The efficiency of Sendai virus genome replication: the importance of the RNA primary sequence independent of terminal complementarity

Identification and Characterization of Defective Viral Genomes in Ebola Virus-Infected Rhesus Macaques

Ebola virus (EBOV), of the family Filoviridae, is an RNA virus that can cause a hemorrhagic fever with a high mortality rate. Defective viral genomes (DVGs) are truncated genomes that have been observed during multiple RNA virus infections, including in vitro EBOV infection, and have previously been associated with viral persistence and immunostimulatory activity. As DVGs have been detected in cells persistently infected with EBOV, we hypothesized that DVGs may also accumulate during viral replication in filovirus-infected hosts. Therefore, we interrogated sequence data from serum and tissue samples using a bioinformatics tool in order to identify the presence of DVGs in nonhuman primates (NHPs) infected with EBOV, Sudan virus (SUDV), or Marburg virus (MARV). Multiple 5' copy-back DVGs (cbDVGs) were detected in NHP serum during the acute phase of filovirus infection. While the relative abundance of total DVGs in most animals was low, serum collected during acute EBOV and SUDV infections, but not MARV infections, contained a higher proportion of short trailer sequence cbDVGs than the challenge stock. This indicated an accumulation of these DVGs throughout infection, potentially due to the preferential replication of short DVGs over the longer viral genome. Using reverse transcriptase PCR (RT-PCR) and deep sequencing, we also confirmed the presence of 5' cbDVGs in EBOV-infected NHP testes, which is of interest due to EBOV persistence in semen of male survivors of infection. This work suggests that DVGs play a role in EBOV infection in vivo and that further study will lead to a better understanding of EBOV pathogenesis. IMPORTANCE The study of filovirus pathogenesis is critical for understanding the consequences of infection and for the development of strategies to ameliorate future outbreaks. Defective viral genomes (DVGs) have been detected during EBOV infections in vitro; however, their presence in in vivo infections remains unknown. In this study, DVGs were detected in samples collected from EBOV- and SUDV-infected nonhuman primates (NHPs). The accumulation of these DVGs in the trailer region of the genome during infection indicates a potential role in EBOV and SUDV pathogenesis. In particular, the presence of DVGs in the testes of infected NHPs requires further investigation as it may be linked to the establishment of persistence.

Analysis of nucleotides 13-96 of the human parainfluenza virus type 3 antigenomic promoter reveals positive- and negative-acting replication elements

During replication of human parainfluenza virus type 3 (HPIV3), the 96-nucleotide antigenomic promoter (AGP) of HPIV3 directs the synthesis of genomic RNA. Previous work showed that nucleotides 1-12 were critical in promoting replication of an HPIV3 minireplicon, but nucleotides 13-96 were not investigated. In this study, the role of nucleotides 13-96 in AGP function was analyzed by creating and assaying mutations in an HPIV3 minireplicon. A replication promoting element known as promoter element II (nt 79-96) was confirmed in the HPIV3 AGP. Additionally, nucleotides 13-39 were found to constitute an additional positive-acting cis-element. However, detailed analysis of the 13-39 element revealed a complicated control element with both stimulatory and repressing elements. Specifically, nucleotides 21-28 were shown to repress RNA replication, while flanking sequences had a stimulatory effect.

The marburg virus 3' noncoding region structurally and functionally differs from that of ebola virus

We have previously shown that the first transcription start signal (TSS) of Zaire Ebola virus (ZEBOV) is involved in formation of an RNA secondary structure regulating VP30-dependent transcription activation. Interestingly, transcription of Marburg virus (MARV) minigenomes occurs independently of VP30. In this study, we analyzed the structure of the MARV 3' noncoding region and its influence on VP30 necessity. Secondary structure formation of the TSS of the first gene was experimentally determined and showed substantial differences from the structure formed by the ZEBOV TSS. Chimeric MARV minigenomes mimicking the ZEBOV-specific RNA secondary structure were neither transcribed nor replicated. Mapping of the MARV genomic replication promoter revealed that the region homologous to the sequence involved in formation of the regulatory ZEBOV RNA structure is part of the MARV promoter. The MARV promoter is contained within the first 70 nucleotides of the genome and consists of two elements separated by a spacer region, comprising the TSS of the first gene. Mutations within the spacer abolished transcription activity and led to increased replication, indicating competitive transcription and replication initiation. The second promoter element is located within the nontranslated region of the first gene and consists of a stretch of three UN(5) hexamers. Recombinant full-length MARV clones, in which the three conserved U residues were substituted, could not be rescued, underlining the importance of the UN(5) hexamers for replication activity. Our data suggest that differences in the structure of the genomic replication promoters might account for the different transcription strategies of Marburg and Ebola viruses.

Cis-acting elements in the antigenomic promoter of Nipah virus

Genome synthesis in paramyxoviruses, including Nipah virus (NiV), is controlled by sequence elements that reside in the non-coding nucleotides at the 5'-trailer (3'-antigenomic) end that make up the antigenomic promoter (AGP). Using a chloramphenicol acetyl transferase-based plasmid-driven minigenome system, the terminal 96 nt of NiV AGP were first mutagenized in blocks of three hexamers to enable broad mapping of the minigenome functional regions. This was followed by further dissection of these functional regions to define the cis-acting elements contained therein. Results based on RNA analysis and reporter gene activity identified a bipartite promoter structure similar to that seen in related viruses, but with some distinct differences: in NiV, each of the two discrete replication control elements was bimodal, characterized by a critical conserved region (nt 1-12 and 79-91) and a contiguous non-conserved region (nt 13-36 and 73-78), which appeared less important. The regulatory role of these less critical regions was underscored by the use of a two-step mutation strategy, which revealed the additive detrimental effect of substitutions in this part of the terminal element. The structure and sequence characteristics of the internal control element was also different: it involved four contiguous hexamers, and the region encompassing three of these (nt 79-96, corresponding to hexamers 14, 15 and 16), although analogous in position to the equivalent element in the Sendai virus AGP, was characterized by the distinct 5'-(GNNNUG)(14-15)(GNNNNN)(16) motif.

Roles of human parainfluenza virus type 3 bases 13 to 78 in replication and transcription: identification of an additional replication promoter element and evidence for internal transcription initiation

The genomic promoter of human parainfluenza virus type 3 (HPIV3) contains multiple cis-elements controlling transcription and replication. Previous work showed that regions 1 to 12 and 79 to 96 were critical in promoting replication of an HPIV3 minireplicon, while the intergenic sequence and N gene start signal (IS/Ngs, bases 49 to 61) were important for transcription. Because these data were collected primarily using point mutations, not every base from position 1 to 96 was analyzed, and some important control elements may have been missed. To clarify the role of bases 13 to 78 in transcription and replication, a series of mutations were made which collectively scanned this entire region. Mutation of bases 13 to 28 resulted in markedly decreased HPIV3 minireplicon replication, indicating these bases constitute an additional cis-element involved in the synthesis of the HPIV3 antigenomic RNA. The position dependence of the IS/Ngs was also examined. Analysis of mutants in which the IS/Ngs was shifted 5' or 3' showed that this segment could be moved without significantly disrupting transcription initiation. Additional mutants which contained two successive IS/Ngs segments were created to test whether the polymerase accessed the gene start signal by proceeding along the template 3' to 5' or by binding internally at the gene start signal. Based on analysis of the double gene start mutants, we propose a model of internal transcription initiation in which the polymerase enters the template at approximately the location of the natural N gene start but then scans the template bidirectionally to find a gene start signal and initiate transcription.

A novel role for viral-defective interfering particles in enhancing dendritic cell maturation

Dendritic cell (DC) maturation is a crucial event in the development of adaptive immune responses that confer long-lasting protection against reinfection with the same virus. Sendai virus strain Cantell has a particularly strong ability to mature DCs independently of type I IFNs and TLR signaling, currently the best-described pathways for the induction of DC maturation. In this study, we demonstrate that defective-interfering (DI) particles present in Sendai virus-Cantell stocks are required for its robust DC maturation ability. DI particles contain incomplete genomes that are unable to replicate unless the viral polymerase is supplied by coinfection with complete virus. Accordingly, the improvement in the virus-induced maturation of DCs provided by DI particles requires standard virus coinfection and likely results from increased production of dsRNA replication intermediaries. This unique ability of DI particles to stimulate DC maturation cannot be mimicked by simply increasing the dose of standard virus. Furthermore, viruses with weak DC maturation abilities can be converted into potent DC stimulators with the addition of DI particles, supporting a potential application for DI particles as a novel natural adjuvant for viral immunizations.

The genomic termini of wild-type and vaccine strains of measles virus

The genomic termini from 18 strains of measles virus (MV) including wild-type MVs from the pre-vaccine period, recent wild-type isolates and various vaccine strains were sequenced. The first 25 nucleotides of the 3' terminus and last 52 nucleotides of the 5' terminus were conserved in all of the viruses examined. Nucleotides 26 and 42 of the 3' leader were A and G, respectively, in all genotype A viruses except Edmonston wild-type (Ed-WT). All non-genotype A viruses and Ed-WT had U in both positions. No consistent substitution pattern was found in the 5' trailer region of the genome. The nucleotide substitutions at positions 26 and 42 in the 3' leader region were introduced into a MV-CAT mini-genome to test for their effect on the production of reporter protein in both a vaccinia T7-driven, plasmid-based replication assay as well as in a helper virus system. Regardless of the source of the polymerase proteins or the natural leader sequence of the helper viruses, the mini-genome 26A42G produced more CAT protein than 26U42U. The nucleotide substitution at 26 had the greatest effect on CAT production. These results indicated that naturally occurring nucleotide variations in the 3' leader region can affect the levels of reporter protein synthesis, and presumably affected the level of replication of the virus.

Novel insights into the regulation of the viral polymerase complex of neurotropic Borna disease virus

Borna disease virus (BDV) genetic information is encoded in a highly condensed non-segmented RNA genome of negative polarity. Replication and transcription of the genome occurs in the nucleus, enabling the virus to employ the cellular splicing machinery to process primary transcripts and to regulate expression of viral gene products. BDV establishes a non-cytolytic, persistent infection that in animals is mainly restricted to neurons of the central nervous system. Based on these unique properties, BDV represents the prototype member of the virus family Bornaviridae in the order Mononegavirales. Analysis of molecular aspects of BDV replication has long been hampered by the lack of a reverse genetics system. Only recently, artificial BDV minigenomes permitted the reconstitution of the viral polymerase complex, allowing finally the recovery of BDV from cDNA. As in other families of the Mononegavirales, the active polymerase complex of BDV is composed of the polymerase (L), the nucleoprotein (N) and the phosphoprotein (P). In addition, the viral X protein was identified as potent negative regulator of polymerase activity. Protein interaction studies combined with minireplicon assays suggested that P is a central regulatory element of BDV replication that directs the assembly of the polymerase complex. Most intriguingly, BDV obtained from cDNA with variable genomic termini suggests a novel strategy for viral replication-control. BDV seems to restrict its propagation efficacy by defined 5' terminal trimming of genomic and antigenomic RNA molecules. This review will summarize these novel findings and will discuss them in the context of BDV neurotropism and persistence.

Functional characterization of the genomic promoter of borna disease virus (BDV): implications of 3'-terminal sequence heterogeneity for BDV persistence

Borna disease virus (BDV) is an enveloped virus with a genome organization characteristic of Mononegavirales. However, based on its unique features, BDV is considered the prototypic member of a new virus family, Bornaviridae, within the order Mononegavirales. We have described the establishment of a reverse genetics system for the rescue of BDV RNA analogues, or minigenomes, that is based on the use of polymerase I/polymerase II. Using this BDV minigenome rescue system, we have examined the functional implications of the reported sequence heterogeneity found at the 5' and 3' termini of the BDV genome and also defined the minimal BDV genomic promoter within the 3'-terminal 25 nucleotides. Our results suggest that the accumulation of RNA genome species containing truncations of one to three nucleotides at their 3' termini may contribute to modulate BDV RNA replication and gene expression during long-term persistence.

A role for virus promoters in determining the pathogenesis of Rinderpest virus in cattle

Rinderpest virus (RPV) is a morbillivirus that causes cattle plague, a disease of large ruminants. The viral genome is flanked at the 3′ and 5′ genome termini by the genome promoter (GP) and antigenome promoter (AGP), respectively. These promoters play essential roles in directing replication and transcription as well as RNA encapsidation and packaging. It has previously been shown that individual changes to the GP of RPV greatly affect promoter activity in a minigenome assay and it was therefore proposed that individual nucleotide changes in the GP and AGP might also have significant effects on the ability of the virus to replicate and cause disease in cattle. The Plowright vaccine strain of RPV has been derived by tissue-culture passage from the virulent Kabete ‘O’ isolate (KO) and is highly attenuated for all ruminant species in which it has been used. Here, it was shown that swapping the GP and the first 76 nt of the AGP between virulent and avirulent strains affected disease progression. In particular, it was shown that flanking the virulent strain with the vaccine GP and AGP sequences, while not appreciably affecting virus growth in vitro, led to attenuation in vivo. The reverse was not true, since the KO promoters did not alter the vaccine's attenuated nature. The GP/AGP therefore play a role in attenuation, but are not the only determinants of attenuation in this vaccine.

Mapping of the RNA promoter of Newcastle disease virus

The RNA promoters of the genome and antigenome of Newcastle disease virus (NDV) were studied by mutational analysis of their 3' terminal ends. Similarly to other paramyxoviruses, NDV RNA replication follows the rule of six, and the genomic and antigenomic promoters require two discontinuous regions: conserved region I (first 18 nucleotides) and conserved region II (nucleotides 73-90). Proper spacing between those regions and the phase of six in region II is critical for efficient RNA promoter activity. As expected, the gene start signal at the 3' end of the NDV genome was required for mRNA transcription, but not for RNA replication. Surprisingly, mutation of the polyadenylation signal in the 5' end did not affect gene expression transcription. Although the conserved region I of NDV (avulavirus) promoter appears to be more similar to that of Sendai virus (SeV) (respirovirus), conserved region II is analogous to that of rubulaviruses.

Genome trimming: a unique strategy for replication control employed by Borna disease virus

Genome and antigenome synthesis of negative-strand RNA viruses is initiated at promoters located in inverted terminal repeats (ITR). The ITR of Borna disease virus (BDV), a persisting neurotropic virus with a nuclear replication phase, are exceptional in that they appear to be noncomplete. Our analysis showed that the vast majority of genomic and antigenomic RNA molecules of BDV lack four 5'-terminal nucleotides required for perfect complementarity with the 3' ITR. By using a previously undescribed reverse genetics system, we investigated whether the structure of the ITR would affect virus propagation. BDV rescued from cDNA encoding complete ITR (rBDVc) showed wild-type virulence, whereas virus rescued from cDNA encoding a viral genome with noncomplete ITR (rBDVnc) was strongly attenuated. Both recombinant viruses expressed similar RNA and protein levels in persistently infected cells. However, rBDVnc particles were less infectious, indicating that complete ITR are required for high viral replicase but not transcriptase activity. Interestingly, genomic RNA from purified rBDVc particles lacked 5'-terminal nucleotides like authentic BDV, strongly suggesting programmed genome truncation. By specifically trimming its genome at the 5' terminus, BDV seems to limit viral genome amplification, which may favor noncytolytic viral persistence.

An internal element of the measles virus antigenome promoter modulates replication efficiency

The cis-acting sequence elements that direct measles virus (MV) genome synthesis reside in the 109 base non-coding region at the 5' trailer (3' antigenomic) end of MV genome that makes up the antigenomic promoter (AGP). The MV-AGP nucleotides 79-96, corresponding to nucleotide hexamers 14, 15 and 16 (the C' element), show sequence similarity with the equivalent region of many paramyxoviruses and are analogous to the three nucleotide hexamers that form the second replication control element in the Sendai virus AGP. In this study, results of two independent procedures demonstrate that the MV C' element also is a replication control sequence. Results of in vivo nucleotide selection experiments show that selection pressure for retaining the wild type nucleotides at the first position of each of the three hexamers, and for the fifth position of the 14th hexamer was relatively high. However, with continued replication, preference for the conservation of wild type nucleotides across the entire C' element was clearly evident. Results of mutational analysis of individual nucleotides in one or more hexamers in a measles-helper-virus driven reporter gene rescue system agreed with these results. Substitutions at the first position of the 14th, the 15th or the 16th hexamers reduced minireplicon activity dramatically. In contrast, changes at the other five positions of any one hexamer had little or no effect on minireplicon activity, even when all the five bases were changed at the same time. However, when minireplicons were analyzed which contained point mutations at equivalent positions in all three hexamers, it was evident that the nucleotides, particularly those at the 5th position, were also important components of the C' element. This pattern of sequence requirement in the C' element based on mutational analysis could be described as a distinct motif, 5'-(GNNNAN)2GNNNCN-3', that is important for MV replication.

Sequence analysis of the Washington/1964 strain of human parainfluenza virus type 1 (HPIV1) and recovery and characterization of wild-type recombinant HPIV1 produced by reverse genetics

A complete consensus sequence was determined for the genomic RNA of human parainfluenza virus type 1 (HPIV1) strain Washington/20993/1964 (HPIV1 WASH/64), a clinical isolate that previously was shown to be virulent in adults. The sequence exhibited a high degree of relatedness to both Sendai virus, a PIV1 virus recovered from mice, and human PIV3 (HPIV3) with regard to cis-acting regulatory regions and protein-coding sequences. This consensus sequence was used to generate a full-length antigenomic cDNA and to recover a recombinant wild-type HPIV1 (rHPIV1). Interestingly, the rHPIV1 could be rescued from full-length antigenomic rHPIV1 cDNA using HPIV3 support plasmids, HPIV1 support plasmids, or a mixture thereof. The replication of rHPIV1 in vitro and in the respiratory tract of hamsters was similar to that of its biologically derived parent virus. The similar biological properties of rHPIV1 and HPIV1 WASH/64 in vitro and in vivo, together with the previous demonstration of the virulence of this specific isolate in humans, authenticates the rHPIV1 sequence as that of a wild-type virus. This rHPIV1 can now be used to study the biological properties of HPIV1 and as a substrate to introduce attenuating mutations for the generation of live-attenuated HPIV1 vaccine candidates.

Analysis of the role of predicted RNA secondary structures in Ebola virus replication

Thermodynamic modeling of Ebola viral RNA predicts the formation of RNA stem-loop structures at the 3' and 5' termini and panhandle structures between the termini of the genomic (or antigenomic) RNAs. Sequence analysis showed a high degree of identity among Ebola Zaire, Sudan, Reston, and Cote d'Ivoire subtype viruses in their 3' and 5' termini (18 nucleotides in length) and within a second region (internal by approximately 20 nucleotides). While base pairing of the two conserved regions could lead to the formation of the base of the putative stem-loop or panhandle structures, the intervening sequence variation altered the predictions for the rest of the structures. Using an in vivo minigenome replication system, we engineered mutations designed to disrupt potential base pairing in the viral RNA termini. Analysis of these variants by screening for enhanced green fluorescent protein reporter expression and by quantitation of minigenomic RNA levels demonstrated that the upper portions of the putative panhandle and 3' genomic structures can be destabilized without affecting virus replication.

Positive- and negative-acting signals combine to determine differential RNA replication from the paramyxovirus simian virus 5 genomic and antigenomic promoters

The cis-acting signals found at the 3' ends of the genomic and antigenomic RNAs are a major factor determining the level of paramyxovirus RNA replication from each promoter. Using a minigenome system that reconstitutes SV5 RNA synthesis from cDNA-derived components, we show here that the genomic promoter (GP) for the paramyxovirus SV5 directs RNA replication approximately 14-fold lower than that seen from the antigenomic promoter (AGP). The goal of this study was to identify cis-acting signals responsible for differential levels of RNA replication from the SV5 GP and AGP. We have previously shown that the SV5 AGP contains three sequence-dependent elements (CRI, CRII, and Region III) that are separated by sequence-independent spacer regions. Minigenomes containing chimeric promoters were constructed to test the hypothesis that transfer of discrete cis-acting AGP elements to the GP could confer higher replication properties to the GP. Minigenomes containing a substitution of the AGP CRI, CRII, or Region III elements alone in place of the corresponding GP sequences did not show enhanced levels of RNA replication. However, transfer of both the AGP 3' terminal CRI and Region III elements into the corresponding sites of the GP led to a minigenome which replicated to approximately 40% of the levels seen with the AGP. This enhanced RNA replication from the GP was further increased up to AGP levels by also including the intervening AGP segment (bases 20-50) located between CRI and Region III. Importantly, transfer of nonviral sequences in place of GP bases 20-50 also increased RNA replication to levels approaching that of the AGP, but only in the context of the AGP CRI and Region III substitutions. These data indicate that differential levels of RNA replication from the SV5 GP and AGP are due to a combination of positive-acting signals in the AGP (CRI and Region III) and a negative-acting signal in the GP (bases 20-50). Possible functions for the SV5 promoter elements in determining RNA replication levels are proposed.

Characterization of the genomic promoter of the prototypic arenavirus lymphocytic choriomeningitis virus

The genome of the prototypic arenavirus lymphocytic choriomeningitis virus (LCMV) consists of two negative-sense, single-strand RNA segments designated L and S. Arenavirus genomes exhibit high sequence conservation at their 3' ends. All arenavirus genomes examined to date have a conserved terminal sequence element (3'-terminal 20 nucleotides [nt]) thought to be a highly conserved viral promoter. Terminal complementarity between the 5' and 3' ends of the L and S RNAs predicts the formation of a thermodynamically stable panhandle structure that could contribute to the control of RNA synthesis. We investigated these issues by using a transcription- and replication-competent minireplicon system. A series of overlapping deletions spanning the 3'-terminal 20-nt region of an LCMV minigenome (MG) was generated, and the mutant MGs were analyzed for their activity as templates for RNA synthesis by the LCMV polymerase. The minimal LCMV genomic promoter was found to be contained within the 3'-terminal 19 nt. Substitution of C for G at the last 3'-end nucleotide position in the MG resulted in nondetection of RNA transcription or replication, whereas the addition of a C at the 3' end did not have any significant affect on RNA synthesis mediated by the LCMV polymerase. All other mutations introduced within the 3'-terminal 19 nt of the MG resulted in undetectable levels of promoter activity. Deletions and nucleotide substitutions within the MG 5' end that disrupted terminal complementarity abolished chloramphenicol acetyltransferase expression and RNA synthesis mediated by the LCMV polymerase. These findings indicate that both sequence specificity within the 3'-terminal 19 nt and the integrity of the predicted panhandle structure appear to be required for efficient RNA synthesis mediated by the LCMV polymerase.

A decade after the generation of a negative-sense RNA virus from cloned cDNA - what have we learned?

Since the first generation of a negative-sense RNA virus entirely from cloned cDNA in 1994, similar reverse genetics systems have been established for members of most genera of the Rhabdo- and Paramyxoviridae families, as well as for Ebola virus (Filoviridae). The generation of segmented negative-sense RNA viruses was technically more challenging and has lagged behind the recovery of nonsegmented viruses, primarily because of the difficulty of providing more than one genomic RNA segment. A member of the Bunyaviridae family (whose genome is composed of three RNA segments) was first generated from cloned cDNA in 1996, followed in 1999 by the production of influenza virus, which contains eight RNA segments. Thus, reverse genetics, or the de novo synthesis of negative-sense RNA viruses from cloned cDNA, has become a reliable laboratory method that can be used to study this large group of medically and economically important viruses. It provides a powerful tool for dissecting the virus life cycle, virus assembly, the role of viral proteins in pathogenicity and the interplay of viral proteins with components of the host cell immune response. Finally, reverse genetics has opened the way to develop live attenuated virus vaccines and vaccine vectors.

Identification of mutations associated with attenuation of virulence of a field Sendai virus isolate by egg passage

Abstract. We have reported that attenuation of the virulence of a field Sendai virus (SeV) isolated by egg passage is associated with an impediment of viral genome replication in mouse respiratory cells (Kiyotani et al., Arch Virol 146, 893-908, 2001). To determine the molecular basis for the attenuation, we sequenced entire genomes of representative SeV clones isolated during egg passages and compared those with that of the parental SeV clone E0. E15c2, a 165-fold attenuated clone in 50% mouse lethal dose (MLD50) isolated at the 15th egg passage, possessed only four mutations in the entire genome: U to A at position 20 (U20A) and U24A in the leader promoter region and A9362G and A12174U in the L gene from the 5'-end of antigenome. The former mutation in the L gene was silent and the latter changed deduced amino acid Ser at position 1207 to Cys (Serl207Cys) in the L protein, a catalytic subunit of viral polymerase. E30c12, a further 6-fold attenuated clone isolated at the 30th egg passage, had an additional four mutations: A8074G (Glu461Gly) and A8077G (Asp462Gly) in the hemagglutinin-neuraminidase (HN) gene and A13598C (silent) and G13927A (Ser1791Asn) in the L gene. On the other hand, a virulent revertant clone, E30M15c15, which was obtained by 15 mouse passages of E30c12 and had 250-fold mouse virulence compared to E30c12, possessed eight mutaions: A24U in the leader, C1325U (silent) in the nucleocapsid gene, G8074A (Gly461Glu) in the HN gene, G10433U (Lys626Asn), C13598A (silent), A13927G (Asn1791Ser), C14626U (Thr2024Ile) and A15272C in the L gene. Among these, the mutations in the leader and the HN gene and two of the mutations in the L gene (C13598A and A13927G) were true reversions to E0. The significance of the mutations detected in the leader as well as in the L and HN genes was discussed in the context of attenuation of SeV pathogenicity by egg passage.

Given the opportunity, the Sendai virus RNA-dependent RNA polymerase could as well enter its template internally

The negative-stranded RNA viral genome is an RNA-protein complex of helicoidal symmetry, resistant to nonionic detergent and high salt, in which the RNA is protected from RNase digestion. The 15,384 nucleotides of the Sendai virus genome are bound to 2,564 subunits of the N protein, each interacting with six nucleotides so tightly that the bases are poorly accessible to soluble reagents. With such a uniform structure, the question of template recognition by the viral RNA polymerase has been raised. In a previous study, the N-phase context has been proposed to be crucial for this recognition, a notion referring to the importance of the position in which the nucleotides interact with the N protein. The N-phase context ruled out the role of the template 3'-OH congruence, a feature resulting from the obedience to the rule of six that implies the precise interaction of the last six 3'-OH nucleotides with the last N protein. The N-phase context then allows prediction of the recognition by the RNA polymerase of a replication promoter sequence even if internally positioned, a promoter which normally lies at the template extremity. In this study, with template minireplicons bearing tandem replication promoters separated by intervening sequences, we present data that indeed show that initiation of RNA synthesis takes place at the internal promoter. This internal initiation can best be interpreted as the result of the polymerase entering the template at the internal promoter. In this way, the data are consistent with the importance of the N-phase context in template recognition. Moreover, by introducing between the two promoters a stretch of 10 A residues which represent a barrier for RNA synthesis, we found that the ability of the RNA polymerase to cross this barrier depends on the type of replication promoter, strong or weak, that the RNA polymerase starts on, a sign that the RNA polymerase may be somehow imprinted in its activity by the nature of the promoter on which it starts synthesis.

"Rule of six": how does the Sendai virus RNA polymerase keep count?

The "rule of six" stipulates that the Paramyxovirus RNA polymerase efficiently replicates only viral genomes counting 6n + 0 nucleotides. Because the nucleocapsid proteins (N) interact with 6 nucleotides, an exact nucleotide-N match at the RNA 3'-OH end (3'-OH congruence) may be required for recognition of an active replication promoter. Alternatively, assuming that the six positions for the interaction of N with the nucleotides are not equivalent, the nucleotide position relative to N may be critical (N phase context). The replication abilities of various minireplicons, designed so that the 3'-OH congruence could be discriminated from the N phase context, were studied. The results strongly suggest that the application of the rule of six depends on the recognition of nucleotides positioned in the proper N phase context.

RNA replication from the simian virus 5 antigenomic promoter requires three sequence-dependent elements separated by sequence-independent spacer regions

We have previously shown for the paramyxovirus simian virus 5 (SV5) that a functional promoter for RNA replication requires proper spacing between two discontinuous elements: a 19-base segment at the 3' terminus (conserved region I [CRI]) and an 18-base internal region (CRII) that is contained within the coding region of the L protein gene. In the work described here, we have used a reverse-genetics system to determine if the 53-base segment between CRI and CRII contains additional sequence-specific signals required for optimal replication or if this segment functions solely as a sequence-independent spacer region. A series of copyback defective interfering minigenome analogs were constructed to contain substitutions of nonviral sequences in place of bases 21 to 72 of the antigenomic promoter, and the relative level of RNA replication was measured by Northern blot analysis. The results from our mutational analysis indicate that in addition to CRI and CRII, optimal replication from the SV5 antigenomic promoter requires a third sequence-dependent element located 51 to 66 bases from the 3' end of the RNA. Minigenome RNA replication was not affected by changes in the either the position of this element in relation to CRI and CRII or the predicted hexamer phase of NP encapsidation. Thus, optimal RNA replication from the SV5 antigenomic promoter requires three sequence-dependent elements, CRI, CRII and bases 51 to 66.

Functional analysis of the genomic and antigenomic promoters of human respiratory syncytial virus

The promoters involved in transcription and RNA replication by respiratory syncytial virus (RSV) were examined by using a plasmid-based minireplicon system. The 3' ends of the genome and antigenome, which, respectively, contain the 44-nucleotide (nt) leader (Le) and 155-nt trailer-complement (TrC) regions, should each contain a promoter for RNA replication. The 3' genome end also should have the promoter for transcription. Substitution for the Le with various lengths of TrC demonstrated that the 3'-terminal 36 nt of TrC are sufficient for extensive (but not maximal) replication and that when juxtaposed with a transcription gene-start (GS) signal, this sequence was also able to direct transcription. It was also shown that the region of Le immediately preceding the GS signal of the first gene could be deleted with either no effect or with a slight decrease in transcription initiation. Thus, the TrC is competent to direct transcription even though it does not do so in nature, and the partial sequence identity it shares with the 3' end of the genome likely represents the important elements of a conserved promoter active in both replication and transcription. Increasing the length of the introduced TrC sequence incrementally to 147 nt resulted in a fourfold increase in replication and a nearly complete inhibition of transcription. These two effects were unrelated, implying that transcription and replication are not interconvertible processes mediated by a common polymerase, but rather are independent processes. The increase in replication was specific to the TrC sequence, implying the presence of a nonessential, replication-enhancing cis-acting element. In contrast, the inhibitory effect on transcription was due solely to the altered spacing between the 3' end of the genome and GS signal, which implies that the transcriptase recognizes the first GS signal as a promoter element. Neither the enhancement of replication nor the inhibition of transcription was due to increased base-pairing potential between the 3' and 5' ends. The relative strengths of the Le and TrC promoters for directing RNA synthesis were compared and found to be very similar. Thus, these findings highlighted a high degree of functional similarity between the RSV antigenomic and genomic promoters, but provided a further distinction between promoter requirements for transcription and replication.

Analysis of RNA secondary structure in replication of human parainfluenza virus type 3

The terminal RNA regions of the genomic and antigenomic RNAs of the paramyxoviruses and rhabdoviruses are known to contain sequences essential for RNA replication and transcription. The 3'- and 5'-termini of human parainfluenza virus type 3 (HPIV3) genomic RNA, termed leader and trailer sequences, respectively, are capable of forming stable stem-loop structures. Additionally, the 17 terminal bases of the leader and trailer are complementary and therefore also capable of forming a helical structure. We investigated the roles of the stem-loop structure and terminal complementarity in HPIV3 RNA replication and transcription in vivo using a minigenome containing all RNA elements necessary for these processes. By mutational analysis, we show that the RNA secondary structure features present at the termini of HPIV3 have no discernible role in replication or transcription. Rather, the primary sequence of these regions is what is critical in promoting replication. Interestingly, a mutation at leader base 24 was found to revert a mutation at leader position 5 but probably not via RNA secondary structure restoration.

Precise mapping of the replication and transcription promoters of human parainfluenza virus type 3

The terminal RNA regions of the genomic and antigenomic RNAs of the paramyxoviruses and rhabdoviruses are known to contain sequences essential for directing RNA replication and transcription. The 3' terminus (leader region) of the negative-sense, genomic RNA of the rhabdoviruses and paramyxoviruses is known as the leader (Le) promoter and directs synthesis of positive-sense replication and transcription products. The 3' terminus of the antigenome is termed the trailer complementary (TrC) promoter and directs the synthesis of genomic RNA. By creating mutations in the corresponding regions of an HPIV3 minireplicon in which the viral protein coding sequences were replaced by the luciferase gene, we were able to precisely define the elements of the leader promoter involved in directing positive-strand replication of HPIV3. Nucleotides 1 through 12 (from the terminus) formed a domain critical for replication. The region from nucleotides 13 through 55 was important but not crucial for replication, while G residues at positions 79, 85, and 91 comprised another domain critical for replication. It was also shown that the TrC promoter is similar, though not identical, to the Le promoter. Nucleotides 1 through 12 of the TrC promoter were critical for synthesis of genomic RNA, though specific positions behaved differently from the corresponding positions of the Le promoter. While many of these mutations could not be analyzed for transcription because they completely abrogated genomic RNA synthesis (the template for transcription), we were surprised to find that no mutations in the leader promoter which decreased replication had any significant effect on transcription. However, mutations in the intergenic sequence and gene start signal following the leader and preceding the luciferase message severely decreased transcription, but not replication.

Mutations in the 5' trailer region of a respiratory syncytial virus minigenome which limit RNA replication to one step

The 3' termini of the genomic and antigenomic RNAs of human respiratory syncytial virus (RSV) are identical at 10 of the first 11 nucleotide positions and 21 of the first 26 positions. These conserved 3'-terminal sequences are thought to contain the genomic and antigenomic promoters. Furthermore, the complement of each conserved sequence (i.e., the 5' end of the RNA it encodes) might contain an encapsidation signal. Using an RSV minigenome system, we individually mutated each of the last seven nucleotides in the 5' trailer region of the genome. We analyzed effects of these mutations on encapsidation of the T7 polymerase-transcribed negative-sense genome, its ability to function as a template for RSV-driven synthesis of positive-sense antigenome and mRNA, and the ability of this antigenome to be encapsidated and to function as template for the synthesis of more genome. As a technical complication, mutations in the last five nucleotides of the trailer region were found to affect the efficiency of the adjoining T7 promoter over more than a 10-fold range, even though three nonviral G residues had been included between the core promoter and the trailer to maximize the efficiency of promoter activity. This was controlled in all experiments by monitoring the levels of total and encapsidated genome. The efficiency of encapsidation of the T7 polymerase-transcribed genome was not affected by any of the trailer mutations. Furthermore, neither the efficiency of positive-sense RNA synthesis from the genome nor the efficiency of encapsidation of the encoded antigenome was affected by the mutations. However, nucleotide substitution at positions 2, 3, 6, or 7 relative to the 5' end of the trailer blocked the production of progeny genome, whereas substitution at positions 1 and 5 allowed a low level of genome production and substitutions at position 4 were tolerated. Position 4 is the only one of the seven positions examined that is not conserved between the 3' ends of genomic and antigenomic RNA. The mutations that blocked the synthesis of progeny genome thus limited RNA replication to one step, namely, the synthesis and encapsidation of antigenome. Restoration of terminal complementarity for one of the trailer mutants by making a compensatory mutation in the leader region did not restore synthesis of genomic RNA, confirming that its loss was not due to reduced terminal complementarity. Interestingly, this leader mutation appeared to prevent antigenome synthesis with only a slight effect on mRNA synthesis, apparently providing a dissociation between these two synthetic activities. Genomes in which the terminal 24 or 325 nucleotides of the trailer have been deleted were competent for encapsidation and the synthesis of mRNA and antigenomic RNA, further confirming that terminal complementarity was not required for these functions.

Replication of paramyxoviruses

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

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

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

Nonsegmented negative-strand RNA viruses: genetics and manipulation of viral genomes

Protocols to recover negative-stand RNA viruses entirely from cDNA have been established in recent years, opening up this virus group to the detailed analysis of molecular genetics and virus biology. The unique gene-expression strategy of nonsegmented negative-strand RNA viruses, which involves replication of ribonucleoprotein complexes and sequential synthesis of free mRNAs, has also allowed the use of these viruses to express heterologous sequences. There are advantages in terms of easy manipulation of constructs, high capacity for foreign sequences, genetically stable expression, and the possibility of adjusting expression levels. Fascinating prospects for biomedical applications and transient gene therapy are offered by chimeric virus vectors carrying novel envelope protein genes and targeted to defined host cells.

Regulation of RNA synthesis by the genomic termini of vesicular stomatitis virus: identification of distinct sequences essential for transcription but not replication

The RNA-dependent RNA polymerase of vesicular stomatitis virus (VSV), a nonsegmented negative-strand RNA virus, directs two discrete RNA synthetic processes, transcription and replication. Available evidence suggests that the two short extragenic regions at the genomic termini, the 3' leader (Le) and the complement of the 5' trailer (TrC), contain essential signals for these processes. We examined the roles in transcription and replication of sequences in Le and TrC by monitoring the effects of alterations to the termini of subgenomic replicons, or infectious viruses, on these RNA synthetic processes. Distinct elements in Le were found to be required for transcription that were not required for replication. The promoter for mRNA transcription was shown to include specific sequence elements within Le at positions 19 to 29 and 34 to 46, a separate element at nucleotides 47 to 50, the nontranscribed leader-N gene junction. The sequence requirements for transcription within the Le region could not be supplied by sequences found at the equivalent positions in TrC. In contrast, sequences from either Le or TrC functioned well to signal replication, indicating that within the confines of the VSV termini, the sequence requirements for replication were less stringent. Deletions engineered at the termini showed that the terminal 15 nucleotides of either Le or TrC allowed a minimal level of replication. Within these confines, levels of replication were affected by both the extent of complementarity between the genomic termini and the involvement of the template in transcription. In agreement with our previous observations, increasing the extent of complementarity between the natural termini increased levels of replication, and this effect was most operative at the extreme genome ends. In addition, abolishing the use of Le as a promoter for transcription enhanced replication. These analyses (i) identified signals at the termini required for transcription and replication and (ii) showed that Le functions as a less efficient promoter for replication than TrC at least in part because of its essential role in transcription. Consequently, these observations help explain the asymmetry of VSV replication which results in the synthesis of more negative- than positive-sense replication products in infected cells.

The short Sendai virus leader region controls induction of programmed cell death

The replication of nonsegmented minus-strand RNA genomes, like that of Sendai paramyxovirus (SeV), are controlled by the short leader regions present at each end of the linear genomes and antigenomes; the left and right promoters (PL and PR), respectively. Wild-type SeV is highly cytopathic in cell culture, because it induces programmed cell death (PCD). We have found that a recombinant SeV (rSeVGP42), in which the first 42 nt of le+ sequences at PL were replaced with the equivalent sequences of PR, and which produces infectious virus in amounts comparable to wild type, does not kill cells. Further, the increasing replacement of the terminal le+ sequences at PL with le- sequences led to a decreasing fraction of infected cells being apoptotic. This property (PCD-), moreover, is dominant in cells co-infected with SeVwt and rSeVGP42, and the mutant virus therefore appears to have gained a function which prevents PCD induced by SeVwt. Even though this virus has not been selected for naturally, it excludes SeVwt during co-infections of cultured cells or embryonated chicken eggs. The noncytopathic nature of cells infected or co-infected with rSeVGP42 leads automatically to stable, persistent infections. The mutation in rSeVGP42 is not in the protein coding regions of the viral genome, but in the 55-nt-long leader region which controls antigenome synthesis from genome templates. The SeV leader regions, which are expressed as short RNAs, thus appear to control the induction of PCD.

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 functional antigenomic promoter for the paramyxovirus simian virus 5 requires proper spacing between an essential internal segment and the 3' terminus

A previous analysis of naturally occurring defective interfering (DI) RNA genomes of the prototypic paramyxovirus simian virus 5 (SV5) indicated that 113 bases at the 3' terminus of the antigenome were sufficient to direct RNA encapsidation and replication. A nucleotide sequence alignment of the antigenomic 3'-terminal 113 bases of members of the Rubulavirus genus of the Paramyxoviridae family identified two regions of sequence identity: bases 1 to 19 at the 3' terminus (conserved region I [CRI]) and a more distal region consisting of antigenome bases 73 to 90 (CRII) that was contained within the 3' coding region of the L protein gene. To determine whether these regions of the antigenome were essential for SV5 RNA replication, a reverse genetics system was used to analyze the replication of copyback DI RNA analogs that contained a foreign gene (GL, encoding green fluorescence protein) flanked by 113 5'-terminal bases and various amounts of SV5 3'-terminal antigenomic sequences. Results from a deletion analysis showed that efficient encapsidation and replication of SV5-GL DI RNA analogs occurred when the 90 3'-terminal bases of the SV5 antigenomic RNA were retained, but replication was reduced approximately 5- to 14-fold in the case of truncated antigenomes that lacked the 3'-end CRII sequences. A chimeric copyback DI RNA containing the 3'-terminal 98 bases including the CRI and CRII sequences from the human parainfluenza virus type 2 (HPIV2) antigenome in place of the corresponding SV5 sequences was efficiently replicated by SV5 cDNA-derived components. However, replication was reduced approximately 20-fold for a truncated SV5-HPIV2 chimeric RNA that lacked the HPIV2 CRII sequences between antigenome bases 72 and 90. Progressive deletions of 6 to 18 bases in the region located between the SV5 antigenomic CRI and CRII segments (3'-end nucleotides 21 to 38) resulted in a approximately 25-fold decrease in SV5-GL RNA synthesis. Surprisingly, replication was restored to wild-type levels when these length alterations between CRI and CRII were corrected by replacing the deleted bases with nonviral sequences. Together, these data suggest that a functional SV5 antigenomic promoter requires proper spacing between an essential internal region and the 3' terminus. A model is presented for the structure of the 3' end of the SV5 antigenome which proposes that positioning of CRI and CRII along the same face of the helical nucleocapsid is an essential feature of a functional antigenomic promoter.

Inhibition of Sendai virus genome replication due to promoter-increased selectivity: a possible role for the accessory C proteins

The role of the negative-stranded virus accessory C proteins is difficult to assess because they appear sometimes as nonessential and thereby of no function. On the other hand, when a function is found, as in the case of Sendai virus, it represents an enigma, in that the C proteins inhibit replication under conditions where the infection follows an exponential course. Furthermore, this inhibitory function is exerted differentially: in contrast to the replication of internal deletion defective interfering (DI) RNAs, that of copy-back DI RNAs appears to escape inhibition, under certain experimental conditions (in vivo assay). In a reexamination of the C effect by the reverse genetics approach, it was found that copy-back RNA replication is inhibited by C in vivo as well, under conditions where the ratio of C to copy-back template is increased. This effect can be reversed by an increase in P but not L protein. The "rule of six" was differentially observed in the presence or absence of C. Finally, a difference in the ability of the replicating complex to tolerate promoter modifications in RNA synthesis initiation was shown to occur in the presence or the absence of C as well. We propose that C acts by increasing the selectivity of the replicating complex for the promoter cis-acting elements governing its activity. The inhibitory effect of C becomes the price to pay for this increased selectivity.

Ambisense gene expression from recombinant rabies virus: random packaging of positive- and negative-strand ribonucleoprotein complexes into rabies virions

We have recovered from cDNA a rabies virus (RV) containing identical, transcriptionally active promoters at its genome (negative-strand) and antigenome RNA and directing efficient expression of a chloramphenicol acetyltransferase (CAT) reporter gene from the antigenome. Transcription of the antigenome CAT gene was terminated by a modified RV gene junction able to mediate transcription stop and polyadenylation but not reinitiation of downstream transcripts. While in standard RV-infected cells genome and antigenome RNAs were present in a 49:1 ratio, the ambisense virus directed synthesis of equal amounts of genome and antigenome RNA (1:1). Total replicative synthesis was reduced by a factor of less than 2, revealing an unexpectedly high level of replication activity of the transcriptionally active promoter in the absence of the parental antigenome promoter. Successful packaging of ambisense ribonucleoprotein complexes (RNPs) into virions demonstrated that the parental 5' end of the RV genome RNA does not contain putative signals required for incorporation into virions. As determined both for standard RV and ambisense RV, virus particles contained genome and antigenome RNPs in the same ratios as those present in infected cells (49:1 and 1:1, respectively), indicating indiscriminate incorporation of RNPs independent of signals in the RNA. Ambisense expression of multiple foreign genes from RV vectors may circumvent problems with transcriptional attenuation of rhabdovirus housekeeping genes.

Replication signals in the genome of vesicular stomatitis virus and its defective interfering particles: identification of a sequence element that enhances DI RNA replication

We have analyzed the role of terminal sequences of a defective interfering (DI) particle RNA of vesicular stomatitis virus (VSV) in replication. A series of internal deletion mutants of DI cDNA was generated to obtain DI genomic RNAs that differed from one another by the presence of different lengths of 3'-terminal and/or 5'-terminal sequences. Analyses of the mutant. RNAs for their ability to replicate in cells transfected with the corresponding plasmids suggested that distinct regions at the termini of DI RNA are important for RNA replication. Region I, encompassing nucleotides 1-24, is absolutely required for replication since DI RNA genomes lacking any part of this region failed to replicate. Region II, spanning nucleotides 25-45, is not essential for replication but it functions as an enhancer of replication in that the presence of these specific sequences confers high efficiency of replication to the template. Deleting these specific sequences from both termini of DI RNA but maintaining the length of terminal complementarity as seen in wild-type DI RNA resulted in a template that replicated poorly (about 20-fold less efficiently). Furthermore, insertion or substitution of these sequences into the 3'-terminus of a VSV minigenome resulted in a template that replicated more efficiently (at least 4-fold to as high as 15-fold) than the parental minigenome. These results strongly support the conclusion that the presence of specific sequences rather than the extent of complementarity at the termini of DI RNA is a major determinant of the efficiency of replication. The presence of the specific sequences at the 3'-terminus of both genomic and antigenomic DI RNAs may explain in part the replicative dominance of DI RNA over the full-length VSV genome which contains these sequences only at the 3'-terminus of the antigenome.

Genome nucleotide lengths that are divisible by six are not essential but enhance replication of defective interfering RNAs of the paramyxovirus simian virus 5

For some members of the Paramyxoviridae family of negative strand RNA viruses, efficient genome replication only occurs when the total genome length is a multiple of six (6N length, where N is any integer). To determine if this "rule of six" requirement applied to the replication of the prototype paramyxovirus simian virus 5 (SV5), defective interfering (DI) RNA genomes were generated by sequential undiluted passage of virus in tissue culture. Molecular cloning and nucleotide sequence analysis of 10 RNA genomes revealed a series of copyback DI RNAs with chain lengths between 449 and 1365 bases, but only 4 of the 10 naturally occurring RNA genomes were of 6N length. Many of the cloned DI genomes could be grouped into two distinct nested sets, with the members of each set having the same polymerase crossover junctions and extent of terminal complementarity but differing from each other by internal deletions. One of these nested sets of genomes consisted of novel DI RNAs that contained a pentameric stretch of nontemplated adenosine residues inserted precisely at the polymerase crossover junction. A reverse genetics system was established in which SV5 DI genomes were replicated in vivo entirely by cDNA-derived components. Using this system, two naturally occurring SV5 DI RNAs were examined in a mutational analysis to determine the role of genome length on SV5 RNA replication. The progressive insertion of one to six nucleotides into a 6N length DI genome (852 bases) resulted in a reduction in replication for RNAs that contained one to four additional bases (approximately 35-50% of WT levels), followed by an increase back to WT replication levels for genomes that were altered by five and six base insertions (approximately 70 and 100% of WT levels, respectively). An insertion of five nucleotides into a second non-6N length DI RNA (499 total bases) created a genome length that was a multiple of six (504 bases) and led to a approximately 10-fold stimulation of replication over that of the unaltered genome. Together, these results indicate that there was a clear influence of 6N genome length on SV5 DI RNA replication, but the stringency of this replication requirement appeared to be less than that found previously for other paramyxoviruses. This work completes the testing of the rule of six replication requirement for representatives of each of the four genera of the Paramyxoviridae family and indicates that the preference for replication of 6N length RNA genomes varies between the individual paramyxoviruses.