Interference with viral infection by RNA replicase deleted at the carboxy-terminal region

Escherichia coli cells harboring an altered Q beta RNA replicase which has amino acid substitutions of the glycine residue at position 357 in the conserved sequence Tyr356-Gly357-Asp358-Asp359 of the beta-subunit protein lost the replicase activity but interfered with proliferation of Q beta phage [Inokuchi and Hirashima (1987) J. Virol. 61, 3946-3949]. To examine the mechanism of the interference, we further analyzed various mutants lacking the carboxy-terminal region of the beta-subunit protein. The cells expressing the beta-subunit gene with up to 17% deletion from the carboxy-terminus of the protein prevented the proliferation of Q beta phage. However, in the case that the deletion extended beyond 25% from the carboxy-terminus, the cells showed no interference. In addition, when the interference took place, the phage coat protein synthesis was inhibited. These results indicate that the region between amino acids 440 and 487 of the beta-subunit protein is involved in the interference and suggest that the defective replicase inhibits the phage coat protein synthesis by competing with the ribosomes at the initiation site of the coat gene.     

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.     

Analysis of the complete nucleotide sequence of the group IV RNA coliphage SP.

We report the nucleotide sequence of the Group IV RNA bacteriophage SP. The entire sequence is 4276 nucleotides long. Four cistrons have been identified by comparison with the related Group III phage Q beta. The maturation protein contains 449 amino acids, the coat protein contains 131 amino acids, the read-through protein contains 330 amino acids and the replicase beta-subunit contains 575 amino acids. SP is 59 nucleotides longer than Q beta. We have analyzed both sequence and structural conservation between SP and Q beta and shown that the sequences for the coat and central region of the replicase are strongly conserved between the two genomes. We also show that the S and M replicase binding sites of Q beta are strongly conserved in SP. Interestingly, the base composition of SP and Q beta differ significantly from one another, and most of the differences can be accounted for by a strong preponderance of U in the third position of each codon of Q beta relative to SP. We also compare conserved hairpins associated with potential coat protein and replicase binding sites.     

Q beta replicase: mapping the functional domains of an RNA-dependent RNA polymerase

We have localized a functional region of the RNA bacteriophage Q beta replicase following an extensive mutational analysis. Using the method of oligonucleotide linker-insertion mutagenesis, we specifically introduced mutations into a cloned DNA copy of the Q beta replicase gene so that the resulting replicase products would putatively contain small amino acid insertions. In a selective phenotypic assay, we screened mutant replicases for RNA-directed replication activity in vivo. Analysis of 37 different mutant clones indicated that Q beta replicase can accept amino acid substitutions and insertions at several sites at the amino and carboxy termini without abolishing functional activity in vivo or in vitro. However, disruption within the internal amino acid sequence resulted almost exclusively in nonfunctional enzyme. The results suggest that the central region of the replicase protein contains a rigid amino acid composition that is required for replicase function, whereas the amino and carboxy termini are much more receptive to small amino acid insertions and substitutions. These experiments should further enable us to analyze the coding function of the Q beta replicase gene independently of other phage RNA functions contained within this nucleotide region.     

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.     

On the nature of spontaneous RNA synthesis by Q beta replicase.

Numerous RNA species of different length and nucleotide sequence grow spontaneously in vitro in Q beta replicase reactions where no RNA templates are added deliberately. Here, we show that this spontaneous RNA synthesis by Q beta replicase is template directed. The immediate source of template RNA can be the laboratory air, but there are ways to eliminate, or at least substantially reduce, the harmful effects of spontaneous synthesis. Solitary RNA molecules were detected in a thin layer of agarose gel containing Q beta replicase, where they grew to form colonies that became visible upon staining with ethidium bromide. This result provides a powerful tool for RNA cloning and selection in vitro. We also show that replicating RNAs similar to those growing spontaneously are incorporated into Q beta phage particles and can propagate in vivo for a number of phage generations. These RNAs are the smallest known molecular parasites, and in many aspects they resemble both the defective interfering genomes of animal and plant viruses and plant virus satellite RNAs.     

Differential stimulation by polyamines of phage RNA-directed synthesis of proteins

The effect of polyamines on Q beta and MS2 phage RNA-directed synthesis of three kinds of protein in an Escherichia coli cell-free system has been studied. With both phage RNAs, the degree of stimulation of protein synthesis by spermidine was in the order RNA replicase greater than A protein, while the synthesis of coat protein was not stimulated significantly by spermidine. The synthesis of RNA replicase was stimulated by 1 mM spermidine approx. 8-fold. From the results of Q beta RNA direct alanyl-tRNA and seryl-tRNA binding to ribosomes and initiation dipeptide synthesis, it is suggested that the preferential stimulation of the synthesis of RNA replicase by spermidine is due at least partially to the stimulation of the initiation of RNA replicase synthesis.     

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.     

Structural consensus of RNA templates replicated by Q beta replicase.

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

Autocatalytic replication of a recombinant RNA

We demonstrate that a heterologous RNA sequence can be copied in vitro by Q beta replicase when it is inserted into a naturally occurring Q beta replicase template. A recombinant RNA was constructed by inserting decaadenylic acid between nucleotides 63 and 64 of MDV-1 (+) RNA, using phage T4 RNA ligase. The insert was located away from regions of the template known to be required for the binding of the replicase and for the initiation of product strand synthesis. To minimize the disruption of template structure, we inserted the heterologous sequence into a hairpin loop on the exterior of the molecule. Q beta replicase copied this recombinant RNA in vitro, and the complementary product strands served as templates for the synthesis of additional copies of the original recombinant RNA. The reaction was therefore autocatalytic and the amount of recombinant RNA increased exponentially. A 300-fold amplification of the recombinant RNA occurred within nine minutes. Insertion of biologically significant RNAs into the MDV-1 RNA sequence should allow them to be replicated autocatalytically.     

Localization of the Q beta replicase recognition site in MDV-1 RNA

Fragments of MDV-1 RNA (a small, naturally occurring template for Q beta replicase) that were missing nucleotides at either their 5' end or their 3' end were still able to form a complex with Q beta replicase. By assaying the binding ability of fragments of different length, it was established that the binding site for Q beta replicase is determined by nucleotide sequences that are located near the middle of MDV-1 RNA. Fragments missing nucleotides at their 5' end were able to serve as templates for the synthesis of complementary strands, but fragments missing nucleotides at their 3' end were inactive, indicating that the 3'-terminal region of the template is required for the initiation of RNA synthesis. The nucleotide sequences of both the 3' terminus and the central binding region of MDV-1 (+) RNA are almost identical to sequences at the 3' terminus and at an internal region of Q beta (-) RNA.     

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.     

Crystal Structure of the Bacteriophage Qβ Coat Protein in Complex with the RNA Operator of the Replicase Gene

The coat proteins of single-stranded RNA bacteriophages specifically recognize and bind to a hairpin structure in their genome at the beginning of the replicase gene. The interaction serves to repress the synthesis of the replicase enzyme late in infection and contributes to the specific encapsidation of phage RNA. While this mechanism is conserved throughout the Leviviridae family, the coat protein and operator sequences from different phages show remarkable variation, serving as prime examples for the co-evolution of protein and RNA structure. To better understand the protein–RNA interactions in this virus family, we have determined the three-dimensional structure of the coat protein from bacteriophage Qβ bound to its cognate translational operator. The RNA binding mode of Qβ coat protein shares several features with that of the widely studied phage MS2, but only one nucleotide base in the hairpin loop makes sequence-specific contacts with the protein. Unlike in other RNA phages, the Qβ coat protein does not utilize an adenine-recognition pocket for binding a bulged adenine base in the hairpin stem but instead uses a stacking interaction with a tyrosine side chain to accommodate the base. The extended loop between β strands E and F of Qβ coat protein makes contacts with the lower part of the RNA stem, explaining the greater length dependence of the RNA helix for optimal binding to the protein. Consequently, the complex structure allows the proposal of a mechanism by which the Qβ coat protein recognizes and discriminates in favor of its cognate RNA.     

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.     

Secondary structure of coliphage Q beta RNA. Analysis by electron microscopy

The secondary structure of genomic RNA from the coliphage Q beta has been examined by electron microscopy in the presence of varying concentrations of spermidine using the Kleinschmidt spreading technique. The size and position of structural features that cover 70% of the viral genome have been mapped. The structural features that are visualized by electron microscopy in Q beta RNA are large. They range in size from 170 to 1600 nucleotides. A loop containing approximately 450 nucleotides is located at the 5' end of the RNA. It includes the initiation region for the viral maturation protein. A large hairpin containing approximately 1600 nucleotides is located in the center of the molecule. It is multibranched and includes most of the viral coat gene, the readthrough region of the A1 gene, and approximately one third of the viral replicase gene. Within the central hairpin, the initiation region for the viral replicase gene pairs with a region within the distal third of the viral coat gene. This structure may participate in the regulation of translational initiation of the viral replicase gene. Two structural variants of the central hairpin were observed. One of them brings the internal S and M viral replicase binding regions into juxtaposition. These observations suggest that the central hairpin may also participate in the regulation of translation of the viral coat gene. The secondary structures that are observed in Q beta RNA differ significantly from structures that we described previously in the genomic RNA of coliphage MS2 but are similar to structures we observed by electron microscopy in the related group B coliphage SP.