On the nature of spontaneous RNA synthesis by Q beta replicase

Design of Novel Synthetic RNA Replicons Based on Emesvirus zinderi

Self-replicating RNAs (srRNAs) are synthetic molecules designed to mimic the self-replicating ability of viral RNAs. srRNAs hold significant promise for a range of applications, including enhancing protein expression, reprogramming cells into pluripotent stem cells, and creating cell-free systems for experimental evolution. However, the development of srRNAs for use in bacterial systems remains limited. Here, we demonstrate how a srRNA scaffold from Emesvirus zinderi can be engineered into a self-encoding srRNA by incorporating the coding region of the catalytically active replicase subunit. With the help of in vitro replication assays, including an in vitro translation-coupled replication approach, we show that the resulting system enables complete replication cycles of RNA both in cis and trans, including long cargo RNAs such as tethered 5S, 16S, and 23S rRNAs. In summary, our findings suggest that these srRNAs have significant potential for fundamental research, synthetic biology, and general in vitro evolution.

Slippage at the initiation of RNA synthesis by Qβ replicase results in a periodic polyG pattern

The repetitive copying of template nucleotides due to transcriptional slippage has not been reported for RNA-directed RNA polymerases of positive-strand RNA phages. We unexpectedly observed that, with GTP as the only substrate, Qβ replicase, the RNA-directed RNA polymerase of bacteriophage Qβ, synthesizes by transcriptional slippage polyG strands, which on denaturing electrophoresis produce a ladder with at least three clusters of bolder bands. The ≈ 15-nt-long G₁₅ , the major product of the shortest cluster, is tightly bound by the enzyme but can be released by the ribosomal protein S1, which, as a Qβ replicase subunit, normally promotes the release of a completed transcript. 7-deaza-GTP suppresses the polyG synthesis and abolishes the periodic pattern, suggesting that the N7 atom is needed for the initiation of RNA synthesis and the formation of the structure recognized by protein S1. The results provide new insights into the mechanism of RNA synthesis by the RNA-directed RNA polymerase of a single-stranded RNA phage.

In vitro characterisation of the MS2 RNA polymerase complex reveals host factors that modulate emesviral replicase activity

The RNA phage MS2 is one of the most important model organisms in molecular biology and virology. Despite its comprehensive characterisation, the composition of the RNA replication machinery remained obscure. Here, we characterised host proteins required to reconstitute the functional replicase in vitro. By combining a purified replicase sub-complex with elements of an in vitro translation system, we confirmed that the three host factors, EF-Ts, EF-Tu, and ribosomal protein S1, are part of the active replicase holocomplex. Furthermore, we found that the translation initiation factors IF1 and IF3 modulate replicase activity. While IF3 directly competes with the replicase for template binding, IF1 appears to act as an RNA chaperone that facilitates polymerase readthrough. Finally, we demonstrate in vitro formation of RNAs containing minimal motifs required for amplification. Our work sheds light on the MS2 replication machinery and provides a new promising platform for cell-free evolution.

Alexander Spirin on Molecular Machines and Origin of Life

Once it was believed that ribosomal RNA encodes proteins, and GTP hydrolysis supplies the energy for protein synthesis. Everything has changed, when Alexander Spirin joined the science. It turned out that proteins are encoded by a completely different RNA, and GTP hydrolysis only accelerates the process already provided with energy. It was Spirin who first put forward the idea of a Brownian ratchet and explained how and why molecular machines could arise in the RNA world.

What can we learn from the construction of in vitro replication systems?

Replication is a central function of living organisms. Several types of replication systems have been constructed in vitro from various molecules, including peptides, DNA, RNA, and proteins. In this review, I summarize the progress in the construction of replication systems over the past few decades and discuss what we can learn from their construction. I introduce various types of replication systems, supporting the feasibility of the spontaneous appearance of replication early in Earth's history. In the latter part of the review, I focus on parasitic replicators, one of the largest obstacles for sustainable replication. Compartmentalization is discussed as a possible solution.

Protein-RNA Interactions in the Single-Stranded RNA Bacteriophages

Bacteriophages of the Leviviridae family are small viruses with short single-stranded RNA (ssRNA) genomes. Protein-RNA interactions play a key role throughout the phage life cycle, and all of the conserved phage proteins - the maturation protein, the coat protein and the replicase - are able to recognize specific structures in the RNA genome. The phage-coded replicase subunit associates with several host proteins to form a catalytically active complex. Recognition of the genomic RNA by the replicase complex is achieved in a remarkably complex manner that exploits the RNA-binding properties of host proteins and the particular three-dimensional structure of the phage genome. The coat protein recognizes a hairpin structure at the beginning of the replicase gene. The binding interaction serves to regulate the expression of the replicase gene and can be remarkably different in various ssRNA phages. The maturation protein is a minor structural component of the virion that binds to the genome, mediates attachment to the host and guides the genome into the cell. The maturation protein has two distinct RNA-binding surfaces that are in contact with different regions of the genome. The maturation and coat proteins also work together to ensure the encapsidation of the phage genome in new virus particles. In this chapter, the different ssRNA phage protein-RNA interactions, as well as some of their practical applications, are discussed in detail.

Transient compartmentalization of RNA replicators prevents extinction due to parasites

The appearance of molecular replicators (molecules that can be copied) was probably a critical step in the origin of life. However, parasitic replicators would take over and would have prevented life from taking off unless the replicators were compartmentalized in reproducing protocells. Paradoxically, control of protocell reproduction would seem to require evolved replicators. We show here that a simpler population structure, based on cycles of transient compartmentalization (TC) and mixing of RNA replicators, is sufficient to prevent takeover by parasitic mutants. TC tends to select for ensembles of replicators that replicate at a similar rate, including a diversity of parasites that could serve as a source of opportunistic functionality. Thus, TC in natural, abiological compartments could have allowed life to take hold.

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.

The first two nucleotides of the respiratory syncytial virus antigenome RNA replication product can be selected independently of the promoter terminus

There is limited knowledge regarding how the RNA-dependent RNA polymerases of the nonsegmented negative-strand RNA viruses initiate genome replication. In a previous study of respiratory syncytial virus (RSV) RNA replication, we found evidence that the polymerase could select the 5'-ATP residue of the genome RNA independently of the 3' nucleotide of the template. To investigate if a similar mechanism is used during antigenome synthesis, a study of initiation from the RSV leader (Le) promoter was performed using an intracellular minigenome assay in which RNA replication was restricted to a single step, so that the products examined were derived only from input mutant templates. Templates in which Le nucleotides 1U, or 1U and 2G, were deleted directed efficient replication, and in both cases, the replication products were initiated at the wild-type position, at position -1 or -2 relative to the template, respectively. Sequence analysis of the RNA products showed that they contained ATP and CTP at the -1 and -2 positions, respectively, thus restoring the mini-antigenome RNA to wild-type sequence. These data indicate that the RSV polymerase is able to select the first two nucleotides of the antigenome and initiate at the correct position, even if the 3'-terminal two nucleotides of the template are missing. Substitution of positions +1 and +2 of the template reduced RNA replication and resulted in increased initiation at positions +3 and +5. Together these data suggest a model for how the RSV polymerase initiates antigenome synthesis.

How RNA viruses maintain their genome integrity

RNA genomes are vulnerable to corruption by a range of activities, including inaccurate replication by the error-prone replicase, damage from environmental factors, and attack by nucleases and other RNA-modifying enzymes that comprise the cellular intrinsic or innate immune response. Damage to coding regions and loss of critical cis-acting signals inevitably impair genome fitness; as a consequence, RNA viruses have evolved a variety of mechanisms to protect their genome integrity. These include mechanisms to promote replicase fidelity, recombination activities that allow exchange of sequences between different RNA templates, and mechanisms to repair the genome termini. In this article, we review examples of these processes from a range of RNA viruses to showcase the diverse approaches that viruses have evolved to maintain their genome sequence integrity, focusing first on mechanisms that viruses use to protect their entire genome, and then concentrating on mechanisms that allow protection of the genome termini, which are especially vulnerable. In addition, we discuss examples in which it might be beneficial for a virus to 'lose' its genomic termini and reduce its replication efficiency.

Question 5: on the chemical reality of the RNA world

The discovery of catalytic RNA has revolutionised modern molecular biology and bears important implications for the origin of Life research. Catalytic RNA, in particular self-replicating RNA, prompted the hypothesis of an early "RNA world" where RNA molecules played all major roles such information storage and catalysis. The actual role of RNA as primary actor in the origin of life has been under debate for a long time, with a particular emphasis on possible pathways to the prebiotic synthesis of mononucleotides; their polymerization and the possibility of spontaneous emergence of catalytic RNAs synthesised under plausible prebiotic conditions. However, little emphasis has been put on the chemical reality of an RNA world; in particular concerning the chemical constrains that such scenario should have met to be feasible. This paper intends to address those concerns with regard to the achievement of high local RNA molecules concentration and the aetiology of unique sequence under plausible prebiotic conditions.

Express hybridization of molecular colonies with fluorescent probes

DNA colonies formed during PCR in a polyacrylamide gel and RNA colonies grown in an agarose gel containing Qbeta replicase can be identified using the procedure of transfer of molecular colonies onto a nylon membrane followed by membrane hybridization with fluorescent oligonucleotide probes. The suggested improvements significantly simplify and accelerate the procedure. By the example of a chimeric AML1-ETO sequence, a marker of frequently occurring leukemia, the express hybridization method was shown to allow the rapid identification of single molecules and the determination of titers of DNA and RNA targets. Hybridization with a mixture of two oligonucleotide probes labeled with different fluorophores complementary to components of the chimeric molecule ensures the identification of molecular colonies containing both parts of the chimeric sequence and improves the specificity of diagnostics.

RNA mutagenesis yields highly diverse mRNA libraries for in vitro protein evolution

BACKGROUND

In protein drug development, in vitro molecular optimization or protein maturation can be used to modify protein properties. One basic approach to protein maturation is the introduction of random DNA mutations into the target gene sequence to produce a library of variants that can be screened for the preferred protein properties. Unfortunately, the capability of this approach has been restricted by deficiencies in the methods currently available for random DNA mutagenesis and library generation. Current DNA based methodologies generally suffer from nucleotide substitution bias that preferentially mutate particular base pairs or show significant bias with respect to transitions or transversions. In this report, we describe a novel RNA-based random mutagenesis strategy that utilizes Qbeta replicase to manufacture complex mRNA libraries with a mutational spectrum that is close to the ideal.

RESULTS

We show that Qbeta replicase generates all possible base substitutions with an equivalent preference for mutating A/T or G/C bases and with no significant bias for transitions over transversions. To demonstrate the high diversity that can be sampled from a Qbeta replicase-generated mRNA library, the approach was used to evolve the binding affinity of a single domain VNAR shark antibody fragment (12Y-2) against malarial apical membrane antigen-1 (AMA-1) via ribosome display. The binding constant (KD) of 12Y-2 was increased by 22-fold following two consecutive but discrete rounds of mutagenesis and selection. The mutagenesis method was also used to alter the substrate specificity of beta-lactamase which does not significantly hydrolyse the antibiotic cefotaxime. Two cycles of RNA mutagenesis and selection on increasing concentrations of cefotaxime resulted in mutants with a minimum 10,000-fold increase in resistance, an outcome achieved faster and with fewer overall mutations than in comparable studies using other mutagenesis strategies.

CONCLUSION

The RNA based approach outlined here is rapid and simple to perform and generates large, highly diverse populations of proteins, each differing by only one or two amino acids from the parent protein. The practical implications of our results are that suitable improved protein candidates can be recovered from in vitro protein evolution approaches using significantly fewer rounds of mutagenesis and selection, and with little or no collateral damage to the protein or its mRNA.

Kinetic analysis of the entire RNA amplification process by Qbeta replicase

The kinetics of the RNA replication reaction by Qbeta replicase were investigated. Qbeta replicase is an RNA-dependent RNA polymerase responsible for replicating the RNA genome of coliphage Qbeta and plays a key role in the life cycle of the Qbeta phage. Although the RNA replication reaction using this enzyme has long been studied, a kinetic model that can describe the entire RNA amplification process has yet to be determined. In this study, we propose a kinetic model that is able to account for the entire RNA amplification process. The key to our proposed kinetic model is the consideration of nonproductive binding (i.e. binding of an enzyme to the RNA where the enzyme cannot initiate the reaction). By considering nonproductive binding and the notable enzyme inactivation we observed, the previous observations that remained unresolved could also be explained. Moreover, based on the kinetic model and the experimental results, we determined rate and equilibrium constants using template RNAs of various lengths. The proposed model and the obtained constants provide important information both for understanding the basis of Qbeta phage amplification and the applications using Qbeta replicase.

Expressible molecular colonies

Carrying out polymerase chain reaction in a gel layer generates a 2-D pattern of DNA colonies comprising pure genetic clones. Here we demonstrate that transcription, translation and protein folding can be performed in the same gel. The resulting nucleoprotein colonies mimic living cells by serving as compartments in which the synthesized RNAs and proteins co-localize with their templates. Yet, due to the absence of penetration barriers, such a molecular colony display allows cloned genes to be directly tested for the encoded functions. Now, the results imply that virtually any manipulations with genes and their expression products can be accomplished in vitro.

Diverse Mechanisms of RNA Recombination

Recombination is widespread among RNA viruses, but many molecular mechanisms of this phenomenon are still poorly understood. It was believed until recently that the only possible mechanism of RNA recombination is replicative template switching, with synthesis of a complementary strand starting on one viral RNA molecule and being completed on another. The newly synthesized RNA is a primary recombinant molecule in this case. Recent studies have revealed other mechanisms of replicative RNA recombination. In addition, recombination between the genomes of RNA viruses can be nonreplicative, resulting from a joining of preexisting parental molecules. Recombination is a potent tool providing for both the variation and conservation of the genome in RNA viruses. Replicative and nonreplicative mechanisms may contribute differently to each of these evolutionary processes. In the form of trans splicing, nonreplicative recombination of cell RNAs plays an important role in at least some organisms. It is conceivable that RNA recombination continues to contribute to the evolution of DNA genomes.

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.

Simultaneous assay of DNA and RNA targets in the whole blood using novel isolation procedure and molecular colony amplification

A universal procedure that permits the whole human blood to be tested for the presence of single molecules of DNA and RNA targets is described. The procedure includes a novel protocol for the isolation of total nucleic acids from the guanidinium thiocyanate lysate of unfractionated blood in which, prior to phenol/chloroform extraction, the sample is deproteinized by precipitation with isopropanol. The procedure results in a nearly 100% yield of DNA and RNA, preserves the integrity of RNA, and removes any polymerase chain reaction (PCR) inhibitors. Following reverse transcription (RT), target molecules are counted after having been amplified as molecular colonies by carrying out PCR in a polyacrylamide gel. The entire procedure was checked by assaying viral DNA and RNA in 100-microl aliquots of the whole blood and was found to be capable of detecting 100% molecules of DNA target and 50% molecules of RNA target. Unexpectedly, nucleic acids at relatively high concentrations (1 ng/microl) were found to selectively inhibit the RT activity of Thermus thermophilus DNA polymerase without affecting its DNA-dependent polymerization activity. It follows that the popular single-enzyme RT-PCR format, in which this DNA polymerase serves for both RT and PCR, is not appropriate for assaying rare RNA targets.

Replicable and recombinogenic RNAs

This paper summarizes results of the 40-year studies on replication and recombination of RNA molecules in the cell-free amplification system of bacteriophage Q. Special attention is paid to the molecular colony technique that has provided for the discovery of the nature of "spontaneous" RNA synthesis by Q replicase and of the ability of RNA molecules to spontaneously rearrange their sequences under physiological conditions. Also discussed is the impact of these data on the concept of RNA World and on the development of new in vitro cloning and diagnostic tools.

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.

Omnipotent RNA

The capability of polyribonucleotide chains to form unique, compactly folded structures is considered the basis for diverse non-genetic functions of RNA, including the function of recognition of various ligands and the catalytic function. Together with well-known genetic functions of RNA - coding and complementary replication - this has led to the concept of the functional omnipotence of RNA and the hypothesis that an ancient RNA world supposedly preceded the contemporary DNA-RNA-protein life. It is proposed that the Woese universal precursor in the ancient RNA world could be a cell-free community of mixed RNA colonies growing and multiplying on solid surfaces.

Polymerization of nontemplate bases before transcription initiation at the 3' ends of templates by an RNA-dependent RNA polymerase: an activity involved in 3' end repair of viral RNAs

The 3' ends of RNAs associated with turnip crinkle virus (TCV), including subviral satellite (sat)C, terminate with the motif CCUGCCC-3'. Transcripts of satC with a deletion of the motif are repaired to wild type (wt) in vivo by RNA-dependent RNA polymerase (RdRp)-mediated extension of abortively synthesized oligoribonucleotide primers complementary to the 3' end of the TCV genomic RNA. Repair of shorter deletions, however, are repaired by other mechanisms. SatC transcripts with the 3' terminal CCC replaced by eight nonviral bases were repaired in plants by homologous recombination between the similar 3' ends of satC and TCV. Transcripts with deletions of four or five 3' terminal bases, in the presence or absence of nonviral bases, generated progeny with a mixture of wt and non-wt 3' ends in vivo. In vitro, RdRp-containing extracts were able to polymerize nucleotides in a template-independent fashion before using these primers to initiate transcription at or near the 3' end of truncated satC templates. The nontemplate additions at the 5' ends of the nascent complementary strands were not random, with a preference for consecutive identical nucleotides. The RdRp was also able to initiate transcription opposite cytidylate, uridylate, guanylate, and possibly adenylate residues without exhibiting an obvious preference, flexibility previously unreported for viral RdRp. The unexpected existence of three different repair mechanisms for TCV suggests that 3' end reconstruction is critical to virus survival.

The puzzle of RNA recombination

For more than three decades, RNA recombination remained a puzzle and has only begun to be solved in the last few years. The available data provide evidence for a variety of RNA recombination mechanisms. Non-homologous recombination seems to be the most common for RNA. Recent experiments in both the in vitro and the in vivo systems indicate that this type of recombination may result from various transesterification reactions which are either performed by RNA molecules themselves or are promoted by some proteins. The high frequency of homologous recombination manifested by some RNA viruses can be easier explained by a replicative template switch.

Spontaneous rearrangements in RNA sequences

The ability of RNAs to spontaneously rearrange their sequences under physiological conditions is demonstrated using the molecular colony technique, which allows single RNA molecules to be detected provided that they are amplifiable by the replicase of bacteriophage Qbeta. The rearrangements are Mg2+-dependent, sequence-non-specific, and occur both in trans and in cis at a rate of 10(-9) h(-1) per site. The results suggest that the mechanism of spontaneous RNA rearrangements differs from the transesterification reactions earlier observed in the presence of Qbeta replicase, and have a number of biologically important implications.

The forces driving molecular evolution

Competitive replication among RNA or DNA molecules at linear and non-linear rates of propagation has been reviewed from the perspective of a recent physicochemical model of molecular evolution and the findings are applied to pre-replication, prebiotic and biological evolution. A system of competitively replicating molecules was seen to follow a path of least action on both its thermodynamic and kinetic branch, in evolving toward steady state kinetics and equilibrium for the nucleotide condensation reaction. Stable and unstable states of coexistence, between competing molecular species, arise at nonlinear rates of propagation, and they derive from an equilibrium between kinetic forces. The de novo formation of self-replicating RNA molecules involves damping of these scalar forces, error tolerance and RNA driven strand separation. Increases in sequence complexity in the transition to self-replication does not exceed the free energy dissipated in RNA synthesis. Retrodiction of metabolic pathways and phylogenetic evidence point to the occurrence of three pre-replication metabolic systems, driven by autocatalytic C-fixation cycles. Thermodynamic and kinetic factors led to the replication take over. Biological evolution was found to involve resource capture, in addition to competition for a shared resource.

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.

Expression and stability of recombinant RQ-mRNAs in cell-free translation systems

Expression of dihydrofolate reductase (DHFR) and chloramphenicol acetyltransferase (CAT) mRNAs in cell-free Escherichia coli translation systems is greatly enhanced as a result of their insertion into RQ135 RNA, a naturally occurring satellite of phage Q beta. The enhancement is due to protection of the recombinant mRNAs against endogenous ribonucleases and to an increased initial rate of translation in the case of the RQ-CAT mRNA.

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.

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.

Sequence analysis of RNA species synthesized by Q beta replicase without template

Q beta replicase amplifies certain short-chained RNA templates autocatalytically with high efficiency. In the absence of extraneously added template, synthesis of new RNA species by Q beta replicase is observed under conditions of high enzyme and substrate concentrations and after long lag times. Even under identical conditions, different RNA species are produced in different experiments. The sequences of several independent template-free products have been determined by cloning their cDNAs into plasmids by a novel cloning procedure. Their nucleotide chain lengths are small, ranging from 25 to about 50 nucleotides. While their primary sequences are unrelated except for the invariant 5'-terminal G and 3'-terminal C clusters, their tentative secondary structures show a common principle: both their plus and minus strands have a stem at the 5' terminus, while the 3' terminus is unpaired. Direct accumulation of sufficient quantities of early template-free synthesis products by Q beta replicase is prevented by the inherent irreproducibility of the synthesis process and by the rapid change of the products during amplification by evolution processes, but large amounts of such RNA can be synthesized in vitro by transcription from the cDNA clones. RNA species produced in template-free reactions replicate much more slowly than the optimized RNA species characterized previously. These experimental results illustrate how biological information can be gained in small bits by trial and error.

Images of evolution: origin of spontaneous RNA replication waves

Self-replicating molecules set up traveling concentration waves that propagate in an aqueous enzyme solution. The velocity of each wave provides an accurate (+/- 0.1%) noninvasive measure of fitness for the RNA species currently growing in its front. Evolution may be followed from changes in the front velocity, and these differ from wave to wave. Thousands of controlled evolution reactions in traveling waves have been monitored in parallel to obtain quantitative images of the stochastic process of natural selection. An RNA polymerase (RNA-dependent RNA nucleotidyltransferase, EC 2.7.7.6), extracted from bacteria infected by the Q beta RNA virus, catalyzes the replication. The traveling waves that arise spontaneously without added RNA provide a model system for major evolutionary change.

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.