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.     

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.     

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.     

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.     

Properties of Bacillus cereus temperature-sensitive mutants altered in spore coat formation.

Three conditional Bacillus cereus mutants altered in the assembly or formation of spore coat layers were analyzed. They all grew as well as the wild type in an enriched or minimal medium but produced lysozyme and octanol-sensitive spores at the nonpermissive temperature (35 to 38 degrees C). The spores also germinated slowly when produced at 35 degrees C. Temperature-shift experiments indicated that the defective protein or regulatory signal is expressed at the time of formation of the outer spore coat layers. Revertants regained all wild-type spore properties at frequencies consistent with initial point mutations. Spore coat defects were evident in thin sections and freeze-etch micrographs of mutant spores produced at 35 degrees C. In addition, one mutant contained an extra surface deposit, perhaps unprocessed spore coat precursor protein. A prevalent band of about 65,000 daltons (the same size as the presumptive precursor) was present in spore coat extracts of this mutant and may be incorrectly processed to mature spore coat polypeptides. Another class of mutants was defective in the late uptake of half-cystine residues into spore coats. Such a defect could lead to improper formation of the outer spore coat layers.     

Molecular genetics of bacteriophage P22 scaffolding protein's functional domains

The assembly intermediates of the Salmonella bacteriophage P22 are well defined but the molecular interactions between the subunits that participate in its assembly are not. The first stable intermediate in the assembly of the P22 virion is the procapsid, a preformed protein shell into which the viral genome is packaged. The procapsid consists of an icosahedrally symmetric shell of 415 molecules of coat protein, a dodecameric ring of portal protein at one of the icosahedral vertices through which the DNA enters, and approximately 250 molecules of scaffolding protein in the interior. Scaffolding protein is required for assembly of the procapsid but is not present in the mature virion. In order to define regions of scaffolding protein that contribute to the different aspects of its function, truncation mutants of the scaffolding protein were expressed during infection with scaffolding deficient phage P22, and the products of assembly were analyzed. Scaffolding protein amino acids 1-20 are not essential, since a mutant missing them is able to fully complement scaffolding deficient phage. Mutants lacking 57 N-terminal amino acids support the assembly of DNA containing virion-like particles; however, these particles have at least three differences from wild-type virions: (i) a less than normal complement of the gene 16 protein, which is required for DNA injection from the virion, (ii) a fraction of the truncated scaffolding protein was retained within the virions, and (iii) the encapsidated DNA molecule is shorter than the wild-type genome. Procapsids assembled in the presence of a scaffolding protein mutant consisting of only the C-terminal 75 amino acids contained the portal protein, but procapsids assembled with the C-terminal 66 did not, suggesting portal recruitment function for the region about 75 amino acids from the C terminus. Finally, scaffolding protein amino acids 280 through 294 constitute its minimal coat protein binding site.     

T=1 capsid structures of Sesbania mosaic virus coat protein mutants: determinants of T=3 and T=1 capsid assembly

Sesbania mosaic virus particles consist of 180 coat protein subunits of 29kDa organized on a T=3 icosahedral lattice. N-terminal deletion mutants of coat protein that lack 36 (CP-NDelta36) and 65 (CP-NDelta65) residues from the N terminus, when expressed in Escherichia coli, produced similar T=1 capsids of approximate diameter 20nm. In contrast to the wild-type particles, these contain only 60 copies of the truncated protein subunits (T=1). CP-NDelta65 lacks the "beta-annulus" believed to be responsible for the error-free assembly of T=3 particles. Though the CP-NDelta36 mutant has the beta-annulus segment, it does not form a T=3 capsid, presumably because it lacks an arginine-rich motif found close to the amino terminus. Both CP-NDelta36 and CP-NDelta65 T=1 capsids retain many key features of the T=3 quaternary structure. Calcium binding geometries at the coat protein interfaces in these two particles are also nearly identical. When the conserved aspartate residues that coordinate the calcium, D146 and D149 in the CP-NDelta65, were mutated to asparagine (CP-NDelta65-D146N-D149N), the subunits assembled into T=1 particles but failed to bind calcium ions. The structure of this mutant revealed particles that were slightly expanded. The analysis of the structures of these mutant capsids suggests that although calcium binding contributes substantially to the stability of T=1 particles, it is not mandatory for their assembly. In contrast, the presence of a large fraction of the amino-terminal arm including sequences that precede the beta-annulus and the conserved D149 appear to be indispensable for the error-free assembly of T=3 particles.     

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.     

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.     

Mutagenic analysis of potato virus X movement protein (TGBp1) and the coat protein (CP): in vitro TGBp1-CP binding and viral RNA translation activation

Previously, we have shown that encapsidated Potato virus X (PVX) RNA was non-translatable in vitro , but could be converted into a translatable form by binding of the PVX movement protein TGBp1 to one end of the virion or by coat protein (CP) phosphorylation. Here, a mutagenic analysis of PVX CP and TGBp1 was used to identify the regions involved in TGBp1–CP binding and translational activation of PVX RNA by TGBp1. It was found that the C-terminal (C-ter) 10/18 amino acids region was not essential for virus-like particle (VP) assembly from CP and RNA. However, the VPs assembled from the CP lacking C-ter 10/18 amino acids were incapable of TGBp1 binding and being translationally activated. It was suggested that the 10-amino-acid C-ter regions of protein subunits located at one end of a polar helical PVX particle contain a domain accessible to TGBp1 binding and PVX remodelling. The non-translatable particles assembled from the C-ter mutant CP could be converted into a translatable form by CP phosphorylation. The TGBp1–CP binding activity was preserved unless a conservative motif IV was removed from TGBp1. By contrast, TGBp1-dependent activation of PVX RNA translation was abolished by deletions of various NTPase/helicase conservative motifs and their combinations. The motif IV might be essential for TGBp1–CP binding, but insufficient for PVX RNA translation activation. The evidence to discriminate between these two events, i.e. TGBp1 binding to the CP-helix and TGBp1-dependent RNA translation activation, is discussed.     

The basis for the super-repressor phenotypes of the AV77 and EK18 mutants of trp repressor

The DNA-binding properties of two super-repressor mutants of the Escherichia coli trp repressor, EK18 and AV77, have been investigated using steady-state fluorescence anisotropy measurements, in order to further elucidate the basis for their super-repressor phenotypes. Several suggestions have been previously proposed as the basis for the super-repressor phenotype of EK18 and AV77. For the negative to positive charge change EK18 mutant, increased electrostatic interactions between the EK18 mutant and the operator and increased protein-protein interactions between EK18 dimers have been suggested as contributing to the super-repressor phenotype of this mutant. We show that EK18 dimers actually bind to wild-type and variant operator sequences with a decrease in apparent cooperativity and an increase in affinity, compared to WTTR dimers. Thus, the EK18 super-repressor phenotype is not due to increased cooperative binding between EK18 dimers. These results support the hypothesis that the super-repressor phenotype of EK18 arises from increased electrostatic interactions between the mutant and DNA. In the case of the AV77 mutant, weaker binding affinity of apo-AV77 to non-specific DNA, increased selectivity of binding of AV77 for the operator, and a higher population of folded functional AV77 dimers available to bind the operator under limiting L-Trp conditions in vivo, have been proposed for the super-repressor phenotype of this mutant. We show that like the EK18 mutant, apoAV77 binds with higher affinity to non-specific DNA compared to apo-WTTR and that the holo-AV77 mutant does not bind with higher selectivity to the operator, has had been previously proposed. We therefore conclude that the super-repressor phenotype of the AV77 mutant is due to an increase in the population of folded, functional AV77 dimers, under limiting L-Trp conditions in vivo.     

Assembly Pathway of Hepatitis B Core Virus-like Particles from Genetically Fused Dimers

Macromolecular complexes are responsible for many key biological processes. However, in most cases details of the assembly/disassembly of such complexes are unknown at the molecular level, as the low abundance and transient nature of assembly intermediates make analysis challenging. The assembly of virus capsids is an example of such a process. The hepatitis B virus capsid (core) can be composed of either 90 or 120 dimers of coat protein. Previous studies have proposed a trimer of dimers as an important intermediate species in assembly, acting to nucleate further assembly by dimer addition. Using novel genetically-fused coat protein dimers, we have been able to trap higher-order assembly intermediates and to demonstrate for the first time that both dimeric and trimeric complexes are on pathway to virus-like particle (capsid) formation.     

Temperature-sensitive translation of MS2 bacteriophage RNA

A comparison was made of bacteriophage MS2 RNA translation in infected Escherichia coli cells and in a defined cell-free system. A number of temperature-sensitive mutants were used as hosts for viral RNA translation at permissive and restrictive temperatures. The amount of viral coat protein synthesis was determined after gel electrophoresis of proteins from the cell lysates. These results were compared to those obtained with cell-free translation assays conducted with ribosomes isolated from the same mutants. Compared with control cells, a reduced activity in vivo and in vitro was found for each mutant examined at elevated temperatures. A good correlation between the two types of translational assays was observed. These findings are discussed in terms of the translational defects known to be a characteristic of some of these mutant strains.     

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.     

Distinct roles for nucleic acid in in vitro assembly of purified Mason-Pfizer monkey virus CANC proteins

In contrast to other retroviruses, Mason-Pfizer monkey virus (M-PMV) assembles immature capsids in the cytoplasm. We have compared the ability of minimal assembly-competent domains from M-PMV and human immunodeficiency virus type 1 (HIV-1) to assemble in vitro into virus-like particles in the presence and absence of nucleic acids. A fusion protein comprised of the capsid and nucleocapsid domains of Gag (CANC) and its N-terminally modified mutant (DeltaProCANC) were used to mimic the assembly of the viral core and immature particles, respectively. In contrast to HIV-1, where CANC assembled efficiently into cylindrical structures, the same domains of M-PMV were assembly incompetent. The addition of RNA or oligonucleotides did not complement this defect. In contrast, the M-PMV DeltaProCANC molecule was able to assemble into spherical particles, while that of HIV-1 formed both spheres and cylinders. For M-PMV, the addition of purified RNA increased the efficiency with which DeltaProCANC formed spherical particles both in terms of the overall amount and the numbers of completed spheres. The amount of RNA incorporated was determined, and for both rRNA and MS2-RNA, quantities similar to that of genomic RNA were encapsidated. Oligonucleotides also stimulated assembly; however, they were incorporated into DeltaProCANC spherical particles in trace amounts that could not serve as a stoichiometric structural component for assembly. Thus, oligonucleotides may, through a transient interaction, induce conformational changes that facilitate assembly, while longer RNAs appear to facilitate the complete assembly of spherical particles.     

Large-scale,pH-dependent,quaternary structure changes in an RNA virus capsid are reversible in the absence of subunit autoproteolysis

The assembly and maturation of the coat protein of a T=4, nonenveloped, single-stranded RNA virus, Nudaurelia capensis omega virus (N omega V), was examined by using a recombinant baculovirus expression system. At pH 7.6, the coat protein assembles into a stable particle called the procapsid, which is 450 A in diameter and porous. Lowering the pH to 5.0 leads to a concerted reorganization of the subunits into a 410-A-diameter particle called the capsid, which has no obvious pores. This conformational change is rapid but reversible until slow, autoproteolytic cleavage occurs in at least 15% of the subunits at the lower pH. In this report, we show that expression of subunits with replacement of Asn-570, which is at the cleavage site, with Thr results in assembly of particles with expected morphology but that are cleavage defective. The conformational change from procapsid to capsid is reversible in N570T mutant virus-like particles, in contrast to wild-type particles, which are locked into the capsid conformation after cleavage of the coat protein. The reexpanded procapsids display slightly different properties than the original procapsid, suggesting hysteretic effects. Because of the stability of the procapsid under near-neutral conditions and the reversible properties of the cleavage-defective mutant, N omega V provides an excellent model for the study of pH-induced conformational changes in macromolecular assemblies. Here, we identify the relationship between cleavage and the conformational change and propose a pH-dependent helix-coil transition that may be responsible for the structural rearrangement in N omega V.     

Mutation of interfacial residues disrupts subunit folding and particle assembly of Physalis mottle tymovirus

Virus-like particles (VLPs) serve as excellent model systems to identify the pathways of virus assembly. To gain insights into the assembly mechanisms of the Physalis mottle tymovirus (PhMV), six interfacial residues, identified based on the crystal structure of the native and recombinant capsids, were targeted for mutagenesis. The Q37E, Y67A, R68Q, D83A, I123A, and S145A mutants of the PhMV recombinant coat protein (rCP) expressed in Escherichia coli were soluble. However, except for the S145A mutant, which assembled into VLPs similar to that of wild type rCP capsids, all the other mutants failed to assemble into VLPs. Furthermore, the purified Q37E, Y67A, R68Q, D83A, and I123A rCP mutants existed essentially as partially folded monomers as revealed by sucrose density gradient analysis, circular dichroism, fluorescence, thermal, and urea denaturation studies. The rCP mutants locked into such conformations probably lack the structural signals/features that would allow them to assemble into capsids. Thus, the mutation of residues involved in inter-subunit interactions in PhMV disrupts both subunit folding and particle assembly.     

Intragenic Suppression of a Capsid Assembly-Defective P22 Tailspike Mutation

The tailspike protein of bacteriophage P22 assembles with mature capsids during the final reaction in phage morphogenesis. The gene 9 mutation hmH3034 synthesizes a tailspike protein with a change at amino acid 100 from Asp to Asn. This mutant form of trimeric tailspike protein fails to assemble with capsids in vivo. By using in vitro quantitative tailspike-capsid assembly assays, this mutant tailspike trimer can be shown to assemble with capsids at very high tailspike concentrations. From these assays, we estimate that this single missense mutation decreases by 100-500-fold the affinity of the tailspike for capsids. Furthermore, hmH3034 tailspike protein has a structural defect which makes the mature tailspike trimers sensitive to SDS at room temperature and causes the trimers to "partially unfold." Spontaneously arising intragenic suppressors of the capsid assembly defect have been isolated. All of these suppressors are changes at amino acid 13 of the tailspike protein, which substitute His, Leu or Ser for the wild type amino acid Arg. These hmH3034/sup3034 mutants and the separated sup3034 mutants form fully functional tailspike proteins with assembly activities indistinguishable from wild type while retaining the SDS-sensitive structural defect. From the analysis of the hmH3034 mutant and its suppressors, we propose that in the wild-type tailspike protein, the Asp residue at position 100 and the Arg residue at position 13 form an intrachain or interchain salt bridge which stabilizes the amino terminus of the tailspike protein and that the unneutralized positive charge at amino acid 13 in the hmH3034 protein is the cause of the assembly defect of this protein.(ABSTRACT TRUNCATED AT 250 WORDS)