Translational repression and specific RNA binding by the coat protein of the Pseudomonas phage PP7

PP7 is a single-strand RNA bacteriophage of Pseudomonas aeroginosa and a distant relative to coliphages like MS2 and Qbeta. Here we show that PP7 coat protein is a specific RNA-binding protein, capable of repressing the translation of sequences fused to the translation initiation region of PP7 replicase. Its RNA binding activity is specific since it represses the translational operator of PP7, but does not repress the operators of the MS2 or Qbeta phages. Conditions for the purification of coat protein and for the reconstitution of its RNA binding activity from disaggregated virus-like particles were established. Its dissociation constant for PP7 operator RNA in vitro was determined to be about 1 nm. Using a genetic system in which coat protein represses translation of a replicase-beta-galactosidase fusion protein, amino acid residues important for binding of PP7 RNA were identified.     

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.     

Control of translational repression by protein-protein interactions.

The coat protein of the RNA bacteriophage MS2 is a translational repressor and interacts with a specific RNA stem-loop to inhibit translation of the viral replicase gene. As part of an effort to dissect genetically its RNA binding function, mutations were identified in the coat protein sequence that suppress mutational defects in the translational operator. Each of the mutants displayed a super-repressor phenotype, repressing translation from the wild-type and a variety of mutant operators better than did the wild-type coat protein. At least one mutant probably binds RNA more tightly than wild-type. The other mutants, however, were defective for assembly of virus-like particles, and self-associated predominantly as dimers. It is proposed that this assembly defect accounts for their super-repressor characteristics, since failure to assemble into virus-like particles elevates the effective concentration of repressor dimers. This hypothesis is supported by the observation that deletion of thirteen amino acids known to be important for assembly of dimers into capsids also resulted in the same assembly defect and in super-repressor activity. A second class of assembly defects is also described. Deletion of two amino acids from the C-terminus of coat protein resulted in failure to form capsids, most of the coat protein having the apparent molecular weight expected of trimers. This mutant (dl-8) was completely defective for repressor activity, probably because of an inability to form dimers. These results point out the inter-dependence of the structural and regulatory functions of coat protein.     

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.     

Exchange of the basic domain of human immunodeficiency virus type 1 Rev for a polyarginine stretch expands the RNA binding specificity, and a minimal arginine cluster is required for optimal RRE RNA binding affinity, nuclear accumulation, and trans-activation

The Rev regulatory protein of human immunodeficiency virus (HIV) facilitates the nuclear export of unspliced and partially spliced HIV RNAs. Using a Rev:MS2 phage coat protein fusion that could be targeted to bind and activate the Rev-responsive element (RRE) RNA or heterologous MS2 phage operator RNA, we analyzed the role(s) of the arginine-rich RNA binding domain in RNA binding and transactivation. The arginine-rich domain could be functionally replaced by a stretch of nine arginines. However, polyarginine substitutions expanded the RNA binding specificity of the resultant mutant Rev protein. Polyarginine insertions in place of residues 24 to 60 that excised the RNA binding and oligomerization domains of Rev preserved the activation for MS2 RNA, but not for the RRE. A nine-arginine insertion outside of the natural context of the Rev nuclear localization signal domain was incompatible with activation of either RNA target. Insertions of fewer than eight arginines impaired RRE activation. Interrupted lysine clusters and disruption of the arginine stretch with lysine or neutral residues resulted in a similar phenotype. Some of these mutants with a null phenotype for RRE activated the heterologous MS2 RNA target. Under steady-state conditions, mutants that preserved the Rev response for RRE RNA localized to the nuclei; those with poor or no Rev response accumulated mostly in the cytoplasm. Many of the cytoplasmically resident derivatives became nuclear when leptomycin B (LMB) treatment inhibited nuclear export of nuclear export signal-containing proteins. Mutants that had a null activation potential for either RNA target were particularly resistant to LMB treatment. Abbreviated nuclear residence times and differences in RRE binding affinity may have compromised their activation potential for RRE. High-affinity binding to MS2 RNA through the intact coat protein was sufficient to overcome the short nuclear residence times and to facilitate MS2 activation by some derivatives.     

Crystal structures of MS2 coat protein mutants in complex with wild-type RNA operator fragments.

In MS2 assembly of phage particles results from an interaction between a coat protein dimer and a stem-loop of the RNA genome (the operator hairpin). Amino acid residues Thr45, which is universally conserved among the small RNA phages, and Thr59 are part of the specific RNA binding pocket and interact directly with the RNA; the former through a hydrogen bond, the latter through hydrophobic contacts. The crystal structures of MS2 protein capsids formed by mutants Thr45Ala and Thr59Ser, both with and without the 19 nt wild-type operator hairpin bound, are reported here. The RNA hairpin binds to these mutants in a similar way to its binding to wild-type protein. In a companion paper both mutants are shown to be deficient in RNA binding in an in vivo assay, but in vitro the equilibrium dissociation constant is significantly higher than wild-type for the Thr45Ala mutant. The change in binding affinity of the Thr45Ala mutant is probably a direct consequence of removal of direct hydrogen bonds between the protein and the RNA. The properties of the Thr59Ser mutant are more difficult to explain, but are consistent with a loss of non-polar contact.     

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.     

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.     

Crystal structure of the coat protein from the GA bacteriophage: model of the unassembled dimer.

There are four groups of RNA bacteriophages with distinct antigenic and physicochemical properties due to differences in surface residues of the viral coat proteins. Coat proteins also play a role as translational repressor during the viral life cycle, binding an RNA hairpin within the genome. In this study, the first crystal structure of the coat protein from a Group II phage GA is reported and compared to the Group I MS2 coat protein. The structure of the GA dimer was determined at 2.8 A resolution (R-factor = 0.20). The overall folding pattern of the coat protein is similar to the Group I MS2 coat protein in the intact virus (Golmohammadi R, Valegård K, Fridborg K, Liljas L. 1993, J Mol Biol 234:620-639) or as an unassembled dimer (Ni Cz, Syed R, Kodandapani R. Wickersham J, Peabody DS, Ely KR, 1995, Structure 3:255-263). The structures differ in the FG loops and in the first turn of the alpha A helix. GA and MS2 coat proteins differ in sequence at 49 of 129 amino acid residues. Sequence differences that contribute to distinct immunological and physical properties of the proteins are found at the surface of the intact virus in the AB and FG loops. There are six differences in potential RNA contact residues within the RNA-binding site located in an antiparallel beta-sheet across the dimer interface. Three differences involve residues in the center of this concave site: Lys/Arg 83, Ser/Asn 87, and Asp/Glu 89. Residue 87 was shown by molecular genetics to define RNA-binding specificity by GA or MS2 coat protein (Lim F. Spingola M, Peabody DS, 1994, J Biol Chem 269:9006-9010). This sequence difference reflects recognition of the nucleotide at position -5 in the unpaired loop of the translational operators bound by these coat proteins. In GA, the nucleotide at this position is a purine whereas in MS2, it is a pyrimidine.     

Dissecting the key recognition features of the MS2 bacteriophage translational repression complex.

The MS2 RNA operator capsid offers an unparalleled opportunity to study sequence-specific protein-protein and RNA-protein interactions in molecular detail. RNA molecules encompassing the minimal translational operator recognition elements can be soaked into crystals of RNA-free coat protein shells, allowing the RNA to access the interior of the capsids and make contact with the operator binding sites. Correct interpretation of these structural studies depends critically on functional analysis in solution to confirm that the interactions seen in the crystal are not an artefact of the unusual approach used to generate the RNA-protein complexes. Here we present a series of in vivo and in vitro functional assays, using coat proteins carrying single amino acid substitutions at residues which either interact with the operator RNA or are involved in stabilizing the conformation of the FG loop, the site of the major quasi-equivalent conformational change. Variant operator RNAs have been assayed for coat protein affinity in vitro. The results reveal the robustness of the operator-coat protein interaction and the requirement for both halves of a protein dimer to contact RNA in order to achieve tight binding. They also suggest that there may be a direct link between the conformation of the FG loop and RNA binding.     

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.     

Role of the coat Protein-RNA interaction in the life cycle of bacteriophage MS2

The coat protein of the RNA bacteriophage MS2 interacts with viral RNA to translationally repress replicase synthesis. This protein-RNA interaction is also thought to play a role in genome encapsidation. In this study the strength of the interaction was perturbed by constructing a recombinant genome containing a super-repressing coat mutation. Because replicase synthesis is prematurely repressed, the mutant produces plaques about five orders of magnitude less efficiently than wild-type. The few plaques obtained are second-site revertants of the original coat mutation and fall into two categories. Those of the first type contain nucleotide substitutions within the translational operator that reduce or destroy its ability to bind coat protein, showing that this interaction is not necessary for genome encapsidation. Revertants of the second type are double mutants in which one substitution converts the coat initiator AUG to AUA and the other substitutes an A for the G normally present two nucleotides upstream of the coat start codon. The mutation of the coat protein gene AUG to AUA, by itself, reduces coat protein synthesis to a few percent of the wild-type level. The second substitution destabilizes the coat initiator stem-loop and restores coat protein synthesis to within a few fold of wild-type levels. Received: 17 June 1996 / Accepted: 5 December 1996     

A comparison of two phage coat protein-RNA interactions.

The interaction between the coat protein of the group I bacteriophage fr with its translational operator site is compared with the previously studied R17 interaction. The sequence of the two RNA binding sites differ by 2 of 20 nucleotides and two coat proteins by 17 of 129 amino acids. An analysis of the binding of fr coat protein to 24 operator variants revealed that the two proteins recognize operator sequences in virtually the same way. However, fr coat protein binds to nearly every RNA 6 to 14-fold tighter than R17 coat protein. Since the fr operator is a weaker binding variant and the fr coat protein shows a different temperature dependence of binding, it is unlikely that the two systems have different Kas in vivo. RNA fragments containing the operator sequences can initiate the capsid assembly with both fr and R17 coat protein. Surprisingly, the two coat proteins can form a mixed capsid in vitro.     

RNA binding properties of the coat protein from bacteriophage GA.

The coat protein of bacteriophage GA, a group II RNA phage, binds to a small RNA hairpin corresponding to its replicase operator. Binding is specific, with a Ka of 71 microM -1. This interaction differs kinetically from the analogous coat protein-RNA hairpin interactions of other RNA phage and also deviates somewhat in its pH and salt dependence. Despite 46 of 129 amino acid differences between the GA and group I phage R17 coat proteins, the binding sites are fairly similar. The essential features of the GA coat protein binding site are a based-paired stem with an unpaired purine and a four nucleotide loop having an A at position -4 and a purine at -7. Unlike the group I phage proteins, the GA coat protein does not distinguish between two alternate positions for the unpaired purine and does not show high specificity for a pyrimidine at position -5 of the loop.     

RNA recognition site of PP7 coat protein

The coat proteins of different single-strand RNA phages use a common protein tertiary structural framework to recognize different RNA hairpins and thus offer a natural model for understanding the molecular basis of RNA-binding specificity. Here we describe the RNA structural requirements for binding to the coat protein of bacteriophage PP7, an RNA phage of Pseudomonas. Its recognition specificity differs substantially from those of the coat proteins of its previously characterized relatives such as the coliphages MS2 and Qbeta. Using designed variants of the wild-type RNA, and selection of binding-competent sequences from random RNA sequence libraries (i.e. SELEX) we find that tight binding to PP7 coat protein is favored by the existence of an 8 bp hairpin with a bulged purine on its 5' side separated by 4 bp from a 6 nt loop having the sequence Pu-U-A-G/U-G-Pu. However, another structural class possessing only some of these features is capable of binding almost as tightly.     

hnRNP A1 Recruited to an Exon In Vivo Can Function as an Exon Splicing Silencer

Some exons contain exon splicing silencers. Their activity is frequently balanced by that of splicing enhancers, and this is important to ensure correct relative levels of alternatively spliced mRNAs. Using an immunoprecipitation and UV-cross-linking assay, we show that RNA molecules containing splicing silencers from the human immunodeficiency virus type 1 tat exon 2 or the human fibroblast growth factor receptor 2 K-SAM exon bind to hnRNP A1 in HeLa cell nuclear extracts better than the corresponding RNA molecule without a silencer. Two different point mutations which abolish the K-SAM exon splicing silencer’s activity reduce hnRNP A1 binding twofold. Recruitment of hnRNP A1 in the form of a fusion with bacteriophage MS2 coat protein to a K-SAM exon whose exon splicing silencer has been replaced by a coat binding site efficiently represses splicing of the exon in vivo. Recruitment of only the glycine-rich C-terminal domain of hnRNP A1, which is capable of interactions with other proteins, is sufficient to repress exon splicing. Our results show that hnRNP A1 can function to repress splicing, and they suggest that at least some exon splicing silencers could work by recruiting hnRNP A1.     

Effect of the sequences upstream from the ribosome-binding site on the yield of protein from the cloned gene for phage MS2 coat protein

The translational efficiency of the coat protein gene of phage MS2 has been examined in vivo with respect to neighbouring sequences. The cloned MS2 DNA has been gradually shortened starting at the 5' or 3' terminus, and its effect on coat protein synthesis monitored. Removal of the 3'-terminal sequences had little influence. In contrast, the gradual removal of the 5'-terminal region profoundly reduces translation. Long before the ribosomal binding site (RBS) of the coat protein (CP) gene is reached, the yield of CP has dropped by one order of magnitude. Functional half-lives of the various messengers were found not to be significantly different. Available evidence indicates that the secondary structure of the RBS in native and shortened MS2 RNA is identical. We infer that important determinants for ribosome recognition lie 5' to the RBS region of the MS2 RNA coat gene.