A P22 scaffold protein mutation increases the robustness of head assembly in the presence of excess portal protein

Bacteriophage with linear, double-stranded DNA genomes package DNA into preassembled protein shells called procapsids. Located at one vertex in the procapsid is a portal complex composed of a ring of 12 subunits of portal protein. The portal complex serves as a docking site for the DNA packaging enzymes, a conduit for the passage of DNA, and a binding site for the phage tail. An excess of the P22 portal protein alters the assembly pathway of the procapsid, giving rise to defective procapsid-like particles and aberrant heads. In the present study, we report the isolation of escape mutant phage that are able to replicate more efficiently than wild-type phage in the presence of excess portal protein. The escape mutations all mapped to the same phage genome segment spanning the portal, scaffold, coat, and open reading frame 69 genes. The mutations present in five of the escape mutants were determined by DNA sequencing. Interestingly, each mutant contained the same mutation in the scaffold gene, which changes the glycine at position 287 to glutamate. This mutation alone conferred an escape phenotype, and the heads assembled by phage harboring only this mutation had reduced levels of portal protein and exhibited increased head assembly fidelity in the presence of excess portal protein. Because this mutation resides in a region of scaffold protein necessary for coat protein binding, these findings suggest that the P22 scaffold protein may define the portal vertices in an indirect manner, possibly by regulating the fidelity of coat protein polymerization.     

Structural transformations accompanying the assembly of bacteriophage P22 portal protein rings in vitro

The Salmonella typhimurium bacteriophage P22 assembles an icosahedral capsid precursor called a procapsid. The oligomeric portal protein ring, located at one vertex, comprises the conduit for DNA entry and exit. In conjunction with the DNA packaging enzymes, the portal ring is an integral component of a nanoscale machine that pumps DNA into the phage head. Although the portal vertex is assembled with high fidelity, the mechanism by which a single portal complex is incorporated during procapsid assembly remains unknown. The assembly of bacteriophage P22 portal rings has been characterized in vitro using a recombinant, His-tagged protein. Although the portal protein remained primarily unassembled within the cell, once purified, the highly soluble monomer assembled into rings at room temperature at high concentrations with a half time of approximately 1 h. Circular dichroic analysis of the monomers and rings indicated that the protein gained alpha-helicity upon polymerization. Thermal denaturation studies suggested that the rings contained an ordered domain that was not present in the unassembled monomer. A combination of 4,4'-dianilino-1,1'-binapthyl-5,5'-disulfonic acid (bis-ANS) binding fluorescence studies and limited proteolysis revealed that the N-terminal portion of the unassembled subunit is meta-stable and is susceptible to structural perturbation by bis-ANS. In conjunction with previously obtained data on the behavior of the P22 portal protein, we propose an assembly model for P22 portal rings that involves a meta-stable monomeric subunit.     

A promiscuous DNA packaging machine from bacteriophage T4

Complex viruses are assembled from simple protein subunits by sequential and irreversible assembly. During genome packaging in bacteriophages, a powerful molecular motor assembles at the special portal vertex of an empty prohead to initiate packaging. The capsid expands after about 10%-25% of the genome is packaged. When the head is full, the motor cuts the concatemeric DNA and dissociates from the head. Conformational changes, particularly in the portal, are thought to drive these sequential transitions. We found that the phage T4 packaging machine is highly promiscuous, translocating DNA into finished phage heads as well as into proheads. Optical tweezers experiments show that single motors can force exogenous DNA into phage heads at the same rate as into proheads. Single molecule fluorescence measurements demonstrate that phage heads undergo repeated initiations, packaging multiple DNA molecules into the same head. These results suggest that the phage DNA packaging machine has unusual conformational plasticity, powering DNA into an apparently passive capsid receptacle, including the highly stable virus shell, until it is full. These features probably led to the evolution of viral genomes that fit capsid volume, a strikingly common phenomenon in double-stranded DNA viruses, and will potentially allow design of a novel class of nanocapsid delivery vehicles.     

Structure–Function Analysis of the DNA Translocating Portal of the Bacteriophage T4 Packaging Machine

Tailed bacteriophages and herpesviruses consist of a structurally well conserved dodecameric portal at a special 5-fold vertex of the capsid. The portal plays critical roles in head assembly, genome packaging, neck/tail attachment, and genome ejection. Although the structures of portals from phages φ29, SPP1, and P22 have been determined, their mechanistic roles have not been well understood. Structural analysis of phage T4 portal (gp20) has been hampered because of its unusual interaction with the Escherichia coli inner membrane. Here, we predict atomic models for the T4 portal monomer and dodecamer, and we fit the dodecamer into the cryo-electron microscopy density of the phage portal vertex. The core structure, like that from other phages, is cone shaped with the wider end containing the “wing” and “crown” domains inside the phage head. A long “stem” encloses a central channel, and a narrow “stalk” protrudes outside the capsid. A biochemical approach was developed to analyze portal function by incorporating plasmid-expressed portal protein into phage heads and determining the effect of mutations on head assembly, DNA translocation, and virion production. We found that the protruding loops of the stalk domain are involved in assembling the DNA packaging motor. A loop that connects the stalk to the channel might be required for communication between the motor and the portal. The “tunnel” loops that project into the channel are essential for sealing the packaged head. These studies established that the portal is required throughout the DNA packaging process, with different domains participating at different stages of genome packaging.     

Purification and organization of the gene 1 portal protein required for phage P22 DNA packaging

The gene 1 protein of Salmonella bacteriophage P22 is located at the DNA packaging vertex of the mature particle. The protein is incorporated into the procapsid shell during shell assembly and is required for DNA packaging. The unassembled precursor form of the gene 1 protein has been purified from cells infected with mutants blocked in procapsid assembly. The purified 90,000-dalton protein was dimeric or monomeric; upon storage in the cold it formed 20S cyclic dodecamers. Computer filtering of negatively stained electron micrographs revealed 12 arms and knobs projecting from a central ring, with a 30-A channel at the center. Similar dodecameric rings were released from disrupted procapsid shells. These results indicate that the gene 1 protein is organized as a cyclic dodecamer within the procapsid shell and serves as the portal through which P22 DNA is threaded during DNA packaging. The presence of a 12-fold ring located at a 5-fold portal vertex appears to be a conserved structural theme of the DNA packaging apparatus of double-stranded DNA phages.     

Involvement of the portal at an early step in herpes simplex virus capsid assembly

DNA enters the herpes simplex virus capsid by way of a ring-shaped structure called the portal. Each capsid contains a single portal, located at a unique capsid vertex, that is composed of 12 UL6 protein molecules. The position of the portal requires that capsid formation take place in such a way that a portal is incorporated into one of the 12 capsid vertices and excluded from all other locations, including the remaining 11 vertices. Since initiation or nucleation of capsid formation is a unique step in the overall assembly process, involvement of the portal in initiation has the potential to cause its incorporation into a unique vertex. In such a mode of assembly, the portal would need to be involved in initiation but not able to be inserted in subsequent assembly steps. We have used an in vitro capsid assembly system to test whether the portal is involved selectively in initiation. Portal incorporation was compared in capsids assembled from reactions in which (i) portals were present at the beginning of the assembly process and (ii) portals were added after assembly was under way. The results showed that portal-containing capsids were formed only if portals were present at the outset of assembly. A delay caused formation of capsids lacking portals. The findings indicate that if portals are present in reaction mixtures, a portal is incorporated during initiation or another early step in assembly. If no portals are present, assembly is initiated in another, possibly related, way that does not involve a portal.     

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.     

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.     

In vitro packaging of DNA of the Bacillus subtilis bacteriophage SPP1

In vitro packaging of bacteriophage SPP1 DNA into procapsids is described and the requirements of this process were determined. Combination of proheads with an extract supplying terminase, DNA and phage tails yielded up to 10(7 )viable phages per milliliter of in vitro reaction under optimized conditions. The presence of neutral polymers and polyamines had a concentration and type dependent effect in the packaging reaction. The terminase donor extract lost rapidly activity at 30 degrees C in contrast to the stability of the prohead donor extract. Maturation to infective virions was observed using both procapsids assembled in SPP1 infected cells and procapsid-like structures assembled in Escherichia coli that overexpressed the SPP1 prohead gene clusters. Neither a majority of aberrant capsid-related structures present in the latter material nor procapsids lacking the portal protein inhibited DNA packaging. Addition of purified portal protein reduced DNA packaging activity in vitro only at concentrations 20-fold higher than those found in the SPP1 infected cell. The SPP1 DNA packaged in vitro originated exclusively from the terminase donor extract. This packaging selectivity was not observed in vivo during mixed infections. The data are compatible with a model for processive headful DNA packaging in which terminase and DNA co-produced in the same cell are tightly associated and can effectively discriminate the portal vertex of DNA packaging-proficient proheads from aberrant structures, from portal-less procapsids, and from isolated portal protein.     

Role of gene 10 protein in the hierarchical assembly of the bacteriophage P22 portal vertex structure

The portal vertex structure of the phage P22 is a 2.8 MDa molecular machine that mediates attachment and injection of the viral genome into the host Salmonella enterica serovar Typhimurium. Five proteins form this molecular machine: the portal protein, gp1; the tail-spike, gp9; the tail-needle, gp26, and the tail accessory factors, gp4 and gp10. In order to understand the assembly of the portal vertex structure, we have isolated the gene encoding tail accessory factor gp10 and defined its structural composition and assembly within the portal vertex structure. In solution, monomeric gp10 is a beta-sheet-rich protein with a stable conformational structure, which spontaneously assembles into hexamers, likely via a dimeric intermediate. This oligomerization enhances the structural stability of the protein, which then becomes competent for assembly to a preformed portal protein:gp4 complex, and acts as a structural adaptor bridging the nascent phage tail to gp26 and gp9. Notably, in vitro purified tail accessory factors gp4, gp10, and gp26 do not significantly interact with each other in solution, but their assembly takes place efficiently when these factors are added sequentially onto an immobilized portal protein. This suggests that the assembly of the P22 tail is a highly sequential and cooperative process, likely mediated by structural rearrangements in the assembly components. The assembled portal vertex structure represents both a membrane-binding and penetrating device as well as a plug that retains the pressurized phage DNA inside the capsid.     

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.     

Portal fusion protein constraints on function in DNA packaging of bacteriophage T4

Architecturally conserved viral portal dodecamers are central to capsid assembly and DNA packaging. To examine bacteriophage T4 portal functions, we constructed, expressed and assembled portal gene 20 fusion proteins. C-terminally fused (gp20-GFP, gp20-HOC) and N-terminally fused (GFP-gp20 and HOC-gp20) portal fusion proteins assembled in vivo into active phage. Phage assembled C-terminal fusion proteins were inaccessible to trypsin whereas assembled N-terminal fusions were accessible to trypsin, consistent with locations inside and outside the capsid respectively. Both N- and C-terminal fusions required coassembly into portals with approximately 50% wild-type (WT) or near WT-sized 20am truncated portal proteins to yield active phage. Trypsin digestion of HOC-gp20 portal fusion phage showed comparable protection of the HOC and gp20 portions of the proteolysed HOC-gp20 fusion, suggesting both proteins occupy protected capsid positions, at both the portal and the proximal HOC capsid-binding sites. The external portal location of the HOC portion of the HOC-gp20 fusion phage was confirmed by anti-HOC immuno-gold labelling studies that showed a gold 'necklace' around the phage capsid portal. Analysis of HOC-gp20-containing proheads showed increased HOC protein protection from trypsin degradation only after prohead expansion, indicating incorporation of HOC-gp20 portal fusion protein to protective proximal HOC-binding sites following this maturation. These proheads also showed no DNA packaging defect in vitro as compared with WT. Retention of function of phage and prohead portals with bulky internal (C-terminal) and external (N-terminal) fusion protein extensions, particularly of apparently capsid tethered portals, challenges the portal rotation requirement of some hypothetical DNA packaging mechanisms.     

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.     

Integral membrane protein P16 of bacteriophage PRD1 stabilizes the adsorption vertex structure

The icosahedral membrane-containing double-stranded DNA bacteriophage PRD1 has a labile receptor binding spike complex at the vertices. This complex, which is analogous to that of adenovirus, is formed of the penton protein P31, the spike protein P5, and the receptor binding protein P2. Upon infection, the internal phage membrane transforms into a tubular structure that protrudes through a vertex and penetrates the cell envelope for DNA injection. We describe here a new class of PRD1 mutants lacking virion-associated integral membrane protein P16. P16 links the spike complex to the viral membrane and is necessary for spike stability. We also show that the unique vertex used for DNA packaging is intact in the P16-deficient particle, indicating that the 11 adsorption vertices and the 1 portal vertex are functionally and structurally distinct.     

The tailless icosahedral membrane virus PRD1 localizes the proteins involved in genome packaging and injection at a unique vertex

The double-stranded DNA (dsDNA) virus PRD1 carries its genome in a membrane surrounded by an icosahedral protein shell. The shell contains 240 copies of the trimeric P3 protein arranged with a pseudo T = 25 triangulation that is reminiscent of the mammalian adenovirus. DNA packaging and infection are believed to occur through the vertices of the particle. We have used immunolabeling to define the distribution of proteins on the virion surface. Antibodies to protein P3 labeled the entire surface of the virus. Most of the 12 vertices labeled with antibodies directed against proteins P5, P2, and P31. These proteins are known to function in virus binding to the cell surface. Proteins P6, P11, and P20 were found on a single vertex per virion. The P6 and P20 proteins are believed to function in DNA packaging. Protein P11 is a pilot protein that is involved in a complex that mediates the early stages of DNA entry to the host cell. Labeling with antibodies to P5 or P2 did not affect the labeling of P6, the unique vertex protein. Labeling with antibodies to the unique vertex protein P6 interfered with the labeling by antibodies to the unique vertex protein P20. We conclude that PRD1 utilizes 11 of its vertices for initial receptor binding. It utilizes a single, unique vertex for both DNA packing during assembly and DNA delivery during infection.     

Peering down the barrel of a bacteriophage portal: the genome packaging and release valve in p22

The encapsidated genome in all double-strand DNA bacteriophages is packaged to liquid crystalline density through a unique vertex in the procapsid assembly intermediate, which has a portal protein dodecamer in place of five coat protein subunits. The portal orchestrates DNA packaging and exit, through a series of varying interactions with the scaffolding, terminase, and closure proteins. Here, we report an asymmetric cryoEM reconstruction of the entire P22 virion at 7.8 ? resolution. X-ray crystal structure models of the full-length portal and of the portal lacking 123 residues at the C terminus in complex with gene product 4 (Δ123portal-gp4) obtained by Olia et?al. (2011) were fitted into this reconstruction. The interpreted density map revealed that the 150 ?, coiled-coil, barrel portion of the portal entraps the last DNA to be packaged and suggests a mechanism for head-full DNA signaling and transient stabilization of the genome during addition of closure proteins.     

Assembly and Maturation of the Bacteriophage Lambda Procapsid: gpC Is the Viral Protease

Viral capsids are robust structures designed to protect the genome from environmental insults and deliver it to the host cell. The developmental pathway for complex double-stranded DNA viruses is generally conserved in the prokaryotic and eukaryotic groups and includes a genome packaging step where viral DNA is inserted into a pre-formed procapsid shell. The procapsids self-assemble from monomeric precursors to afford a mature icosahedron that contains a single “portal” structure at a unique vertex; the portal serves as the hole through which DNA enters the procapsid during particle assembly and exits during infection. Bacteriophage λ has served as an ideal model system to study the development of the large double-stranded DNA viruses. Within this context, the λ procapsid assembly pathway has been reported to be uniquely complex involving protein cross-linking and proteolytic maturation events. In this work, we identify and characterize the protease responsible for λ procapsid maturation and present a structural model for a procapsid-bound protease dimer. The procapsid protease possesses autoproteolytic activity, it is required for degradation of the internal “scaffold” protein required for procapsid self-assembly, and it is responsible for proteolysis of the portal complex. Our data demonstrate that these proteolytic maturation events are not required for procapsid assembly or for DNA packaging into the structure, but that proteolysis is essential to late steps in particle assembly and/or in subsequent infection of a host cell. The data suggest that the λ-like proteases and the herpesvirus-like proteases define two distinct viral protease folds that exhibit little sequence or structural homology but that provide identical functions in virus development. The data further indicate that procapsid assembly and maturation are strongly conserved in the prokaryotic and eukaryotic virus groups.     

Herpes simplex virus tegument protein VP22 contains an internal VP16 interaction domain and a C-terminal domain that are both required for VP22 assembly into the virus particle

Many steps along the herpesvirus assembly and maturation pathway remain unclear. In particular, the acquisition of the virus tegument is a poorly understood process, and the molecular interactions involved in tegument assembly have not yet been defined. Previously we have shown that the two major herpes simplex virus tegument proteins VP22 and VP16 are able to interact, although the relevance of this to virus assembly is not clear. Here we have constructed a number of recombinant viruses expressing N- and C-terminal truncations of VP22 and have used them to identify regions of the protein involved in its assembly into the virus structure. Analysis of the packaging of these VP22 variants into extracellular virions revealed that the C terminus of VP22 is absolutely required for this process, with removal of the C-terminal 89 residues abrogating its incorporation. However, while these 89 residues alone were sufficient for specific incorporation of small amounts of VP22 into the tegument, efficient packaging of VP22 to the levels of full-length protein required an additional 52 residues of the protein. Coimmunoprecipitation assays indicated that these 52 residues also contained the interaction domain for VP16. Furthermore, analysis of the subcellular localization of the mutant forms of VP22 revealed that only those truncations that were efficiently assembled formed characteristic cytoplasmic trafficking complexes, suggesting that these complexes may represent the cellular location for VP22 assembly into the virus. Taken together, these results suggest that there are two determinants involved in the packaging of VP22-a C-terminal domain and an internal VP16 interaction domain, both of which are required for the efficient recruitment of VP22 to sites of virus assembly.     

A Structural Model of the Genome Packaging Process in a Membrane-Containing Double Stranded DNA Virus

Two crucial steps in the virus life cycle are genome encapsidation to form an infective virion and genome exit to infect the next host cell. In most icosahedral double-stranded (ds) DNA viruses, the viral genome enters and exits the capsid through a unique vertex. Internal membrane-containing viruses possess additional complexity as the genome must be translocated through the viral membrane bilayer. Here, we report the structure of the genome packaging complex with a membrane conduit essential for viral genome encapsidation in the tailless icosahedral membrane-containing bacteriophage PRD1. We utilize single particle electron cryo-microscopy (cryo-EM) and symmetry-free image reconstruction to determine structures of PRD1 virion, procapsid, and packaging deficient mutant particles. At the unique vertex of PRD1, the packaging complex replaces the regular 5-fold structure and crosses the lipid bilayer. These structures reveal that the packaging ATPase P9 and the packaging efficiency factor P6 form a dodecameric portal complex external to the membrane moiety, surrounded by ten major capsid protein P3 trimers. The viral transmembrane density at the special vertex is assigned to be a hexamer of heterodimer of proteins P20 and P22. The hexamer functions as a membrane conduit for the DNA and as a nucleating site for the unique vertex assembly. Our structures show a conformational alteration in the lipid membrane after the P9 and P6 are recruited to the virion. The P8-genome complex is then packaged into the procapsid through the unique vertex while the genome terminal protein P8 functions as a valve that closes the channel once the genome is inside. Comparing mature virion, procapsid, and mutant particle structures led us to propose an assembly pathway for the genome packaging apparatus in the PRD1 virion.     

The SPP1 connection

Abstract: The connector of the virulent Bacillus subtilis bacteriophage SPP1 (Styloviridae) is a structure localized at the phage head vertex which attaches the tail. It is formed by oligomerization of SPP1 gene product 6 (gp6; portal protein). The purified protein is found in solution essentially as a homo-tredecamer. Its assembly pattern resembles the turbine-like organization found for other portal proteins and has a defined handedness (Dube et al. (1993) EMBO J. 12, 1303–1309). A preliminary reconstruction of the structure shows that gp6 is composed of a lower ring connected by a narrow region to the upper area consisting of 13 lobes radiating from an inner ring. The assembly is organized around a central channel which spans its full height. A functional characterization of gp6 mutants showed that substitutions of defined amino acids by more basic residues lead to packaging of reduced amounts of DNA into the phage head (Tavares et al. (1992) J. Mol. Biol. 225, 81–92). Since SPP1 encapsidates its DNA by a headful mechanism, these mutations ( siz ) affect most probably a function on the headful sensor—signal transduction—headful cut system. Combination of siz alleles has severe effects in packaging. The resulting gp6 versions lead to the encapsidation of shorter DNA molecules at a lower efficiency than single siz mutants. Gene 6 is expressed late during SPP1 infection. Interestingly, the mass of portal protein inside the cell then increases continuously until lysis, reaching a level several fold higher than the amount required to accomplish its role as a structural component of the virion.