Identification of an interacting coat-external scaffolding protein domain required for both the initiation of phiX174 procapsid morphogenesis and the completion of DNA packaging

The phiX174 external scaffolding protein D mediates the assembly of coat protein pentamers into procapsids. There are four external scaffolding subunits per coat protein. Organized as pairs of asymmetric dimers, the arrangement is unrelated to quasi-equivalence. The external scaffolding protein contains seven alpha-helices. The protein's core, alpha-helices 2 to 6, mediates the vast majority of intra- and interdimer contacts and is strongly conserved in all Microviridae (canonical members are phiX174, G4, and alpha3) external scaffolding proteins. On the other hand, the primary sequences of the first alpha-helices have diverged. The results of previous studies with alpha3/phiX174 chimeric external scaffolding proteins suggest that alpha-helix 1 may act as a substrate specificity domain, mediating the initial coat scaffolding protein recognition in a species-specific manner. However, the low sequence conservation between the two phages impeded genetic analyses. In an effort to elucidate a more mechanistic model, chimeric external scaffolding proteins were constructed between the more closely related phages G4 and phiX174. The results of biochemical analyses indicate that the chimeric external scaffolding protein inhibits two morphogenetic steps: the initiation of procapsid formation and DNA packaging. phiX174 mutants that can efficiently utilize the chimeric protein were isolated and characterized. The substitutions appear to suppress both morphogenetic defects and are located in threefold-related coat protein sequences that most likely form the pores in the viral procapsid. These results identify coat-external scaffolding domains needed to initiate procapsid formation and provide more evidence, albeit indirect, that the pores are the site of DNA entry during the packaging reaction.     

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.     

In VITRO ASSEMBLY of the øX174 procapsid from external scaffolding protein oligomers and early pentameric assembly intermediates

Bacteriophage øX174 morphogenesis requires two scaffolding proteins: an internal species, similar to those employed in other viral systems, and an external species, which is more typically associated with satellite viruses. The current model of øX174 assembly is based on structural and in vivo data. During morphogenesis, 240 copies of the external scaffolding protein mediate the association of 12 pentameric particles into procapsids. The hypothesized pentameric intermediate, the 12S? particle, contains 16 proteins: 5 copies each of the coat, spike and internal scaffolding proteins and 1 copy of the DNA pilot protein. Assembly naïve 12S? particles and external scaffolding oligomers, most likely tetramers, formed procapsid-like particles in vitro, suggesting that the 12S? particle is a bona fide assembly intermediate and validating the current model of procapsid morphogenesis. The in vitro system required a crowding agent, was influenced by the ratio of the reactants and was most likely driven by hydrophobic forces. While the system reported here shared some characteristics with other in vitro internal scaffolding protein-mediated systems, it displayed unique features. These features most likely reflect external scaffolding protein-mediated morphogenesis and the øX174 procapsid structure, in which external scaffolding-scaffolding protein interactions, as opposed to coat-coat protein interactions between pentamers, constitute the primary lattice-forming contacts.     

Initiation of P22 procapsid assembly in vivo

The procapsids of all double-stranded DNA phages have a unique portal vertex, which is the locus of DNA packaging and DNA injection. Procapsid assembly is also initiated at this vertex, which is defined by the presence of a cyclic dodecamer of the portal protein. Assembly of the procapsid shell of phage P22 requires the gene 5 coat protein and the gene 8 scaffolding protein. We report here that removal of gene product (gp) 1 portal protein of P22 by mutation does not slow the rate of polymerization of coat and scaffolding subunits into shells, indicating that the portal ring is dispensable for shell initiation. Mutant scaffolding subunits specified by tsU172 copolymerize with coat subunits into procapsids at restrictive temperature, and also correctly autoregulate their synthesis. However, the shell structures formed from the temperature-sensitive scaffolding subunits fail to incorporate the portal ring and the three minor DNA injection proteins. This mutation identifies a domain of the scaffolding protein specifically involved in organization of the portal vertex. The results suggest that it is a complex of the scaffolding protein that initiates procapsid assembly and organizes the portal ring.     

Conformational switching by the scaffolding protein D directs the assembly of bacteriophage phiX174

The three-dimensional structure of bacteriophage phiX174 external scaffolding protein D, prior to its interaction with other structural proteins, has been determined to 3.3 angstroms by X-ray crystallography. The crystals belong to space group P4(1)2(1)2 with a dimer in the asymmetric unit that closely resembles asymmetric dimers observed in the phiX174 procapsid structure. Furthermore, application of the crystallographic 4(1) symmetry operation to one of these dimers generates a tetramer similar to the tetramer in the icosahedral asymmetric unit of the procapsid. These data suggest that both dimers and tetramers of the D protein are true morphogenetic intermediates and can form independently of other proteins involved in procapsid morphogenesis. The crystal structure of the D scaffolding protein thus represents the state of the polypeptide prior to procapsid assembly. Hence, comparison with the procapsid structure provides a rare opportunity to follow the conformational switching events necessary for the construction of complex macromolecular assemblies.     

Eliminating the requirement of an essential gene product in an already very small virus: scaffolding protein B-free øX174, B-free

Unlike most viral assembly systems, two scaffolding proteins, B and D, mediate bacteriophage ?X174 morphogenesis. The external scaffolding protein D is highly ordered in the atomic structure and proper function is very sensitive to mutation. In contrast, the internal scaffolding protein B is relatively unordered and extensive alterations do not eliminate function. Despite this genetic laxity, protein B is absolutely required for virus assembly. Thus, this system, with its complex arrangements of overlapping reading frames, can be regarded as an example of "irreducible complexity." To address the biochemical functions of a dual scaffolding protein system and the evolution of complexity, progressive and targeted genetic selections were employed to lessen and finally eliminate B protein-dependence. The biochemical and genetic bases of adaptation were characterized throughout the analysis that led to the sextuple mutant with a B-independent phenotype, as evaluated by plaque formation in wild-type cells. The primary adaptation appears to be the over-expression of a mutant external scaffolding protein. Progeny production was followed in lysis-resistant cells. The ability to produce infectious virions does not require all six mutations. However, the lag phase before progeny production is shortened as mutations accumulate. The results suggest that the primary function of the internal scaffolding protein may be to lower the critical concentration of the external scaffolding protein needed to nucleate procapsid formation. Moreover, they demonstrate a novel mechanism by which a stringently required gene product can be bypassed, even in a system encoding only eight strictly essential proteins.     

Structural studies of bacteriophage alpha3 assembly

Bacteriophage alpha3 is a member of the Microviridae, a family of small, single-stranded, icosahedral phages that include phiX174. These viruses have an ssDNA genome associated with approximately 12 copies of an H pilot protein and 60 copies of a small J DNA-binding protein. The surrounding capsid consists of 60 F coat proteins decorated with 12 pentameric spikes of G protein. Assembly proceeds via a 108S empty procapsid that requires the external D and internal B scaffolding proteins for its formation.The alpha3 "open" procapsid structural intermediate was determined to 15A resolution by cryo-electron microscopy (cryo-EM). Unlike the phiX174 "closed" procapsid and the infectious virion, the alpha3 open procapsid has 30A wide pores at the 3-fold vertices and 20A wide gaps between F pentamers as a result of the disordering of two helices in the F capsid protein. The large pores are probably used for DNA entry and internal scaffolding protein exit during DNA packaging. Portions of the B scaffolding protein are located at the 5-fold axes under the spike and in the hydrophobic pocket on the inner surface of the capsid. Protein B appears to have autoproteolytic activity that cleaves at an Arg-Phe motif and probably facilitates the removal of the protein through the 30A wide pores.The structure of the alpha3 mature virion was solved to 3.5A resolution by X-ray crystallography and was used to interpret the open procapsid cryo-EM structure. The main differences between the alpha3 and phiX174 virion structures are in the spike and the DNA-binding proteins. The alpha3 pentameric spikes have a rotation of 3.5 degrees compared to those of phiX174. The alpha3 DNA-binding protein, which is shorter by 13 amino acid residues at its amino end when compared to the phiX174 J protein, retains its carboxy-terminal-binding site on the internal surface of the capsid protein. The icosahedrally ordered structural component of the ssDNA appears to be substantially increased in alpha3 compared to phiX174, allowing the building of about 10% of the ribose-phosphate backbone.     

Scaffolding proteins altered in the ability to perform a conformational switch confer dominant lethal assembly defects

In the phiX174 procapsid crystal structure, 240 external scaffolding protein D subunits form 60 pairs of asymmetric dimers, D(1)D(2) and D(3)D(4), in a non-quasi-equivalent structure. To achieve this arrangement, alpha-helix 3 assumes two different conformations: (i) kinked 30 degrees at glycine residue 61 in subunits D(1) and D(3) and (ii) straight in subunits D(2) and D(4). Substitutions for G61 may inhibit viral assembly by preventing the protein from achieving its fully kinked conformation while still allowing it to interact with other scaffolding and structural proteins. Mutations designed to inhibit conformational switching in alpha-helix 3 were introduced into a cloned gene, and expression was demonstrated to inhibit wild-type morphogenesis. The severity of inhibition appears to be related to the size of the substituted amino acid. For infections in which only the mutant protein is present, morphogenesis does not proceed past the first step that requires the wild-type external scaffolding protein. Thus, mutant subunits alone appear to have little or no morphogenetic function. In contrast, assembly in the presence of wild-type and mutant subunits is blocked prematurely, before D protein is required in a wild-type infection, or channeled into an off-pathway reaction. These data suggest that the wild-type protein transports the inhibitory protein to the pathway. Viruses resistant to the lethal dominant proteins were isolated, and mutations were mapped to the coat and internal scaffolding proteins. The affected amino acids cluster in the atomic structure and may act to exclude mutant subunits from occupying particular positions atop pentamers of the viral coat protein.     

Shape and DNA packaging activity of bacteriophage SPP1 procapsid: protein components and interactions during assembly

The procapsid of the Bacillus subtilis bacteriophage SPP1 is formed by the major capsid protein gp13, the scaffolding protein gp11, the portal protein gp6, and the accessory protein gp7. The protein stoichiometry suggests a T=7 symmetry for the SPP1 procapsid. Overexpression of SPP1 procapsid proteins in Escherichia coli leads to formation of biologically active procapsids, procapsid-like, and aberrant structures. Co-production of gp11, gp13 and gp6 is essential for assembly of procapsids competent for DNA packaging in vitro. Presence of gp7 in the procapsid increases the yield of viable phages assembled during the reaction in vitro five- to tenfold. Formation of closed procapsid-like structures requires uniquely the presence of the major head protein and the scaffolding protein. The two proteins interact only when co-produced but not when mixed in vitro after separate synthesis. Gp11 controls the polymerization of gp13 into normal (T=7) and small sized (T=4?) procapsids. Predominant formation of T=7 procapsids requires presence of the portal protein. This implies that the portal protein has to be integrated at an initial stage of the capsid assembly process. Its presence, however, does not have a detectable effect on the rate of procapsid assembly during SPP1 infection. A stable interaction between gp6 and the two major procapsid proteins was only detected when the three proteins are co-produced. Efficient incorporation of a single portal protein in the procapsid appears to require a structural context created by gp11 and gp13 early during assembly, rather than strong interactions with any of those proteins. Gp7, which binds directly to gp6 both in vivo and in vitro, is not necessary for incorporation of the portal protein in the procapsid structure.     

The role of scaffolding proteins in the assembly of the small, single-stranded DNA virus phiX174.

An empty precursor particle called the procapsid is formed during assembly of the single-stranded DNA bacteriophage phiX174. Assembly of the phiX174 procapsid requires the presence of the two scaffolding proteins, D and B, which are structural components of the procapsid, but are not found in the mature virion. The X-ray crystallographic structure of a "closed" procapsid particle has been determined to 3.5 A resolution. This structure has an external scaffold made from 240 copies of protein D, 60 copies of the internally located B protein, and contains 60 copies of each of the viral structural proteins F and G, which comprise the shell and the 5-fold spikes, respectively. The F capsid protein has a similar conformation to that seen in the mature virion, and differs from the previously determined 25 A resolution electron microscopic reconstruction of the "open" procapsid, in which the F protein has a different conformation. The D scaffolding protein has a predominantly alpha-helical fold and displays remarkable conformational variability. We report here an improved and refined structure of the closed procapsid and describe in some detail the differences between the four independent D scaffolding proteins per icosahedral asymmetric unit, as well as their interaction with the F capsid protein. We re-analyze and correct the comparison of the closed procapsid with the previously determined cryo-electron microscopic image reconstruction of the open procapsid and discuss the major structural rearrangements that must occur during assembly. A model is proposed in which the D proteins direct the assembly process by sequential binding and conformational switching.     

Chlamydiaphage Chp2, a skeleton in the phiX174 closet: scaffolding protein and procapsid identification

Chlamydiaphage Chp2 is a member of the family Microviridae, of which bacteriophage phiX174 is the type species. Although grouped in the same family, the relationship between the Microviridae coliphages and the Chp2-like viruses, which infect obligate intracellular parasitic bacteria, is quite distant, with major differences in structural protein content and scaffolding protein dependence. To investigate the morphogenesis of Chp2, large particles were isolated from infected Chlamydophila abortus by equilibrium and rate zonal sedimentation. A monoclonal antibody that recognizes only assembled viral coat proteins was used in these detection assays. Thus, the detected particles represent virions and/or postcapsid formation assembly intermediates. Two distinct particle types were detected, differing in both protein and DNA content. Filled particles lacked VP3, the putative internal scaffolding protein, whereas empty particles contained this protein. These results indicate that VP3 is a scaffolding protein and that the isolated VP3-containing particles most likely represent Chp2 procapsids.     

Mechanism of scaffolding-directed virus assembly suggested by comparison of scaffolding-containing and scaffolding-lacking P22 procapsids.

Assembly of certain classes of bacterial and animal viruses requires the transient presence of molecules known as scaffolding proteins, which are essential for the assembly of the precursor procapsid. To assemble a procapsid of the proper size, each viral coat subunit must adopt the correct quasiequivalent conformation from several possible choices, depending upon the T number of the capsid. In the absence of scaffolding protein, the viral coat proteins form aberrantly shaped and incorrectly sized capsids that cannot package DNA. Although scaffolding proteins do not form icosahedral cores within procapsids, an icosahedrally ordered coat/scaffolding interaction could explain how scaffolding can cause conformational differences between coat subunits. To identify the interaction sites of scaffolding protein with the bacteriophage P22 coat protein lattice, we have determined electron cryomicroscopy structures of scaffolding-containing and scaffolding-lacking procapsids. The resulting difference maps suggest specific interactions of scaffolding protein with only four of the seven quasiequivalent coat protein conformations in the T = 7 P22 procapsid lattice, supporting the idea that the conformational switching of a coat subunit is regulated by the type of interactions it undergoes with the scaffolding protein. Based on these results, we propose a model for P22 procapsid assembly that involves alternating steps in which first coat, then scaffolding subunits form self-interactions that promote the addition of the other protein. Together, the coat and scaffolding provide overlapping sets of binding interactions that drive the formation of the procapsid.     

Conformational Switch-Defective X174 Internal Scaffolding Proteins Kinetically Trap Assembly Intermediates before Procapsid Formation

Conformational switching is an overarching paradigm in which to describe scaffolding protein-mediated virus assembly. However, rapid morphogenesis with small assembly subunits hinders the isolation of early morphogenetic intermediates in most model systems. Consequently, conformational switches are often defined by comparing the structures of virions, procapsids and aberrantly assembled particles. In contrast, X174 morphogenesis proceeds through at least three preprocapsid intermediates, which can be biochemically isolated. This affords a detailed analysis of early morphogenesis and internal scaffolding protein function. Amino acid substitutions were generated for the six C-terminal, aromatic amino acids that mediate most coat-internal scaffolding protein contacts. The biochemical characterization of mutant assembly pathways revealed two classes of molecular defects, protein binding and conformational switching, a novel phenotype. The conformational switch mutations kinetically trapped assembly intermediates before procapsid formation. Although mutations trapped different particles, they shared common second-site suppressors located in the viral coat protein. This suggests a fluid assembly pathway, one in which the scaffolding protein induces a single, coat protein conformational switch and not a series of sequential reactions. In this model, an incomplete or improper switch would kinetically trap intermediates.     

Effects of an Early Conformational Switch Defect during ?X174 Morphogenesis Are Belatedly Manifested Late in the Assembly Pathway

C-terminal, aromatic amino acids in the ϕX174 internal scaffolding protein B mediate conformational switches in the viral coat protein. These switches direct the coat protein through early assembly. In addition to the aromatic amino acids, two acidic residues, D111 and E113, form salt bridges with basic, coat protein side chains. Although salt bridge formation did not appear to be critical for assembly, the substitution of an aromatic amino acid for D111 produced a lethal phenotype. This side chain is uniquely oriented toward the center of the coat-scaffolding binding pocket, which is heavily dominated by aromatic ring-ring interactions. Thus, the D111Y substitution may restructure pocket contacts. Previously characterized B⁻ mutants blocked assembly before procapsid formation. However, the D111Y mutant produced an assembled particle, which contained the structural and external scaffolding proteins but lacked protein B and DNA. A suppressor within the external scaffolding protein, which mediates the later stages of particle morphogenesis, restored viability. The unique formation of a postprocapsid particle and the novel suppressor may be indicative of a novel B protein function. However, genetic data suggest that the particle represents the delayed manifestation of an early assembly error. This seemingly late-acting defect was rescued by previously characterized suppressors of early, preprocapsid, B⁻ assembly mutations, which act on the level of coat protein flexibility. Likewise, the newly isolated suppressor in the external scaffolding protein also exhibited a global suppressing phenotype. Thus, the off-pathway product isolated from infected cells may not accurately reflect the temporal nature of the initial defect.     

Detection of intermediates and kinetic control during assembly of bacteriophage P22 procapsid

Bacteriophage P22 serves as a model for the assembly and maturation of other icosahedral double-stranded DNA viruses. P22 coat and scaffolding proteins assemble in vitro into an icosahedral procapsid, which then expands during DNA packaging (maturation). Efficient in vitro assembly makes this system suitable for design and production of monodisperse spherical nanoparticles (diameter ≈ 50 nm). In this work, we explore the possibility of controlling the outcome of assembly by scaffolding protein engineering. The scaffolding protein exists in monomer-dimer-tetramer equilibrium. We address the role of monomers and dimers in assembly by using three different scaffolding proteins with altered monomer-dimer equilibrium (weak dimer, covalent dimer, monomer). The progress and outcome of assembly was monitored by time-resolved X-ray scattering, which allowed us to distinguish between closed shells and incomplete assembly intermediates. Binding of scaffolding monomer activates the coat protein for assembly. Excess dimeric scaffolding protein resulted in rapid nucleation and kinetic trapping yielding incomplete shells. Addition of monomeric wild-type scaffold with excess coat protein completed these metastable shells. Thus, the monomeric scaffolding protein plays an essential role in the elongation phase by activating the coat and effectively lowering its critical concentration for assembly.     

Novel second-site suppression of a cold-sensitive defect in phage P22 procapsid assembly

The DNA packaging portal of the phage P22 procapsid is formed of 12 molecules of the 90,000 dalton gene 1 protein. The assembly of this dodecameric complex at a unique capsid vertex requires scaffolding subunits. The mechanism that ensures the location of the 12-fold symmetrical portal at only one of the 12 5-fold vertices of an icosahedral virus capsid presents a unique assembly problem, which, in some viruses, is solved by the portal also acting as initiator of procapsid assembly. Phage P22 procapsids, however, are formed in the absence of the portal protein. The 1-csH137 mutation prevents the incorporation of the portal protein into procapsids. In a mixed infection with cs+ phage, the mutant subunits are able to form functional portals, suggesting that the cold-sensitivity does not affect portal-portal interactions, but affects the interaction of portal subunits with some other molecular species involved in the initiation of portal assembly. Interestingly, the cs defect is suppressed by temperature-sensitive folding mutations at four sites in the P22 tailspike gene 9. The suppression is allele-specific; other tailspike tsf mutations fail to suppress the cs defect. Translation through a suppressor site is required for suppression. This observation is unexpected, since analysis of nonsense mutations in this gene indicates that it is not required for procapsid assembly. Examination of the nucleic acid sequences in the neighborhood of each of the suppressor sites shows significant sequence similarity with the scaffolding gene translational initiation region on the late message. This supports a previously proposed model, in which procapsid assembly is normally initiated in a region on the late messenger RNA that includes the gene 8 start site. By this model, the suppressor mutations may be acting through protein-RNA interactions, changing sequences that identify alternative or competing sites at which the mutant portal subunits may be organized for assembly into the differentiated vertex of the phage capsid.     

Control of the synthesis of phage p22 scaffolding protein is coupled to capsid assembly

The assembly of the precursor shells of bacteriophage P22 entails the co-polymerization of gene 5 coat protein with gene 8 scaffolding protein into double shell structures. During DNA encapsidation, the inner shell of scaffolding molecules dissociates and exits from the prohead. These molecules then recycle, catalyzing the assembly of newly synthesized coat protein to form new proheads (King and Casjens, 1974).Although gene 5 and gene 8 are adjacent on the phage chromosome, we find that the synthesis of the two proteins is differentially regulated. In productively infected cells, scaffolding protein is synthesized at a low rate relative to the coat protein. In contrast, cells that are infected with mutants blocked in DNA packaging and accumulate precursor shells synthesize scaffolding protein at a much higher rate. If a mutation is introduced into the coat protein gene, however, preventing shell assembly, the rate of scaffolding protein synthesis decreases to less than the wild-type rate.The experiments are consistent with models in which either continued synthesis of scaffolding protein depends upon co-polymerization with coat subunits, or soluble scaffolding subunits (but not assembled subunits) depress their own further synthesis. The finding that amber fragments of the scaffolding protein are synthesized at a very low rate is inconsistent with the second model. There is evidence, however, that fragments of the protein may have regulatory activity.The regulatory circuit couples scaffolding protein synthesis to morphogenesis. Gene dosage experiments show that regulation results in the maintenance of coat and scaffolding subunits in the proper ratio for shell assembly.     

In vitro assembly of the herpes simplex virus procapsid: formation of small procapsids at reduced scaffolding protein concentration

The herpes simplex virus 1 capsid is formed in the infected cell nucleus by way of a spherical, less robust intermediate called the procapsid. Procapsid assembly requires the capsid shell proteins (VP5, VP19C, and VP23) plus the scaffolding protein, pre-VP22a, a major component of the procapsid that is not present in the mature virion. Pre-VP22a is lost as DNA is packaged and the procapsid is transformed into the mature, icosahedral capsid. We have employed a cell-free assembly system to examine the role of the scaffolding protein in procapsid formation. While other reaction components (VP5, VP19C, and VP23) were held constant, the pre-VP22a concentration was varied, and the resulting procapsids were analyzed by electron microscopy and SDS-polyacrylamide gel electrophoresis. The results demonstrated that while standard-sized (T = 16) procapsids with a measured diameter of approximately 100 nm were formed above a threshold pre-VP22a concentration, at lower concentrations procapsids were smaller. The measured diameter was approximately 78 nm and the predicted triangulation number was 9. No procapsids larger than the standard size or smaller than 78-nm procapsids were observed in appreciable numbers at any pre-VP22a concentration tested. SDS-polyacrylamide gel analyses indicated that small procapsids contained a reduced amount of scaffolding protein compared to the standard 100-nm form. The observations indicate that the scaffolding protein concentration affects the structure of nascent procapsids with a minimum amount required for assembly of procapsids with the standard radius of curvature and scaffolding protein content.     

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.