Functional cDNA clones of the human respiratory syncytial (RS) virus N, P, and L proteins support replication of RS virus genomic RNA analogs and define minimal trans-acting requirements for RNA replication

Diverse gene junctions of respiratory syncytial virus modulate the efficiency of transcription termination and respond differently to M2-mediated antitermination

The ability of the diverse gene junctions of respiratory syncytial (RS) virus to signal the termination of transcription was analyzed. Nine dicistronic subgenomic replicons of RS virus were constructed; each contained one of the RS virus gene junctions in its natural upstream and downstream sequence context. The RNA synthesis activities of these subgenomic replicons were analyzed in the absence and presence of the M2 protein, which we showed previously to function as a transcription antiterminator. Our data showed that the efficiency with which the polymerase terminated transcription was affected by the gene junction that it encountered. The M2 protein significantly decreased the efficiency of the termination of transcription, resulting in increased levels of readthrough transcription at all the gene junctions. The diverse gene junctions fell into three broad groups with respect to their ability to signal transcription termination. One group of gene junctions (NS1/NS2, NS2/N, M2/L, and L/trailer) showed inefficient termination in the absence or the presence of the M2 protein. A second group of gene junctions (N/P, P/M, M/SH, SH/G, and G/F) terminated transcription efficiently. The SH/G gene junction terminated transcription with the greatest efficiency and produced low levels of readthrough transcripts in the absence or the presence of the M2 protein, correlating with the absence of SH/G polycistronic transcripts in RS virus-infected cells. The F/M2 gene junction was particularly sensitive to the M2 protein: it efficiently signaled termination in the absence of the M2 protein but produced high levels of readthrough transcripts in the presence of the M2 protein. This result suggests that the M2 protein may regulate its own production by negative feedback. The data presented here show that the different gene junctions of RS virus do modulate RS virus transcription termination. The M2 protein reduced termination at all gene junctions. The magnitude of antitermination due to the M2 protein, however, varied at the different gene junctions. The data presented here indicate that the mechanism for the regulation of RS virus gene expression is more complex than was previously appreciated.

Generation of bovine respiratory syncytial virus (BRSV) from cDNA: BRSV NS2 is not essential for virus replication in tissue culture, and the human RSV leader region acts as a functional BRSV genome promoter

In order to generate recombinant bovine respiratory syncytial virus (BRSV), the genome of BRSV strain A51908, variant ATue51908, was cloned as cDNA. We provide here the sequence of the BRSV genome ends and of the entire L gene. This completes the sequence of the BRSV genome, which comprises a total of 15,140 nucleotides. To establish a vaccinia virus-free recovery system, a BHK-derived cell line stably expressing T7 RNA polymerase was generated (BSR T7/5). Recombinant BRSV was reproducibly recovered from cDNA constructs after T7 RNA polymerase-driven expression of antigenome sense RNA and of BRSV N, P, M2, and L proteins from transfected plasmids. Chimeric viruses in which the BRSV leader region was replaced by the human respiratory syncytial virus (HRSV) leader region replicated in cell culture as efficiently as their nonchimeric counterparts, demonstrating that all cis-acting sequences of the HRSV promoter are faithfully recognized by the BRSV polymerase complex. In addition, we report the successful recovery of a BRSV mutant lacking the complete NS2 gene, which encodes a nonstructural protein of unknown function. The NS2-deficient BRSV replicated autonomously and could be passaged, demonstrating that NS2 is not essential for virus replication in cell culture. However, growth of the mutant was considerably slower than and final infectious titers were reduced by a factor of at least 10 compared to wild-type BRSV, indicating that NS2 provides a supporting factor required for full replication capacity.

Role of cellular actin in the gene expression and morphogenesis of human respiratory syncytial virus

Cytoskeletal protein actin and nonactin cellular proteins were essential for human respiratory syncytial virus (RSV) gene expression. In vitro, specific antibodies against actin inhibited RSV transcription, whereas antibodies against other cytoskeletal proteins had little or no effect. Affinity purified cellular actin or bacterially expressed recombinant actin activated RSV transcription. However, optimal transcription required additional cellular protein(s) that appeared to function as accessory factor(s) for actin. In the absence of actin, these proteins did not activate viral transcription. Purified viral nucleocapsids contained actin, but no cytokeratin, tubulin, or vimentin. Cytochalasin D or DNasel--agents that destabilize actin polymers--had little effect on RSV transcription. RSV infection itself seemed to alter the structure of the cellular actin filaments. Treatment of infected cells with cytochalasin D produced a more severe disruption of the filaments and drastically reduced the production of infectious virus particles but still had little effect on intracellular synthesis of viral macromolecules. Thus actin seems to serve a dual role in RSV life cycle: its monomeric form as well as polymeric form activate viral transcription, while only the microfilament form may take part in viral morphogenesis and/or budding.

Recombinant human respiratory syncytial virus (RSV) from cDNA and construction of subgroup A and B chimeric RSV

Infectious human respiratory syncytial virus (RSV) was produced from a cDNA clone that contains 15,222 nucleotides of RSV genome derived from the A2 strain of subgroup A. Recovery of infectious RSV from cDNA required cotransfection of only three expression plasmids encoding the nucleoprotein (N), the phosphoprotein (P), and the major polymerase protein (L). Inclusion of the M2-1 plasmid was not required in the transfection reaction and if included did not significantly increase the rescue efficiency. However, a single nucleotide substitution in the RSV leader region (C to G at position 4 in the antigenomic sense), greatly increased the amount of infectious virus recovered from cDNA. A recombinant RSVA2 virus that expresses an additional structural G protein derived from a subgroup B RSV was also obtained. Both A2 and B strain G glycoproteins were expressed in cells infected with the chimeric RSV. A chimeric RSV that expresses a heterologous subgroup antigen in a live attenuated vaccine candidate may be important for prevention of diseases associated with both RSV subgroup A and subgroup B infection.

Detection and quantitation of human respiratory syncytial virus (RSV) using minigenome cDNA and a Sindbis virus replicon: a prototype assay for negative-strand RNA viruses

We describe here a novel approach for detecting and quantitating human respiratory syncytial virus (RSV) based on expression of a reporter gene from an RSV minigenome. BHK cells were cytoplasmically transformed with a noncytopathic Sindbis virus replicon expressing T7 RNA polymerase. These cells were then cotransfected with T7 expression plasmids that contain the cDNA of an RSV minigenome and the genes for RSV nucleocapsid proteins N, P, and L. The minigenome contains a reporter gene such as lacZ or CAT flanked by cis-acting RSV transcription signals. Subsequent infection of these cells with RSV resulted in a high level of reporter gene expression which could be inhibited by ribavirin. Mock-infected cells exhibited background levels of expression. This assay can be used to quantitate RSV and titer neutralizing antibody and may be a valuable tool for screening compounds for anti-RSV activity. It serves as a prototype for other negative-strand RNA viruses.

Three of the four nucleocapsid proteins of Marburg virus, NP, VP35, and L, are sufficient to mediate replication and transcription of Marburg virus-specific monocistronic minigenomes

This paper describes the first reconstituted replication system established for a member of the Filoviridae, Marburg virus (MBGV). MBGV minigenomes containing the leader and trailer regions of the MBGV genome and the chloramphenicol acetyltransferase (CAT) gene were constructed. In MBGV-infected cells, these minigenomes were replicated and encapsidated and could be passaged. Unlike most other members of the order Mononegavirales, filoviruses possess four proteins presumed to be components of the nucleocapsid (NP, VP35, VP30, and L). To determine the protein requirements for replication and transcription, a reverse genetic system was established for MBGV based on the vaccinia virus T7 expression system. Northern blot analysis of viral RNA revealed that three nucleocapsid proteins (NP, VP35, and L) were essential and sufficient for transcription as well as replication and encapsidation. These data indicate that VP35, rather than VP30, is the functional homologue of rhabdo- and paramyxovirus P proteins. The reconstituted replication system was profoundly affected by the NP-to-VP35 expression ratio. To investigate whether CAT gene expression was achieved entirely by mRNA or in part by full-length plus-strand minigenomes, a copy-back minireplicon containing the CAT gene but lacking MBGV-specific transcriptional start sites was employed in the artificial replication system. This construct was replicated without accompanying CAT activity. It was concluded that the CAT activity reflected MBGV-specific transcription and not replication.

Rapid and efficient recovery of Sendai virus from cDNA: factors influencing recombinant virus rescue

In a comparative study the factors influencing the recovery of recombinant Sendai viruses (SeV) from plasmid based cDNA were analysed systematically in order to establish an efficient and robust method for virus rescue. The amounts and ratios of transfected helper plasmids encoding the viral N, P and L proteins proved to be crucial for virus rescue, and they were optimised step-by-step for enhanced virus release. When the C open reading frame from the P gene was expressed at low level, virus rescue was generally possible but virus release could be improved when C gene expression was abolished completely. SeV particle formation could be increased greatly when the transcription initiation site for T7 polymerase in the cDNA was modified or when the genomic ribozyme instead of the antigenomic ribozyme of hepatitis delta virus was used for processing the 3'end of the viral RNA transcript. Heterologous helper viruses vTF7-3 and MVA-T7, which are necessary for T7 polymerase production in transfected cells, were compared for their use in SeV recovery and subsequent elimination of the helper virus from recombinant SeV. Interference with SeV replication was less severe with MVA-T7, and MVA-T7 was eliminated efficiently without the need for any inhibitors by serial passages in Vero cells. Optimal combination of all parameters led to a highly efficient generation of recombinant SeV from cDNA. Titres of the released virus particles are high enough to enable analysis of the recombinant SeV directly on test cells or propagation in cell cultures without the need for amplification in embryonated chicken eggs. The system is very robust and allows rapid generation of defined SeV mutants that require specialised host cells for propagation.

The activity of Sendai virus genomic and antigenomic promoters requires a second element past the leader template regions: a motif (GNNNNN)3 is essential for replication

The paramyxovirus genome, a nonsegmented, negative-polarity, single-stranded RNA of approximately 15 kb, contains six transcription units flanked at the 3' and 5' ends by a short (approximately 50- to 60-nucleotide) extracistronic sequence, dubbed the positive and negative leader regions. These leader template regions, present at the 3' end of the genome and the antigenome, have been shown to contain essential signals governing RNA replication activity. Whether they are sufficient to promote replication is still open to question. By using a series of Sendai virus defective interfering RNAs carrying a nested set of deletions in the promoter regions, it is shown here that for both the genomic and antigenomic promoters, a 3'-end RNA sequence of 96 nucleotides is required to allow replication. Sequence comparison of active and inactive promoters led to the identification of a set of three nucleotide hexamers (nucleotides 79 to 84, 85 to 90, and 91 to 96) containing a repeated motif RXXYXX [shown as 5'-3' positive-strand]. Sequential mutation of each hexamer into its complementary sequence confirmed their essential role. The three hexamers are required, and their relative positioning is important, since displacing them by 6 nucleotides destroyed promoter function. RNAs carrying degenerate nucleotides in the three hexamers were used as replication templates. They led to the selection of actively replicating RNA species exclusively carrying the basic motif (GNNNNN)3 from nucleotides 79 to 96. These results clearly show that, apart from the region from nucleotides 1 to 31, previously identified as governing Sendai virus replication activity, a second element, spanning at the most nucleotides 79 to 96, appears essential. Thus, the paramyxovirus replication promoters are not confined to the leader template regions, as seems to be the case for the rhabdoviruses.

A system for functional analysis of Ebola virus glycoprotein

Ebola virus causes hemorrhagic fever in humans and nonhuman primates, resulting in mortality rates of up to 90%. Studies of this virus have been hampered by its extraordinary pathogenicity, which requires biosafety level 4 containment. To circumvent this problem, we developed a novel complementation system for functional analysis of Ebola virus glycoproteins. It relies on a recombinant vesicular stomatitis virus (VSV) that contains the green fluorescent protein gene instead of the receptor-binding G protein gene (VSVDeltaG*). Herein we show that Ebola Reston virus glycoprotein (ResGP) is efficiently incorporated into VSV particles. This recombinant VSV with integrated ResGP (VSVDeltaG*-ResGP) infected primate cells more efficiently than any of the other mammalian or avian cells examined, in a manner consistent with the host range tropism of Ebola virus, whereas VSVDeltaG* complemented with VSV G protein (VSVDeltaG*-G) efficiently infected the majority of the cells tested. We also tested the utility of this system for investigating the cellular receptors for Ebola virus. Chemical modification of cells to alter their surface proteins markedly reduced their susceptibility to VSVDeltaG*-ResGP but not to VSVDeltaG*-G. These findings suggest that cell surface glycoproteins with N-linked oligosaccharide chains contribute to the entry of Ebola viruses, presumably acting as a specific receptor and/or cofactor for virus entry. Thus, our VSV system should be useful for investigating the functions of glycoproteins from highly pathogenic viruses or those incapable of being cultured in vitro.

The product of the respiratory syncytial virus M2 gene ORF1 enhances readthrough of intergenic junctions during viral transcription

The mRNA encoding the M2 protein of respiratory syncytial (RS) virus contains two open reading frames (ORFs). ORF1 encodes the 22-kDa structural protein, M2, and ORF2 has the potential to encode a 10-kDa protein (90 amino acids). Using a vaccinia virus T7 expression system, we examined the RNA synthetic activities of mono- and dicistronic subgenomic replicons of RS virus by direct metabolic labeling of RNA in the presence and absence of the products of ORF1 and ORF2. In the absence of ORF1 and ORF2, the negative- and positive-sense products of genomic RNA replication and positive-sense polyadenylated mRNA(s) were synthesized. Expression of the whole M2 transcription unit (containing ORF1 and ORF2) or ORF1 alone caused an increase in the synthesis of polyadenylated mRNA, the majority of which was due to a substantial increase in the quantity of polycistronic mRNAs generated by the polymerase failing to terminate at gene end signals. In agreement with previous reports, the ORF2 product was found to inhibit viral RNA replication and mRNA transcription. These data show that the M2 protein functions as a transcriptional antiterminator that enhances the ability of the viral RNA polymerase to read through intergenic junctions. The role of such a function during the viral life cycle is discussed.

Analysis of the gene start and gene end signals of human respiratory syncytial virus: quasi-templated initiation at position 1 of the encoded mRNA

The gene start (GS) and gene end (GE) transcription signals of human respiratory syncytial virus (RSV) strain A2 were analyzed in helper-dependent monocistronic and dicistronic minireplicons which were complemented by a standard RSV strain. The GS signal, which is the start site for mRNA synthesis, is highly conserved for the first nine genes: 3'-CCCCGUUUA(U/C) (negative sense). This conserved version of the signal was analyzed by "saturation" mutagenesis, in which all 10 positions, as well as one downstream and one upstream position, were changed one at a time into each of the other three nucleotides. Most of the positions appear to contribute to the signal: positions 1, 3, 6, 7, and, in particular, 9 were the most sensitive, whereas position 5 was relatively insensitive. The effect of nucleotide substitution in the first position of the signal was examined further by cDNA cloning and sequence analysis of the residual mRNA which was produced. For the two mutants examined (1C to U, and 1C to A), the site of initiation was unchanged. However, the mRNAs were dimorphic with regard to the assignment of the 5'-terminal nucleotide: two-thirds contained the predicted mutant substitution, and one-third contained the parental assignment. Intracellular minigenome contained only the mutant assignment, indicating that the heterogeneity was at the level of transcription by the RSV polymerase. This suggests that the templated mutant assignment at position 1 can sometimes be overridden by an innate preference for the parental assignment, a phenomenon which we dubbed quasi-templated initiation. The GS signal of the L gene, encoding the 10th RSV mRNA, contains three differences (3'-CCCUGUUUUA) compared to the conserved version. It was shown to be equal in efficiency to the conserved version. This was unexpected, since the saturation mutagenesis described above indicated that U in place of A at position 9 should be highly inhibitory. Instead, the A at position 10 of the L GS signal was found to be critical for activity, indicating that an essential A residue indeed was present in both versions of the GS signal but that its spacing differed. The GE signal, which directs termination and polyadenylation, has more sequence diversity in nature than does the GS signal. The naturally occurring GE signals of strain A2 were compared by their individual incorporation into a dicistronic minigenome. They were similar in the ability to produce translatable mRNA except in the cases of NS1 and NS2, which were approximately 60% as efficient.

Biochemical characterizations of two temperature-sensitive and attenuated strains of respiratory syncytial virus subgroup B

Cold-adapted, temperature-sensitive (ts), attenuated strains of respiratory syncytial virus have been developed from a B subgroup clinical isolate for potential use as vaccine candidates. The replication of two B subgroup ts mutant viruses (2B33F and 2B20L) at the permissive and nonpermissive temperatures have been compared with that of the parental 2B virus to establish differences that may account for their ts and/or attenuated phenotypes. We have shown that the ts restriction at 39 degrees C in the replication of the two mutant viruses in tissue culture occurs at a step after virus adsorption but before or including initiation of virus-specific mRNA transcription. At the permissive temperature of 32 degrees C a 12- to 24-h delay in the accumulation of mRNA for both mutant viruses in comparison to that of the parental 2B virus was exhibited. This effect was mirrored by equivalent delays in viral protein synthesis and production of infectious virus. By 36 h postinfection both mutants had produced levels of viral mRNA, protein, and infectious virus that were similar to those of the parent virus at 32 degrees C. ts+ revertant viruses derived from both mutants have also reverted in their viral mRNA, protein, and infectious virus production kinetics at 32 degrees C to rates more like those exhibited by the parental 2B virus. This suggests a positive correlation between the ts step in the replication of the mutant viruses and the initial delay in mRNA production that occurs at the permissive temperature.

An infectious clone of human parainfluenza virus type 3

A full-length clone of the human parainfluenza virus type 3 (HPIV-3) genome (called pHPIV-3) was constructed, and recombinant, infectious HPIV-3 was generated by transfecting pHPIV-3 and support plasmids encoding the HPIV-3 NP, P, and L proteins into HeLa cells infected with a vaccinia virus recombinant which expresses T7 RNA polymerase. T7 RNA polymerase promoters on the transfected plasmids direct the synthesis of transcripts encoding the NP, P, and L proteins and a full-length, positive-sense copy of the HPIV-3 genome. Generation of virus was dependent on transfection of pHPIV-3 and the HPIV-3 P- and L-encoding plasmids. However, a plasmid encoding the NP protein was not required since NP was expressed from pHPIV-3. Recovered virus was neutralized by anti-HPIV-3 antisera and shown to contain specific base substitutions characteristic of pHPIV-3. Recombination was shown to occur during recovery, as viruses with two distinct genotypes and phenotypes were isolated. The ability to produce infectious HPIV-3 engineered to contain specific alterations within the HPIV-3 genes and cis-acting elements expedites the study of all aspects of the virus replication cycle. Additionally, analysis of mutations may lead to the identification of attenuating genotypes, a key step in the development of a live virus vaccine.

Rescue of measles virus using a replication-deficient vaccinia-T7 vector

A system which allows the reconstitution of measles virus (MV) from cloned cDNA is described. The severely host cell restricted vaccinia vector MVA-T7 expressing bacteriophage T7 RNA polymerase was used to generate full-length antigenomic MV RNA and simultaneously the mRNAs encoding the viral N, P and L proteins in order to produce replicationally and transcriptionally active nucleocapsids. The functionality of the N, P and L proteins was demonstrated first by their ability to rescue MV specific subgenomic RNAs. Assembly and budding of reconstituted MV was shown by syncytia formation and subsequently by virus isolation. The inability of MVA-T7 to produce progeny virus in most mammalian cells circumvents the necessity to separate the reconstituted MV from the MVA-T7 helper virus. Since all components are expressed transiently, this system is especially suitable for studying the functions of N, P and L. Furthermore, it is useful for investigating later steps in the MV life cycle.

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.

Recovery of infectious respiratory syncytial virus expressing an additional, foreign gene

A previous report described the recovery from cDNA of infectious recombinant respiratory syncytial virus (RSV) strain A2 (P. L. Collins, M. G. Hill, E. Camargo, H. Grosfeld, R. M. Chanock, and B. R. Murphy, Proc. Natl. Acad. Sci. USA, 92:11563-11567, 1995). Here, the system was used to construct recombinant RSV containing an additional gene encoding chloramphenicol acetyltransferase (CAT). The CAT coding sequence was flanked by RSV-specific gene-start and gene-end motifs, the transcription signals for the viral RNA-dependent RNA polymerase. The RSV-CAT chimeric transcription cassette was inserted into the region between the G and F genes of the complete cDNA-encoded positive-sense RSV antigenome, and infectious CAT-expressing recombinant RSV was recovered. Transcription of the inserted gene into the predicted subgenomic polyadenylated mRNA was demonstrated by Northern (RNA) blot hybridization analysis, and the encoded protein was detected by enzyme assay and by radioimmunoprecipitation. Quantitation of intracellular CAT, SH, G, and F mRNAs showed that the CAT mRNA was efficiently expressed and that the levels of the G and F mRNAs (which represent the genes on either side of the inserted CAT gene) were comparable to those expressed by a wild-type recombinant RSV. Consistent with this finding, the CAT-containing and wild-type viruses were very similar with regard to the levels of synthesis of the major viral proteins. Each of 25 RSV isolates obtained by plaque purification following eight serial passages expressed CAT, showing that the foreign gene was faithfully maintained in functional form. Analysis by reverse transcription and PCR did not reveal evidence of deletion of the foreign sequence. This finding demonstrated that the RSV genome can accept and maintain an increase in length of 762 nucleotides of foreign sequence and can be engineered to encode an additional, 11th mRNA. The presence of the additional gene resulted in a 10% decrease in plaque diameter and was associated with delay in virus growth and 20-fold decrease in virus yield in vitro. Thus, introduction of an additional gene into the RSV genome might represent a method of attenuation. The ability to express foreign genes by recombinant RSV has implications for basic studies as well as for the development of live recombinant vaccines.

The structurally diverse intergenic regions of respiratory syncytial virus do not modulate sequential transcription by a dicistronic minigenome

The first nine genes of respiratory syncytial virus (RSV), a nonsegmented negative-strand RNA virus, are separated by intergenic regions which range in size from 1 to 52 nucleotides for strain A2 and lack obvious consensus elements except that each ends in an A (genome sense). Their significance for gene expression was investigated by using RSV-CAT-LUC RNA, a helper-dependent cDNA-encoded dicistronic analog of RSV genomic RNA in which the viral genes were replaced by a negative-sense copy of the translational open reading frame (ORF) encoding chloramphenicol acetyltransferase (CAT) as the upstream, leader-proximal gene and that encoding luciferase (LUC) as the downstream gene. These foreign ORFs were flanked by the RSV gene-start (GS) and gene-end (GE) transcription signals and separated by the naturally occurring G/F intergenic region. The RSV-CAT-LUC minigenome was synthesized in vitro and transfected into RSV-infected cells, and synthesis of the CAT and LUC mRNAs was monitored by enzyme assay and Northern (RNA) blot hybridization. Surprisingly, substitution of each of the other naturally occurring RSV intergenic regions in turn did not significantly alter the absolute or relative amounts of the two mRNAs. Substitution of a nonnatural 10-nucleotide intergenic region, or elimination of the intergenic region altogether, also had little effect on the level of expression of the two genes. Four of the minigenome variants containing naturally occurring intergenic regions were modified further by replacing part of the LUC ORF with a second copy of the CAT ORF, so that each of the two mRNAs would hybridize equally with a CAT-specific probe and their relative molar amounts could be determined. The level of expression of the downstream gene was 0.30 to 0.36 that of the upstream one. This determined the magnitude of RSV transcriptional polarity across a gene pair and confirmed that this value was very similar among the various intergenic regions. Minigenome transcription also yielded a CAT-LUC readthrough mRNA at a level 0.10 to 0.13 that of the LUC mRNA. In summary, the structurally diverse RSV intergenic regions do not appear to play a role in modulating RSV gene expression.

RNA replication by a respiratory syncytial virus RNA analog does not obey the rule of six and retains a nonviral trinucleotide extension at the leader end

Genome analogs ("minigenomes") of Sendai and measles viruses replicate efficiently only if their nucleotide length is an even multiple of six, a requirement called the rule of six (P. Calain and L. Roux, J. Virol. 67:4822-4830, 1993; M. S. Sidhu, J. Chan, K. Kaelin, P. Spielhofer, F. Radecke, H. Schneider, M. Masurekar, P. C. Dowling, M. A. Billeter, and S. A. Udem, Virology 208:800-807, 1995). The existence of a comparable requirement was tested for respiratory syncytial virus (RSV), which also is a member of family Paramyxoviridae and whose natural genome length also is a multiple of six. An internally truncated analog of RSV positive-sense replicative intermediate RNA (antigenome) bearing the chloramphenicol acetyltransferase gene as a reporter was synthesized from cDNA in vitro. This RNA was transfected into cells which were infected with RSV as a helper. Miniantigenomic RNA was indistinguishable from previously studied negative-sense minigenome RNA in its ability to participate in transcription, RNA replication, and incorporation into transmissible particles. Sixteen miniantigenomes which were of slightly different lengths and which in aggregate represented multiples of a wide range of integers including 1 to 15 were constructed. During transfection and two serial passages, the various miniantigenomes were essentially indistinguishable with regard to the efficiency of transcription, RNA replication, and packaging into transmissible particles. Progeny minigenomes of six different mutants were recovered postpassage, copied into cDNA, cloned, and sequenced completely. The length of each of these RNAs was found to have remained unchanged during replication and passage. Thus, RSV transcription and replication appear to lack the requirement that the template length be an even multiple of an integer such as six, which for Sendai and measles viruses is obligatory for nucleocapsid function. Each of the in vitro-synthesized miniantigenomes used in transfection contained a nonviral extension of three nucleotides, GGG, on the 5' (leader) end contributed by the T7 promoter. The termini of the recovered minigenomes were examined for five mutants by RNA circularization followed by cDNA synthesis, amplification, cloning, and sequencing. Unexpectedly, each recovered minigenome contained the complement of this nonviral extension on the 3' (leader) end, showing that it had been faithfully copied and maintained during RNA replication and passage. The nonviral trinucleotide did not appear to affect the activity of the template.

Expression and characterisation of the NS1 and NS2 proteins of respiratory syncytial virus

The NS1 and NS2 proteins of human respiratory syncytial virus (RSV) were expressed using baculovirus. Antisera to these expressed proteins and to synthetic peptides were raised in rabbits and used to characterise the proteins. Multiple forms of both NS1 and NS2 proteins were detected in RSV infected cells by both immunoblotting and radioimmunoprecipitation when non-reducing, but not reducing, conditions were used. In pulse-labelling experiments the monomeric form of NS1 was stable, while that of NS2 was unstable with a half life of about 30 min. The NS1 protein associated with the matrix (M) protein and could be co-precipitated by a monoclonal antibody to M protein. The NS2 protein did not show any detectable association with RSV structural proteins. These results indicate that the NS1 and NS2 proteins have distinct roles in the viral life cycle.

Transgenic cell lines for detection of animal viruses

Rapid diagnostic assays based on direct detection of viral antigen or nucleic acid are being used with increasing frequency in clinical virology laboratories. Virus culture, however, remains the only way to detect infectious virus and to analyze clinically relevant viral phenotypes, such as drug resistance. Growth of viruses in cell culture is labor intensive and time-consuming and requires the use of many different cell lines. Transgenic technology, together with increasing knowledge of the molecular pathways of virus replication, offers the possibility of using genetically modified cell lines to improve virus growth in cell culture and to facilitate detection of virus-infected cells. Genetically modifying cells so that they express a reporter gene only after infection with a specific virus can allow the detection of infectious virus by rapid and simple enzyme assays such as beta-galactosidase assays without the need for antibodies. Although transgenic cells have recently been successfully used for herpes simplex virus detection, much more work needs to be done to adapt this technology to other human viral pathogens such as cytomegalovirus and respiratory viruses. This review offers some strategies for applying this technology to a wide spectrum of animal viruses.

Identification of protein regions involved in the interaction of human respiratory syncytial virus phosphoprotein and nucleoprotein: significance for nucleocapsid assembly and formation of cytoplasmic inclusions

We have reported previously that the nucleoprotein (N), the phosphoprotein (P), and the 22-kDa protein of human respiratory syncytial virus (HRSV) are components of the cytoplasmic inclusion bodies observed in HEp-2-infected cells. In addition, coexpression of N and P was sufficient to induce the formation of N-P complexes detectable by either coimmunoprecipitation with anti-P antibodies or generation of cytoplasmic inclusions. We now report the identification of protein regions required for these interactions. Deletion mutant analysis of the P protein gene indicated that its C-terminal end was essential for interacting with N. This conclusion was strengthened by the finding that an anti-P monoclonal antibody (021/12P), reacting with a 21-residue P protein C-terminal peptide, apparently displaced N from N-P complexes. The same effect was observed with high concentrations of the C-terminal peptide. However, sequence requirements for the P protein C-terminal end were not absolute, and mutants with the substitution Ser-237-->Ala or Ser-237-->Thr were as efficient as the wild type in interacting with N. In addition, P and N proteins from strains of different HRSV antigenic groups, with sequence differences in the P protein C-terminal end, were able to coimmunoprecipitate and formed cytoplasmic inclusions. Deletion mutant analysis of the N gene indicated that large segments of this polypeptide were required for interacting with P. The relevance of these interactions for HRSV is discussed in comparison with those of analogous proteins from related viruses.

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.

Production of infectious human respiratory syncytial virus from cloned cDNA confirms an essential role for the transcription elongation factor from the 5' proximal open reading frame of the M2 mRNA in gene expression and provides a capability for vaccine development

Infectious human respiratory syncytial virus (RSV) was produced by the intracellular coexpression of five plasmid-borne cDNAs. One cDNA encoded a complete positive-sense version of the RSV genome (corresponding to the replicative intermediate RNA or antigenome), and each of the other four encoded a separate RSV protein, namely, the major nucleocapsid N protein, the nucleocapsid P phosphoprotein, the major polymerase L protein, or the protein from the 5' proximal open reading frame of the M2 mRNA [M2(ORF1)]. RSV was not produced if any of the five plasmids was omitted. The requirement for the M2(ORF1) protein is consistent with its recent identification as a transcription elongation factor and confirms its importance for RSV gene expression. It should thus be possible to introduce defined changes into infectious RSV. This should be useful for basic studies of RSV molecular biology and pathogenesis; in addition, there are immediate applications to the development of live attenuated vaccine strains bearing predetermined defined attenuating mutations.

RNA replication by respiratory syncytial virus (RSV) is directed by the N, P, and L proteins; transcription also occurs under these conditions but requires RSV superinfection for efficient synthesis of full-length mRNA

Previously, a cDNA was constructed so that transcription by T7 RNA polymerase yielded a approximately 1-kb negative-sense analog of genomic RNA of human respiratory syncytial virus (RSV) containing the gene for chloramphenicol acetyltransferase (CAT) under the control of putative RSV transcription motifs and flanked by the RSV genomic termini. When transfected into RSV-infected cells, this minigenome was "rescued," as evidenced by high levels of CAT expression and the production of transmissible particles which propagated and expressed high levels of CAT expression during serial passage (P.L. Collins, M. A. Mink, and D. S. Stec, Proc. Natl. Acad. Sci. USA, 88:9663-9667, 1991). Here, this cDNA, together with a second one designed to yield an exact-copy positive-sense RSV-CAT RNA antigenome, were each modified to contain a self-cleaving hammerhead ribozyme for the generation of a nearly exact 3' end. Each cDNA was transfected into cells infected with a vaccinia virus recombinant expressing T7 RNA polymerase, together with plasmids encoding the RSV N, P, and L proteins, each under the control of a T7 promoter. When the plasmid-supplied template was the mini-antigenome, the minigenome was produced. When the plasmid-supplied template was the minigenome, the products were mini-antigenome, subgenomic polyadenylated mRNA and progeny minigenome. Identification of progeny minigenome made from the plasmid-supplied minigenome template indicates that the full RSV RNA replication cycle occurred. RNA synthesis required all three RSV proteins, N, P, and L, and was ablated completely by the substitution of Asn for Asp at position 989 in the L protein. Thus, the N, P, and L proteins were sufficient for the synthesis of correct minigenome and antigenome, but this was not the case for subgenomic mRNA, indicating that the requirements for RNA replication and transcription are not identical. Complementation with N, P, and L alone yielded an mRNA pattern containing a large fraction of molecules of incomplete, heterogeneous size. In contrast, complementation with RSV (supplying all of the RSV gene products) yielded a single discrete mRNA band. Superinfection with RSV of cells staging N/P/L-based RNA synthesis yielded the single discrete mRNA species. Some additional factor supplied by RSV superinfection appeared to be involved in transcription, the most obvious possibility being one or more additional RSV gene products.

Efficient recovery of infectious vesicular stomatitis virus entirely from cDNA clones

Infectious vesicular stomatitis virus (VSV), the prototypic nonsegmented negative-strand RNA virus, was recovered from a full-length cDNA clone of the viral genome. Bacteriophage T7 RNA polymerase expressed from a recombinant vaccinia virus was used to drive the synthesis of a genome-length positive-sense transcript of VSV from a cDNA clone in baby hamster kidney cells that were simultaneously expressing the VSV nucleocapsid protein, phosphoprotein, and polymerase from separate plasmids. Up to 10(5) infectious virus particles were obtained from transfection of 10(6) cells, as determined by plaque assays. This virus was amplified on passage, neutralized by VSV-specific antiserum, and shown to possess specific nucleotide sequence markers characteristic of the cDNA. This achievement renders the biology of VSV fully accessible to genetic manipulation of the viral genome. In contrast to the success with positive-sense RNA, attempts to recover infectious virus from negative-sense T7 transcripts were uniformly unsuccessful, because T7 RNA polymerase terminated transcription at or near the VSV intergenic junctions.