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.     

Interactions of Q beta replicase with Q beta RNA

The interactions of Qβ replicase with Qβ RNA were investigated by treating replicase-Qβ RNA complexes under various conditions with ribonuclease T₁, and by characterizing enzyme-bound RNA fragments recovered by a filter binding technique. Evidence for replicase binding at two internal regions of Qβ RNA was obtained. One region (at about 1250 to 1350 nucleotides from the 5′ end) overlaps with the initiation site for coat protein synthesis; this interaction is thought to be inessential for template activity but rather to be involved in the regulation of protein synthesis. Binding to this site (called the S-site) requires moderate concentrations of salt but no magnesium ions. The other region (at about 2550 to 2870 nucleotides from the 5′ end) is probably essential for template activity; binding to this site (called the M-site) is dependent on the presence of magnesium ions. The nucleotide sequences of the RNA fragments from the two sites were determined and found to have no common features. Under the conditions tested, replicase binding at the 3′ end of Qβ RNA could not be demonstrated, except when initiation of RNA synthesis was allowed to occur in the presence of GTP and host factor. If instead of intact Qβ RNA, a complete RNAase T₁ digest of Qβ RNA was allowed to bind to replicase, oligonucleotides from the S-site and the M-site, and oligonucleotides from a region close to the 3′ end, were found to have the highest affinity to the enzyme.The RNA fragments recovered in highest yield, M-2 and S-3 from the M and S-site, respectively, were isolated on a preparative scale and their enzyme binding properties were studied. In competition assays with random RNA fragments of the same size, selective binding was observed both for the M and the S-site fragment. Partial competition for replicase binding was found if M-2 and S-3 were presented simultaneously to the enzyme. Either fragment, if preincubated with replicase, caused a specific inhibition of initiation of Qβ RNA-directed RNA synthesis, without inhibiting the poly(rC)-directed reaction.The results are discussed in terms of a model of replicase-Qβ RNA recognition. Template specificity is attributed to binding of internal RNA regions to replicase, resulting in a specific spatial orientation of the RNA by which the inherently weak, but essential, interaction at the 3′ end is allowed to occur and to lead to the initiation of RNA synthesis.     

Kinetic analysis of template-instructed and de novo RNA synthesis by Q beta replicase

The kinetics of template-free and template-instructed RNA synthesis by Q_β replicase were investigated. Template-instructed RNA synthesis has different growth rates in the exponential (excess enzyme) and the linear (excess template) phase of growth. In the absence of exogenous template, Q_β replicase synthesizes self-replicating RNA after an initial lag phase (“template-free” synthesis). The lag time can be determined by extrapolating the growth curve to the time of appearance of the first self-replicating strand. Growth rates in the exponential and linear phase, and especially the times of the lag phase for nucleotide incorporations under identical template-free conditions, show considerable scattering in contrast to the deterministic behavior of template-instructed synthesis. Evaluation of the kinetic data reveals that the time lag of template-free synthesis is strongly dependent on the concentration of the nucleoside triphosphate and the enzyme. The lag time is approximately inversely proportional to the powers 2.75 of the nucleotide and 2.5 of the enzyme concentration, respectively, both being lower limit values. The rate of template-instructed RNA synthesis is linearly proportional to the enzyme concentration and less than linearly proportional to the triphosphate concentration, in accordance with a substrate dependence of a Michaelis-Menten type of mechanism. The kinetic data cannot be reconciled with the proposition that template-free synthesis is due to low concentrations of templates present as impurities in the incorporation mixture and giving rise to autocatalytic RNA synthesis by a template-instructed mechanism. The data strongly favor the de novo mechanism proposed by Sumper &; Luce (1975).     

Structural consensus of RNA templates replicated by Q beta replicase.

Q beta replicase replicates a variety of enzyme-specific small RNAs in addition to the phage genomic RNA. The sequence analysis has revealed that all these RNAs are potentially capable of forming a consensus secondary structure element. It represents a stalk which is formed by the 5'-GGG ... and ... CCCA-3' complementary stretches at the termini of the replicating RNA molecules and adjacent 5'- and 3'-hairpins, which may form a stacking with the stalk. The structure found is rather similar to the analogous structure in the tRNA molecule. The genomic RNA of the Q beta phage and other related phages can also form a similar structural element.     

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.     

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.     

Self-catalysed affinity labeling of Q beta replicase.

The spatial neighbourhood of the active center of Q beta replicase can be selectively modified by the method of self-catalysed affinity labeling. In the template-directed, mainly intramolecular enzymatic catalysis, the product [32P]GpG becomes specifically attached to the beta subunit. Using limited digestion of the radioactively labeled polypeptide by cyanogen bromide or N-chlorosuccinimide, we have mapped the attachment site to the region of subunit beta between Trp93 and Met130. Under our reaction conditions, Lys95 is the amino acid most likely to be modified, suggesting that Lys95 lies near the nucleotide binding site in the active center.     

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.     

A polarity gradient in the expression of the replicase gene of RNA bacteriophage Q beta

Nine mutants of bacteriophage Qβ were studied, each having an amber mutation in the coat protein gene. The N-terminal coat protein fragments synthesized in vitro by a non-suppressing Escherichia coli cell extract directed by the mutant RNA's were characterized by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, agarose column gel filtration, and their relative content of certain amino acids. These methods permitted the mutant codon in the coat protein gene to be identified unambiguously; in three cases the amber mutation was at position 17; in five cases, at position 37, and in one case at position 86.Phage-specific uracil incorporation and Qβ replicase activities were measured in infected, non-suppressing cells. Their amounts for each mutant were related to the position of the amber mutation, indicating that across the coat protein gene of Qβ there exists a gradient of polarity for the expression of the replicase gene.     

The accuracy of Q beta RNA translation. 2. Errors during the synthesis of Q beta proteins by cell-free Escherichia coli extracts

The accuracy of Q beta translation by Escherichia coli extracts in polymix and a conventional Tris/Mg2+ system has been followed. Misinsertions of histidine and of tryptophan into the phage coat protein were less frequent in polymix than in Tris/Mg2+, as were errors leading to a change in the coat protein pI. Even the lowest Q beta error rates, however, were still an order of magnitude greater than those for poly(U) or poly(U-G) translation. Comparing Q beta translational errors made in vitro to those found in whole cells, histidine misinsertions were almost twice as frequent, errors leading to a coat protein charge change six times more frequent and tryptophan misinsertions at least 15 times more frequent in vitro. The relation of these findings to measurements of translational accuracy and to factors affecting fidelity is discussed.     

The accuracy of Q beta RNA translation. 1. Errors during the synthesis of Q beta proteins by intact Escherichia coli cells

The fidelity of Q beta RNA translation by intact Escherichia coli cells has been studied. After infection, host protein synthesis was eliminated by adding rifampicin and the radioactive, phage-specified, proteins separated by one or two-dimensional gel electrophoresis. Labelled histidine and tryptophan were incorporated into the phage coat protein, whose message does not specify these amino acids, at a frequency of 0.09-0.13 per molecule. Errors leading to a change in the pI of the coat protein occurred at a rate of 0.05 per molecule, while the coat protein UGA stop codon was misread 6.5% of the time. These error rates are similar to data in some recent publications but much higher than the canonical 3-4 X 10(-4). They further provide a reference point in vivo to which the translation of the same message by E. coli extracts can be compared.     

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.     

"Pseudolysogenization" by RNA phage Q beta.

We isolated fairly stable lysogenic-like bacteria from a lysogenic state established between an amber mutant for the maturation protein gene of RNA phage Q beta (Q beta am 205) and its nonpermissive host BE110. These bacteria contained few mature phages intracellularly (less than 10(-3) plaque forming unit per cell), continued to grow with a potentiality to produce Q beta am 205 spontaneously, and showed an immunity-like response against homologous phage infection. These characteristics were maintained by growth in liquid medium containing anti-Q beta serum. We designated these cells as pseudolysogenic bacteria. The relative amounts of RNA genomes in these pseudolysogenic cells (about 10(2) infectious RNA strands per cell) indicated that the RNA genomes could replicate in nonpermissive cells and be distributed in daughter cells synchronizing well with cell division.     

Primer-dependent synthesis of covalently linked dimeric RNA molecules by poliovirus replicase.

Poliovirus-specific RNA-dependent RNA polymerase (replicase, 3Dpol) was purified from HeLa cells infected with poliovirus. The purified enzyme preparation contained two proteins of apparent molecular weights 63,000 and 35,000. The 63,000-Mr polypeptide was virus-specific RNA-dependent RNA polymerase, and the 35,000-Mr polypeptide was of host origin. Both polypeptides copurified through five column chromatographic steps. The purified enzyme preparation catalyzed synthesis of covalently linked dimeric RNA products from a poliovirion RNA template. This reaction was absolutely dependent on added oligo(U) primer, and the dimeric product appeared to be made of both plus- and minus-strand RNA molecules. Experiments with 5' [32P]oligo(U) primer and all four unlabeled nucleotides suggest that the viral replicase elongates the primer, copying the poliovirion RNA template (plus strand), and the newly synthesized minus strand snaps back on itself to generate a template-primer structure which is elongated by the replicase to form covalently linked dimeric RNA molecules. Kinetic studies showed that a partially purified preparation of poliovirus replicase contains a nuclease which can cleave the covalently linked dimeric RNA molecules, generating template-length RNA products.     

Reversion of Q beta RNA phage mutants by homologous RNA recombination.

Q beta phage RNAs with inactivating insertion (8-base) or deletion (17-base) mutations within their replicase genes were prepared from modified Q beta cDNAs and transfected into Escherichia coli spheroplasts containing Q beta replicase provided in trans by a resident plasmid. Replicase-defective (Rep-) Q beta phage produced by these spheroplasts were detected as normal-sized plaques on lawns of cells containing plasmid-derived Q beta replicase, but were unable to form plaques on cells lacking this plasmid. When individual Rep- phage were isolated and grown to high titer in cells containing plasmid-derived Q beta replicase, revertant (Rep+) Q beta phage were obtained at a frequency of ca. 10(-8). To investigate the mechanism of this reversion, a point mutation was placed into the plasmid-derived Q beta replicase gene by site-directed mutagenesis. Q beta mutants amplified on cells containing the resultant plasmid also yielded Rep+ revertants. Genomic RNA was isolated from several of the latter phage revertants and sequenced. Results showed that the original mutation (insertion or deletion) was no longer present in the phage revertants but that the marker mutation placed into the plasmid was now present in the genomic RNAs, indicating that recombination was one mechanism involved in the reversion of the Q beta mutants. Further experiments demonstrated that the 3' noncoding region of the plasmid-derived replicase gene was necessary for the reversion-recombination of the deletion mutant, whereas this region was not required for reversion or recombination of the insertion mutant. Results are discussed in terms of a template-switching model of RNA recombination involving Q beta replicase, the mutant phage genome, and plasmid-derived replicase mRNA.