Nucleotide sequences for the gene junctions of human respiratory syncytial virus reveal distinctive features of intergenic structure and gene order

RNA sequences involved in transcriptional termination of respiratory syncytial virus

RNA signals at the ends of the genes of respiratory syncytial (RS) virus direct polyadenylation and termination of viral transcription. These gene ends contain two conserved regions, a pentanucleotide and a tract of uridylate (U) residues, separated by an A/U-rich central region that is less well conserved. The U tract is thought to be the template for polyadenylation of viral mRNAs by reiterative transcription. The cis-acting requirements for termination were investigated by mutagenesis of the matrix (M) gene end (3'-UCAAUUAUUUUUU-5') in a dicistronic RNA replicon. Termination efficiencies were quantitated by intracellular metabolic labeling of monocistronic mRNAs and the dicistronic readthrough RNAs that result when termination fails to occur. All three regions of the gene end were necessary for termination. Mutation of each of the first 8 nucleotides of the M gene end to all other nucleotides showed that nucleotides 2 to 6 were important for termination and intolerant of change, whereas nucleotides 1 and 7 were tolerant of change. At position 8, A or U allowed termination, but G or C did not. Both the length and the position of the U tract were important for termination. U residues at positions 9 to 12 were necessary, while additional U residues at position 8, and especially position 13, enhanced termination efficiency. Altering the length of the central region abolished termination, suggesting that the position of the U tract with respect to the 3'-UCAAU-5' sequence was critical. The termination efficiencies of each of the 10 genes of RS virus are different. Since transcription is obligatorily sequential and termination of each gene is required for transcription of the next gene downstream, these differences may contribute to gene regulation. In agreement with our data, the naturally occurring gene ends of RS virus that terminate inefficiently have short U tracts or other sequence features that correlated with decreased termination when similar mutations were analyzed in RNA replicons.

Respiratory syncytial virus can tolerate an intergenic sequence of at least 160 nucleotides with little effect on transcription or replication in vitro and in vivo

The intergenic sequences (IGS) between the first nine genes of human respiratory syncytial virus (RSV) vary in length from 1 to 56 nucleotides and lack apparent conserved sequence motifs. To investigate their influence on sequential transcription and viral growth, recombinant RSV strain A2, from which the SH gene had been deleted to facilitate manipulation, was further modified to contain an M-G IGS of 16, 30, 44, 58, 65, 72, 86, 100, 120, 140, or 160 nucleotides. All of the viruses were viable. For viruses with an M-G IGS of 100 nucleotides or more, plaque size decreased with increasing IGS length. In this same length range, increasing IGS length was associated with modest attenuation during single-step, but not multistep, growth in HEp-2 cells. Surprisingly, Northern blot analysis of the accumulation of six different mRNAs indicated that there was little or no change in transcription with increasing IGS length. Thus, the RSV polymerase apparently can readily cross IGS of various lengths, including unnaturally long ones, with little or no effect on the efficiency of termination and reinitiation. This finding supports the view that the IGS do not have much effect on sequential transcription and provides evidence from infectious virus that IGS length is not an important regulatory feature. To evaluate replication in vivo, BALB/c mice were infected intranasally with RSV containing an M-G IGS of 65, 140, or 160 nucleotides. Replication of the latter two viruses was decreased up to 5- and 25-fold in the upper and lower respiratory tracts, respectively, on day 3 following infection. However, the level of replication at both sites on days 4 and 5 was very similar to that of the virus with an IGS of 65 nucleotides. Thus, the modest attenuation in vivo associated with the longer IGS was additive to that conferred by deletion of the SH gene and might be useful to incrementally increase the level of attenuation of a live-attenuated vaccine virus.

Spacing constraints on reinitiation of paramyxovirus transcription: the gene end U tract acts as a spacer to separate gene end from gene start sites

The paramyxovirus gene end U tracts are thought to serve as templates for the addition of a 3' polyA tail to viral mRNAs. The goal of the work described here was to determine the function in transcription of the naturally occurring variability in length of the gene end U tracts of the paramyxovirus simian virus 5 (SV5). An anchored RT-PCR assay was developed to test the hypothesis that the variable U tracts template the addition of variable lengths of polyA tails to mRNAs. The results showed that although the SV5 NP, M, and SH genes encode U tracts of seven, four, and six U residues, respectively, their mRNAs contain similar polyA tails of approximately 250-290 bases. These results indicate that the variable gene end U tracts are functionally equivalent in directing polyadenylation. A reverse genetics system based on a dicistronic minigenome containing the SH-HN gene junction was used to test the hypothesis that the variable U tracks affect the efficiency of transcription termination. Minigenome templates containing an SH gene end with a long U tract of six residues (U6) directed efficient transcription termination and reinitiation at the downstream HN start site with no nucleotide preference for the downstream intergenic region. Surprisingly, truncating the SH gene end U tract to four residues (U4) did not affect SH termination but, rather, reduced downstream HN reinitiation to 20-30% of wild-type levels. Efficient HN reinitiation could be restored to mutant U4 templates in either of two ways: by increasing the U-tract length from four to six residues or by increasing the length of the intergenic region. Efficient HN reinitiation required a minimum of six bases between the last nucleotide in SH and the first nucleotide in HN. We propose that for some paramyxoviruses, the gene end U tract serves a previously unrecognized role as a spacer region between the gene end and gene start sites.

Role of the M2-1 transcription antitermination protein of respiratory syncytial virus in sequential transcription

M2-1 protein of human respiratory syncytial virus (RSV) is a transcription antitermination factor that is important for the efficient synthesis of full-length mRNAs as well as for the synthesis of polycistronic readthrough mRNAs, which are characteristic of nonsegmented negative-strand RNA viruses. The contributions of these effects to RSV sequential transcription were investigated with minigenomes which contained one to five genes which were either foreign marker genes or authentic RSV genes. When evaluated on a promoter-proximal gene, the effect of M2-1 on the synthesis of full-length mRNA was much greater for a long (1,212- or 1,780-nucleotide) gene (up to a 615-fold increase) than for a short (274-nucleotide) gene (less than a 2-fold increase). This was independent of whether the gene contained non-RSV or RSV-specific sequence. Once the polymerase had terminated prematurely, it was unable to reinitiate at a downstream gene. These studies also confirmed that M2-1 enhances the synthesis of polycistronic mRNAs and that the magnitude of this effect varied greatly among different naturally occurring gene junctions. The synthesis of polycistronic mRNAs, which presumably involves antitermination at the gene-end signal, required a higher level of M2-1 than did the synthesis of the corresponding monocistronic mRNAs. M2-1 did not have a comparable antitermination effect at the junction between the leader region and the first gene. In a minigenome containing the NS1 and NS2 genes in their authentic sequence context, synthesis of full-length NS1 and NS2 mRNAs in the absence of M2-1 was remarkably high (36 and 57%, respectively, of the maximum levels observed in the presence of M2-1). In contrast, synthesis of mRNA from additional downstream genes was highly dependent on M2-1. Thus, RSV has the potential for two transcription programs: one in the absence of M2-1, in which only the NS1 and NS2 genes are transcribed, and one in the presence of M2-1, in which sequential transcription of the complete genome occurs. The dependence on M2-1 for transcription was greater for a gene in the fifth position from the promoter than for one in the third position. This indicates that under conditions where M2-1 is limiting, its concentration affects the gradient of transcription. Although M2-1 was found to have profound effects on transcription, it had no effect on replication of any minigenome tested, suggesting that it is not an active participant in RNA replication or regulation of RNA replication. Finally, since a permissive RSV infection is marked by a gradual increase in the intracellular accumulation of viral proteins including M2-1, we examined the relative abundances of various mRNAs during RSV infection for evidence of temporal regulation of transcription. None was found, implying that the availability of M2-1 during a permissive infection is sufficient at all times such that its concentration does not mediate temporal regulation of gene transcription.

Highly diverse intergenic regions of the paramyxovirus simian virus 5 cooperate with the gene end U tract in viral transcription termination and can influence reinitiation at a downstream gene

A dicistronic minigenome containing the M-F gene junction was used to determine the role of the simian virus 5 (SV5) intergenic regions in transcription. The M-F junction differs from the other SV5 junctions by having a short M gene end U tract of only four residues (U4 tract) and a 22-base M-F intergenic sequence between the M gene end and F gene start site. Replacing the 22-base M-F intergenic region with nonviral sequences resulted in a minigenome template (Rep 22) that was defective in termination at the end of the M gene. Efficient M gene termination could be restored to the mutant Rep 22 template in either of two ways: by increasing the U tract length from four to six residues or by restoring a G residue immediately downstream of the wild-type (WT) U4 tract. In a dicistronic SH-HN minigenome, a U4-G combination was functionally equivalent to the naturally occurring SH U6-A gene end in directing SH transcription termination. In addition to affecting termination, the M-F intergenic region also influenced polymerase reinitiation. In the context of the WT U4-G M gene end, substituting nonviral sequences into the M-F intergenic region had a differential effect on F gene reinitiation, where some but not all nonviral sequences inhibited reinitiation. The inhibition of F gene reinitiation correlated with foreign sequences having a high C content. Deleting 6 bases or inserting 18 additional nucleotides into the middle of the 22-base M-F intergenic segment did not influence M gene termination or F gene reinitiation, indicating that M-F intergenic length per se is not a important factor modulating the SV5 polymerase activity. Our results suggest that the sequence diversity at an SV5 gene junction reflects specific combinations which may differentially affect SV5 gene expression and provide an additional level of transcriptional control beyond that which results from the distance of a gene from the 3' end promoter.

Respiratory syncytial virus infection: immune response, immunopathogenesis, and treatment

Respiratory syncytial virus (RSV) is the single most important cause of lower respiratory tract infection during infancy and early childhood. Once RSV infection is established, the host immune response includes the production of virus-neutralizing antibodies and T-cell-specific immunity. The humoral immune response normally results in the development of anti-RSV neutralizing-antibody titers, but these are often suboptimal during an infant's initial infection. Even when the production of RSV neutralizing antibody following RSV infection is robust, humoral immunity wanes over time. Reinfection during subsequent seasons is common. The cellular immune response to RSV infection is also important for the clearance of virus. This immune response, vital for host defense against RSV, is also implicated in the immunopathogenesis of severe lower respiratory tract RSV bronchiolitis. Many details of the immunology and immunopathologic mechanisms of RSV disease known at present have been learned from rodent models of RSV disease and are discussed in some detail. In addition, the roles of immunoglobulin E, histamine, and eosinophils in the immunopathogenesis of RSV disease are considered. Although the treatment of RSV bronchiolitis is primarily supportive, the role of ribavirin is briefly discussed. Novel approaches to the development of new antiviral drugs with promising anti-RSV activity in vitro are also described.

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.

Model for polymerase access to the overlapped L gene of respiratory syncytial virus

The last two genes of respiratory syncytial virus (RSV), M2 and L, overlap by 68 nucleotides, an arrangement which has counterparts in a number of nonsegmented negative-strand RNA viruses. Thus, the gene-end (GE) signal of M2 lies downstream of the L gene-start (GS) signal, separated by 45 nucleotides. Since RSV transcription ostensibly is sequential and unidirectional from a single promoter within the 3' leader region, it was unclear how the polymerase accesses the L GS signal. Furthermore, it was previously shown that 90% of transcripts which are initiated at the L GS signal are polyadenylated and terminated at the M2 GE signal, yielding a short, truncated L mRNA as the major transcription product of the L gene. Despite these apparent down-regulatory features, we show that the accumulation of full-length L mRNA during RSV infection is only sixfold less than that of its upstream neighbor, M2. We used cDNA-encoded genome analogs in an intracellular transcription assay to investigate the mechanism of transcription of the overlapped genes. Expression of L was found to be dependent on sequential transcription from the 3' end of the genome. Apart from the L GS signal, the only other strict requirement for initiation at L was the M2 GE signal. This implies that the polymerase accesses the L GS signal only following arrival at the M2 GE signal. Thus, polymerase which terminates at the M2 GE signal presumably scans upstream to initiate at the L GS signal. This also would provide a mechanism whereby polymerase which terminates prematurely during transcription of L could recycle from the M2 GE signal to the L GS signal, thereby accounting for the unexpectedly high level of synthesis of full-length L mRNA. The sequence and spacing between the two signals were not critical. Furthermore, the polymerase also was capable of efficiently transcribing from an L GS signal placed downstream of the M2 GE signal, implying that the overlapping arrangement is not obligatory. When copies of the L GS signal were placed concurrently upstream and downstream of the M2 GE signal, both were utilized. This finding indicates that a polymerase situated at a GE signal is capable of scanning for a GS signal in either the upstream or downstream direction and thereafter initiating transcription.

The length and sequence composition of vesicular stomatitis virus intergenic regions affect mRNA levels and the site of transcript initiation

In this study, we used a dicistronic vesicular stomatitis virus (VSV) minigenome to investigate the effects of either single or multiple nucleotide insertions placed immediately after the nontranscribed intergenic dinucleotide of the M gene on VSV transcription. Both Northern blot and primer extension analysis showed that the polymerase responded to the inserted nucleotides in a sequence-specific manner such that some insertions had no effect on mRNA synthesis from the downstream G gene, nor on the site of transcript initiation, whereas other insertions resulted in dramatic reductions in transcript accumulation. Some of these transcripts were initiated at the wild-type site, while others initiated within the inserted sequence. We also examined the transcriptional events that occurred when a natural, 21-nucleotide intergenic region located between the G and L genes from the New Jersey (NJ) serotype of VSV was inserted into the minigenome gene junction. In contrast to the normal 25 to 30% attenuation observed for downstream transcription at gene junctions containing the typical dinucleotide (3'-GA-5') intergenic region, the NJ variant showed greater than 75% attenuation at the gene junction. In addition, the polymerase initiated transcription at two major start sites, one of which was located within the intergenic sequence. Collectively, these data suggest that the polymerase "samples" the intergenic sequences following polyadenylation and termination of the upstream transcript by scanning until an appropriate start site is found. One implication of a scanning polymerase is that the polymerase presumably switches states from a processive elongation mode to a stuttering mode for polyadenylation to one in which no transcription occurs, before it reinitiates at the downstream gene. Our data support the hypothesis that sequences surrounding the intergenic region modulate these events such that appropriate amounts of each mRNA are synthesized.

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.

Rescue of synthetic minireplicons establishes the absence of the NS1 and NS2 genes from avian pneumovirus

We have determined the nucleotide sequences of the regions 3' and 5' proximal to the avian pneumovirus (APV) N and L genes, respectively. These sequences were used in the construction of a synthetic minireplicon construct in which the chloramphenicol acetyltransferase (CAT) reporter gene was flanked at its 3' end with the APV leader together with the APV N gene start signal and at its 5' end with the APV L gene end signal and the genome trailer region. The ability of T7 RNA polymerase runoff transcripts to direct the replication and expression of the CAT reporter gene in APV-infected cells demonstrated the ability of the putative leader and trailer regions to direct genome replication and gene expression. Furthermore, this confirms the absence of the NS1 and NS2 gene analogs within the APV genome. We were able to detect the expression of CAT protein from cells that had been infected with supernatants from the initially infected and transfected cells. These results have identified the cis-acting sequences of APV responsible for viral replication, gene expression, and packaging into virus-like particles.

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.

Mutational analyses of the intergenic dinucleotide and the transcriptional start sequence of vesicular stomatitis virus (VSV) define sequences required for efficient termination and initiation of VSV transcripts

We have used dicistronic vesicular stomatitis virus (VSV) minigenomes to dissect the functional importance of the nontranscribed intergenic dinucleotide and the conserved transcription start sequence found at the beginning of all VSV genes. The minigenomes were generated entirely from cDNA and contained the G and M protein genes, flanked by the leader and trailer regions from the Indiana serotype of VSV. All mutations were made either within the nontranscribed M-G intergenic dinucleotide or within the transcription start sequence of the downstream G gene. Immunofluorescence microscopy and immunoprecipitation analysis of the mutated minigenomes indicated that the first three nucleotides of the transcriptional start sequence are the most critical for efficient VSV gene expression, whereas the nontranscribed, intergenic dinucleotide and the other conserved nucleotides found at the 5' mRNA start sequence can tolerate significant sequence variability without affecting G protein production. RNA analysis indicated that nucleotide changes in the transcriptional start sequence which resulted in reduced G protein expression correlated with the amount of transcript present. Therefore, this conserved sequence appears to be required for efficient transcript initiation following polyadenylation of the upstream mRNA. While the minimum sequence for efficient transcription (3'-UYGnn-5') is similar to that of other rhabdoviruses, it is not homologous to the start sites for viruses from the Paramyxoviridae or Filoviridae families. Using Northern blot analysis, we also found that some nucleotide changes in the nontranscribed intergenic region resulted in higher levels of read-through transcription. Therefore, the nontranscribed intergenic dinucleotide plays a role in transcript termination.

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.

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.

Antibody responses of children to the C-terminal peptide of the SH protein of respiratory syncytial virus and the immunological characterization of this protein

The SH protein of RSV, a small integrated hydrophobic membrane protein, consists of 64 amino acid residues in the polypeptide of subgroup A and 65 amino acid residues in the polypeptide of subgroup B. We synthesized five peptides, representing the SH protein of each RSV subgroup comprised of the following amino acid residues: 2-16, 12-26, 35-49, 45-60, and for subgroup A, 51-64 and for subgroup B, 51-65. Peptides 2-16 and 51-64/65 represented the N-terminal and C-terminal ends of the protein, respectively. In RIPA, under reducing conditions with mercaptoethanol, hyperimmune guinea pig (GP) serum against C-terminal peptide of the two subgroups precipitated the homologous 7.5 kDa and 21-30 kDa SH proteins. Under nonreducing conditions, the GP antipeptide sera precipitated all three SH proteins, suggesting that the 13-15 kDa protein exists as a dimer. The subgroup A 7.5 and 13-15 kDa proteins had apparent molecular weights about 1-2 kDa higher than the corresponding subgroup B proteins. The C-terminal peptides of subgroups A and B were used to characterize the immune response of 11 children, age 1 month to 1 year, with presumed primary RSV infection. Three of 4 children with subgroup A infection and 4 of 7 children with subgroup B infection developed homologous 4-fold rises in antibody to C-terminal peptide (aa 51-64/65) during convalescence. Except for one child with subgroup A and one child with subgroup B infection, the other 5 children developed heterologous rises also.(ABSTRACT TRUNCATED AT 250 WORDS)

Frequent polymerase errors observed in a restricted area of clones derived from the attachment (G) protein gene of respiratory syncytial virus

Sequence analysis of a large number of clones derived from the carboxy-terminal one-third of the attachment (G) protein gene of subgroup A respiratory syncytial viruses revealed a region very prone to polymerase errors which resulted mainly in frameshifts because of the insertion or deletion of adenosine residues in some but not all runs of such residues. Such mutations were detected in 14% of clones derived from mRNA, 58% of clones derived from genomic-sense RNA, and 50% of clones derived from in vitro-transcribed RNA. This phenomenon appears to be dependent on the template sequence.

Transcription of human respiratory syncytial virus genome RNA in vitro: requirement of cellular factor(s)

Extracts made from human respiratory syncytial virus (RSV)-infected Hep-2 cells synthesized mRNAs encoded by all known viral genes. In contrast, RSV ribonucleoproteins purified from infected cells failed to transcribe in vitro; transcription was restored by addition of a cytoplasmic extract of uninfected Hep-2 cells, demonstrating that a cellular factor(s) has a role in RSV gene expression. Quantitation of the individual gene mRNAs transcribed in vitro revealed polarity of transcription of the genome.

Respiratory syncytial virus detection by dot blot hybridization with a nonradioactive synthetic oligo deoxynucleotide probe

A synthetic oligodeoxynucleotide corresponding to a region of the nucleocapside gene (N) of respiratory syncytial virus (RSV), was used as a DNA probe to develop a nonradioactive hybridization assay for the detection of RSV. The probe was labeled by incorporation of biotin-7-dATP to the 3' end by a reaction catalyzed by terminal deoxynucleotydil transferase. The dot blot hybridization assay was found to be specific for RSV when tested against RSV isolates (subgroups A and B) obtained from cell cultures and isolates of adenovirus, reovirus, rotavirus, and pararotavirus. The assay detected both RSV subgroups (A and B) without significant differences. The dot blot hybridization assay using the nonradioactive probe led to similar results to indirect immunofluorescence (IFI) when tested against a panel of 64 clinical samples from nasopharyngeal secretions of infants with clinical symptoms of respiratory disease. This assay may provide the basis for a rapid, simple, and inexpensive method for routine RSV diagnosis.

Nucleotide sequence analysis and expression from recombinant vectors demonstrate that the attachment protein G of bovine respiratory syncytial virus is distinct from that of human respiratory syncytial virus

Bovine respiratory syncytial (BRS) virus causes a severe lower respiratory tract disease in calves similar to the disease in children caused by human respiratory syncytial (HRS) virus. While there is antigenic cross-reactivity among the other major viral structural proteins, the major glycoprotein, G, of BRS virus and that of HRS virus are antigenically distinct. The G glycoprotein has been implicated as the attachment protein for HRS virus. We have carried out a molecular comparison of the glycoprotein G of BRS virus with the HRS virus counterparts. cDNA clones corresponding to the BRS virus G glycoprotein mRNA were isolated and analyzed by dideoxynucleotide sequencing. The BRS virus G mRNA contained 838 nucleotides exclusive of poly(A) and had a major open reading frame coding for a polypeptide of 257 amino acid residues. The deduced amino acid sequence of the BRS virus G polypeptide showed only 29 to 30% amino acid identity with the G protein of either the subgroup A or B HRS virus. However, despite this low level of identity, there were strong similarities in the predicted hydropathy profiles of the BRS virus and HRS virus G proteins. A cDNA molecule containing the complete BRS virus G major open reading frame was inserted into the thymidine kinase gene of vaccinia virus by homologous recombination, and a recombinant virus containing the BRS virus G protein gene was isolated. This recombinant virus expressed the BRS virus G protein, as demonstrated by Western immunoblot analysis and immunofluorescence of infected cells. The BRS virus G protein expressed from the recombinant vector was transported to and expressed on the surface of infected cells. Antisera to the BRS virus G protein made by using the recombinant vector to immunize animals recognized the BRS virus attachment protein but not the HRS virus G protein and vice versa, confirming the lack of antigenic cross-reactivity between the BRS and HRS virus attachment proteins. On the basis of the data presented here, we conclude that BRS virus should be classified within the genus Pneumovirus in a group separate from HRS virus and that it is no more closely related to HRS virus subgroup A than it is to HRS virus subgroup B.

Molecular cloning of pneumonia virus of mice

cDNA clones representing nine genes of pneumonia virus of mice (PVM) have been generated. The sizes of the corresponding mRNAs and a provisional transcriptional map of the virus genome have been determined. The apparent gene order is very similar to that of respiratory syncytial virus. The sequences adjacent to the 3' termini of the PVM genes were determined and are very similar to those of respiratory syncytial virus. Several PVM gene polypeptide products have been assigned.

Immunity to human and bovine respiratory syncytial virus

Human and bovine respiratory syncytial viruses resemble each other closely. During annual winter outbreaks, they cause similar respiratory tract disease in infants and calves. The disease is most severe in children and calves between 1 and 3 months old, when maternal antibodies against the virus are usually present. Reinfections, which are common, are accompanied by progressively milder illnesses in children, but are symptomless in calves. Because maternal antibodies suppress serum and mucosal antibody responses of all isotypes, the development of a vaccine that is effective in young children and calves with high levels of maternal antibodies has been severely hampered. Although virus administered intranasally to young calves with maternal antibodies does not evoke antibody responses, it can prime these calves for a protective memory response upon reinfection. Protection appears to be associated with the capacity to mount a mucosal memory IgA response. There are several indications that one or more immunopathologic mechanisms contribute to the disease. An Arthus reaction (type III) may have a role in the pathogenesis, because activated complement may cause most of the pathologic lesions, including edema and emphysema in uninfected parts of the lung. Lungs from calves with severe or fatal disease have depositions of complement component C3 and a low histamine content. The most immunogenic and protective antigen of the virus is the fusion (F) glycoprotein, which evokes a strong antibody response and is a target for cytotoxic T cells. On the F protein, epitopes that induce neutralizing and non-neutralizing antibodies, both of which may enhance complement activation, were identified. Immunity to the F protein may have beneficial and harmful effects.

The 1A protein of respiratory syncytial virus is an integral membrane protein present as multiple, structurally distinct species

The respiratory syncytial virus (RSV) 1A protein was previously identified as a 7.5-kilodalton (kDa) nonglycosylated species that, on the basis of its predicted sequence determined from the sequence of its mRNA, contains a hydrophobic central domain that was suggestive of membrane interaction. Here, four major, structurally distinct intracellular species of the 1A protein were identified in cells infected by RSV or by a recombinant vaccinia virus expressing the 1A gene. The four species of 1A were: (i) the previously described, nonglycosylated 7.5-kDa species that appeared to be the full-length, unmodified 1A protein; (ii) a nonglycosylated 4.8-kDa species that was carboxy-coterminal with the 7.5-kDa species and might be generated by translational initiation at the second AUG in the sequence; (iii) a 13- to 15-kDa species that contained one or two N-linked carbohydrate side chains of the high-mannose type; and (iv) a 21- to 30-kDa glycosylated species that appeared to be generated from the 13- to 15-kDa species by further modification of the N-linked carbohydrate. All four forms of the 1A protein were synthesized and processed on intracellular membranes, and several lines of biochemical evidence showed that all four species were integral membrane proteins. Thus, the 1A protein is a third RSV integral membrane protein and is present as such in both glycosylated and nonglycosylated forms. With the use of antiserum raised against a synthetic peptide representing the C terminus of the 1A protein, indirect immunofluorescence showed that the 1A protein was expressed at the cell surface. Antibody-antigen complexes formed at the surface of intact infected cells were immunoprecipitated, showing that the 7.5-kDa, 13- to 15-kDa, and 21- to 30-kDa, but not the 4.8-kDa, species, were accessible to extracellular antibodies. Thus, the 1A protein is a candidate to be a viral surface antigen. The small size, gene map location integral membrane association, and cell surface expression of the 1A protein strongly suggested that it is a counterpart to the SH protein that has been described for simian virus type 5. We suggest that, in the future, the RSV 1A protein be given the same designation, namely, SH.

Characterization of bovine respiratory syncytial virus proteins and mRNAs and generation of cDNA clones to the viral mRNAs

We have characterized the proteins and mRNAs of bovine respiratory syncytial (BRS) virus strain 391-2 and constructed cDNA clones corresponding to 9 of the 10 BRS virus mRNAs. The proteins of BRS virus-infected cells were compared with the proteins from human respiratory syncytial (HRS) virus-infected cells. Nine proteins specific to BRS virus-infected cells, corresponding to nine HRS virus proteins, were identified. Only a BRS virus polymerase protein remains to be identified. The BRS virus G glycoprotein showed major antigenic differences from the HRS virus G glycoprotein by immunoprecipitation and Western (immuno-) blot analysis, whereas the BRS virus F, N, M, and P proteins showed antigenic cross-reactivity with their HRS virus counterparts. Analysis of RNAs from BRS virus-infected cells showed virus-specific RNAs which had electrophoretic mobilities similar to those of mRNAs of HRS virus but which hybridized poorly or not at all with HRS virus-specific probes in Northern (RNA) blot analysis. To analyze the BRS virus RNAs further, cDNA clones to the BRS virus mRNAs were generated. Nine separate groups of clones were identified and shown to correspond to nine BRS virus mRNAs by Northern blot analysis. A 10th BRS virus large mRNA was identified by analogy with the HRS virus polymerase mRNA. These data show that like HRS virus, BRS virus has 10 genes coding for 10 mRNAs.

Primary respiratory syncytial virus infection in mice

A mouse model of respiratory syncytial virus (RSV) infection is described. A high-titered, large-volume inoculum results in replication of RSV to a high titer in lungs of BALB/c mice. Mice older than 15 weeks of age are more susceptible to RSV infection. Titers up to 10(6.9) plaque-forming units (pfu)/gram lung can be attained in 32-week-old mice. Older mice experience a clinical illness manifested by ruffled fur, reduced activity, and weight loss. Lung histology of older mice infected with RSV shows bronchiolitis and increased number of lymphocytes and macrophages in alveolar spaces compared with that of mice less than 8 weeks old. This model will serve as the basis for investigating immunodeterminants of recovery and protection from RSV infection.

Antigenic relatedness between glycoproteins of human respiratory syncytial virus subgroups A and B: evaluation of the contributions of F and G glycoproteins to immunity

The degree of antigenic relatedness between human respiratory syncytial virus (RSV) subgroups A and B was estimated from antibody responses induced in cotton rats by respiratory tract infection with RSV. Glycoprotein-specific enzyme-linked immunosorbent assays of antibody responses induced by RSV infection demonstrated that the F glycoproteins of subgroups A and B were antigenically closely related (relatedness, R approximately 50%), whereas the G glycoproteins were only distantly related (R approximately 5%). Intermediate levels of antigenic relatedness (R approximately 25%) were seen in neutralizing antibodies from cotton rats infected with RSV of the two subgroups. Immunity against the F glycoprotein of subgroup A, induced by vaccinia-A2-F, conferred a high level of protection which was of comparable magnitude against challenge by RSV of either subgroup. In comparison, immunity against the G glycoprotein of subgroup A, induced by vaccinia-A2-G, conferred less complete, but significant, protection. Importantly, in vaccinia-A2-G-immunized animals, suppression of homologous challenge virus replication was significantly greater (13-fold) than that observed for the heterologous virus.

Gene overlap and site-specific attenuation of transcription of the viral polymerase L gene of human respiratory syncytial virus

Sequence analysis of the gene encoding polymerase L protein of respiratory syncytial virus showed that L-gene transcription initiates within its upstream neighbor, the gene encoding the 22-kDa protein 22K. This is an exception to the canonical mode of sequential transcription of nonoverlapping genes described for other nonsegmented negative-strand RNA viruses. As a consequence of the gene overlap, the termination/polyadenylylation signal for the 22K gene is located at nucleotides 56-68 within the L gene. L-gene transcription yielded two RNAs: an abundant, truncated, polyadenylylated transcript resulting from termination at the internal signal and a markedly less abundant large polyadenylylated transcript representing the complete L gene. This result showed that the internal termination/polyadenylylation signal is an attenuator of L-gene transcription.

The G glycoprotein of human respiratory syncytial viruses of subgroups A and B: extensive sequence divergence between antigenically related proteins

Two major antigenic subgroups (designated A and B) have been described for human respiratory syncytial virus (RSV). Previously, on the basis of reactivity patterns with monoclonal antibodies, the greatest intersubgroup variation was shown to occur in the G protein, the putative attachment glycoprotein. To delineate the molecular basis for this variation, we have determined the nucleotide and deduced amino acid sequences of the G mRNAs and proteins representing a subgroup A (Long strain) and a subgroup B (18537 strain) virus. These sequences were compared to the available G mRNA sequence for another subgroup A (A2 strain) virus. The Long G protein shared 94% amino acid identity with the A2 G protein. In contrast, the 18537 G protein shared only 53% amino acid identity with the A2 sequence; interestingly, most of the sequence divergence occurred in the proposed extracellular domain of the G protein. This extensive divergence for the G protein was significantly greater than that observed for other RSV proteins. Despite this considerable divarication, the proposed extracellular domains of the G proteins contained a single region of highly conserved sequence and secondary structure that may represent a conserved structural or function domain, perhaps involved in attachment to cellular receptors. Furthermore, this conserved region may comprise part of an epitope that is shared between the two subgroup G proteins and may significantly contribute to the fact that, despite extensive overall amino acid sequence divergence, the RSV G proteins maintain significant antigenic relatedness.

A single nucleotide change in the E2 glycoprotein gene of Sindbis virus affects penetration rate in cell culture and virulence in neonatal mice

The nucleotide sequence of the glycoprotein genes of fully virulent Sindbis virus and derived mutants that have reduced neurovirulence for neonatal mice (attenuated mutants) has been determined. A single amino acid difference, arginine instead of serine at position 114 of the mature E2 glycoprotein, distinguished the prototype attenuated mutant from its virulent wild-type parent. Virulent revertants of the attenuated mutant showed same-site reversion to the wild-type sequence. An identical single amino acid substitution, an arginine for the serine at E2 position 114, was found in a second independently selected attenuated mutant. The strains are characterized by genetic linkage between attenuation, accelerated penetration of baby hamster kidney cells, and efficient neutralization by the E2-specific monoclonal antibodies R6 and R13; selection for change in one property simultaneously selected for change in the other two (Olmsted, R. A., Baric, R. S., Sawyer, B. A. & Johnston, R. E. (1984) Science 225, 424-427 and Olmsted, R. A., Meyer, W. J. & Johnston, R. E. (1986) Virology 148, 1-10). The nucleotide sequence data suggest that a single mutation in the E2 gene is sufficient to cause these coordinate phenotypic changes. These findings identify a single locus in a Sindbis virus surface glycoprotein gene that determines both efficiency of interaction with cultured baby hamster kidney cells and degree of virulence in neonatal mice.