Qbeta RNA replicase and protein synthesis elongation factors EF-Tu and EF-Ts

Identifying RNA recombination events and non-covalent RNA-RNA interactions with the molecular colony technique

Molecular colonies (also known under names nanocolonies, polonies, RNA or DNA colonies, PCR colonies) form when nucleic acids are amplified in a porous solid or semi-solid medium, such as a gel, which contains a system for the exponential multiplication of RNA or DNA. As an individual colony comprises many copies of a single molecule (a molecular clone), the method can be used for the detection, enumeration, and analysis of individual DNA or RNA molecules, including the products of such rare events as RNA recombinations. Here we describe protocols for the detection of RNA molecules by growing colonies of RNA (in a gel containing Qβ replicase, the RNA-dependent RNA polymerase of phage Qβ) or cDNA (in a gel containing the components of PCR), and visualizing them by hybridization with fluorescent probes directly in the gel, including in real time, or by hybridization with fluorescent or radioactive probes followed by transfer to a nylon membrane.

Effects of ribosomes on the kinetics of Qβ replication

Bacteriophage Qβ utilizes some host cell translation factors during replication. Previously, we constructed a kinetic model that explains replication of long RNA molecules by Qβ replicase. Here, we expanded the previous kinetic model to include the effects of ribosome concentration on RNA replication. The expanded model quantitatively explained single- and double-strand formation kinetics during replication with various ribosome concentrations for two artificial long RNAs. This expanded model and the knowledge obtained in this study provide useful frameworks to understand the precise replication mechanism of Qβ replicase with ribosomes and to design amplifiable RNA genomes in translation-coupling systems.

Identification of two forms of Q{beta} replicase with different thermal stabilities but identical RNA replication activity

The enzyme Qβ replicase is an RNA-dependent RNA polymerase, which plays a central role in infection by the simple single-stranded RNA virus bacteriophage Qβ. This enzyme has been used in a number of applications because of its unique activity in amplifying RNA from an RNA template. Determination of the thermal stability of Qβ replicase is important to gain an understanding of its function and potential applications, but data reported to date have been contradictory. Here, we provide evidence that these previous inconsistencies were due to the heterogeneous forms of the replicase with different stabilities. We purified two forms of replicase expressed in Escherichia coli, which differed in their thermal stability but showed identical RNA replication activity. Furthermore, we found that the replicase undergoes conversion between these forms due to oxidation, and the Cys-533 residue in the catalytic β subunit and Cys-82 residue in the EF-Tu subunit of the replicase are essential prerequisites for this conversion to occur. These results strongly suggest that the thermal stable replicase contains the intersubunit disulfide bond between these cysteines. The established strategies for isolating and purifying a thermally stable replicase should increase the usefulness of Qβ replicase in various applications, and the data regarding thermal stability obtained in this study may yield insight into the precise mechanism of infection by bacteriophage Qβ.

Functional circularity of legitimate Qbeta replicase templates

Qbeta replicase (RNA-directed RNA polymerase of bacteriophage Qbeta) exponentially amplifies certain RNAs in vitro. Previous studies have shown that Qbeta replicase can initiate and elongate on a variety of RNAs; however, only a minute fraction of them are recognized as 'legitimate' templates. Guanosine 5'-triphosphate (GTP)-dependent initiation on a legitimate template generates a stable replicative complex capable of elongation in the presence of aurintricarboxylic acid, a powerful inhibitor of RNA-protein interactions. On the contrary, initiation on an illegitimate template is GTP independent and does not result in the aurintricarboxylic-acid-resistant replicative complex. This article demonstrates that the 3' and 5' termini of a legitimate template cooperate during and after the initiation step. Breach of the cooperation by dividing the template into fragments or by introducing point mutations at the 5' terminus reduces the rate and the yield of initiation, increases the GTP requirement, decreases the overall rate of template copying, and destabilizes the postinitiation replicative complex. These results revive the old idea of a functional circularity of legitimate Qbeta replicase templates and complement the increasing body of evidence that functional circularity may be a common property of RNA templates directing the synthesis of either RNA or protein molecules.

Factors influencing RNA degradation by Thermus thermophilus polynucleotide phosphorylase

At the optimal temperature (65 degrees C), Thermus thermophilus polynucleotide phosphorylase (Tth PNPase), produced in Escherichia coli cells and isolated to functional homogeneity, completely destroys RNAs that possess even a very stable intramolecular secondary structure, but leaves intact RNAs whose 3' end is protected by chemical modification or by hybridization with a complementary oligonucleotide. This allows individual RNAs to be isolated from heterogeneous populations by degrading unprotected species. If oligonucleotide is hybridized to an internal RNA segment, the Tth PNPase stalls eight nucleotides downstream of that segment. This allows any arbitrary 5'-terminal fragment of RNA to be prepared with a precision similar to that of run-off transcription, but without the need for a restriction site. In contrast to the high Mg(2+) requirements of mesophilic PNPases, Tth PNPase retains significant activity when the free Mg(2+) concentration is in the micromolar range. This allows minimization of the Mg(2+)-catalysed nonenzymatic hydrolysis of RNA when phosphorolysis is performed at a high temperature. This capability of Tth PNPase for fully controlled RNA phosphorolysis could be utilized in a variety of research and practical applications.

Functional Qbeta replicase genetically fusing essential subunits EF-Ts and EF-Tu with beta-subunit

Qbeta replicase, an RNA-dependent RNA polymerase of RNA coliphage Qbeta, is a heterotetramer composed of a phage-encoded beta-subunit and three host-encoded proteins: the ribosomal protein S1 (alpha-subunit), EF-Tu, and EF-Ts. Several purification methods for Qbeta replicase were described previously. However, in our efforts to improve the production of Qbeta replicase, a substantial amount of the beta-subunit overproduced in Escherichia coli cells was found as insoluble aggregates. In this paper, we describe two kinds of method of producing Qbeta replicase. In one kind, both EF-Tu and EF-Ts subunits were expressed with the beta-subunit, and in the other kind, the beta-subunit was genetically fused with EF-Tu and EF-Ts. The fused protein, a single-chain alpha-less Qbeta replicase, was mostly found in the soluble fraction and could be readily purified. These results pave the way for the large-scale production of the highly purified form of this enzyme.

In vivo effect of inactivation of ribosome recycling factor - fate of ribosomes after unscheduled translation downstream of open reading frame

The post-termination ribosomal complex is disassembled by ribosome recycling factor (RRF) and elongation factor G. Without RRF, the ribosome is not released from mRNA at the termination codon and reinitiates translation downstream. This is called unscheduled translation. Here, we show that at the non-permissive temperature of a temperature-sensitive RRF strain, RRF is lost quickly, and some ribosomes reach the 3' end of mRNA. However, instead of accumulating at the 3' end of mRNA, ribosomes are released as monosomes. Some ribosomes are transferred to transfer-messenger RNA from the 3' end of mRNA. The monosomes thus produced are able to translate synthetic homopolymer but not natural mRNA with leader and canonical initiation signal. The pellet containing ribosomes appears to be responsible for rapid but reversible inhibition of most but not all of protein synthesis in vivo closely followed by decrease of cellular RNA and DNA synthesis.

Viral RNA-directed RNA polymerases use diverse mechanisms to promote recombination between RNA molecules

An earlier developed purified cell-free system was used to explore the potential of two RNA-directed RNA polymerases (RdRps), Qbeta phage replicase and the poliovirus 3Dpol protein, to promote RNA recombination through a primer extension mechanism. The substrates of recombination were fragments of complementary strands of a Qbeta phage-derived RNA, such that if aligned at complementary 3'-termini and extended using one another as a template, they would produce replicable molecules detectable as RNA colonies grown in a Qbeta replicase-containing agarose. The results show that while 3Dpol efficiently extends the aligned fragments to produce the expected homologous recombinant sequences, only nonhomologous recombinants are generated by Qbeta replicase at a much lower yield and through a mechanism not involving the extension of RNA primers. It follows that the mechanisms of RNA recombination by poliovirus and Qbeta RdRps are quite different. The data favor an RNA transesterification reaction catalyzed by a conformation acquired by Qbeta replicase during RNA synthesis and provide a likely explanation for the very low frequency of homologous recombination in Qbeta phage.

Qbeta replicase discriminates between legitimate and illegitimate templates by having different mechanisms of initiation

Qbeta replicase (RNA-directed RNA polymerase of bacteriophage Qbeta) exponentially amplifies certain RNAs (RQ RNAs) in vitro. Here we characterize template properties of the 5' and 3' fragments obtained by cleaving one of such RNAs at an internal site. We unexpectedly found that, besides the 3' fragment, Qbeta replicase can copy the 5' fragment and a number of its variants, although they lack the initiator region of RQ RNA. This copying can occur as a 3'-terminal elongation or through de novo initiation. In contradistinction to RQ RNA and its 3' fragment, initiation on these templates occurs without regard to the 3'-terminal or internal oligo(C) clusters, is GTP-independent, and does not result in a stable replicative complex capable of elongation in the presence of aurintricarboxylic acid. The results suggest that, although Qbeta replicase can initiate and elongate on a variety of RNAs, only some of them are recognized as legitimate templates. GTP-dependent initiation on a legitimate template drives the enzyme to a "closed" conformation that may be important for keeping the template and the complementary nascent strand unannealed, without which the exponential replication is impossible. Triggering the GTP-dependent conformational transition at the initiation step could serve as a discriminative feature of legitimate templates providing for the high template specificity of Qbeta replicase.

Eukaryotic elongation factor 1A interacts with the upstream pseudoknot domain in the 3' untranslated region of tobacco mosaic virus RNA

The genomic RNA of tobacco mosaic virus (TMV), like that of other positive-strand RNA viruses, acts as a template for both translation and replication. The highly structured 3' untranslated region (UTR) of TMV RNAs plays an important role in both processes; it is not polyadenylated but ends with a tRNA-like structure (TLS) preceded by a conserved upstream pseudoknot domain (UPD). The TLS of tobamoviral RNAs can be specifically aminoacylated and, in this state, can interact with eukaryotic elongation factor 1A (eEF1A)/GTP with high affinity. Using a UV cross-linking assay, we detected another specific binding site for eEF1A/GTP, within the UPDs of TMV and crucifer-infecting tobamovirus (crTMV), that does not require aminoacylation. A mutational analysis revealed that UPD pseudoknot conformation and some conserved primary sequence elements are required for this interaction. Its possible role in the regulation of tobamovirus gene expression and replication is discussed.

De novo initiation of RNA synthesis by the RNA-dependent RNA polymerase (NS5B) of hepatitis C virus

Hepatitis C virus (HCV) NS5B protein possesses an RNA-dependent RNA polymerase (RdRp) activity, a major function responsible for replication of the viral RNA genome. To further characterize the RdRp activity, NS5B proteins were expressed from recombinant baculoviruses, purified to near homogeneity, and examined for their ability to synthesize RNA in vitro. As a result, a highly active NS5B RdRp (1b-42), which contains an 18-amino acid C-terminal truncation resulting from a newly created stop codon, was identified among a number of independent isolates. The RdRp activity of the truncated NS5B is comparable to the activity of the full-length protein and is 20 times higher in the presence of Mn(2+) than in the presence of Mg(2+). When a 384-nucleotide RNA was used as the template, two major RNA products were synthesized by 1b-42. One is a complementary RNA identical in size to the input RNA template (monomer), while the other is a hairpin dimer RNA synthesized by a "copy-back" mechanism. Substantial evidence derived from several experiments demonstrated that the RNA monomer was synthesized through de novo initiation by NS5B rather than by a terminal transferase activity. Synthesis of the RNA monomer requires all four ribonucleotides. The RNA monomer product was verified to be the result of de novo RNA synthesis, as two expected RNA products were generated from monomer RNA by RNase H digestion. In addition, modification of the RNA template by the addition of the chain terminator cordycepin at the 3' end did not affect synthesis of the RNA monomer but eliminated synthesis of the self-priming hairpin dimer RNA. Moreover, synthesis of RNA on poly(C) and poly(U) homopolymer templates by 1b-42 NS5B did not require the oligonucleotide primer at high concentrations (>/=50 microM) of GTP and ATP, further supporting a de novo initiation mechanism. These findings suggest that HCV NS5B is able to initiate RNA synthesis de novo.

RNA-protein interactions: involvement of NS3, NS5, and 3' noncoding regions of Japanese encephalitis virus genomic RNA

The mechanism of replication of the flavivirus Japanese encephalitis virus (JEV) is not well known. The structures at the 3' end of the viral genome are highly conserved among divergent flaviviruses, suggesting that they may function as cis-acting signals for RNA replication and, as such, might specifically bind to cellular or viral proteins. UV cross-linking experiments were performed to identify the proteins that bind with the JEV plus-strand 3' noncoding region (NCR). Two proteins, p71 and p110, from JEV-infected but not from uninfected cell extracts were shown to bind specifically to the plus-strand 3' NCR. The quantities of these binding proteins increased during the course of JEV infection and correlated with the levels of JEV RNA synthesis in cell extracts. UV cross-linking coupled with Western blot and immunoprecipitation analysis showed that the p110 and p71 proteins were JEV NS5 and NS3, respectively, which are proposed as components of the RNA replicase. The putative stem-loop structure present within the plus-strand 3' NCR was required for the binding of these proteins. Furthermore, both proteins could interact with each other and form a protein-protein complex in vivo. These findings suggest that the 3' NCR of JEV genomic RNA may form a replication complex together with NS3 and NS5; this complex may be involved in JEV minus-strand RNA synthesis.

Nonhomologous RNA recombination in a cell-free system: evidence for a transesterification mechanism guided by secondary structure

Extensive nonhomologous recombinations occur between the 5' and 3' fragments of a replicable RNA in a cell-free system composed of pure Qbeta phage replicase and ribonucleoside triphosphates, providing direct evidence for the ability of RNAs to recombine without DNA intermediates and in the absence of host cell proteins. The recombination events are revealed by the molecular colony technique that allows single RNA molecules to be cloned in vitro. The observed nonhomologous recombinations are entirely dependent on the 3' hydroxyl group of the 5' fragment, and are due to a splicing-like reaction in which RNA secondary structure guides the attack of this 3' hydroxyl on phosphoester bonds within the 3' fragment.

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.

Evolution of RNA genomes: does the high mutation rate necessitate high rate of evolution of viral proteins?

RNA genomes have been shown to mutate much more frequently than DNA genomes. It is generally assumed that this results in rapid evolution of RNA viral proteins. Here, an alternative hypothesis is proposed that close cooperation between positive-strand RNA viral proteins and those of the host cells required their coevolution, resulting in similar amino acid substitution rates. Constraints on compatibility with cellular proteins should determine, at any time, the covarion sets in RNA viral proteins. These ideas may be helpful in rationalizing the accumulating data on significant sequence similarities between proteins of positive-strand RNA viruses infecting evolutionarily distant hosts as well as between viral and cellular proteins.

An NTP-binding motif is the most conserved sequence in a highly diverged monophyletic group of proteins involved in positive strand RNA viral replication

NTP-motif, a consensus sequence previously shown to be characteristic of numerous NTP-utilizing enzymes, was identified in nonstructural proteins of several groups of positive-strand RNA viruses. These groups include picorna-, alpha-, and coronaviruses infecting animals and como-, poty-, tobamo-, tricorna-, hordei-, and furoviruses of plants, totalling 21 viruses. It has been demonstrated that the viral NTP-motif-containing proteins constitute three distinct families, the sequences within each family being similar to each other at a statistically highly significant level. A lower, but still valid similarity has also been revealed between the families. An overall alignment has been generated, which includes several highly conserved sequence stretches. The two most prominent of the latter contain the socalled "A" and "B" sites of the NTP-motif, with four of the five invariant amino acid residues observed within these sequences. These observations, taken together with the results of comparative analysis of the positions occupied by respective proteins (domains) in viral multidomain proteins, suggest that all the NTP-motif-containing proteins of positive-strand RNA viruses are homologous, constituting a highly diverged monophyletic group. In this group the "A" and "B" sites of the NTP-motif are the most conserved sequences and, by inference, should play the principal role in the functioning of the proteins. A hypothesis is proposed that all these proteins possess NTP-binding capacity and possibly NTPase activity, performing some NTP-dependent function in viral RNA replication. The importance of phylogenetic analysis for the assessment of the significance of the occurrence of the NTP-motif (and of sequence motifs of this sort in general) in proteins is emphasized.

An in vivo recombinant RNA capable of autocatalytic synthesis by Q beta replicase

A variety of small RNAs ranging from tens to hundreds of nucleotides in length grow autocatalytically in a Q beta replicase (Q beta phage RNA-dependent RNA polymerase) reaction in the absence of added template, and similar RNAs are found in Q beta phage-infected Escherichia coli cells. Three such RNAs have been sequenced. One of them that is 221 nucleotides (nt) long ('MDV-1' RNA) has been found to be partially homologous to Q beta phage RNA 8, which might be considered as an indication of its origination from by-products of the Q beta RNA replication. To gain further insight into the origin and function of these RNAs, we have sequenced a new RNA, 120 nt long, isolated from the products of spontaneous synthesis by the nominally RNA-free Q beta replicase preparation. The minus strand of this RNA appeared to be a recombinant RNA, composed of the internal fragment of Q beta RNA (approximately 80 nt long) and the 33-nt-long 3'-terminal fragment of E. coli tRNA(1Asp). This seems to be the first strong indication of RNA recombination in bacterial cells. The various implications of this finding are discussed.

Electron microscopy study of Q beta replicase

Purified preparations of Q beta replicase have been studied by electron microscopy using a negative staining technique, and a three-dimensional model of the enzyme molecule has been constructed. The molecule of this four-subunit protein appears to be a compact structure having a size of 100 +/- 10 A; it is subdivided into two unequal bipartite subparticles. The conclusion has been made that all the constituent subunits, including the ribosomal protein Sl, acquire a globular conformation when associated in the replicase complex.

Dissociation of NS5 from cell fractions containing West Nile virus-specific polymerase activity

West Nile virus replication complexes were partially purified from cytoplasmic extracts of virus-infected cells by centrifugation through a 20% glycerol cushion. Numerous cell proteins, as well as the largest nonstructural protein, NS5, were separated from the replication complexes without significant loss of in vitro West Nile virus polymerase activity.

Characterization of West Nile virus RNA-dependent RNA polymerase and cellular terminal adenylyl and uridylyl transferases in cell-free extracts

To facilitate further studies of flavivirus transcription, cell extraction methods and in vitro reaction conditions which increased West Nile virus (WNV) RNA-dependent RNA polymerase activity were determined. Subcellular fractions from WNV-infected BHK-21/W12 cells were characterized with regard to their protein and RNA content and in vitro polymerase activity. In both a cytoplasmic fraction, designated S1, and a fraction enriched for outer nuclear membranes, designated S2, seven virus-specific proteins, NS5 (96 kilodaltons [kDa]), NS3 (67 kDa), E (48 kDa), NS1 (47 kDa), ns4a (26 kDa), ns2a (17 kDa), and ns2b (14.5 kDa), were detected. The fractions also contained virus-specific RNA and cellular rRNA and mRNA. Polymerase activity in S1 and S2 fractions from WNV-infected cells was concentrated by pelleting and consisted of two types of enzyme activities: the WNV RNA-dependent RNA polymerase and terminal transferases of cellular origin. Enhanced levels of WNV polymerase activity were obtained from these cell fractions by altering several of the in vitro reaction conditions. Although Mg2+ was the divalent cation preferred by WNV polymerase, virus-specific in vitro transcription was detected at reduced levels when Mn2+ (0.05 or 0.5 mM) was present as the sole divalent cation. Product analysis revealed that the viral polymerase incorporated radiolabeled ribonucleotides into three distinct RNA species. Free single-stranded genome-sized RNA which was LiCl insoluble and RNase sensitive was found by fingerprint analysis to have an oligonucleotide pattern similar to that of WNV genomic RNA. RNA molecules which comigrated as a broad band near the top of the gel were separable into LiCl-insoluble, partially RNase-sensitive replicative-intermediate RNA and LiCl-soluble, RNase-resistant replicative-form RNA. The cellular transferases added UMP or AMP residues to the 3'-termini of cellular mRNA, tRNA, and 18S and 28S rRNA. Although a cellular terminal transferase has been reported to function in initiation of poliovirus transcription, no labeling of the WNV RNA by either of these cellular enzymes was detected. Therefore, they appear to play no specific role in flavivirus RNA synthesis.

Template-free RNA synthesis by Q beta replicase

In the absence of extraneously added template, standard preparations of Q beta replicase spontaneously synthesize RNA in vitro, possibly as a result of RNA contamination. Using special enzyme purifications, Sumper and Luce presented evidence that self-replicating RNA not present ab initio can grow out of 'template-free' incorporation mixtures. In contrast to DNA polymerase I and RNA polymerase, which also show de novo synthesis, the products synthesized 'de novo' by Q beta replicase are RNA species containing nonrepetitive sequences of defined lengths which differ between experiments, even when synthesized under identical conditions, in fingerprints, chain lengths and kinetic parameters. Kinetic analysis of the de novo processes distinguished it from template-instructed synthesis and excluded an assumption of self-replicating RNA contamination. These conclusions were questioned recently by Hill and Blumenthal, who claimed to show that highly purified Q beta replicase preparations cannot produce RNA de novo. We now present evidence that, under the conditions required for de novo synthesis, Q beta replicase prepared according to their method is also capable of de novo synthesis. Furthermore, we show that Q beta replicase condenses nucleoside triphosphates to more or less random oligonucleotides.

Q beta replicase containing a Bacillus stearothermophilus elongation factor

We purified Q beta replicase containing EF-Ts from Bacillus stearothermophilus in place of the homologous polypeptide from Escherichia coli. The hybrid enzyme was fully active in the transcription of a variety of templates. It was found to be qualitatively similar to native Q beta replicase with respect to a variety of parameters which measure the efficiency of initiation of RNA synthesis. The results demonstrated that Q beta replicase can tolerate substantial alterations in the EF-Tu X Ts component of the enzyme. These alterations resulted in only minor perturbations of catalytic properties.

Does Q beta replicase synthesize RNA in the absence of template?

Q beta replicase, in the absence of added template, will synthesize RNA autocatalytically. A variety of small RNa species, termed '6S RNAs' are generated. As this reaction purportedly occurs in the absence of template, it has been termed 'de novo' RNA synthesis. The question of whether Q beta replicase can polymerize replicatable RNA molecules, without instruction from a template, has important evolutionary implications. The finding that Q beta replicase was able to synthesize RNA de novo was based on (1) failure to find contaminating RNA in Q beta replicase preparations; (2) differences in the sizes of products of apparently identical reactions; and (3) kinetic differences between template-instructed and de novo reactions. Here wer describe a procedure for production of Q beta replicase lacking one of its subunits, ribosomal protein S1, involving column chromatography in the presence of a low concentration of urea. We show that the resulting highly purified enzyme will not synthesize detectable RNA in the absence of added template. We show also that the ability to perform a reaction kinetically indistinguishable from the de novo synthesis reaction can be restored to the highly purified enzyme by adding a heat-stable, alkali-labile component of Q beta replicase preparations. Thus our findings suggest that, in the novo reaction, Q beta replicase is replicating previously undetected contaminating RNA molecules.

Protein synthesis elongation factors Tu and Tu.Ts from Caulobacter crescentus: sensitivity to kirromycin and activity in Q beta replicase

The protein synthesis elongation factors Tu and Ts are responsible for binding aminoacyl-transfer ribonucleic acid (RNA) to the ribosome. In addition, they perform an undefined function, as the EF-Tu.Ts complex, in the RNA phage RNA replicases. In an effort to obtain insight into these two apparently unrelated roles, we purified the elongation factors from Caulobacter crescentus and compared them to the analogous Escherichia coli polypeptides. Although most physical and functional characteristics were found to be similar, significant differences were found in the molecular weight of EF-Ts and relative affinities of guanine nucleotides, sensitivity to trypsin cleavage, and rate of heat denaturation of EF-Tu. The antibiotic kirromycin was active with EF-Tu from both bacterial species. When C. crescentus EF-Tu.Ts was substituted for the E. coli elongation factors in Q beta phage RNA replicase, an enzyme capable of apparently normal RNA synthetic activity was formed.

Q beta replicase template specificity: different templates require different GTP concentrations for initiation

Qbeta replicase is notable for its high degree of template specificity. It has been shown to transcribe Qbeta RNA and synthetic polymers containing cytidylate. However, other natural RNAs are not transcribed unless Mn2+ ions are present. The enzyme initiates all RNA synthesis with GTP. In this report it is shown that Qbeta replicase can transcribe heterologous natural RNA species in the absence of Mn2+ if sufficient GTP is present. Each RNA tested requires a different GTP concentration for initiation. These results indicate that the site for the initiating nucleoside triphosphate on Qbeta replicase is strongly influenced by the template. It is proposed that the high degree of template specificity is a consequence of the fact that different templates induce initiation sites with varying affinities for GTP. Two lines of evidence support this idea. First, Mn2+ ions, which reduce template specificity, reduce the concentration of GTP required for initiation. Second, high ionic strength, which decreases transcription of all templates except Qbeta RNA, increases the GTP requirement. The possibility is considered that variable promoter or ribosome binding site strengths could result from a mechanism similar to that proposed here.