypic consequences of rearranging the P, M, and G genes of vesicular stomatitis virus

The nonsegmented negative-strand RNA viruses (order Mononegavirales) include many important human pathogens. The order of their genes, which is highly conserved, is the major determinant of the relative levels of gene expression, since genes that are close to the single promoter site at the 3' end of the viral genome are transcribed at higher levels than those that occupy more distal positions. We manipulated an infectious cDNA clone of the prototypic vesicular stomatitis virus (VSV) to rearrange three of the five viral genes, using an approach which left the viral nucleotide sequence otherwise unaltered. The central three genes in the gene order, which encode the phosphoprotein P, the matrix protein M, and the glycoprotein G, were rearranged into all six possible orders. Viable viruses were recovered from each of the rearranged cDNAs. The recovered viruses were examined for their levels of gene expression, growth potential in cell culture, and virulence in mice. Gene rearrangement changed the expression levels of the encoded proteins in concordance with their distance from the 3' promoter. Some of the viruses with rearranged genomes replicated as well or slightly better than wild-type virus in cultured cells, while others showed decreased replication. All of the viruses were lethal for mice, although the time to symptoms and death following inoculation varied. These data show that despite the highly conserved gene order of the Mononegavirales, gene rearrangement is not lethal or necessarily even detrimental to the virus. These findings suggest that the conservation of the gene order observed among the Mononegavirales may result from immobilization of the ancestral gene order due to the lack of a mechanism for homologous recombination in this group of viruses. As a consequence, gene rearrangement should be irreversible and provide an approach for constructing viruses with novel phenotypes.

Interference by a non-defective variant of influenza A virus is due to enhanced RNA synthesis and assembly

Mouse-adapted influenza A virus, FM-MA, interferes with the replication of wild-type strains on co-infection. The interference phenotype was previously mapped to FM-MA segment 2 encoding a mutant PB1 protein, the catalytic component of the RNA polymerase complex. To identify the point at which FM-MA interferes with wild-type A/HK/1/68 (HK), the relative levels of transcription and genome replication of the PB1, NP and M1 genes were determined for FM-MA and HK viruses in co-infected cells using RT-PCR. All stages of HK macromolecular synthesis (primary and secondary transcription, genomic RNA, complementary RNA and protein synthesis) were suppressed relative to FM-MA. Infection with HK virus alone resulted in the accumulation of similar or greater amounts of RNA at late times post-infection relative to FM-MA thus indicating that the presence of FM-MA specifically compromised HK transcription and replication in co-infected cells. However early in infection FM-MA was ten times more active in mRNA transcription than HK or its parental strain FM. FM-MA's ability to interfere was primarily due to an increased capacity for primary transcription. FM-MA genomes were also selectively assembled into progeny virus from cells co-infected with HK and FM-MA, a step which was distinct from the capacity for enhanced RNA synthesis. This suggests that interference of HK growth by FM-MA in mixed infections results from two distinct events: a preferential synthesis of FM-MA-specific macromolecules which is then augmented by a preferential assembly of FM-MA genomes.

Molecular basis for naturally occurring elevated readthrough transcription across the M-F junction of the paramyxovirus SV5

Transcription of the paramyxovirus RNA genome is thought to involve a sequential stop-start mechanism whereby monocistronic mRNAs are produced by polyadenylation and termination of 3' upstream gene followed by reinitiation at the downstream start site. For a number of paramyxoviruses, transcription across the M-F gene junction results in the synthesis of high levels of a dicistronic M-F readthrough RNA. In cells infected with the paramyxovirus SV5, 15% or less of the transcripts from the viral P, M, SH, HN, and L genes were detected as readthrough products with the 3' proximal gene. By contrast, approximately 40% of the SV5 F mRNA was detected as a dicistronic M-F transcript. A comparison of the individual SV5 gene junctions showed that elevated M-F readthrough transcription correlate with the M gene end having the shortest U tract for directing polyadenylation and a gene end sequence that differs from the consensus sequence. We have tested the hypothesis that elevated M-F readthrough transcription results from an inefficient termination signal at the end of the M gene. A reverse genetics system was established whereby SV5 transcription was reconstituted in transfected cells using cDNA-derived polymerase components and dicistronic minigenomes that encoded either the SV5 M-F or the SH-HN gene junction. Chimeric SV5 minigenomes were constructed to contain exchanges of a 10 base gene end sequence and the U tract from the M-F (approximately 40% readthrough) and SH-HN (approximately 15% readthrough) junctions. Northern blot analysis of RNA synthesized from these altered templates showed that, in the context of the M-F intergenic region, increasing the length of the M gene end U tract from four residues to six or eight U residues did not decrease M-F readthrough transcription. In contrast, chimeric minigenomes that contained the 10 base region from the end of the SH gene directed very efficient gene termination and a corresponding decrease in readthrough transcription. Mutational analysis showed that a single G to A substitution located five bases 3' to the M gene U tract was sufficient to convert the M gene end region to an efficient signal for polyadenylation-termination. These results demonstrate a role for the gene end region located immediately 3' to the U tract as a major determinant of transcription termination in the paramyxovirus genome. The possible role of M-F readthrough transcription in the paramyxovirus growth cycle is discussed.

Gene rearrangement attenuates expression and lethality of a nonsegmented negative strand RNA virus

The nonsegmented negative strand RNA viruses comprise hundreds of human, animal, insect, and plant pathogens. Gene expression of these viruses is controlled by the highly conserved order of genes relative to the single transcriptional promoter. We utilized this regulatory mechanism to alter gene expression levels of vesicular stomatitis virus by rearranging the gene order. This report documents that gene expression levels and the viral phenotype can be manipulated in a predictable manner. Translocation of the promoter-proximal nucleocapsid protein gene N, whose product is required stoichiometrically for genome replication, to successive positions down the genome reduced N mRNA and protein expression in a stepwise manner. The reduction in N gene expression resulted in a stepwise decrease in genomic RNA replication. Translocation of the N gene also attenuated the viruses to increasing extents for replication in cultured cells and for lethality in mice, without compromising their ability to elicit protective immunity. Because monopartite negative strand RNA viruses have not been reported to undergo homologous recombination, gene rearrangement should be irreversible and may provide a rational strategy for developing stably attenuated live vaccines against this type of virus.

Elimination of L-A double-stranded RNA virus of Saccharomyces cerevisiae by expression of gag and gag-pol from an L-A cDNA clone

We report that expression of a nearly full-length cDNA clone of the L-A double-stranded RNA virus causes virus loss in a wild-type strain of Saccharomyces cerevisiae. We show that in this system exclusion of the L-A virus is independent of the presence of the packaging site or of cis sites for replication and transcription and completely dependent on expression of functional recombinant gag and gag-pol fusion protein. Thus, this exclusion is not explained in terms of overexpression of packaging signals. Mutation of the chromosomal SKI2 gene, known to repress the copy number of double-stranded RNA cytoplasmic replicons of S. cerevisiae, nearly eliminates the exclusion. We suggest that exclusion is due to competition by proteins expressed from the plasmid for a possibly limiting cellular factor. Our hypotheses on exclusion of L-A proteins may also apply to resistance to plant viruses produced by expression of viral replicases in transgenic plants.

The Sendai virus nonstructural C proteins specifically inhibit viral mRNA synthesis

An in vitro transcription system for paramyxoviruses is described, in which polymerase-free templates are combined with cell extracts containing polymerase made in vivo via transfected plasmids. Both P and L are required for polymerase activity, and both must be coexpressed for optimum activity. mRNA synthesis here was found to be inversely proportional to the level of C expression, whereas defective interfering genome replication was largely unaffected by the level of C in the extract. The inhibition of transcription appeared to be due to the C' and C, but not the Y1 and Y2 proteins, and only occurred when C'/C was coexpressed with P and L. C'/C appears to intervene during polymerase formation, possibly by forming polymerase complexes which are inactive for transcription, but still competent for genome replication.

Complexes of Sendai virus NP-P and P-L proteins are required for defective interfering particle genome replication in vitro

We present evidence that the formation of NP-P and P-L protein complexes is essential for replication of the genome of Sendai defective interfering (DI-H) virus in vitro, using extracts of cells expressing these viral proteins from plasmids. Optimal replication of DI-H nucleocapsid RNA required extracts of cells transfected with critical amounts and ratios of each of the plasmids and was three- to fivefold better than replication with a control extract prepared from a natural virus infection. Extracts in which NP and P proteins were coexpressed supported replication of the genome of purified DI-H virus which contained endogenous polymerase proteins, but extracts in which NP and P were expressed separately and then mixed were inactive. Similarly, the P and L proteins must be coexpressed for biological activity. The replication data thus suggest that two protein complexes, NP-P and P-L, are required for nucleocapsid RNA replication and that these complexes must form during or soon after synthesis of the proteins. Biochemical evidence in support of the formation of each complex includes coimmunoprecipitation of both proteins of each complex with an antibody specific for one component and cosedimentation of the subunits of each complex. We propose that the P-L complex serves as the RNA polymerase and NP-P is required for encapsidation of newly synthesized RNA.

Studies on the regulation of influenza virus RNA replication: a differential inhibition of the synthesis of vRNA segments in shift-up experiments with ts mutants

The regulation of influenza virus vRNA synthesis in the course of the reproduction cycle was studied with the use of a series of ts mutants in shift-up experiments. The synthesis of vRNA segments was registered by means of polyacrylamide gel electrophoresis of nucleocapsid-associated RNA isolated from the infected cells labelled with [3H]uridine after the shift-up to a semi-permissive temperature. Each mutant exhibited a specific differential pattern of vRNA synthesis inhibition after the shift-up. The most affected segments were either vRNA 4, vRNAs 4 and 7, or vRNAs 4, 6, and 7 in cells infected, respectively, with ts mutants C15 (ts lesion in PB1 gene), C45 (ts lesion in PA gene) and CmN3 (ts lesion in NS gene). The synthesis of vRNAs 1, 2, and 3 was relatively resistant to the shift-up in the cells infected with C15 or C45 and more sensitive in the cells infected with C44 (ts lesion in PB2 gene) or CmN3. The replication of the "early" genes (vRNAs 5 and 8) was generally least affected by the shift-up. The results are discussed in connection with the "early-late" transition of vRNA synthesis pattern in the course of infection.

Cellular mechanisms in the superinfection exclusion of vesicular stomatitis virus

The superinfection exclusion of VSV has been studied and found to be caused by a combination of three distinct effects on endocytosis by VSV-infected cells: first, a decreased rate of formation of endocytic vesicles as judged by an inhibition of fluid-phase uptake at 2 hr postinfection; second, a decreased rate of internalization of receptor-bound ligands, which was detected at 4 hr postinfection; and third, a competition with newly synthesized virus for occupancy of coated pits, as indicated by electron microscopy of infected cells. At the same time that fluid-phase uptake decreased, numerous uncoated invaginations were observed at the cell surface.

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.

Role of matrix protein in cytopathogenesis of vesicular stomatitis virus

The matrix (M) protein of vesicular stomatitis virus (VSV) plays an important structural role in viral assembly, and it also has a regulatory role in viral transcription. We demonstrate here that the M protein has an additional function. It causes visible cytopathic effects (CPE), as evidenced by the typical rounding of polygonal cells after VSV infection. We have analyzed a temperature-sensitive mutant of the M protein of VSV (tsG33) which is defective in viral assembly and which fails to cause morphological changes of the cells after infection at the nonpermissive temperature (40 degrees C). Interestingly, this defect in viral assembly as well as the CPE were reversible. Microinjection of antisense oligonucleotides which specifically inhibit M protein translation also inhibited the occurrence of CPE. Most importantly, when cells were transfected with a cDNA encoding the temperature-sensitive M protein of tsG33, no CPE was observed at the nonpermissive temperature. However, when these cells were shifted to the permissive temperature (32 degrees C), they rounded up and detached from the dish. These results demonstrate that M protein in the absence of the other viral proteins causes rounding of the cells, probably through a disorganization of the cytoskeleton. The absence of CPE at the nonpermissive temperature is correlated with an abnormal dotted staining pattern of M in these cells, suggesting that the mutant M protein may self-aggregate or associate with membranes rather than interact with cytoskeletal elements.

Rescue of Sendai virus from viral ribonucleoprotein-transfected cells by infection with recombinant vaccinia viruses carrying Sendai virus L and P/C genes

The Sendai virus ribonucleoprotein (RNP) showed only very low plaque-forming titers upon transfection and the virus yields after one-step growth were quite limited. We tried to enhance the Sendai virus yield by supplying the viral L and P/C gene products through vaccinia vectors. A combination of the recombinant vaccinia viruses carrying the L gene (Vac-HL) and the P/C gene (Vac-HPC), both of which were driven by the promoter of the vaccinia virus 7.5K protein gene, enhanced the yield only a little whereas another combination of Vac-HLd7.5, the L gene insert of which was driven by the promoter of the vaccinia virus thymidine kinase gene in place of the 7.5K promoter, and Vac-HPC greatly enhanced the Sendai virus yield. This seemed to correlate with the fact that the Vac-HL interfered with Sendai virus growth markedly while the Vac-HLd7.5 did not. These results strongly suggest that the L and P/C gene products act in cooperation as the RNA polymerase, and overproduction of the L protein is inhibitory for Sendai virus growth. This system seems to be of value as a tool for analyzing the functions of L and P/C genes of Sendai virus.

Vesicular stomatitis virus and its defective interfering particles exhibit in vitro transcriptional and replicative competition for purified L-NS polymerase molecules

We have quantitated replication of the RNA genomes of vesicular stomatitis virus (VSV) and its defective interfering (DI) particles in a BHK21 cell-free system into which nucleocapsids were introduced in varying amounts and ratios, with or without addition of purified virus polymerase components. The quantitative transcriptional and replicative competition observed in vitro between virus and DI genomes resembled DI particle interference observed in vivo in infected cells. The effects of an added polymerase protein (L-NS) complex from purified virions showed that this competition varies with polymerase availability. When DI nucleocapsids were added in small amounts, addition of L-NS polymerase protein complex stimulated a linear increase in viral mRNA transcription until the viral templates' transcription capacity became saturated; then there was a reproducible sudden switch toward RNA replication (mainly of DI genomes). Purified L or NS proteins added separately produced different effects than the L-NS complex. These findings support earlier evidence for replicative competition as the mechanism of DI particle interference with standard virus, and suggest that the major competition is for limiting amounts of L-NS molecules involved in transcription and replication, and in facilitation of encapsidation.

Detection of virus-specific RNA-dependent RNA polymerase activity in extracts from cells infected with lymphocytic choriomeningitis virus: in vitro synthesis of full-length viral RNA species

We have developed an in vitro assay for the lymphocytic choriomeningitis virus (LCMV) RNA-dependent RNA polymerase with ribonucleoprotein complexes extracted from acutely infected tissue culture cells. The RNA products synthesized in vitro corresponded in size to the full-length genomic L and S RNAs and subgenomic NP and GP mRNAs normally produced in vivo during acute LCMV infection. In a temporal analysis spanning the first 72 h of acute infection, the in vitro polymerase activity of ribonucleoprotein complexes was maximal at 16 h and declined significantly at later times. In contrast, the intracellular levels of the viral L protein (the putative polymerase protein) appeared to be maximal at 48 to 72 h postinfection. Our results suggest that the accumulation of L protein correlates with reduced viral replication and transcription at later times in acute infection and may be involved in the transition from acute to persistent LCMV infection.

Altered replicase specificity is responsible for resistance to defective interfering particle interference of an Sdi- mutant of vesicular stomatitis virus

The in vitro resistance of an Sdi- mutant of vesicular stomatitis virus to interference by wild-type defective interfering (DI) particles was expressed quantitatively in a cell-free replication system derived from mutant-infected cells. Added wild-type DI particle templates were replicated very poorly by extracts of Sdi- mutant-infected cells. However, the addition of purified viral polymerase (a complex of L and NS proteins) from wild-type vesicular stomatitis virus allowed efficient replication of wild-type DI particle genomes in these cell extracts. Added wild-type NS protein alone did not complement DI particle genome replication in these cell extracts, but it did complement a defect in the in vitro transcriptional activity of Sdi- mutant virus. These results clearly implicate the vesicular stomatitis virus polymerase complex in the inability of Sdi- mutants to replicate DI particles and in the quantitative escape from DI particle interference in evolving virus populations.

Completion of the rabies virus genome sequence determination: highly conserved domains among the L (polymerase) proteins of unsegmented negative-strand RNA viruses

We have now completed the rabies genome structure by the cloning and the sequencing of the entire L gene and the 5' untranscribed region. The L gene encodes a single open reading frame 2142 amino acids in length (244,206 Da) that corresponds to the viral RNA-dependent RNA polymerase. In contrast with other isofunctional proteins, the rabies polymerase exhibits a high degree of homology with the vesicular stomatitis virus polymerase, and a lesser degree, although significant, with those of Sendai virus and Newcastle disease virus, which suggests a differential evolution of the different cistrons. We have observed several strongly conserved stretches which may designate the independent functional domains of this multifunctional protein. In addition to the conservation of related transcription signals (N. Tordo et al. (1986) Proc. Natl. Acad. Sci. USA 83, 3914-3918.), this highlights the striking selective pressure on elements involved in transcription and replication mechanisms, and provides further evidence for a common ancestry of Rhabdoviridae and Paramyxoviridae families. The terminal complementarity observed in the rabies genome suggests the conservation of important genomic signals.

Analysis of the transcript of the herpes simplex virus DNA polymerase gene provides evidence that polymerase expression is inefficient at the level of translation

We have mapped the termini and determined the relative abundance and ribosome density of the major cytoplasmic transcript of the DNA polymerase (pol) gene of herpes simplex virus type 1. Nuclease protection and primer extension analyses located the 5' end of the major pol transcript at two closely spaced sites 51 and 57 nucleotides to the left of a BamHI site at map position 0.413. S1-sensitive sites corresponding to additional minor transcripts were found to map further upstream within a palindromic sequence that contains a viral replication origin. The major 3' end was found to map 90 nucleotides upstream of a KpnI site at map position 0.439. Quantitative S1 nuclease assays revealed that pol transcripts were nearly as abundant as transcripts encoded by the viral thymidine kinase gene. However, relatively few pol transcripts were found on large polysomes at 5.5 h after infection, when pol transcripts were most abundant. This was in marked contrast to the polyribosome distribution of transcripts from the thymidine kinase gene and the major DNA-binding protein gene. These results and sequence features of the pol transcript suggest that pol expression is regulated, in part, at the level of translation.

Measles virus L protein evidences elements of ancestral RNA polymerase

We have determined the nucleotide sequence of the measles virus (MV) L gene using a cDNA library encompassing the entire MV genome (J. Crowley et al. (1987) Intervirology, 28, 65-77). The L gene is 6639 nucleotides in length, and contains a single long open reading frame that could code for a protein of 247,611 kDa. Both the L gene and in particular the predicted L protein of MV bear substantial homology to their counterparts in Sendai virus and Newcastle disease virus, suggesting that the multifunctional nature of paramyxovirus L proteins imposes strong evolutionary constraints. The predicted MV L protein also contains distinct elements of a postulated ancestral RNA polymerase.