Subgenomic RNA promoters dictate the mode of recognition by bromoviral RNA-dependent RNA polymerases

Positive strand RNA viruses differ in the constraints they place on the folding of their negative strand

Genome replication of positive strand RNA viruses requires the production of a complementary negative strand RNA that serves as a template for synthesis of more positive strand progeny. Structural RNA elements are important for genome replication, but while they are readily observed in the positive strand, evidence of their existence in the negative strand is more limited. We hypothesized that this was due to viruses differing in their capacity to allow this latter RNA to adopt structural folds. To investigate this, ribozymes were introduced into the negative strand of different viral constructs; the expectation being that if RNA folding occurred, negative strand cleavage and suppression of replication would be seen. Indeed, this was what happened with hepatitis C virus (HCV) and feline calicivirus (FCV) constructs. However, little or no impact was observed for chikungunya virus (CHIKV), human rhinovirus (HRV), hepatitis E virus (HEV), and yellow fever virus (YFV) constructs. Reduced cleavage in the negative strand proved to be due to duplex formation with the positive strand. Interestingly, ribozyme-containing RNAs also remained intact when produced in vitro by the HCV polymerase, again due to duplex formation. Overall, our results show that there are important differences in the conformational constraints imposed on the folding of the negative strand between different positive strand RNA viruses.

Functional insights into the role of C-terminal disordered domain of Sesbania mosaic virus RNA-dependent RNA polymerase and the coat protein in viral replication in vivo

The C-terminal disordered domain of sesbania mosaic virus (SeMV) RNA-dependent RNA polymerase (RdRp) interacts with the viral protein P10. The functional significance of this interaction in viral replication was examined by a comparative analysis of genomic and sub-genomic RNA levels (obtained by quantitative real time PCR) in the total RNA extracted from Cyamopsis plants agro-infiltrated with wild-type or mutant forms of SeMV infectious cDNA (icDNA). The sgRNA copy numbers were found to be significantly higher than those of gRNA in the wild-type icDNA transfected plants. Transfection of a mutant icDNA expressing an RdRp lacking the C-terminal disordered domain led to a drastic reduction in the copy numbers of both forms of viral RNA. This could be due to the loss of interaction between the disordered domain of RdRp and P10 and possibly other viral/host proteins that might be required for the assembly of viral replicase. The C-terminal disordered domain also harbours the motif E which is essential for the catalytic function of RdRp. Mutation of the conserved tyrosine within this motif in the full length icDNA resulted in complete inhibition of progeny RNA synthesis in the transfected plants confirming the importance of motif E in the polymerase function in vivo. The role of coat protein (CP) in viral infection was also investigated by agro-infiltration of a CP start codon mutant icDNA which suggested that CP is essential for the encapsidation of viral progeny RNAs at later stages of infection.

Roles of the genomic sequence surrounding the stem-loop structure in the junction region including the 3' terminus of open reading frame 1 in hepatitis E virus replication

Hepatitis E virus (HEV), a member of the family Hepeviridae, causes both acute and chronic viral hepatitis. We have previously demonstrated that the stem-loop structure in the junction region (JR) of HEV genome plays a critical role in HEV replication. However, the function of the sequence bordering the JR, including the 3' terminus of open reading frame (ORF1), in HEV replication is unknown. In this study, a panel of HEV Renilla luciferase (Rluc) replicons containing various deletions at 5' or 3' termini of the JR was constructed to determine the effect of the deletions on HEV replication in Huh7 human liver cells. We showed that even a single nucleotide deletion at the 5' terminus of the JR abolished HEV replication, whereas deletions at the 3' terminus of the JR also decreased virus replication efficiency. Furthermore, we also constructed firefly luciferase and Rluc dual-reporter HEV replicons containing the 3' terminal ORF1 of various lengths and the JR inserted upstream of the Rluc reporter. A higher level of HEV replication was observed in cells transfected with replicons containing the 3' terminal ORF1 than that of the JR only replicon. We also showed that the ORF3 noncoding sequence along with the JR promoted a higher level of translation activity than that promoted by JR and the ORF2 noncoding sequence.

Subgenomic promoter recognition by the norovirus RNA-dependent RNA polymerases

The replication enzyme of RNA viruses must preferentially recognize their RNAs in an environment that contains an abundance of cellular RNAs. The factors responsible for specific RNA recognition are not well understood, in part because viral RNA synthesis takes place within enzyme complexes associated with modified cellular membrane compartments. Recombinant RNA-dependent RNA polymerases (RdRps) from the human norovirus and the murine norovirus (MNV) were found to preferentially recognize RNA segments that contain the promoter and a short template sequence for subgenomic RNA synthesis. Both the promoter and template sequence contribute to stable RdRp binding, accurate initiation of the subgenomic RNAs and efficient RNA synthesis. Using a method that combines RNA crosslinking and mass spectrometry, residues near the template channel of the MNV RdRp were found to contact the hairpin RNA motif. Mutations in the hairpin contact site in the MNV RdRp reduced MNV replication and virus production in cells. This work demonstrates that the specific recognition of the norovirus subgenomic promoter is through binding by the viral RdRp.

The molecular biology of ilarviruses

Ilarviruses were among the first 16 groups of plant viruses approved by ICTV. Like Alfalfa mosaic virus (AMV), bromoviruses, and cucumoviruses they are isometric viruses and possess a single-stranded, tripartite RNA genome. However, unlike these other three groups, ilarviruses were recognized as being recalcitrant subjects for research (their ready lability is reflected in the sigla used to create the group name) and were renowned as unpromising subjects for the production of antisera. However, it was recognized that they shared properties with AMV when the phenomenon of genome activation, in which the coat protein (CP) of the virus is required to be present to initiate infection, was demonstrated to cross group boundaries. The CP of AMV could activate the genome of an ilarvirus and vice versa. Development of the molecular information for ilarviruses lagged behind the knowledge available for the more extensively studied AMV, bromoviruses, and cucumoviruses. In the past 20 years, genomic data for most known ilarviruses have been developed facilitating their detection and allowing the factors involved in the molecular biology of the genus to be investigated. Much information has been obtained using Prunus necrotic ringspot virus and the more extensively studied AMV. A relationship between some ilarviruses and the cucumoviruses has been defined with the recognition that members of both genera encode a 2b protein involved in RNA silencing and long distance viral movement. Here, we present a review of the current knowledge of both the taxonomy and the molecular biology of this genus of agronomically and horticulturally important viruses.

The subgenomic promoter of brome mosaic virus folds into a stem-loop structure capped by a pseudo-triloop that is structurally similar to the triloop of the genomic promoter

In brome mosaic virus, both the replication of the genomic (+)-RNA strands and the transcription of the subgenomic RNA are carried out by the viral replicase. The production of (-)-RNA strands is dependent on the formation of an AUA triloop in the stem-loop C (SLC) hairpin in the 3'-untranslated region of the (+)-RNA strands. Two alternate hypotheses have been put forward for the mechanism of subgenomic RNA transcription. One posits that transcription commences by recognition of at least four key nucleotides in the subgenomic promoter by the replicase. The other posits that subgenomic transcription starts by binding of the replicase to a hairpin formed by the subgenomic promoter that resembles the minus strand promoter hairpin SLC. In this study, we have determined the three-dimensional structure of the subgenomic promoter hairpin using NMR spectroscopy. The data show that the hairpin is stable at 30°C and that it forms a pseudo-triloop structure with a transloop base pair and a nucleotide completely excluded from the helix. The transloop base pair is capped by an AUA triloop that possesses an extremely well packed structure very similar to that of the AUA triloop of SLC, including the formation of a so-called clamped-adenine motif. The similarities of the NMR structures of the hairpins required for genomic RNA and subgenomic RNA synthesis show that the replicase recognizes structure rather than sequence-specific motifs in both promoters.

RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase in human cells reveals requirements for de novo initiation and protein-protein interaction

Brome mosaic virus (BMV) is a model positive-strand RNA virus whose replication has been studied in a number of surrogate hosts. In transiently transfected human cells, the BMV polymerase 2a activated signaling by the innate immune receptor RIG-I, which recognizes de novo-initiated non-self-RNAs. Active-site mutations in 2a abolished RIG-I activation, and coexpression of the BMV 1a protein stimulated 2a activity. Mutations previously shown to abolish 1a and 2a interaction prevented the 1a-dependent enhancement of 2a activity. New insights into 1a-2a interaction include the findings that helicase active site of 1a is required to enhance 2a polymerase activity and that negatively charged amino acid residues between positions 110 and 120 of 2a contribute to interaction with the 1a helicase-like domain but not to the intrinsic polymerase activity. Confocal fluorescence microscopy revealed that the BMV 1a and 2a colocalized to perinuclear region in human cells. However, no perinuclear spherule-like structures were detected in human cells by immunoelectron microscopy. Sequencing of the RNAs coimmunoprecipitated with RIG-I revealed that the 2a-synthesized short RNAs are derived from the message used to translate 2a. That is, 2a exhibits a strong cis preference for BMV RNA2. Strikingly, the 2a RNA products had initiation sequences (5'-GUAAA-3') identical to those from the 5' sequence of the BMV genomic RNA2 and RNA3. These results show that the BMV 2a polymerase does not require other BMV proteins to initiate RNA synthesis but that the 1a helicase domain, and likely helicase activity, can affect RNA synthesis by 2a.

Subgenomic messenger RNAs: mastering regulation of (+)-strand RNA virus life cycle

Many (+)-strand RNA viruses use subgenomic (SG) RNAs as messengers for protein expression, or to regulate their viral life cycle. Three different mechanisms have been described for the synthesis of SG RNAs. The first mechanism involves internal initiation on a (−)-strand RNA template and requires an internal SGP promoter. The second mechanism makes a prematurely terminated (−)-strand RNA which is used as template to make the SG RNA. The third mechanism uses discontinuous RNA synthesis while making the (−)-strand RNA templates. Most SG RNAs are translated into structural proteins or proteins related to pathogenesis: however other SG RNAs regulate the transition between translation and replication, function as riboregulators of replication or translation, or support RNA–RNA recombination. In this review we discuss these functions of SG RNAs and how they influence viral replication, translation and recombination.

RNA-RNA recombination in plant virus replication and evolution

RNA-RNA recombination is one of the strongest forces shaping the genomes of plant RNA viruses. The detection of recombination is a challenging task that prompted the development of both in vitro and in vivo experimental systems. In the divided genome of Brome mosaic virus system, both inter- and intrasegmental crossovers are described. Other systems utilize satellite or defective interfering RNAs (DI-RNAs) of Turnip crinkle virus, Tomato bushy stunt virus, Cucumber necrosis virus, and Potato virus X. These assays identified the mechanistic details of the recombination process, revealing the role of RNA structure and proteins in the replicase-mediated copy-choice mechanism. In copy choice, the polymerase and the nascent RNA chain from which it is synthesized switch from one RNA template to another. RNA recombination was found to mediate the rearrangement of viral genes, the repair of deleterious mutations, and the acquisition of nonself sequences influencing the phylogenetics of viral taxa. The evidence for recombination, not only between related viruses but also among distantly related viruses, and even with host RNAs, suggests that plant viruses unabashedly test recombination with any genetic material at hand.

Analyses of subgenomic promoters of Hibiscus chlorotic ringspot virus and demonstration of 5' untranslated region and 3'-terminal sequences functioning as subgenomic promoters

Hibiscus chlorotic ringspot virus (HCRSV), which belongs to the genus Carmovirus, generates two 3'-coterminal subgenomic RNAs (sgRNAs) of 1.4 kb and 1.7 kb. Transcription start sites of the two sgRNAs were identified at nucleotides (nt) 2178 and 2438, respectively. The full promoter of sgRNA1, a 118-base sequence, is localized between positions +6 and -112 relative to its transcription start site (+1). Similarly, a 132-base sequence, from +6 to -126, defines the sgRNA2 promoter. Computer analysis revealed that both sgRNA promoters share a similar two-stem-loop (SL1 + SL2) structure, immediately upstream of the transcription start site. Mutational analysis of the primary sequence and secondary structures showed further similarities between the two subgenomic promoters. The basal portion of SL2, encompassing the transcription start site, was essential for transcription activity in each promoter, while SL1 and the upper portion of SL2 played a role in transcription enhancement. Both the 5' untranslated region (UTR) and the last 87 nt at the 3' UTR of HCRSV genomic RNA are likely to be the putative genomic plus-strand and minus-strand promoters, respectively. They function well as individual sgRNA promoters to produce ectopic subgenomic RNAs in vivo but not to the same levels of the actual sgRNA promoters. This suggests that HCRSV sgRNA promoters share common features with the promoters for genomic plus-strand and minus-strand RNA synthesis. To our knowledge, this is the first demonstration that both the 5' UTR and part of the 3' UTR can be duplicated and function as sgRNA promoters within a single viral genome.

A cell-free system for the synthesis of Sindbis virus subgenomic RNA: importance of the concentration of the initiating NTP

We describe here an in vitro system for template-dependent initiation and synthesis of a Sindbis virus (SV) subgenomic (SG) RNA transcript. The critical components of this system were (1) a minus-strand promoter-template corresponding to the region of the SV genome from nt 7441 to nt 7772 (-157 to +175 relative to the SG RNA transcription initiation site at nt 7598), and (2) a p15 fraction from cells infected with recombinant vaccinia viruses expressing the SV nonstructural proteins, P123 and nsP4 (the nsP2 coding region in P123 contained a mutation which results in more rapid than normal processing of P123). Our data indicate that the SG RNA transcript is of the expected size, of positive polarity, and is initiated at the expected site. Changing the +1 nt from A to G, U, or C resulted in decreased synthesis of the SG RNA transcript. However, in each case, increasing the concentration of the initiating NTP restored synthesis of the transcript to the wild-type level. This is the first demonstration of an in vitro synthesis of an alphavirus SG RNA transcript which is dependent on the addition of an exogenous promoter-template. As such, it will make possible new approaches for learning how the synthesis of SG RNA is regulated.

Mutual interference between genomic RNA replication and subgenomic mRNA transcription in brome mosaic virus

Replication by many positive-strand RNA viruses includes genomic RNA amplification and subgenomic mRNA (sgRNA) transcription. For brome mosaic virus (BMV), both processes occur in virus-induced, membrane-associated compartments, require BMV replication factors 1a and 2a, and use negative-strand RNA3 as a template for genomic RNA3 and sgRNA syntheses. To begin elucidating their relations, we examined the interaction of RNA3 replication and sgRNA transcription in Saccharomyces cerevisiae expressing 1a and 2a, which support the full RNA3 replication cycle. Blocking sgRNA transcription stimulated RNA3 replication by up to 350%, implying that sgRNA transcription inhibits RNA3 replication. Such inhibition was independent of the sgRNA-encoded coat protein and operated in cis. We further found that sgRNA transcription inhibited RNA3 replication at a step or steps after negative-strand RNA3 synthesis, implying competition with positive-strand RNA3 synthesis for negative-strand RNA3 templates, viral replication factors, or common host components. Consistent with this, sgRNA transcription was stimulated by up to 400% when mutations inhibiting positive-strand RNA3 synthesis were introduced into the RNA3 5'-untranslated region. Thus, BMV subgenomic and genomic RNA syntheses mutually interfered with each other, apparently by competition for one or more common factors. In plant protoplasts replicating all three BMV genomic RNAs, mutations blocking sgRNA transcription often had lesser effects on RNA3 accumulation, possibly because RNA3 also competed with RNA1 and RNA2 replication templates and because any increase in RNA3 replication at the expense of RNA1 and RNA2 would be self-limited by decreased 1a and 2a expression from RNA1 and RNA2.

Replicase-binding sites on plus- and minus-strand brome mosaic virus RNAs and their roles in RNA replication in plant cells

The cis-acting elements for Brome mosaic virus (BMV) RNA synthesis have been characterized primarily for RNA3. To identify additional replicase-binding elements, nested fragments of all three of the BMV RNAs, both plus- and minus-sense fragments, were constructed and tested for binding enriched BMV replicase in a template competition assay. Ten RNA fragments containing replicase-binding sites were identified; eight were characterized further because they were more effective competitors. All eight mapped to noncoding regions of BMV RNAs, and the positions of seven localized to sequences containing previously characterized core promoter elements (C. C. Kao, Mol. Plant Pathol. 3:55-62, 2001), thus suggesting the identities of the replicase-binding sites. Three contained the tRNA-like structures that direct minus-strand RNA synthesis, three were within the 3' region of each minus-strand RNA that contained the core promoter for genomic plus-strand initiation, and one was in the core subgenomic promoter. Single-nucleotide mutations known previously to abolish RNA synthesis in vitro prevented replicase binding. When tested in the context of the respective full-length RNAs, the same mutations abolished BMV RNA synthesis in transfected barley protoplasts. The eighth site was within the intercistronic region (ICR) of plus-strand RNA3. Further mapping showed that a sequence of 22 consecutive adenylates was responsible for binding the replicase, with 16 being the minimal required length. Deletion of the poly(A) sequence was previously shown to severely debilitate BMV RNA replication in plants (E. Smirnyagina, Y. H. Hsu, N. Chua, and P. Ahlquist, Virology 198:427-436, 1994). Interestingly, the B box motif in the ICR of RNA3, which has previously been determined to bind the 1a protein, does not bind the replicase. These results identify the replicase-binding sites in all of the BMV RNAs and suggest that the recognition of RNA3 is different from that of RNA1 and RNA2.

Dissecting the requirement for subgenomic promoter sequences by RNA recombination of brome mosaic virus in vivo: evidence for functional separation of transcription and recombination

Previously, we and others mapped an increased homologous recombination activity within the subgenomic promoter (sgp) region in brome mosaic virus (BMV) RNA3. In order to correlate sgp-mediated recombination and transcription, in the present work we used BMV RNA3 constructs that carried altered sgp repeats. We observed that the removal or extension of the poly(U) tract reduced or increased recombination, respectively. Deletion of the sgp core hairpin or its replacement by a different stem-loop structure inhibited recombination activity. Nucleotide substitutions at the +1 or +2 transcription initiation position reduced recombination. The sgp core alone supported only basal recombination activity. The sites of crossovers mapped to the poly(U) region and to the core hairpin. The observed effects on recombination did not parallel those observed for transcription. To explain how both activities operate within the sgp sequence, we propose a dual mechanism whereby recombination is primed at the poly(U) tract by the predetached nascent plus strand, whereas transcription is initiated de novo at the sgp core.

Requirements for brome mosaic virus subgenomic RNA synthesis in vivo and replicase-core promoter interactions in vitro

Based solely on in vitro results, two contrasting models have been proposed for the recognition of the brome mosaic virus (BMV) subgenomic core promoter by the replicase. The first posits that the replicase recognizes at least four key nucleotides in the core promoter, followed by an induced fit, wherein some of the nucleotides base pair prior to the initiation of RNA synthesis (S. Adkins and C. C. Kao, Virology 252:1-8, 1998). The second model posits that a short RNA hairpin in the core promoter serves as a landing pad for the replicase and that at least some of the key nucleotides help form a stable hairpin (P. C. J. Haasnoot, F. Brederode, R. C. L. Olsthoorn, and J. Bol, RNA 6:708-716, 2000; P. C. J. Haasnoot, R. C. L. Olsthoorn, and J. Bol, RNA 8:110-122, 2002). We used transfected barley protoplasts to examine the recognition of the subgenomic core promoter by the BMV replicase. Key nucleotides required for subgenomic initiation in vitro were found to be important for RNA4 levels in protoplasts. In addition, additional residues not required in vitro and the formation of an RNA hairpin within the core promoter were correlated with wild-type RNA4 levels in cells. Using a template competition assay, the core promoter of ca. 20 nucleotides was found to be sufficient for replicase binding. Mutations of the key residues in the core promoter reduced replicase binding, but deletions that disrupt the predicted base pairing in the proposed stem retained binding at wild-type levels. Together, these results indicate that key nucleotides in the BMV subgenomic core promoter direct replicase recognition but that the formation of a stem-loop is required at a step after binding. Additional functional characterization of the subgenomic core promoter was performed. A portion of the promoter for BMV minus-strand RNA synthesis could substitute for the subgenomic core promoter in transfected cells. The comparable sequence from Cowpea Chlorotic Mottle Virus (CCMV) could also substitute for the BMV subgenomic core promoter. However, nucleotides in the CCMV core required for RNA synthesis are not identical to those in BMV, suggesting that the subgenomic core promoter can induce the BMV replicase in interactions needed for subgenomic RNA transcription in vivo.

Synthesis in vitro of rabbit hemorrhagic disease virus subgenomic RNA by internal initiation on (-)sense genomic RNA: mapping of a subgenomic promoter

Rabbit hemorrhagic disease virus (RHDV), a positive-strand RNA virus, is the type species of the Lagovirus within the Caliciviridae. In addition to the genomic RNA of 7.4 kb, a subgenomic mRNA (sgRNA) of 2.2 kb, which is identical in sequence to the 3' one-third of the genomic RNA, is also synthesized in RHDV-infected cells. Numerous RNA viruses make sgRNA for expression of their 3'-proximal genes. A relevant mechanism for viral gene expression is the regulation of sgRNA synthesis by specific promoter elements. In this study, we have investigated in vitro the sgRNA synthesis mechanism using recombinant RHDV RNA-dependent RNA polymerase produced in baculovirus-infected insect cells and synthetic RHDV (-)RNAs of different lengths containing regions located upstream of the subgenomic start site. We report evidences supporting that the sgRNA of RHDV is synthesized in vitro by internal initiation (subgenomic promoter) on (-)RNA templates of genomic length. The deletion mapping of the subgenomic promoter starting from minus-strand genomic length RNA showed that a sequence of 50 nucleotides upstream of the sgRNA start site (+1) is sufficient for full subgenomic promoter activity in an in vitro assay using recombinant RHDV RNA-dependent RNA polymerase. This study reports the first description of a subgenomic promoter in a member of the Caliciviridae.

Positive and negative modulation of virus infectivity and envelope glycoprotein incorporation into virions by amino acid substitutions at the N terminus of the simian immunodeficiency virus matrix protein

The matrix (MA) protein of the simian immunodeficiency viruses (SIVs) is encoded by the amino-terminal region of the Gag precursor and is the component of the viral capsid that lines the inner surface of the virus envelope. Previously, we identified domains in the SIV MA that are involved in the transport of Gag to the plasma membrane and in particle assembly. In this study, we characterized the role in the SIV life cycle of highly conserved residues within the SIV MA region spanning the two N-terminal alpha-helices H1 and H2. Our analyses identified two classes of MA mutants: (i) viruses encoding amino acid substitutions within alpha-helices H1 or H2 that were defective in envelope (Env) glycoprotein incorporation and exhibited impaired infectivity and (ii) viruses harboring mutations in the beta-turn connecting helices H1 and H2 that were more infectious than the wild-type virus and displayed an enhanced ability to incorporate the Env glycoprotein. Remarkably, among the latter group of MA mutants, the R22L/G24L double amino acid substitution increased virus infectivity eightfold relative to the wild-type virus in single-cycle infectivity assays, an effect that correlated with a similar increase in Env incorporation. Furthermore, the R22L/G24L MA mutation partially or fully complemented single-point MA mutations that severely impair or block Env incorporation and virus infectivity. Our finding that the incorporation of the Env glycoprotein into virions can be upregulated by specific mutations within the SIV MA amino terminus strongly supports the notion that the SIV MA domain mediates Gag-Env association during particle formation.

Effects of modification of the transcription initiation site context on citrus tristeza virus subgenomic RNA synthesis

Citrus tristeza virus (CTV), a member of the Closteroviridae, has a positive-sense RNA genome of about 20 kb organized into 12 open reading frames (ORFs). The last 10 ORFs are expressed through 3'-coterminal subgenomic RNAs (sgRNAs) regulated in both amounts and timing. Additionally, relatively large amounts of complementary sgRNAs are produced. We have been unable to determine whether these sgRNAs are produced by internal promotion from the full-length template minus strand or by transcription from the minus-stranded sgRNAs. Understanding the regulation of 10 sgRNAs is a conceptual challenge. In analyzing commonalities of a replicase complex in producing so many sgRNAs, we examined initiating nucleotides of the sgRNAs. We mapped the 5' termini of intermediate- (CP and p13) and low- (p18) produced sgRNAs that, like the two highly abundant sgRNAs (p20 and p23) previously mapped, all initiate with an adenylate. We then examined modifications of the initiation site, which has been shown to be useful in defining mechanisms of sgRNA synthesis. Surprisingly, mutation of the initiating nucleotide of the CTV sgRNAs did not prevent sgRNA accumulation. Based on our results, the CTV replication complex appears to initiate sgRNA synthesis with purines, preferably with adenylates, and is able to initiate synthesis using a nucleotide a few positions 5' or 3' of the native initiation nucleotide. Furthermore, the context of the initiation site appears to be a regulatory mechanism for levels of sgRNA production. These data do not support either of the established mechanisms for synthesis of sgRNAs, suggesting that CTV sgRNA production utilizes a different mechanism.

A transcriptionally active subgenomic promoter supports homologous crossovers in a plus-strand RNA virus

Genetic RNA recombination plays an important role in viral evolution, but its molecular mechanism is not well understood. In this work we describe homologous RNA recombination activity that is supported by a subgenomic promoter (sgp) region in the RNA3 segment of brome mosaic bromovirus (BMV), a tripartite plus-strand RNA virus. The crossover frequencies were determined by coinoculations with pairs of BMV RNA3 variants that carried a duplicated sgp region flanked by marker restriction sites. A region composed of the sgp core, a poly(A) tract, and an upstream enhancer supported homologous exchanges in 25% of the analyzed RNA3 progeny. However, mutations in the sgp core stopped both the transcription of the sgp RNA and homologous recombination. These data provide evidence for an association of RNA recombination with transcription.

The molecular variability analysis of the RNA 3 of fifteen isolates of Prunus necrotic ringspot virus sheds light on the minimal requirements for the synthesis of its subgenomic RNA

The nucleotide sequences of the RNA 3 of fifteen isolates of Prunus necrotic ringspot virus (PNRSV) varying in the symptomatology they cause in six different Prunus spp. were determined. Analysis of the molecular variability has allowed, in addition to study the phylogenetic relationships among them, to evaluate the minimal requirements for the synthesis of the subgenomic RNA in Ilarvirus genus and their comparison to other members of the Bromoviridae family. Computer assisted comparisons led recently to Jaspars (Virus Genes 17, 233-242, 1998) to propose that a hairpin structure in viral minus strand RNA is required for subgenomic promoter activity of viruses from at least two, and possibly all five, genera in the family of Bromoviridae. For PNRSV and Apple mosaic virus two stable hairpins were proposed whereas for the rest of Ilarviruses and the other four genera of the Bromoviridae family only one stable hairpin was predicted. Comparative analysis of this region among the fifteen PNRSV isolates characterized in this study revealed that two of them showed a 12-nt deletion that led to the disappearance of the most proximal hairpin to the initiation site. Interestingly, the only hairpin found in these two isolates is very similar in primary and secondary structure to the one previously shown in Brome mosaic virus to be required for the synthesis of the subgenomic RNA. In this hairpin, the molecular diversity was concentrated mostly at the loop whereas compensatory mutations were observed at the base of the stem strongly suggesting its functional relevance. The evolutionary implications of these observations are discussed.

Requirements for de novo initiation of RNA synthesis by recombinant flaviviral RNA-dependent RNA polymerases

RNA-dependent RNA polymerases (RdRps) that initiate RNA synthesis by a de novo mechanism should specifically recognize the template initiation nucleotide, T1, and the substrate initiation nucleotide, the NTPi. The RdRps from hepatitis C virus (HCV), bovine viral diarrhea virus (BVDV), and GB virus-B all can initiate RNA synthesis by a de novo mechanism. We used RNAs and GTP analogs, respectively, to examine the use of the T1 nucleotide and the initiation nucleotide (NTPi) during de novo initiation of RNA synthesis. The effects of the metal ions Mg(2+) and Mn(2+) on initiation were also analyzed. All three viral RdRps require correct base pairing between the T1 and NTPi for efficient RNA synthesis. However, each RdRp had some distinct tolerances for modifications in the T1 and NTPi. For example, the HCV RdRp preferred an NTPi lacking one or more phosphates regardless of whether Mn(2+) was present or absent, while the BVDV RdRp efficiently used GDP and GMP for initiation of RNA synthesis only in the presence of Mn(2+). These and other results indicate that although the three RdRps share a common mechanism of de novo initiation, each has distinct preferences.

Internal initiation by the cucumber necrosis virus RNA-dependent RNA polymerase is facilitated by promoter-like sequences

Tombusviruses, small positive sense RNA viruses of plants, are replicated by the viral-coded RNA-dependent RNA polymerase (RdRp) in infected cells. An unusual feature of the tombusvirus RdRp that is partially purified from cucumber necrosis virus (CNV)-infected plants is the ability to initiate complementary RNA synthesis from several internal positions on minus-strand templates derived from DI RNAs ( Nagy and Pogany, 2000 ). In this study, we used template deletion, mutagenesis, and oligo-based inhibition of RNA synthesis to map the internal initiation sites observed with the in vitro CNV RdRp system. Comparing sequences around the internal initiation sites reveals that they have either (i) similar sequences to the core minus-strand initiation promoter; or (ii) similar structures to the core plus-strand initiation promoter. In addition, we find similarities among the internal initiation sites and the subgenomic RNA initiation sites. These similarities suggest that the mechanism of internal initiation is similar to initiation from the terminal core promoters or the putative subgenomic promoter sequences. We propose that internal initiation on full-length RNA templates may be important in defective interfering (DI) RNA formation/evolution by producing intermediate templates for RNA recombination in tombusviruses. This may explain why tombusviruses are frequently associated with DI RNAs.

Analysis of minimal promoter sequences for plus-strand synthesis by the Cucumber necrosis virus RNA-dependent RNA polymerase

Tombusviruses are small, plus-sense, single-stranded RNA viruses of plants. A partially purified RNA-dependent RNA polymerase (RdRp) preparation of Cucumber necrosis virus (CNV), which is capable of de novo initiation of complementary RNA synthesis from either plus-strand or minus-strand templates, was used to dissect minimal promoter sequences for tombusviruses and their defective interfering (DI) RNAs. In vitro RdRp assay revealed that the core plus-strand initiation promoter included only the 3'-terminal 11 nucleotides. A hypothetical promoter-like sequence, which has been termed consensus sequence by Wu and White (1998, J. Virol. 72, 9897-9905), is recognized less efficiently by the CNV RdRp than the core plus-strand initiation promoter. The CNV RdRp can efficiently recognize the core plus-strand initiation promoter for a satellite RNA associated with the distantly related Turnip crinkle virus, while artificial AU- or GC-rich 3'-terminal sequences make poor templates in the in vitro assays. Comparison of the "strength" of minimal plus-strand and minus-strand initiation promoters reveals that the latter is almost twice as efficient in promoting complementary RNA synthesis. Template competition experiments, however, suggest that the minimal plus-strand initiation promoter makes an RNA template more competitive than the minimal minus-strand initiation promoter. Taken together, these results demonstrate that promoter recognition by the tombusvirus RdRp requires only short sequences present at the 3' end of templates.

Lessons learned from the core RNA promoters of Brome mosaic virus and Cucumber mosaic virus

summary RNA core promoters are nucleotide sequences needed to direct proper initiation of viral RNA synthesis by the viral replicase. Minimal length core promoter-templates that can direct accurate initiation of the genomic plus-, genomic minus-, and subgenomic RNAs of Brome mosaic virus and Cucumber mosaic virus were characterized in previous works. Several common themes and differences were observed in how each of the core promoters directed the initiation of viral RNA synthesis in vitro. These observations are summarized and compared in this short review.

Small-Scale Isolation of Viral RNA-Dependent RNA Polymerase from Protoplasts Inoculated with In Vitro Transcripts

Cowpea chlorotic mottle virus (CCMV) replicated in tobacco suspension cell protoplasts inoculated with in vitro transcripts of CCMV RNA1, 2, and 3. CCMV RNA-dependent RNA polymerase (RdRp) isolated from these protoplasts specifically recognized CCMV and Brome mosaic virus (BMV) subgenomic RNA promoters and directed in vitro RNA synthesis in a manner indistinguishable from CCMV RdRp more laboriously isolated from systemically infected cowpea leaves. Omission of CCMV RNA3 from the protoplast inoculum or replacement with in vitro transcripts of BMV RNA3 reduced CCMV (+)-strand RNA1 and 2 accumulation to approximately 1/40 and approximately 1/10, respectively, of the level attained when CCMV RNA3 was present. The absence of CCMV RNA3 did not prevent assembly and isolation of highly active, template-dependent and template-specific CCMV RdRp, which directed synthesis of products identical in size to those of RdRp isolated from protoplasts inoculated with all three CCMV genomic RNAs. These results demonstrate that CCMV RNA1 and 2 are sufficient for CCMV replication and RdRp assembly in tobacco protoplasts. This approach for isolation of functional viral RdRp will be especially useful for viruses for which large quantities of infected tissue are unavailable, such as those with specific tissue tropisms or mutants incapable of systemic movement.

Factors regulating template switch in vitro by viral RNA-dependent RNA polymerases: implications for RNA-RNA recombination

Copy-choice RNA recombination occurs during viral RNA synthesis when the viral transcription complex switches templates. We demonstrate that RNA-dependent RNA polymerase from bovine viral diarrhea virus and the replicases from three plant-infecting RNA viruses can produce easily detectable recombination products in vitro by switching templates during elongative RNA synthesis. Template sequence and/or structure, and NTP availability affected the frequency of template switch by the transcription complex. Our results provide biochemical support for copy-choice recombination and establish assays for mechanistic analyses of intermolecular RNA recombination in vitro.

Efficient and specific initiation of subgenomic RNA synthesis by cucumber mosaic virus replicase in vitro requires an upstream RNA stem-loop

We defined the minimal core promoter sequences responsible for efficient and accurate initiation of cucumber mosaic virus (CMV) subgenomic RNA4. The necessary sequence maps to positions -28 to +15 relative to the initiation cytidylate used to initiate RNA synthesis in vivo. Positions -28 to -5 contain a 9-bp stem and a 6-nucleotide purine-rich loop. Considerable changes in the stem and the loop are tolerated for RNA synthesis, including replacement with a different stem-loop. In a template competition assay, the stem-loop and the initiation cytidylate are sufficient to interact with the CMV replicase. Thus, the mechanism of core promoter recognition by the CMV replicase appears to be less specific in comparison to the minimal subgenomic core promoter of the closely related brome mosaic virus.

Recognition of the core RNA promoter for minus-strand RNA synthesis by the replicases of Brome mosaic virus and Cucumber mosaic virus

Replication of viral RNA genomes requires the specific interaction between the replicase and the RNA template. Members of the Bromovirus and Cucumovirus genera have a tRNA-like structure at the 3' end of their genomic RNAs that interacts with the replicase and is required for minus-strand synthesis. In Brome mosaic virus (BMV), a stem-loop structure named C (SLC) is present within the tRNA-like region and is required for replicase binding and initiation of RNA synthesis in vitro. We have prepared an enriched replicase fraction from tobacco plants infected with the Fny isolate of Cucumber mosaic virus (Fny-CMV) that will direct synthesis from exogenously added templates. Using this replicase, we demonstrate that the SLC-like structure in Fny-CMV plays a role similar to that of BMV SLC in interacting with the CMV replicase. While the majority of CMV isolates have SLC-like elements similar to that of Fny-CMV, a second group displays sequence or structural features that are distinct but nonetheless recognized by Fny-CMV replicase for RNA synthesis. Both motifs have a 5'CA3' dinucleotide that is invariant in the CMV isolates examined, and mutational analysis indicates that these are critical for interaction with the replicase. In the context of the entire tRNA-like element, both CMV SLC-like motifs are recognized by the BMV replicase. However, neither motif can direct synthesis by the BMV replicase in the absence of other tRNA-like elements, indicating that other features of the CMV tRNA can induce promoter recognition by a heterologous replicase.

Partial purification and characterization of Cucumber necrosis virus and Tomato bushy stunt virus RNA-dependent RNA polymerases: similarities and differences in template usage between tombusvirus and carmovirus RNA-dependent RNA polymerases

Tombusviruses are small, plus-sense, single-stranded RNA viruses of plants. RNA-dependent RNA polymerases (RdRp) of two tombusviruses, Tomato bushy stunt virus (TBSV) and Cucumber necrosis virus (CNV), have been partially purified from infected Nicotiana benthamiana plants. The obtained RdRp complexes are capable of de novo initiation of complementary RNA synthesis using either plus- or minus-strand templates derived from tombusvirus defective interfering (DI) RNAs. In addition to template-sized products, shorter than full-length products were also generated efficiently apparently because of internal initiation of RNA synthesis by the tombusvirus RdRp. This property could be important for the formation of DI RNAs that are observed in tombusvirus infections. The tombusvirus RdRp is also able to use heterologous RNAs derived from satellite RNAs associated with Turnip crinkle virus (TCV) as templates. Generation of full-length, complementary RNA by the tombusvirus RdRp suggests that it can correctly and efficiently recognize the heterologous TCV-specific promoters. Reduced generation of a 3'-terminal extension product in the preceding assay suggests that the previously characterized replication enhancer present in sat-RNA C (Nagy et al., 1999, EMBO J. 18, 5653-5665) does not stimulate tombusvirus RdRp activity. Taken together, these results suggest that template usage by the tombusvirus and carmovirus RdRps are similar, but not identical.

Mapping of the Tobacco mosaic virus movement protein and coat protein subgenomic RNA promoters in vivo

The Tobacco mosaic virus movement protein (MP) and coat protein (CP) are expressed from 3'-coterminal subgenomic RNAs (sgRNAs). The transcription start site of the MP sgRNA, previously mapped to positions 4838 (Y. Watanabe, T. Meshi, and Y. Okada (1984), FEBS Lett. 173, 247-250) and 4828 (K. Lehto, G. L. Grantham, and W. O. Dawson (1990), Virology 174, 145-157) for the TMV OM and U1 strains, respectively, has been reexamined and mapped to position 4838 for strain U1. Sequences of the MP and CP sgRNA promoters were delineated by deletion analysis. The boundaries for minimal and full MP sgRNA promoter activity were localized between -35 and +10 and -95 and +40, respectively, relative to the transcription start site. The minimal CP sgRNA promoter was mapped between -69 and +12, whereas the boundaries of the fully active promoter were between -157 and +54. Computer analysis predicted two stem-loop structures (SL1 and SL2) upstream of the MP sgRNA transcription start site. Deletion analysis and site-directed mutagenesis suggested that SL1 secondary structure, but not its sequence, was required for MP sgRNA promoter activity, whereas a 39-nt deletion removing most of the SL2 region increased MP sgRNA accumulation fourfold. Computer-predicted folding of the fully active CP sgRNA promoter revealed one long stem-loop structure. Deletion analysis suggested that the upper part of this stem-loop, located upstream of the transcription start site, was essential for transcription and that the lower part of the stem had an enhancing role.

Brome mosaic virus, good for an RNA virologist's basic needs

Abstract Taxonomic relationship: Type member of the Bromovirus genus, family Bromoviridae. A member of the alphavirus-like supergroup of positive-sense single-stranded RNA viruses. Physical properties: Virions are nonenveloped icosahedrals made up of 180 coat protein subunits (Fig. 1). The particles are 26 nm in diameter and contain 22% nucleic acid and 78% protein. The BMV genome is composed of three positive-sense, capped RNAs: RNA1 (3.2 kb), RNA2 (2.9 kb), RNA3 (2.1 kb) (Fig. 2). Viral proteins: RNA1 encodes protein 1a, containing capping and putative RNA helicase activities. RNA2 encodes protein 2a, a putative RNA-dependent RNA polymerase. RNA3 codes for two proteins: 3a, which is required for cell-to-cell movement, and the capsid protein. The capsid is translated from a subgenomic RNA, RNA4 (1.2 kb). Hosts: Monocots in the Poacea family, including Bromus inermis, Zea mays and Hordeum vulgare, in which BMV causes brown streaks. BMV can also infect the dicots Nicotiana benthamiana and several Chenopodium species. In N. benthamiana, the infection is asymptomatic while infection of Chenopodium can cause either necrotic or chlorotic lesions. Useful website:http://www4.ncbi.nlm.nih.gov/ICTVdb/ICTVdB/10030001.htm.

RNA sequence and secondary structural determinants in a minimal viral promoter that directs replicase recognition and initiation of genomic plus-strand RNA synthesis

Viral RNA replication provides a useful system to study the structure and function of RNAs and the mechanism of RNA synthesis from RNA templates. Previously we demonstrated that a 27 nt RNA from brome mosaic virus (BMV) can direct correct initiation of genomic plus-strand RNA synthesis by the BMV replicase. In this study, using biochemical, nuclear magnetic resonance, and thermodynamic analyses, we determined that the secondary structure of this 27 nt RNA can be significantly altered and retain the ability to direct RNA synthesis. In contrast, we find that position-specific changes in the RNA sequence will affect replicase recognition, modulate the polymerization process, and contribute to the differential accumulation of viral RNAs. These functional results are in agreement with the phylogenetic analysis of BMV and related viral sequences and suggest that a similar mechanism of RNA synthesis takes place for members of the alphavirus superfamily.

Use of DNA, RNA, and chimeric templates by a viral RNA-dependent RNA polymerase: evolutionary implications for the transition from the RNA to the DNA world

All polynucleotide polymerases have a similar structure and mechanism of catalysis, consistent with their evolution from one progenitor polymerase. Viral RNA-dependent RNA polymerases (RdRp) are expected to have properties comparable to those from this progenitor and therefore may offer insight into the commonalities of all classes of polymerases. We examined RNA synthesis by the brome mosaic virus RdRp on DNA, RNA, and hybrid templates and found that precise initiation of RNA synthesis can take place from all of these templates. Furthermore, initiation can take place from either internal or penultimate initiation sites. Using a template competition assay, we found that the BMV RdRp interacts with DNA only three- to fourfold less well than it interacts with RNA. Moreover, a DNA molecule with a ribonucleotide at position -11 relative to the initiation nucleotide was able to interact with RdRp at levels comparable to that observed with RNA. These results suggest that relatively few conditions were needed for an ancestral RdRp to replicate DNA genomes.