Localization of the Q beta replicase recognition site in MDV-1 RNA

Fragments of MDV-1 RNA (a small, naturally occurring template for Q beta replicase) that were missing nucleotides at either their 5' end or their 3' end were still able to form a complex with Q beta replicase. By assaying the binding ability of fragments of different length, it was established that the binding site for Q beta replicase is determined by nucleotide sequences that are located near the middle of MDV-1 RNA. Fragments missing nucleotides at their 5' end were able to serve as templates for the synthesis of complementary strands, but fragments missing nucleotides at their 3' end were inactive, indicating that the 3'-terminal region of the template is required for the initiation of RNA synthesis. The nucleotide sequences of both the 3' terminus and the central binding region of MDV-1 (+) RNA are almost identical to sequences at the 3' terminus and at an internal region of Q beta (-) RNA.     

RNA replication: required intermediates and the dissociation of template, product, and Q beta replicase.

Replication complexes containing only one molecule of Q beta replicase and one strand of midivariant RNA (MDV-1 RNA) template were prepared by incubating the replicase with an excess of MDV-1 (-) RNA. In the presence of excess minus strands, these monoenzyme replication complexes were shown to synthesize essentially pure MDV-1 (+) RNA in both the first and second cycles of replication. When an equivalent concentration of mutant MDV-1 (-) RNA was added to this reaction before completion of the first cycle of replication, only wild-type MDV-1 (+) RNA was produced in the first cycle, but both mutant and wild-type MDV-1 (+) RNA were produced in the second cycle of replication. These results demonstrate that a monoenzyme complex is competent to synthesize RNA and, therefore, that a multienzyme replication complex is not a necessary intermediate of replication. The data also imply that after the completion of chain elongation, the product strand is released from the replication complex and that the template and the replicase then dissociate.     

Efficient templates for Q beta replicase are formed by recombination from heterologous sequences.

A very efficient replicase template has been isolated from the products of spontaneous RNA synthesis in an in vitro Q beta replicase reaction that was incubated in the absence of added RNA. This template was named RQ135 RNA because it is 135 nucleotides in length. Its sequence consists entirely of segments that are homologous to ribosomal 23 S RNA and the phage lambda origin of replication. The sequence segments are unrelated to the sequence of Q beta bacteriophage genomic RNA. Nonetheless, this natural recombinant is replicated in vitro at a rate equal to the most efficient of the known Q beta RNA variants. Apparently, the structural properties that ensure recognition of an RNA template by Q beta replicase are not confined to viral RNA, but can appear as a result of recombination among other RNAs that usually occur in cells.     

Terminal adenylation in the synthesis of RNA by Q beta replicase

We investigated the apparent requirement that Q beta replicase must add a nontemplated adenosine to the 3' end of newly synthesized RNA strands. We used abbreviated MDV-1 (+)-RNA templates that lacked either 62 or 63 nucleotides at their 5' end in Q beta replicase reactions. The MDV-1 (-)-RNA strands synthesized from these abbreviated (+)-strand templates were released from the replication complex, yet they did not possess a nontemplated 3'-terminal adenosine. These results imply that, despite observations that all naturally occurring RNAs synthesized by Q beta replicase possess a nontemplated 3'-adenosine, the addition of an extra adenosine is not an obligate step for the release of completed strands. Since the abbreviated templates lacked a normal 5' end, it is probable that a particular sequence at the 5' end of the template is required for terminal adenylation to occur.     

On the nature of spontaneous RNA synthesis by Q beta replicase.

Numerous RNA species of different length and nucleotide sequence grow spontaneously in vitro in Q beta replicase reactions where no RNA templates are added deliberately. Here, we show that this spontaneous RNA synthesis by Q beta replicase is template directed. The immediate source of template RNA can be the laboratory air, but there are ways to eliminate, or at least substantially reduce, the harmful effects of spontaneous synthesis. Solitary RNA molecules were detected in a thin layer of agarose gel containing Q beta replicase, where they grew to form colonies that became visible upon staining with ethidium bromide. This result provides a powerful tool for RNA cloning and selection in vitro. We also show that replicating RNAs similar to those growing spontaneously are incorporated into Q beta phage particles and can propagate in vivo for a number of phage generations. These RNAs are the smallest known molecular parasites, and in many aspects they resemble both the defective interfering genomes of animal and plant viruses and plant virus satellite RNAs.     

In vitro recombination and terminal elongation of RNA by Q beta replicase.

SV-11 is a short-chain [115 nucleotides (nt)] RNA species that is replicated by Q beta replicase. It is reproducibly selected when MNV-11, another 87 nt RNA species, is extensively amplified by Q beta replicase at high ionic strength and long incubation times. Comparing the sequences of the two species reveals that SV-11 contains an inverse duplication of the high-melting domain of MNV-11. SV-11 is thus a recombinant between the plus and minus strands of MNV-11 resulting in a nearly palindromic sequence. During chain elongation in replication, the chain folds consecutively to a metastable secondary structure of the RNA, which can rearrange spontaneously to a more stable hairpin-form RNA. While the metastable form is an excellent template for Q beta replicase, the stable RNA is unable to serve as template. When initiation of a new chain is suppressed by replacing GTP in the replication mixture by ITP, Q beta replicase adds nucleotides to the 3' terminus of RNA. The replicase uses parts of the RNA sequence, preferentially the 3' terminal part for copying, thereby creating an interior duplication. This reaction is about five orders of magnitude slower than normal template-instructed synthesis. The reaction also adds nucleotides to the 3' terminus of some RNA molecules that are unable to serve as templates for Q beta replicase.     

Template-determined,variable rate of RNA chain elongation

Qβ replicase polymerizes MDV-1 RNA at a markedly variable rate. Electrophoretic analyses of partially synthesized strands showed that a few of the elongation intermediates are much more abundant than others, reflecting a variable rate of chain elongation. Our data suggest that at a relatively small number of specific sites in the sequence of this RNA, the progress of the replicase is temporarily interrupted, and then resumes spontaneously, with a finite probability. Since the time spent between these pause sites is negligible compared with the time spent at pause sites, the mean time of chain elongation is well approximated by the sum of the mean times spent at each pause site.Nucleotide sequence analysis of the most prominent elongation intermediates indicated that they all have the potential to form a 3′ terminal hairpin structure. This suggests that the marked variability in the rate of chain elongation is due to the formation of terminal hairpins in the product strand, or the reformation of hairpins in the template strand. A survey of the literature shows that this phenomenon occurs with most, if not all, nucleic acid polymerases. Structure-induced pauses may play a role in the regulation of nucleic acid synthesis.     

Minus-strand initiation by brome mosaic virus replicase within the 3' tRNA-like structure of native and modified RNA templates

An RNA-dependent RNA polymerase (replicase) extract from brome mosaic virus-infected barley leaves has been shown to initiate synthesis of (-) sense RNA from (+) sense virion RNA. Initiation occurred de novo, as demonstrated by the incorporation of [gamma-32P]GTP into the product. Sequencing using cordycepin triphosphate to terminate (-) strands during their synthesis by the replicase generated sequence ladders that confirmed that copying was accurate, and that initiation occurred very close to the 3' end. The precise site of initiation was further defined by testing the replicase template activity after stepwise removal of 3'-terminal nucleotides. Whereas removal of the terminal A did not decrease template activity, removal of the next nucleotide (C-2) did. Thus, initiation almost certainly occurs opposite the penultimate 3'-nucleotide (C-2) in vitro. The structure of the double-stranded replicative form of RNA isolated from brome mosaic virus-infected leaves was consistent with such a mechanism occurring in vivo, in that it lacked the 3'-terminal A found on virion RNAs. The specific site of (-) strand initiation and normal template activity were retained for RNAs with as many as 15 to 30 A residues added to the 3' end. However, only limited oligonucleotide 3' extensions can be present on active templates. In order to assess the 5' extent of sequences required for an active template, a 134-nucleotide-long fragment of brome mosaic virus RNA, corresponding to the tRNA-like structure, was generated. This RNA had high template activity, but a shorter 3' (85-nucleotide) fragment was inactive. RNAs with various heterologous sequences 5' to position 134 also showed high template activity. Thus, the 3'-terminal tRNA-like structure common to all four brome mosaic virus virion RNAs contains all of the signals required for initiation of replication, and sequences 5' to it do not play a role in template selection.     

Rotavirus RNA polymerase requires the core shell protein to synthesize the double-stranded RNA genome.

Rotavirus cores contain the double-stranded RNA (dsRNA) genome, RNA polymerase VP1, and guanylyltransferase VP3 and are enclosed within a lattice formed by the RNA-binding protein VP2. Analysis of baculovirus-expressed core-like particles (CLPs) has shown that VP1 and VP2 assemble into the simplest core-like structures with replicase activity and that VP1, but not VP3, is essential for replicase activity. To further define the role of VP1 and VP2 in the synthesis of dsRNA from viral mRNA, recombinant baculoviruses containing gene 1 (rBVg1) and gene 2 (rBVg2) of SA11 rotavirus were generated and used to express recombinant VP1 (rVP1) and rVP2, respectively. After purification, the proteins were assayed individually and together for the ability to catalyze the synthesis of dsRNA in a cell-free replication system. The results showed that dsRNA was synthesized only in assays containing rVP1 and rVP2, thus establishing that both proteins are essential for replicase activity. Even in assays containing a primer-linked mRNA template, neither rVP1 nor rVP2 alone directed RNA synthesis. Characterization of the cis-acting replication signals in mRNA recognized by the replicase of rVP1 and rVP2 showed that they were the same as those recognized by the replicase of virion-derived cores, thus excluding a role for VP3 in recognition of the mRNA template by the replicase. Analysis of RNA-protein interactions indicated that the mRNA template binds strongly to VP2 in replicase assays but that the majority of the dsRNA product neither is packaged nor stably associates with VP2. The results of replicase assays performed with mutant VP2 containing a deletion in its RNA-binding domain suggests that the essential role for VP2 in replication is linked to the protein's ability to bind the mRNA template for minus-strand synthesis.     

Differential stimulation by polyamines of phage RNA-directed synthesis of proteins

The effect of polyamines on Q beta and MS2 phage RNA-directed synthesis of three kinds of protein in an Escherichia coli cell-free system has been studied. With both phage RNAs, the degree of stimulation of protein synthesis by spermidine was in the order RNA replicase greater than A protein, while the synthesis of coat protein was not stimulated significantly by spermidine. The synthesis of RNA replicase was stimulated by 1 mM spermidine approx. 8-fold. From the results of Q beta RNA direct alanyl-tRNA and seryl-tRNA binding to ribosomes and initiation dipeptide synthesis, it is suggested that the preferential stimulation of the synthesis of RNA replicase by spermidine is due at least partially to the stimulation of the initiation of RNA replicase synthesis.     

Q beta replicase: mapping the functional domains of an RNA-dependent RNA polymerase

We have localized a functional region of the RNA bacteriophage Q beta replicase following an extensive mutational analysis. Using the method of oligonucleotide linker-insertion mutagenesis, we specifically introduced mutations into a cloned DNA copy of the Q beta replicase gene so that the resulting replicase products would putatively contain small amino acid insertions. In a selective phenotypic assay, we screened mutant replicases for RNA-directed replication activity in vivo. Analysis of 37 different mutant clones indicated that Q beta replicase can accept amino acid substitutions and insertions at several sites at the amino and carboxy termini without abolishing functional activity in vivo or in vitro. However, disruption within the internal amino acid sequence resulted almost exclusively in nonfunctional enzyme. The results suggest that the central region of the replicase protein contains a rigid amino acid composition that is required for replicase function, whereas the amino and carboxy termini are much more receptive to small amino acid insertions and substitutions. These experiments should further enable us to analyze the coding function of the Q beta replicase gene independently of other phage RNA functions contained within this nucleotide region.     

Correlation of pause sites in MDV-1 RNA replication with kinetic refolding of the growing chain. A Monte Carlo simulation of the Markov process

We consider a template-instructed MDV-1 RNA replication catalyzed by Q beta replicase. The relaxation of the effective binding of the growing chain to the enzyme is simulated, considering a Markov process where refolding events in the chain are concomitant with chain elongation events. When realistic transition probabilities are considered, it becomes evident that the pause sites in replication are due to relaxation of the binding by folding of the growing chain.     

Purification of the cucumber necrosis virus replicase from yeast cells: role of coexpressed viral RNA in stimulation of replicase activity

Purified recombinant viral replicases are useful for studying the mechanism of viral RNA replication in vitro. In this work, we obtained a highly active template-dependent replicase complex for Cucumber necrosis tombusvirus (CNV), which is a plus-stranded RNA virus, from Saccharomyces cerevisiae. The recombinant CNV replicase showed properties similar to those of the plant-derived CNV replicase (P. D. Nagy and J. Pogany, Virology 276:279-288, 2000), including the ability (i). to initiate cRNA synthesis de novo on both plus- and minus-stranded templates, (ii). to generate replicase products that are shorter than full length by internal initiation, and (iii). to perform primer extension from the 3' end of the template. We also found that isolation of functional replicase required the coexpression of the CNV p92 RNA-dependent RNA polymerase and the auxiliary p33 protein in yeast. Moreover, coexpression of a viral RNA template with the replicase proteins in yeast increased the activity of the purified CNV replicase by 40-fold, suggesting that the viral RNA might promote the assembly of the replicase complex and/or that the RNA increases the stability of the replicase. In summary, this paper reports the first purified recombinant tombusvirus replicase showing high activity and template dependence, a finding that will greatly facilitate future studies on RNA replication in vitro.     

Defining the roles of cis-acting RNA elements in tombusvirus replicase assembly in vitro

In addition to its central role as a template for replication and translation, the viral plus-strand RNA genome also has nontemplate functions, such as recruitment to the site of replication and assembly of the viral replicase, activities that are mediated by cis-acting RNA elements within viral genomes. Two noncontiguous RNA elements, RII(+)-SL (located internally in the tombusvirus genome) and RIV (located at the 3'-terminus), are involved in template recruitment into replication and replicase assembly; however, the importance of each of these RNA elements for these two distinct functions is not fully elucidated. We used an in vitro replicase assembly assay based on yeast cell extract and purified recombinant tombusvirus replication proteins to show that RII(+)-SL, in addition to its known requirement for recruitment of the plus-strand RNA into replication, is also necessary for assembly of an active viral replicase complex. Additional studies using a novel two-component RNA system revealed that the recruitment function of RII(+)-SL can be provided in trans by a separate RNA and that the replication silencer element, located within RIV, defines the template that is used for initiation of minus-strand synthesis. Collectively, this work has revealed new functions for tombusvirus cis-acting RNA elements and provided insights into the pioneering round of minus-strand synthesis.     

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.