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.     

Nucleotide sequences of two fragments from the coat-protein cistron of bacteriophage R17 ribonucleic acid

Bacteriophage R17 RNA was labelled with ³²P and was subjected to partial digestion with ribonuclease T₁. The products were fractionated by ionophoresis on polyacrylamide gel. Two fragments were purified and their nucleotide sequences determined by methods involving complete and further partial digestion with ribonucleases A and T₁. Fragment 20 had a sequence that coded for the amino acids in positions 32–53 of the coat protein of the bacteriophage. Fragment 20X, on further purification in 7m-urea, gave rise to two smaller nucleotides whose sequences coded for the amino acids in positions 56–66 and 67–76 of the coat protein. The sequence of the two fragments was such that they could be written in the form of loops stabilized by base-pairing.     

Probing sequence-specific RNA recognition by the bacteriophage MS2 coat protein.

We present the results of in vitro binding studies aimed at defining the key recognition elements on the MS2 RNA translational operator (TR) essential for complex formation with coat protein. We have used chemically synthesized operators carrying modified functional groups at defined nucleotide positions, which are essential for recognition by the phage coat protein. These experiments have been complemented with modification-binding interference assays. The results confirm that the complexes which form between TR and RNA-free phage capsids, the X-ray structure of which has recently been reported at 3.0 A, are identical to those which form in solution between TR and a single coat protein dimer. There are also effects on operator affinity which cannot be explained simply by the alteration of direct RNA-protein contacts and may reflect changes in the conformational equilibrium of the unliganded operator. The results also provide support for the approach of using modified oligoribonucleotides to investigate the details of RNA-ligand interactions.     

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.     

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 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.     

Determination of the first half of the coat protein cistron of bacteriophage Qbeta as an application of a mapping procedure for RNA fragments.

A method is described to classify, in regard to their location within the genome, fragments obtained by partial cleavage of 32P-labeled bacteriophage Qbeta RNA. The location of many fragments suitable for sequence analysis could be established using as markers 29 large RNase T1-resistant oligonucleotides with known map positions. Applying this method four fragments originating from the coat protein cistron were isolated and analyzed. The sequence of a segment of 239 nucleotides located immediately adjacent to the initiation triplet was determined to be G-C-A-A-A-A-U-U-A-G-A-G-A-C-U-G-U-U-A-C-U-U-U-A-G-G-U-A-A-C-A-U-C-G-G-G-A-A-A-G-A-U-G-G-A-A-A-A-C-A-A-A-C-U-C-U-G-G-U-C-C-U-C-A-A-U-C-C-G-C-G-U-G-G-G-G-U-A-A-A-U-C-C-C-A-C-U-A-A-C-G-G-C-G-U-U-G-C-C-U-C-G-C-U-U-U-C-A-C-A-A-G-C-G-G-G-U-G-C-A-G-U-U-C-C-U-G-C-G-C-U-G-G-A-G-A-A-G-C-G-U-G-U-U-A-C-C-G-U-U-U-C-G-G-U-A-U-C-U-C-A-G-C-C-U-U-C-U-C-G-C-A-A-U-C-G-U-A-A-G-A-A-C-U-A-C-A-A-G-G-U-C-C-A-G-G-U-U-A-A-G-A-U-C-C-A-G-A-A-C-C-C-G-A-C-C-G-C-U-U-G-C-A-C-U-G-C-A-A-A-C-G-G-U-U-C-U-U-Gp. The primary structure and the secondary structure model derived from it did not provide any evidence of homology with the corresponding RNA region of bacteriophage MS2.     

Translational repression by bacteriophage MS2 coat protein does not require cysteine residues.

Previous studies implicated cysteine residues in the translational repressor (i.e. RNA binding) activity of the coat protein of bacteriophage MS2. It has been proposed that a protein sulfhydryl forms a transient covalent bond with an essential pyrimidine in the translational operator by a Michael addition reaction. We have utilized codon-directed mutagenesis methods to determine the importance of each of the two coat protein cysteines for repressor function in vivo. The results indicate that cys46 can be replaced by a variety of amino acids without loss of repressor function. Cys101, on the other hand, is more sensitive to substitution. Most position 101 substitutions inactivate the repressor, but one (arginine) results in normal repressor activity. Although the possibility of a transient covalent contact between cys101 and RNA is not categorically ruled out, construction of double mutants demonstrates that cysteines are not absolutely required for translational repression by coat protein.     

Phenotypic suppression by streptomycin of amber mutants in the ribonucleic Acid bacteriophage coat protein cistron

After mutagenesis with nitrosoguanidine or ultraviolet light, 298 streptomycin high-resistant and 98 streptomycin high-dependent mutants were isolated from HfrC Su⁻. They were tested for their ability to phenotypically suppress five different amber ribonucleic acid (RNA) bacteriophage mutants in the presence of streptomycin. The phage mutants are all in the coat protein, which is 129 amino acids long; the uracil-adenine-guanine codons were at the following positions: sus3 and amB2, 6; amB11, 50; amB21, 54; sus11, 70. Only sus3 and amB2 could be phenotypically suppressed by streptomycin; this was clearly demonstrated in nine mutant strains, seven str-HR and two str-HD. The suppression was always dependent upon added streptomycin and was dose-dependent in all cases. None of the mutants showed measurable suppression in absence of the drug. Among revertants to streptomycin independence from streptomycin-dependent strains that could show phenotypic suppression, most of those that were still resistant to streptomycin (10 μg or more) retained the capacity to show phenotypic suppression; whereas among those revertants sensitive to 10 μg of streptomycin or less, none retained the capacity. Eight different amber polar mutants (strong and weak) in gene 34 of phage T4 were also tested for pleiotypic suppression by streptomycin in all the streptomycin-resistant and -dependent strains isolated. No suppression was found in any of the 396 strains tested.     

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.