Facile production and rapid purification of functional recombinant Qß replicase heterotetramer complex.

We describe an improved method for the production of recombinant Qß replicase heterotetramer. The successful expression of the soluble Qß RNA polymerase complex depends on the EF-Ts and EF-Tu subunits being co-expressed prior to ß-subunit expression. Efficient co-expression requires two different inducible operons to co-ordinate the expression of the heterotrimer. The complete heterotetramer enzyme complex is achieved by production of the recombinant S1-subunit of Qß replicase in a separate host. This approach represents a facile way for producing and purifying large amounts of soluble and active recombinant Qß replicase tetramer without the necessity of a His-tag for purification.

Isolation and crystallization of a chimeric Qß replicase containing Thermus thermophilus EF-Ts.

Qß replicase is a protein complex responsible for the replication of the genomic RNA of bacteriophage Qß. In addition to the phage-encoded catalytic ß subunit, it recruits three proteins from the host Escherichia coli cell: elongation factors EF-Tu and EF-Ts and ribosomal protein S1. We prepared a chimeric Qß replicase in which the E. coli EF-Ts is replaced with EF-Ts from Thermus thermophilus. The chimeric protein is produced in E. coli cells during coexpression of the genes encoding the ß subunit and thermophilic EF-Ts. The developed isolation procedure yields a substantially homogeneous preparation of the chimeric replicase. Unlike the wild-type enzyme, the S1-less chimeric replicase could be crystallized. This result facilitates studies on the structure of Qß replicase and the mechanism of recognition of its templates that can replicate in vitro at a record rate.

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.

Evolution of host cell RNA into efficient template RNA by Q beta replicase: the origin of RNA in untemplated reactions.

Q beta replicase can replicate a single molecule of certain species of RNA to 10(14) copies in minutes. This replication ability has been used for in vitro studies of molecular evolution and is currently being utilized as a method of amplifying RNAs that contain probe sequences. It has been observed that Q beta replicase can produce replicatable RNA even in the absence of exogenously added template RNA. The origin of this RNA has been ascribed either to contamination with replicatable RNA or to an ability of Q beta replicase to synthesize RNA de novo from the nucleotides present in the reaction. Technologies that employ Q beta replicase require a thorough understanding of the conditions that lead to this so-called spontaneous RNA production. We have created an expression system and purification method with which we produce gram quantities of highly purified Q beta replicase, and we have identified reaction conditions that prevent the amplification of RNA in assays that do not contain added RNA. However, when these reaction conditions are relaxed, spontaneous RNA replication is seen in up to 100% of the assays. To understand the origin of this RNA, we have cloned several spontaneously produced RNAs. Sequence analysis of one of these RNAs shows that it arose by the evolution of Escherichia coli tRNA into a replicatable template and not by de novo synthesis from nucleoside triphosphates in the reaction.

Traveling waves of in vitro evolving RNA.

Populations of short self-replicating RNA variants have been confined to one side of a reaction-diffusion traveling wave front propagating along thin capillary tubes containing the Q beta viral enzyme. The propagation speed is accurately measurable with a magnitude of about 1 micron/sec, and the wave persists for hundreds of generations (of duration less than 1 min). Evolution of RNA occurs in the wavefront, as established by front velocity changes and gel electrophoresis of samples drawn from along the capillary. The high population numbers (approximately equal to 10(11], their well-characterized biochemistry, their short generation time, and the constant conditions make the system ideal for evolution experiments. Growth is monitored continuously by excitation of an added RNA-sensitive fluorescent dye, ethidium bromide. An analytic expression for the front velocity is derived for the multicomponent kinetic scheme that reduces, for a high RNA-enzyme binding constant, to the Fisher form v = 2 square root of kappa D, where D is the diffusion constant of the complex and kappa is the low-concentration overall replication rate coefficient. The latter is confirmed as the selective value-determining parameter by numerical solution of a two-species system.

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.

Phage Qbeta replicase: cell-free synthesis of the phage-specific subunit and its assembly with host subunits to form active enzyme.

Cell-free translation of Qbeta RNA and subsequent partial purification of the enzyme resulted in replicase activity. From 0.5 to 1.5% of all R chains synthesised were found in the 7-S replicase complex. The presence in the 7-S complex of the host subunits of authentic replicase, i (= S1) and EF-Ts, was shown by the effect of antisera directed against ribosomal protein S1 and EF-Ts, respectively. Furthermore, the presence of EF-Ts was demonstrated by thermal denaturation of in vitro replicase made by a cell extract from an Escherichia coli mutant with a thermolabile EF-Ts. In vitro replicase did not assemble spontaneously during protein synthesis but was formed upon subsequent purification. Assembly could be induced by ammonium sulphate precipitation (60% saturation) alone. It is concluded that the functional phage-coded subunit synthesised in vitro recognises i and the EF-Tu - EF-Ts complex among a mixture of host proteins.

Isolation of bacterial and phage proteins by homopolymer RNA-cellulose chromatography.

Nucleic acid-free extracts of Escherichia coli have been analyzed by chromatography on columns of cellulose, to which poly(A), poly(U), or poly(C) have been attached by ultraviolet irradiation. Proteins are released from the columns by stepwise elution with increasingly higher concentrations of salt, followed by washing with urea to remove very tightly bound molecules. The pattern of protein elution is reproducibly different for each of the homopolymer RNA-cellulose columns used: some proteins bind very tightly to one column, but poorly to others. Analysis by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis, by immunological cross-reactivity in double diffusion tests, and by enzymological assays, has allowed the identification of a number of these proteins. The RNA polymerase core enzyme binds to poly(C)- and to poly(U)-cellulose columns, and can be purified to 20 to 30 percent homogeneity in a single step. Ribosomal protein S1 and the termination factor rho bind very tightly to poly(C)-cellulose, and both can be purified to homogeneity rapidly, in much higher yields than previously reported. Poly(A)-cellulose chromatography allows the isolation of large amounts of an 80,000 molecular weight protein having an as yet unassigned cellular function. The host factor required for RNA phage Qbeta RNA replication in vitro can also be obtained from poly(A)-cellulose, and chromatography of extracts of phage Qbeta-infected E. coli on RNA-cellulose columns results in very rapid isolation of the Qbeta replicase enzyme. Homopolymer RNA-cellulose chromatography thus appears to be a simple, general technique, useful for the efficient isolation of a variety of RNA-binding proteins.