Scaffolding protein regulates the polymerization of P22 coat subunits into icosahedral shells in vitro

Coat and scaffolding subunits derived from P22 procapsids have been purified in forms that co-assemble rapidly and efficiently into icosahedral shells in vitro under native conditions. The half-time for this reaction is approximately five minutes at 21 degrees C. The in vitro reaction exhibits the regulated features observed in vivo. Neither coat nor scaffolding subunits alone self-assemble into large structures. Upon mixing the subunits together they polymerize into procapsid-like shells with the in vivo coat and scaffolding protein composition. The subunits in the purified coat protein preparations are monomeric. The scaffolding subunits appear to be monomeric or dimeric. These results confirm that P22 procapsid formation does not proceed through the assembly of a core of scaffolding, which then organizes the coat, but requires copolymerization of coat and scaffolding. To explore the mechanisms of the control of polymerization, shell assembly was examined as a function of the input ratio of scaffolding to coat subunits. The results indicated that scaffolding protein was required for both initiation of shell assembly and continued polymerization. Though procapsids produced in vivo contain about 300 molecules of scaffolding, shells with fewer subunits could be assembled down to a lower limit of about 140 scaffolding subunits per shell. The overall results of these experiments indicate that coat and scaffolding subunits must interact in both the initiation and the growth phases of shell assembly. However, it remains unclear whether during growth the coat and scaffolding subunits form a mixed oligomer prior to adding to the shell or whether this occurs at the growing edge.     

Regulation of coat protein polymerization by the scaffolding protein of bacteriophage P22.

In the morphogenesis of double stranded DNA phages, a precursor protein shell empty of DNA is first assembled and then filled with DNA. The assembly of the correctly dimensioned precursor shell (procapsid) of Salmonella bacteriophage P22 requires the interaction of some 420 coat protein subunits with approximately 200 scaffolding protein subunits to form a double shelled particle with the scaffolding protein on the inside. In the course of DNA packaging, all of the scaffolding protein subunits exit from the procapsid and participate in further rounds of procapsid assembly (King and Casjens. 1974. Nature (Lond.). 251:112-119). To study the mechanism of shell assembly we have purified the coat and scaffolding protein subunits by selective dissociation of isolated procapsids. Both proteins can be obtained as soluble subunits in Tris buffer at near neutral pH. The coat protein sedimented in sucrose gradients as a roughly spherical monomer, while the scaffolding protein sedimented as if it were an elongated monomer. When the two proteins were mixed together in 1.5 M guanidine hydrochloride and dialyzed back to buffer at room temperature, procapsids formed which were very similar in morphology, sedimentation behavior, and protein composition to procapsids formed in vivo. Incubation of either protein alone under the same conditions did not yield any large structures. We interpret these results to mean that the assembly of the shell involves a switching of both proteins from their nonaggregating to their aggregating forms through their mutual interaction. The results are discussed in terms of the general problem of self-regulated assembly and the control of protein polymerization in morphogenesis.     

Identification and characterization of the domain structure of bacteriophage P22 coat protein.

The bacteriophage P22 serves as a model for assembly of icosahedral dsDNA viruses. The P22 procapsid, which constitutes the precursor for DNA packaging, is built from 420 copies of a single coat protein with the aid of stoichiometric amounts of scaffolding protein. Upon DNA entry, the procapsid shell expands and matures into a stable virion. It was proposed that expansion is mediated by hinge bending and domain movement. We have used limited proteolysis to map the dynamic stability of the coat protein domain structures. The coat protein monomer is susceptible to proteolytic digestion, but limited proteolysis by small quantities of elastase or chymotrypsin yielded two metastable fragments (domains). The N-terminal domain (residues 1-180) is linked to the C-terminal domain (residues 205-429) by a protease-susceptible loop (residues 180-205). The two domains remain associated after the loop cleavage. Although only a small change of secondary structure results from the loop cleavage, both tertiary interdomain contacts and subunit thermostability are diminished. The intact loop is also required for assembly of the monomeric coat protein into procapsids. Upon assembly, coat protein becomes largely protease-resistant, baring cleavage within the loop region of about half of the subunits. Loop cleavage decreases the stability of the procapsids and facilitates heat-induced shell expansion. Upon expansion, the loop becomes protease-resistant. Our data suggest the loop region becomes more ordered during assembly and maturation and thereby plays an important role in both of these stages.     

NMR assignments for the telokin-like domain of bacteriophage P22 coat protein

The bacteriophage P22 virion is assembled from identical coat protein monomers in a complex reaction that is generally conserved among tailed, double-stranded DNA bacteriophages and viruses. Many coat proteins of dsDNA viruses have structures based on the HK97 fold, but in some viruses and phages there are additional domains. In the P22 coat protein, a “telokin-like” domain was recently identified, whose structure has not yet been characterized at high-resolution. Two recently published low-resolution cryo-EM reconstructions suggest markedly different folds for the telokin-like domain that lead to alternative conclusions about its function in capsid assembly and stability. Here we report ¹H, ¹⁵N, and ¹³C NMR resonance assignments for the telokin-like domain. The secondary structure predicted from the chemical shift values obtained in this work shows significant discrepancies from both cryo-EM models but agrees better with one of the models. In particular, the functionally important “D-loop” in one model shows chemical shifts and solvent exchange protection more consistent with β-sheet structure. Our work will set the basis for a high-resolution NMR structure determination of the telokin-like domain that will help improve the cryo-EM models, and in turn lead to a better understanding of how coat protein monomers assemble into the icosahedral capsids required for virulence.     

Conformational changes in bacteriophage P22 scaffolding protein induced by interaction with coat protein

Many prokaryotic and eukaryotic double-stranded DNA viruses use a scaffolding protein to assemble their capsid. Assembly of the double-stranded DNA bacteriophage P22 procapsids requires the interaction of 415 molecules of coat protein and 60-300 molecules of scaffolding protein. Although the 303-amino-acid scaffolding protein is essential for proper assembly of procapsids, little is known about its structure beyond an NMR structure of the extreme C-terminus, which is known to interact with coat protein. Deletion mutagenesis indicates that other regions of scaffolding protein are involved in interactions with coat protein and other capsid proteins. Single-cysteine and double-cysteine variants of scaffolding protein were generated for use in fluorescence resonance energy transfer and cross-linking experiments designed to probe the conformation of scaffolding protein in solution and within procapsids. We showed that the N-terminus and the C-terminus are proximate in solution, and that the middle of the protein is near the N-terminus but not accessible to the C-terminus. In procapsids, the N-terminus was no longer accessible to the C-terminus, indicating that there is a conformational change in scaffolding protein upon assembly. In addition, our data are consistent with a model where scaffolding protein dimers are positioned parallel with one another with the associated C-termini.     

Determinants of bacteriophage P22 polyhead formation: the role of coat protein flexibility in conformational switching

We have investigated determinants of polyhead formation in bacteriophage P22 in order to understand the molecular mechanism by which coat protein assembly goes astray. Polyhead assembly is caused by amino acid substitutions in coat protein at position 170, which is located in the β‐hinge. In vivo scaffolding protein does not correct polyhead assembly by F170A or F170K coat proteins, but does for F170L. All F170 variants bind scaffolding protein more weakly than wild‐type as observed by affinity chromatography with scaffolding protein‐agarose and scaffolding protein shell re‐entry experiments. Electron cryo‐microscopy and three‐dimensional image reconstructions of F170A and F170K empty procapsid shells showed that there is a decreased flexibility of the coat subunits relative to wild‐type. This was confirmed by limited proteolysis and protein sequencing, which showed increased protection of the A‐domain. Our data support the conclusion that the decrease in flexibility of the A‐domain leads to crowding of the subunits at the centre of the pentons, thereby favouring the hexon configuration during assembly. Thus, correct coat protein interactions with scaffolding protein and maintenance of sufficient coat protein flexibility are crucial for proper P22 assembly. The coat protein β‐hinge region is the major determinant for both features.     

Structure and stability of icosahedral particles of a covalent coat protein dimer of bacteriophage MS2

Particles formed by the bacteriophage MS2 coat protein mutants with insertions in their surface loops induce a strong immune response against the inserted epitopes. The covalent dimers created by fusion of two copies of the coat protein gene are more tolerant to various insertions into the surface loops than the single subunits. We determined a 4.7‐Å resolution crystal structure of an icosahedral particle assembled from covalent dimers and compared its stability with wild‐type virions. The structure resembled the wild‐type virion except for the intersubunit linker regions. The covalent dimer orientation was random with respect to both icosahedral twofold and quasi‐twofold symmetry axes. A fraction of the particles was unstable in phosphate buffer because of assembly defects. Our results provide a structural background for design of modified covalent coat protein dimer subunits for use in immunization.     

Assembly in vitro of bacteriophage P22 procapsids from purified coat and scaffolding subunits

The coat and scaffolding proteins of bacteriophage P22 procapsids have been purified in soluble form. By incubating both purified proteins with a mutant-infected cell extract lacking procapsids, but competent for DNA packaging in vitro (Poteete et al., 1979), we were able to obtain assembly of biologically active procapsids in vitro. The active species for complementation in vitro in both protein preparations copurified with the soluble subunits, indicating that these subunits represent precursors in procapsid polymerization.When the purified coat and scaffolding subunits were mixed directly, they polymerized into double-shelled procapsid-like structures during dialysis from 1.5 m-guanidine hydrochloride to buffer. When dialyzed separately under the same conditions, the scaffolding subunits did not polymerize but remained as soluble subunits, as did most of the coat subunits. No evidence was found for self-assembly of the scaffolding protein in the absence of the coat protein.The unassembled coat subunits sedimented at 3.9 S and the unassembled scaffolding subunits sedimented at 2.4 S in sucrose gradients. The Stokes' radius, determined by gel filtration, was 25 Å for the coat subunits and 34 Å for the scaffolding subunits. These results indicate that the scaffolding subunits are relatively slender elongated molecules, whereas the coat subunits are more globular.The experiments suggest that the procapsid is built by copolymerization of the two protein species. Their interaction on the growing surface of the shell structure, and not in solution, appears to regulate successive binding interactions.     

Nucleation and growth phases in the polymerization of coat and scaffolding subunits into icosahedral procapsid shells.

The polymerization of protein subunits into precursor shells empty of DNA is a critical process in the assembly of double-stranded DNA viruses. For the well-characterized icosahedral procapsid of phage P22, coat and scaffolding protein subunits do not assemble separately but, upon mixing, copolymerize into double-shelled procapsids in vitro. The polymerization reaction displays the characteristics of a nucleation limited reaction: a paucity of intermediate assembly states, a critical concentration, and kinetics displaying a lag phase. Partially formed shell intermediates were directly visualized during the growth phase by electron microscopy of the reaction mixture. The morphology of these intermediates suggests that assembly is a highly directed process. The initial rate of this reaction depends on the fifth power of the coat subunit concentration and the second or third power of the scaffolding concentration, suggesting that pentamer of coat protein and dimers or trimers of scaffolding protein, respectively, participate in the rate-limiting step.     

Purification and characterization of bacteriophage P22 Xis protein

The temperate bacteriophages λ and P22 share similarities in their site-specific recombination reactions. Both require phage-encoded integrase (Int) proteins for integrative recombination and excisionase (Xis) proteins for excision. These proteins bind to core-type, arm-type, and Xis binding sites to facilitate the reaction. λ and P22 Xis proteins are both small proteins (λ Xis, 72 amino acids; P22 Xis, 116 amino acids) and have basic isoelectric points (for P22 Xis, 9.42; for λ Xis, 11.16). However, the P22 Xis and λ Xis primary sequences lack significant similarity at the amino acid level, and the linear organizations of the P22 phage attachment site DNA-binding sites have differences that could be important in quaternary intasome structure. We purified P22 Xis and studied the protein in vitro by means of electrophoretic mobility shift assays and footprinting, cross-linking, gel filtration stoichiometry, and DNA bending assays. We identified one protected site that is bent approximately 137 degrees when bound by P22 Xis. The protein binds cooperatively and at high protein concentrations protects secondary sites that may be important for function. Finally, we aligned the attP arms containing the major Xis binding sites from bacteriophages λ, P22, L5, HP1, and P2 and the conjugative transposon Tn916. The similarity in alignments among the sites suggests that Xis-containing bacteriophage arms may form similar structures.     

Structure of phage P22 coat protein aggregates formed in the absence of the scaffolding protein.

Previous studies have shown that the assembly of the precursor shell (prohead) of bacteriophage P22 requires the copolymerization of the gene 5 coat protein with the gene 8 scaffolding protein. Removal of the scaffolding protein by mutation prevents efficient coat protein assembly, but some aberrant particles do form. We have now isolated these structures and characterized them with respect to morphology, protein composition, and small-angle X-ray scattering properties.The aberrant particles fall into three morphological classes, i.e. complex spirals and closed shells of two sizes. Small-angle X-ray scattering studies confirm that the larger particles are hollow shells with the radius of proheads ($\text{r = 260}\text{A}\text{?}$), and not of the mature virus ($\text{r = 285}\text{A}\text{?}$). These structures lack the inner shell of scaffolding protein found in proheads. The small particles have a radius of 195 Å, smaller than proheads, and appear to contain material, not scaffolding protein, within the outer shell.The aberrant particles contain two minor protein species, the gene 9 tail-spike protein, and an unidentified 67,000 molecular weight polypeptide, probably from the host. Neither is found in normal proheads. Removal of gene.9 product by mutation did not affect the formation of the aggregates. Fractionation of the morphological classes of particles revealed that the 67,000 molecular weight band was associated with the closed shells. It may be serving as a pseudo-initiator.Earlier studies had shown that treatment of proheads with sodium dodecyl sulfate in vitro resulted in loss of the scaffolding protein, and expansion of the shell to the mature radius of 285 Å. When the 8^? prohead-sized shells were treated similarly, they also expanded to the mature-sized shell. These results support the idea that there are at least two stable states of the coat protein, one of which, the prohead form, is an obligatory precursor of the mature form.     

Preliminary crystallographic analysis of the bacteriophage P22 portal protein

Portal proteins are components of large oligomeric dsDNA pumps connecting the icosahedral capsid of tailed bacteriophages to the tail. Prior to the tail attachment, dsDNA is actively pumped through a central cavity formed by the subunits. We have studied the portal protein of bacteriophage P22, which is the largest connector characterized among the tailed bacteriophages. The molecular weight of the monomer is 82.7 kDa, and it spontaneously assembles into an oligomeric structure of approximately 1.0 MDa. Here we present a preliminary biochemical and crystallographic characterization of this large macromolecular complex. The main difficulties related to the crystallization of P22 portal protein lay in the intrinsic dynamic nature of the portal oligomer. Recombinant connectors assembled from portal monomers expressed in Escherichia coli form rings of different stoichiometry in solution, which cannot be separated on the basis of their size. To overcome this intrinsic heterogeneity we devised a biochemical purification that separates different ring populations on the basis of their charge. Small ordered crystals were grown from drops containing a high concentration of the kosmotropic agent tert-butanol and used for data collection. A preliminary crystallographic analysis to 7.0-A resolution revealed that the P22 portal protein crystallized in space group I4 with unit cell dimensions a=b=409.4A, c=260.4A. This unit cell contains a total of eight connectors. Analysis of the noncrystallographic symmetry by the self-rotation function unambiguously confirmed that bacteriophage P22 portal protein is a dodecamer with a periodicity of 30 degrees. The cryo-EM reconstruction of the dodecahedral bacteriophage T3 portal protein will be used as a model to initiate phase extension and structure determination.     

UV sensitivity of a nonrepressor regulatory protein of bacteriophage P22.

The product of phage P22 gene c1 has two functions: it promotes synthesis of P22 repressor and it retards expression of some lytic genes. We present evidence that this product is inactivated in UV-irradiated hosts. The conditions for inactivation of c1 product include a functional DNA recombination system involving the host recA gene.     

Assembly-controlled autogenous modulation of bacteriophage P22 scaffolding protein gene expression.

In the assembly of bacteriophage P22, precursor particles containing two major proteins, the gene 5 coat protein and the gene 8 scaffolding protein, package the DNA molecule. During the encapsidation reaction all of the scaffolding protein molecules are released intact and subsequently participate in further rounds of DNA encapsidation. We have previously shown that even though it lies in the center of the late region of the genetic map, the scaffolding protein gene is not always expressed coordinately with the remainder of the late proteins and that some feature of the phage assembly process affects its expression. We present here in vivo experiments which show that there is an inverse correlation between the amount of unassembled scaffolding protein and the rate of scaffolding protein synthesis and that long amber fragments of the scaffolding protein can turn down the synthesis of intact scaffolding protein in trans. These results support a model for scaffolding protein regulation in which the feature of the assembly process which modulates the rate of scaffolding protein synthesis is the amount of unassembled scaffolding protein itself.     

Dynamics of fd coat protein in the bacteriophage

The dynamics of the coat protein in fd bacteriophage are described with solid-state 15N and 2H NMR experiments. The virus particles and the coat protein subunits are immobile on the time scales of the 15N chemical shift anisotropy (10(3) Hz) and 2H quadrupole (10(6) Hz) interactions. Previously we have shown that the Trp-26 side chain is immobile, that the two Tyr and three Phe side chains undergo only rapid twofold jump motions about their C beta-C gamma bond axis [Gall, C. M., Cross, T. A., DiVerdi, J. A., & Opella, S. J. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 101-105], and that most of the backbone peptide linkages are highly constrained but do undergo rapid small amplitude motions [Cross, T. A., & Opella, S. J. (1982) J. Mol. Biol. 159, 543-549] in the coat protein subunits in the virus particles. In this paper, we demonstrate that the four N-terminal residues of the coat protein subunits are highly mobile, since both backbone and side-chain sites of these residues undergo large amplitude motions that are rapid on the time scales of the solid-state NMR experiments. In addition, the dynamics of the methyl-containing aliphatic residues Ala, Leu, Val, Thr, and Met are analyzed. Large amplitude jump motions are observed in nearly all of these side chains even though, with the exception of the N-terminal residue Ala-1, their backbone peptide linkages are highly constrained. The established information about the dynamics of the structural form of fd coat protein in the virus particle is summarized qualitatively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Localization of a DNA-binding determinant in the bacteriophage P22 Erf protein

Four amber fragments of the recombination-promoting P22 Erf protein were characterized. The intact Erf monomer contains 204 amino acids. The amber mutations produce fragments of 190, 149, 130 and 95 amino acid residues, all of which are inactive in vivo. The 190 residue fragment is more susceptible to proteolysis in cell extracts than is intact Erf. It breaks down to a stable remnant that is slightly larger than the 149 residue fragment. The 149 and 130 residue fragments are stable; electron microscopy of the purified fragments reveals that they have similar morphologies, retaining the ring-like oligomeric structure, but lacking the tooth-like protruding portions of intact Erf. Intact Erf and the 149 residue fragment have similar affinities for single-stranded DNA; the affinity of the 130 residue fragment is 40-fold lower in low salt at pH 6.0. The 95 residue fragment is unstable in vivo. These observations, combined with previous observations, are interpreted as suggesting that the boundary of the amino-terminal domain of the protein lies between residues 96 and 130, that certain residues between 131 and 149 form part of an interdomain DNA-binding segment of the protein, that the boundary of the carboxy-terminal domain lies to the C-terminal side of residue 149, and that the carboxy-terminal domain is not necessary for assembly of the ring oligomer, although it is essential for Erf activity in vivo.