Control of Replication in RNA Bacteriophages

The rates of viral RNA and protein syntheses for wild-type RNA bacteriophages and their nonpolar, coat protein amber mutants were determined in amber suppressor (S26R1E, Su-1 and H12R8a, Su-3) and nonsuppressor (AB259, S26, and Q13) strains of Escherichia coli in the presence of rifamycin. It was demonstrated that the rates of synthesis of phage-specific replicase and RNA minus strands drop off concurrently in both wild-type and coat protein mutant-infected Su(-) and Su(+) cells after 10 and 15 min postinfection, respectively. The rate of synthesis of RNA plus strands started to decline 5 to 10 min later in both cases. Excessive synthesis of replicase in the coat protein mutant-infected cells was accompanied by a similar overproduction of RNA minus strands, but not of plus strands. Partial suppression of protein synthesis in wild-type phage-infected cells abolishing coat protein control over replicase accumulation led to prolongation of replicase synthesis. Such an effect was observed also in coat protein mutant-infected cells, indicating that the excess of replicase itself may be capable of suppression of replicase synthesis in the absence of coat protein. The prolongation of replicase synthesis was followed by the prolonged synthesis of RNA minus strands in both cases. Moreover, replicase and minus strands were formed in nearly equal amounts when protein synthesis was partially inhibited. Assuming functional instability of phage RNAs, the observed coupling of replicase and minus-strand RNA synthesis offers a possibility for control of viral RNA replication by means of control of replicase synthesis on the translational level. A hypothesis is put forward to explain the molecular mechanism of such coupling between the syntheses of replicase and RNA minus strands.     

The regulatory region of MS2 phage RNA replicase cistron. Functional activity of individual MS2 RNA fragments

The present work deals with the structural-functional organization of regulatory regions of messenger RNAs. Some principles of the action of a translational repressor (coat protein) and the formation of the ribosomal initiation complex at the replicase cistron have been studied with MS2 phage RNA. When the complex of MS2 RNA with the coat protein is treated with T₁ ribonuclease, the coat protein selectively protects mainly two fragments (59 and 103 nucleotides in length) from digestion; these fragments contain the intercistronic regulatory region and the beginning of the MS2 replicase cistron. These polynucleotides have been isolated in a pure state and their primary structure has been established.It has been established that both MS2 RNA fragments contain all the necessary information for specific interaction with MS2 coat protein and form a complex with it with an efficiency close to that observed in the case of native MS2 RNA. They also provide the normal polypeptide chain initiation at the replicase cistron. Enzymatic binding of the second aminoacyl-tRNA and electrophoretic analysis of N-terminal dipeptides prove that only the true initiator codon of the replicase cistron is recognized by a ribosome despite the presence of a few additional AUG triplets within the polynucleotides. Under conditions of limited hydrolysis by T₁ ribonuclease, the beginning of the replicase cistron has been removed from the shortest polynucleotide leading to a complete loss of its ability to bind both the coat protein and a ribosome.Some principles of the functioning of the regulatory region in MS2 RNA as well as the nature of the initiator signal of protein biosynthesis are discussed.     

The binding site for coat protein on bacteriophage Qbeta RNA.

The site of interaction of phage Qbeta coat protein with Qbeta RNA was determined by ribonuclease T1 degradation of complexes of coat protein and [32P]-RNA obtained by codialysis of the components from urea into buffer solutions. The degraded complexes were recovered by filtration through nitrocellulose filters, and bound [32P]RNA fragments were extracted and separated by polyacrylamide gel electrophoresis. Fingerprinting and further sequence analysis established that the three main fragments obtained (chain lengths 88, 71 and 27 nucleotides) all consist of sequences extending from the intercistronic region to the beginning of the replicase cistron. These results suggest that in the replication of Qbeta, as in the case of R17, coat protein acts as a translational repressor by binding to the ribosomal initiation site of the replicase cistron.     

The lysis function of RNA bacteriophage Qbeta is mediated by the maturation (A2) protein

Complete or partial cDNA sequences of the RNA bacteriophage Qbeta were cloned in plasmids under the control of the lambdaP(L) promoter to allow regulated expression in Escherichia coli harbouring the gene for the temperature-sensitive lambdaCI857 repressor. Induction of the complete Qbeta sequence leads to a 100-fold increase in phage production, accompanied by cell lysis. Induction of the 5'-terminal sequence containing the intact maturation protein (A2) cistron also causes cell lysis. Alterations of the A2 cistron, leading to proteins either devoid of approximately 20% of the C-terminal region or of six internal amino acids, abolish the lysis function. Expression of other cistrons in addition to the A2 cistron does not enhance host lysis. Thus, in Qbeta, the A2 protein, in addition to its functions as maturation protein, appears to trigger cell lysis. This contrasts with the situation in the distantly related group I RNA phages such as f2 and MS2 where a small lysis polypeptide is coded for by a region overlapping the end of the coat gene and the beginning of the replicase gene.     

The RNA binding site of bacteriophage MS2 coat protein.

The coat protein of the RNA bacteriophage MS2 binds a specific stem-loop structure in viral RNA to accomplish encapsidation of the genome and translational repression of replicase synthesis. In order to identify the structural components of coat protein required for its RNA binding function, a series of repressor-defective mutants has been isolated. To ensure that the repressor defects were due to substitution of binding site residues, the mutant coat proteins were screened for retention of the ability to form virus-like particles. Since virus assembly presumably requires native structure, this approach eliminated mutants whose repressor defects were secondary consequences of protein folding or stability defects. Each of the variant coat proteins was purified and its ability to bind operator RNA in vitro was measured. DNA sequence analysis identified the nucleotide and amino acid substitutions responsible for reduced RNA binding affinity. Localization of the substituted sites in the three-dimensional structure of coat protein reveals that amino acid residues on three adjacent strands of the coat protein beta-sheet are required for translational repression and RNA binding. The sidechains of the affected residues form a contiguous patch on the interior surface of the viral coat.     

Resynchronization of RNA synthesis by coliphage Qbeta replicase at an internal site of the RNA template

In previous work Qβ replicase has been used to synthesize labelled 5′ terminal segments of Qβ plus or minus strands of defined length. A procedure has now been developed which allows resynchronization of Qβ replicase at an internal position and synthesis of a labelled minus-strand segment complementary to the coat cistron ribosome binding site and the intercistronic region between the A₂ (maturation) and the coat cistron. Resynchronization is accomplished by binding a ribosome to Qβ RNA and allowing Qβ replicase to initiate and elongate up to the ribosome, using unlabelled ribonucleoside triphosphates. The ribosome is dissociated by EDTA treatment and the EDTA is removed. The replicating complex remains functional after this treatment, and addition of labelled substrates leads to synchronized elongation. The radioactive part of the product recovered after a short elongation period with labelled substrates was shown to be complementary to the coat protein ribosome binding site.     

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.     

Mechanism of translational coupling between coat protein and replicase genes of RNA bacteriophage MS2.

We have analyzed the molecular mechanism that makes translation of the MS2 replicase cistron dependent on the translation of the upstream coat cistron. Deletion mapping on cloned cDNA of the phage shows that the ribosomal binding site of the replicase cistron is masked by a long distance basepairing to an internal coat cistron region. Removal of the internal coat cistron region leads to uncoupled replicase synthesis. Our results confirm the model as originally proposed by Min Jou et al. (1). Activation of the replicase start is sensitive to the frequency of upstream translation, but never reaches the level of uncoupled replicase synthesis.     

Translational repression by bacteriophage MS2 coat protein expressed from a plasmid. A system for genetic analysis of a protein-RNA interaction

The coat protein of bacteriophage MS2 is a translational repressor. It inhibits the synthesis of the viral replicase by binding a specific RNA structure that contains the replicase translation initiation region. In order to begin a genetic dissection of the repressor activity of coat protein, a two-plasmid system has been constructed that expresses coat protein and a replicase-beta-galactosidase fusion protein from different, compatible plasmids containing different antibiotic-resistant determinants. The coat protein expressed from the first plasmid (pCT1) represses synthesis of a replicase-beta-galactosidase fusion protein encoded on the other plasmid (pRZ5). Mutations in the translational operator or in coat protein result in constitutive synthesis of the enzyme. This permits the straightforward isolation of mutations in the coat sequence that affect repressor function. Because of the potential importance of cysteine residues for RNA binding, mutations were constructed that substitute serines for the cysteine residues normally present at positions 46 and 101. Both of these mutations result in translational repressor defects. Chromatographic and electron microscopic analyses indicate that the plasmid-encoded wild-type coat protein forms capsids in vivo. The ability of the mutants to adopt and/or maintain the appropriate conformation was assayed by comparing them to the wild-type protein for their ability to form capsids. Both mutants exhibited evidence of improper folding and/or instability as indicated by their aberrant elution behavior on a column of Sepharose CL-4B. Methods were developed for the rapid purification of plasmid-encoded coat protein, facilitating future biochemical analyses of mutant coat proteins.     

Emergence of distinct brome mosaic virus recombinants is determined by the polarity of the inoculum RNA

Despite overwhelming interest in the impact exerted by recombination during evolution of RNA viruses, the relative contribution of the polarity of inoculum templates remains poorly understood. Here, by agroinfiltrating Nicotiana benthamiana leaves, we show that brome mosaic virus (BMV) replicase is competent to initiate positive-strand [(+)-strand] synthesis on an ectopically expressed RNA3 negative strand [(-) strand] and faithfully complete the replication cycle. Consequently, we sought to examine the role of RNA polarity in BMV recombination by expressing a series of replication-defective mutants of BMV RNA3 in (+) or (-) polarity. Temporal analysis of progeny sequences revealed that the genetic makeup of the primary recombinant pool is determined by the polarity of the inoculum template. When the polarity of the inoculum template was (+), the recombinant pool that accumulated during early phases of replication was a mixture of nonhomologous recombinants. These are longer than the inoculum template length, and a nascent 3' untranslated region (UTR) of wild-type (WT) RNA1 or RNA2 was added to the input mutant RNA3 3' UTR due to end-to-end template switching by BMV replicase during (-)-strand synthesis. In contrast, when the polarity of the inoculum was (-), the progeny contained a pool of native-length homologous recombinants generated by template switching of BMV replicase with a nascent UTR from WT RNA1 or RNA2 during (+)-strand synthesis. Repair of a point mutation caused by polymerase error occurred only when the polarity of the inoculum template was (+). These results contribute to the explanation of the functional role of RNA polarity in recombination mediated by copy choice mechanisms.     

Translational control by a long range RNA-RNA interaction; a basepair substitution analysis.

One of the two mechanisms that regulate expression of the replicase cistron in the single stranded RNA coliphages is translational coupling. This mechanism prevents ribosomes from binding at the start of the replicase cistron unless the upstream coat cistron is being translated. Genetic analysis had identified a maximal region of 132 nucleotides in the coat gene over which ribosomes should pass to activate the replicase start. Subsequent deletion studies in our laboratory had further narrowed down the regulatory region to 12 nucleotides. Here, we identify a long-distance RNA-RNA interaction of 6 base pairs as the basis of the translational polarity. The 3' side of the complementarity region is located in the coat-replicase intercistronic region, some 20 nucleotides before the start codon of the replicase. The 5' side encodes amino acids 31 and 32 of the coat protein. Mutations that disrupt the long-range interaction abolish the translational coupling. Repair of basepairing by second site base substitutions restores translational coupling.     

Defective lysis of streptomycin-resistant escherichia coli cells infected with bacteriophage f2

A lysis defect was found to account for the failure of a streptomycin-resistant strain of Escherichia coli to form plaques when infected with the male-specific bacteriophage f2. The lysis defect was associated with the mutation to streptomycin resistance. Large amounts of apparently normal bacteriophage accumulated in these cells. Cell-free extracts from both the parental and mutant strains synthesized a potential lysis protein in considerable amounts in response to formaldehyde-treated f2 RNA but not in response to untreated RNA. As predicted from the nucleotide sequence of the analogous MS2 phage, the protein synthesized in vitro had the expected molecular weight and lacked glycine. The cistron for the lysis protein overlapped portions of the coat and replicase cistrons and was translated in the +1 reading frame. Initiation at the lysis protein cistron may be favored by translation errors that expose the normally masked initiation site, and streptomycin-resistant ribosomes, known to have more faithful translation properties, may be unable to efficiently synthesize the lysis protein.     

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.     

Escherichia coli ribosomal protein S1 recognizes two sites in bacteriophage Qbeta RNA.

As a component of bacteriophage Qbeta replicase, S1 is required both for initiation of Qbeta minus strand RNA synthesis and for translational repression, which has been traced to the ability of the enzyme to bind to an internal site in the Qbeta RNA molecule. Previously, Senear and Steitz (Senear, A. W., and Steitz, J. A. (1976) J. Biol. Chem. 251, 1902-1912) found that isolated S1 protein binds specifically to an oligonucleotide spanning residues -38 to -63 from the 3' terminus of Qbeta RNA. Here we report that S1 also interacts strongly with a second oligonucleotide in Qbeta RNA, which is derived from the region recognized by replicase just 5' to the Qbeta coat protein cistron. Both sequences exhibit pyrimidine-rich regions.     

Studies on the bacteriophage MS 2

Summary The viral proteins synthesized in non-suppressor cells by amber mutants in the A protein cistron of the RNA bacteriophage MS2 were analyzed. Protein synthesis was studied in rifampicin-inhibited cultures and the labeled, viral proteins were separated on sodium dodecyl sulphate containing polyacrylamide gels. We found that 7 out of 19 mutants synthesized an A protein-fragment corresponding in length to 88% of the wild-type A protein. This fragment was not incorporated into the defective particles formed by the mutants. 12 mutants synthesized no detectable amount of fragment. It was shown that the absence of fragment is not due to selective proteolytic breakdown.     

Mutations that increase the affinity of a translational repressor for RNA.

The coat protein of the RNA bacteriophage MS2 is a specific RNA binding protein that represses translation of the viral replicase gene during the infection cycle. As an approach to characterizing the RNA-binding site of coat protein we have isolated a series of coat mutants that suppress the effects of a mutation in the translational operator. Each of the mutants exhibits a super-repressor phenotype, more tightly repressing both the mutant and wild-type operators than does the wild-type protein. The variant coat proteins were purified and subjected to filter binding assays to determine their affinities for the mutant and wild-type operators. Each protein binds the operators from 3 to 7.5-fold more tightly than normal coat protein. The amino acid substitutions seem to extend the normal binding site by introducing new interactions with RNA.     

Encapsidation of heterologous RNAs by bacteriophage MS2 coat protein.

The RNA bacteriophages of E. coli specifically encapsidate a single copy of the viral genome in a protein shell composed mainly of 180 molecules of coat protein. Coat protein is also a translational repressor and shuts off viral replicase synthesis by interaction with a RNA stem-loop containing the replicase initiation codon. We wondered whether the translational operator also serves as the viral pac site, the signal which mediates the exclusive encapsidation of viral RNA by its interaction with coat protein. To test this idea we measured the ability of lacZ RNA fused to the translational operator to be incorporated into virus-like particles formed from coat protein expressed from a plasmid. The results indicate that the operator-lacZ RNA is indeed encapsidated and that nucleotide substitutions in the translational operator which reduce the tightness of the coat protein-operator interaction also reduce or abolish encapsidation of the hybrid RNA. When coat protein is expressed in excess compared to the operator-lacZ RNA, host RNAs are packaged as well. However, elevation of the level of operator-lacZ RNA relative to coat protein results in its selective encapsidation at the expense of cellular RNAs. Our results are consistent with the proposition that this single protein-RNA interaction accounts both for translational repression and viral genome encapsidation.     

Studies on the bacteriophage MS2. XVI. The termination signal of the A protein cistron

The RNA of bacteriophage MS2 codes for three viral proteins: the coat protein, the A protein and the replicase. Upon infection of various amber suppressor strains of Escherichia coli, we found a fourth viral protein, the synthesis of which was specifically dependent on the presence of an amber suppressor gene. It is shown that this polypeptide is formed by reading through the natural termination signal of the A protein cistron. This cistron therefore terminates with the nonsense codon UAG. The observed prolongation accounts for the addition of some 30 amino acids. Unlike the normal A protein, the longer polypeptide is probably not incorporated into mature phage particles.     

Regulatory region of fr phage replicase cistron. II. Isolation and structure of specific fr RNA fragments

A new set of short RNA templates has been prepared for functional studies in initiation of translation in vitro. Number of individual RNA fragments which contain complete or part of the initiatory region of phage fr replicase cistron were isolated from complex fr RNA--fr coat protein. Their primary structure were determined by using standard fingerprint technique and rapid gel sequencing. Secondary structure of several RNA fragments and their binding activity with phage fr and MS2 coat proteins has been also studied.