Beta Replicase Research Articles

1P126 Qβレプリカーゼの酵素学 : 鋳型RNAがQβレプリカーゼを罠に捕らえる(核酸結合蛋白質))

1P126 Qβレプリカーゼの酵素学 : 鋳型RNAがQβレプリカーゼを罠に捕らえる(核酸結合蛋白質))

RNA replication by Q beta replicase: a working model.

Two classes of RNA ligands that bound to separate, high affinity nucleic acid binding sites on Q beta replicase were previously identified. RNA ligands to the two sites, referred to as site I and site II, were used to investigate the molecular mechanism of RNA replication employed by the four-subunit replicase. Replication inhibition by site I- and site II-specific ligands defined two subsets of replicatable RNAs. When provided with appropriate 3' ends, ligands to either site served as replication templates. UV crosslinking experiments revealed that site I is associated with the S1 subunit, site II with elongation factor Tu, and polymerization with the viral subunit of the holoenzyme. These results provide the framework for a three site model describing template recognition and product strand initiation by Q beta replicase.

Extremely sensitive, background-free gene detection using binary probes and beta replicase.

We have developed a specific and sensitive nucleic acid amplification assay that is suitable for routine gene detection. The assay is based on a novel molecular genetic strategy in which two different RNA probes are hybridized to adjacent positions on a target nucleic acid and then ligated to form an amplifiable reporter RNA. The reporter RNA is then replicated up to a hundred billion-fold in a 30-min isothermal reaction that signals the presence of the target. The assay can detect fewer than 100 nucleic acid molecules; it provides quantitative results over a wide range of target concentrations and it employs a universal format that can detect any infectious agent.

Significance of strand configuration in self-replicating RNA molecules.

The kinetic theory of replication has been extended to include dual mechanisms for conversion of self-annealed single-strand RNA to double-strand molecules, which do not replicate. An analysis of experimental results established that the replicate-template annealing reaction during transcription significantly retarded replication in vitro among three RNA variants copied by Q beta replicase. Annealing between complementary RNA strands free in solution had far less significance. The finding that an RNA variant can be replicated in a multiple hairpin configuration, but not as its single, long hairpin conformer, the correlation between stability of strand secondary structure and replicative fitness, and a lack of homology in the internal sequence of RNA variants copied by Q beta replicase support the conclusion that template competence depends on strand configuration, independent of most of the underlying base sequence. Occurrence of self-annealed strands in the Q beta replicase system was attributed to its reliance on RNA-driven strand separation, in the absence of enzyme catalysed strand unwinding. A 'configuration before sequence' path to self-replication exhibited a substantially lower combinatorial barrier than standard sequence-dependent evolution. RNA-dependent RNA synthesis in the Q beta system thus displays features of an RNA World and, interestingly, they reveal a rapid path for evolution of the first self-replicating molecule on Earth.

Selection and characterization of RNAs replicated by Q beta replicase.

RNAs replicated by Q beta replicase were isolated from two random sequence RNA populations (one 56 nucleotides in length, the second 83) using a replication/dilution protocol. The selected molecules were cloned and sequenced, generating data set of 54 replicatable RNAs bound with higher affinity to Q beta replicase than did the random populations from which they were selected. Deletion analyses on two of the molecules indicated that internal regions of the RNAs were responsible for the specific binding of Q beta replicase. Truncated molecules representing the minimized RNA binding sites could inhibit replication of the full-length molecules, apparently by obstructing their binding to the replicase. The binding regions of the two RNAs were dominated by extended runs of pyrimidines. Similar C/U-rich regions existed in 85% of the sequences in the data set as well as in all of the previously published replicatable sequences. Mutation of the polypyrimidine domain of one of the replicatable sequences reduced the affinity of the molecule for Q beta replicase by 10-fold and completely abolished its ability to be replicated.

Template recognition by an RNA-dependent RNA polymerase: identification and characterization of two RNA binding sites on Q beta replicase.

Two different SELEX protocols were used to generate two classes of RNA ligands that bound Q beta replicase with nanomolar equilibrium dissociation constants. One set of RNAs appeared to exist as pseudoknots with conserved loop sequences. These ligands bound Q beta replicase and ribosomal protein S1 with equal affinities, indicating that the RNAs bind the replicase through its S1 subunit. The second class of ligands bound the replicase via a pyrimidine rich region. The two sets of ligands did not compete for binding to Q beta replicase, demonstrating that the two RNA families bind unique sites on the phage polymerase. Because the second class of ligands bound ribosomal protein S1 very poorly, it is likely that the second RNA binding site is located on one of the three remaining replicase subunits. Published sequences of RNAs replicated by Q beta replicase possess similarities to the two classes of RNA ligands, providing a possible solution to the question of template recognition by the phage polymerase.

Comparison of characteristics of Q beta replicase-amplified assay with competitive PCR assay for Chlamydia trachomatis

In order to study infections due to Chlamydia trachomatis, we have compared semiquantitative PCR and Q beta replicase-amplified assays for detection of this organism. The PCR assay was directed against the C. trachomatis 16S rRNA gene. Quantitation was accomplished by adding known amounts of a plasmid containing a truncated segment of the 16S rRNA gene target to chlamydia-containing samples and then amplifying with a common primer set. The Q beta replicase assay consisted of reversible target capture of C. trachomatis 16S rRNA, which was followed by amplification of an RNA detector probe in the presence of the enzyme Q beta replicase. In a clinical matrix, the lower limit of detection of both the PCR and Q beta replicase assays was five elementary bodies. The Q beta replicase and PCR assays were quantitative over 10,000- and 1,000-fold ranges of organisms, respectively. Analysis of the effects of endocervical matrix on amplification was accomplished by examining 94 endocervical specimens by each technique. Both assays detected five of six culture-confirmed specimens as well as three culture-negative specimens. PCR inhibitors were detected in 13 specimens. The Q beta replicase assay, in contrast, showed no evidence of sample inhibition. The Q beta replicase and PCR assays should allow quantitative investigation of infections due to C. trachomatis. In addition, because it targets highly labile RNA, the Q beta replicase assay may facilitate investigations into the role of active persisting infection in culture-negative inflammatory conditions.

Design of artificial short-chained RNA species that are replicated by Q beta replicase.

Different RNA species that are replicated by Q beta replicase have related secondary structures: for both plus and minus strands, "leader" stem structures were found at their 5' termini, while their 3' termini were unpaired. Parallel structures in complementary strands rather than antiparallel ones require the occurrence of wobble pairs and other imperfections in the stem regions. To test whether the leader structures are required for replication, artificial RNA sequences were synthesized by transcription from synthetic oligodeoxynucleotides with T7 RNA polymerase and assayed for their ability to be replicated by Q beta replicase. A synthetic short RNA species known to be replicated was amplified, forming a stable quasi-species; i.e., its sequence was conserved during hundreds of replication rounds. A synthetic mutant of this sequence that stabilized the leader in one strand but favored a 3'-terminal stem in the other one led to the complete loss of template activity. When new RNA sequences with the described structural requirements were designed and synthesized, their template activity was too low to be directly measurable; however, incubation with replicase produced replicating RNA whose sequence was closely related to the synthesized RNA species. The most likely interpretation is that the designed sequences were in a low montainous region in the replication fitness landscape and were optimized during amplification by Q beta replicase to a nearby fitness peak. The structural features postulated to be required for replication were not only conserved but even improved in the outgrowing mutants.(ABSTRACT TRUNCATED AT 250 WORDS)

A complete plasmid-based complementation system for RNA coliphage Qβ: Three proteins of bacteriophages Qβ (Group III) and SP (Group IV) can be interchanged

Our laboratory has established a bacteriophage Q beta cDNA-containing plasmid system in which virtually all coding defects present within the 4217 nucleotide Q beta genome can be complemented in trans. In this system, Q beta minus strand RNAs are constitutively transcribed from plasmid cDNA by Escherichia coli RNA polymerase. Replication of these minus strands results in the synthesis of Q beta plus RNA, thereby triggering an infectious cycle in which Q beta phase particles are generated. Genetically engineered Q beta genome mutations that result in defective viral proteins can be complemented in trans by the products of one or more Q beta helper plasmids that express either: (1) Q beta maturation protein, which can complement defects in the Q beta maturation cistron (nucleotides 61 to 1320); (2) Q beta readthrough protein, which can complement defects in the readthrough cistron (nucleotides 1344 to 2330); or (3) Q beta replicase, which can complement defects in the replicase cistron (nucleotides 2352 to 4118). Each plasmid component of this system contains a unique origin of replication and carries a different antibiotic gene, thereby enabling all combinations of these plasmids to coexist in the same host. We have further developed a second series of helper plasmids that generate the corresponding viral proteins of the related group IV RNA phage SP. Each of these SP helper proteins can complement respective defects within the Q beta genome with efficiencies similar to those observed for the Q beta helper proteins. It is now possible to supply functional Q beta or SP proteins in trans to examine Q beta genomes that contain protein coding defects for their ability to synthesize Q beta proteins, replicate Q beta RNA, assemble virions, and/or lyse the host cell.

Coupled replication-translation of amplifiable messenger RNA. A cell-free protein synthesis system that mimics viral infection.

Amplifiable messenger RNAs (Wu, Y., Zhang, D. Y., and Kramer, F. R. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 11769-11773) were used as templates in coupled replication-translation reactions. These amplifiable mRNAs contained a preselected messenger sequence embedded within the sequence of MDV-1 RNA, which is a small, naturally occurring template for Q beta replicase. When these recombinant mRNAs were incubated in vitro in reactions that contained both an Escherichia coli cell-free translation system and Q beta replicase, the encoded protein was synthesized more efficiently than in corresponding reactions that did not contain Q beta replicase. Moreover, when coupled replication-translation reactions were carried out in a continuous-flow format (Spirin, A. S., Baranov, V. I., Ryabova, L. A., Ovodov, S. Yu., and Alakhov, Yu. B. (1988) Science 242, 1162-1164), the synthesis of biologically active protein continued for a prolonged period. The results suggest that the mechanism of replication and translation in coupled reactions is similar to the mechanism by which Q beta phage genomic RNA is simultaneously replicated and translated in Q beta-infected E. coli: protein synthesis occurs on nascent RNA strands; many more sense strands are synthesized than antisense strands; and the integrity of the messenger sequence is preserved because a relatively small number of antisense strands serve as master templates for the synthesis of new messenger strands.

Synergism in replication and translation of messenger RNA in a cell-free system.

Combination of the Q beta replicase reaction with the Escherichia coli cell-free translation system markedly enhances replication of a recombinant RQ-DHFR RNA consisting of the dihydrofolate reductase (DHFR) mRNA sequence inserted into RQ135(-1) RNA, an efficient naturally occurring Q beta replicase template. The enhancement is associated with a replication asymmetry previously described for the replication of Q beta phage RNA in vivo; the sense (+)-strands are produced in large excess over the antisense (-)-strands. This, in turn, results in increased synthesis of the functionally active DHFR. These effects are not observed when DHFR mRNAs or RQ135(-1) RNAs are used as templates, if the translation system is not complete, or if it is inhibited by puromycin. The coupled replication-translation of nonviral mRNA recombinants can serve as a useful model for studying the fundamental aspects of virus amplification and can be implemented for large-scale protein synthesis in vitro.

Nucleic acid amplification technologies.

The polymerase chain reaction, Q beta replicase methodology, the ligase chain reaction, the self-sustained sequence replication system, and the new strand displacement assay have continued to progress with the development of improved reagents and new applications. These advances in enzymatic nucleic acid amplification strategies continue to provide research and medical communities with an ever-improving arsenal of ways to amplify RNA and DNA.

Cloning of RNA molecules in vitro.

A method for RNA amplification in an immobilized medium is described. The medium contains a complete set of nucleotide substrates and purified Q beta replicase, an enzyme capable of exponentially amplifying RNAs under isothermal conditions. RNA amplification in the immobilized medium results in the formation of separate 'colonies', each comprising the progeny of a single RNA molecule (a clone). The colonies were visualized by staining with ethidium bromide, by utilizing radioactive substrates, and by hybridization with sequence-specific labeled probes. The number and identity of the RNA colonies corresponded to that of the RNAs seeded. When a mixture of different RNA species was seeded, these species were found in different colonies. Possible implementations of this technique include a search for recombinant RNAs, very sensitive nucleic acid diagnostics, and gene cloning in vitro.

Amplifiable messenger RNA.

RNA molecules were prepared that consisted of an mRNA encoding chloramphenicol acetyltransferase embedded within the sequence of midivariant RNA, which is a template for the RNA-directed RNA polymerase Q beta replicase. These recombinant RNAs were shown to be bifunctional: they are amplified exponentially by incubation with Q beta replicase, and the replicated RNA serves as template for the cell-free synthesis of enzymatically active chloramphenicol acetyltransferase. The availability of amplifiable mRNAs will enable relatively large amounts of protein to be synthesized in vitro.

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.

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.

Self‐catalysed affinity labeling of Qβ 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.

Polymerase chain reaction and Q beta replicase amplification

The polymerase chain reaction (PCR) and Q beta replicase are two methods in which nucleic acid polymerases are used for amplification. Although these approaches share many similar problems concerning target contamination and probe specificity, they differ dramatically in their mechanisms of action and modes of application. The PCR method amplifies target sequences between two priming oligonucleotides and in essence amplifies a portion of the analyte. Q beta replicase, on the other hand, amplifies a specific template molecule hybridized to target sequences and therefore amplifies a signal component of the system. For this reason, Q beta replicase amplification has applications in areas other than for the detection of nucleic acid sequences. The requirements for application and the advantages of both PCR and Q beta replicase amplification are reviewed.

Ribosome-messenger recognition: mRNA target sites for ribosomal protein S1

Ribosomal protein S1 is known to play an important role in translational initiation, being directly involved in recognition and binding of mRNAs by 30S ribosomal particles. Using a specially developed procedure based on efficient crosslinking of S1 to mRNA induced by UV irradiation, we have identified S1 binding sites on several phage RNAs in preinitiation complexes. Targets for S1 on Q beta and fr RNAs are localized upstream from the coat protein gene and contain oligo(U)-sequences. In the case of Q beta RNA, this S1 binding site overlaps the S-site for Q beta replicase and the site for S1 binding within a binary complex. It is reasonable that similar U-rich sequences represent S1 binding sites on bacterial mRNAs. To test this idea we have used E. coli ssb mRNA prepared in vitro with the T7 promoter/RNA polymerase system. By the methods of toeprinting, enzymatic footprinting, and UV crosslinking we have shown that binding of the ssb mRNA to 30S ribosomes is S1-dependent. The oligo(U)-sequence preceding the SD domain was found to be the target for S1. We propose that S1 binding sites, represented by pyrimidine-rich sequences upstream from the SD region, serve as determinants involved in recognition of mRNA by the ribosome.

Q beta RNA bacteriophage: mapping cis-acting elements within an RNA genome

We have identified, for the first time, regions of cis-acting RNA elements within the bacteriophage Q beta replicase cistron by analyzing the infectivities of 76 replicase gene mutant phages in the presence of a helper replicase. Two separate classes of mutant Q beta phage genomes (35 different insertion mutants, each containing an insertion of 3 to 15 nucleotides within the replicase gene, and 41 deletion genomes, each having from 15 to 935 nucleotides deleted from different regions of the gene) were constructed, and their corresponding RNAs were tested for the ability to direct the formation of progeny virus particles. Each mutant phage was tested for plaque formation in an Escherichia coli (F+) host strain that supplied helper Q beta replicase in trans from a plasmid DNA. Of the 76 mutant genomes, 34% were able to direct virus production at or close to wild-type levels (with plaque yield ratios of greater than 0.5), another 36% also produced virus particles, but at much lower levels than those of wild-type virus (with plaque yield ratios of less than 0.05), and the remaining 30% produced no virus at all. From these data, we have been able to define regions within the Q beta replicase gene that contain functional cis-acting RNA elements and further correlate them with regions of RNA that are solely required to code for functional RNA polymerase.