Mechanism of head assembly and DNA encapsulation in Salmonella phage P22. II. Morphogenetic pathway

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.

Three-dimensional structure of the bacteriophage P22 tail machine

The tail of the bacteriophage P22 is composed of multiple protein components and integrates various biological functions that are crucial to the assembly and infection of the phage. The three-dimensional structure of the P22 tail machine determined by electron cryo-microscopy and image reconstruction reveals how the five types of polypeptides present as 51 subunits are organized into this molecular machine through twelve-, six- and three-fold symmetry, and provides insights into molecular events during host cell attachment and phage DNA translocation.

A concerted mechanism for the suppression of a folding defect through interactions with chaperones

Specific amino acid substitutions confer a temperature-sensitive-folding (tsf) phenotype to bacteriophage P22 coat protein. Additional amino acid substitutions, called suppressor substitutions (su), relieve the tsf phenotype. These su substitutions are proposed to increase the efficiency of procapsid assembly, favoring correct folding over improper aggregation. Our recent studies indicate that the molecular chaperones GroEL/ES are more effectively recruited in vivo for the folding of tsf:su coat proteins than their tsf parents. Here, the tsf:su coat proteins are studied with in vitro equilibrium and kinetic techniques to establish a molecular basis for suppression. The tsf:su coat proteins were monomeric, as determined by velocity sedimentation analytical ultracentrifugation. The stability of the tsf:su coat proteins was ascertained by equilibrium urea titrations, which were best described by a three-state folding model, N <--> I <--> U. The tsf:su coat proteins either had stabilized native or intermediate states as compared with their tsf coat protein parents. The kinetics of the I <--> U transition showed a decrease in the rate of unfolding and a small increase in the rate of refolding, thereby increasing the population of the intermediate state. The increased intermediate population may be the reason the tsf:su coat proteins are aggregation-prone and likely enhances GroEL-ES interactions. The N --> I unfolding rate was slower for the tsf:su proteins than their tsf coat parents, resulting in an increase in the native state population, which may allow more competent interactions with scaffolding protein, an assembly chaperone. Thus, the suppressor substitution likely improves folding in vivo through increased efficiency of coat protein-chaperone interactions.

Folding of phage P22 coat protein monomers: kinetic and thermodynamic properties

To assemble into a virus with icosahedral symmetry, capsid proteins must be able to attain multiple conformations. Whether this conformational diversity is achieved during folding of the subunit, or subsequently during assembly, is not clear. Phage P22 coat protein offers an ideal model to investigate the folding of a monomeric capsid subunit since its folding is independent of assembly. Our early studies indicated that P22 coat protein monomers could be folded into an assembly-competent state in vitro, with evidence of a kinetic intermediate. Using urea denaturation, coat protein monomers are shown to be marginally stable. The reversible folding of coat protein follows a three-state model, N if I if U, with an intermediate exhibiting most of the tryptophan fluorescence of the folded state, but little secondary structure. Folding and unfolding kinetics monitored by circular dichroism, tryptophan fluorescence, and bisANS fluorescence indicate that several kinetic intermediates are populated sequentially through parallel channels en route to the native state. Additionally, two native states were identified, suggesting that the several conformers required to assemble an icosahedral capsid may be found in solution before assembly ensues.

Penton release from P22 heat-expanded capsids suggests importance of stabilizing penton-hexon interactions during capsid maturation

Bacteriophage assembly frequently begins with the formation of a precursor capsid that serves as a DNA packaging machine. The DNA packaging is accompanied by a morphogenesis of the small round precursor capsid into a large polyhedral DNA-containing mature phage. In vitro, this transformation can be induced by heat or chemical treatment of P22 procapsids. In this work, we examine bacteriophage P22 morphogenesis by comparing three-dimensional structures of capsids expanded both in vitro by heat treatment and in vivo by DNA packaging. The heat-expanded capsid reveals a structure that is virtually the same as the in vivo expanded capsid except that the pentons, normally present at the icosahedral fivefold positions, have been released. The similarities of these two capsid structures suggest that the mechanism of heat expansion is similar to in vivo expansion. The loss of the pentons further suggests the necessity of specific penton-hexon interactions during expansion. We propose a model whereby the penton-hexon interactions are stabilized through interactions of DNA, coat protein, and other minor proteins. When considered in the context of other studies using chemical or heat treatment of capsids, our study indicates that penton release may be a common trend among double-stranded DNA containing viruses.

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.

Bacteriophage p22 portal vertex formation in vivo

Bacteriophage with double-stranded, linear DNA genomes package DNA into pre-assembled icosahedral procapsids through a unique vertex. The packaging vertex contains an oligomeric ring of a portal protein that serves as a recognition site for the packaging enzymes, a conduit for DNA translocation, and the site of tail attachment. Previous studies have suggested that the portal protein of bacteriophage P22 is not essential for shell assembly; however, when assembled in the absence of functional portal protein, the assembled heads are not active in vitro packaging assays. In terms of head assembly, this raises an interesting question: how are portal vertices defined during morphogenesis if their incorporation is not a requirement for head assembly? To address this, the P22 portal gene was cloned into an inducible expression vector and transformed into the P22 host Salmonella typhimurium to allow control of the dosage of portal protein during infections. Using pulse-chase radiolabeling, it was determined that the portal protein is recruited into virion during head assembly. Surprisingly, over-expression of the portal protein during wild-type P22 infection caused a dramatic reduction in the yield of infectious virus. The cause of this reduction was traced to two potentially related phenomena. First, excess portal protein caused aberrant head assembly resulting in the formation of T=7 procapsid-like particles (PLPs) with twice the normal amount of portal protein. Second, maturation of the PLPs was blocked during DNA packaging resulting in the accumulation of empty PLPs within the host. In addition to PLPs with normal morphology, smaller heads (apparently T=4) and aberrant spirals were also produced. Interestingly, maturation of the small heads was relatively efficient resulting in the formation of small mature particles that were tailed and contained a head full of DNA. These data suggest that incorporation of portal vertices into heads occurs during growth of the coat lattice at decision points that dictate head assembly fidelity.

Structure of bacteriophage P22 portal protein in relation to assembly: investigation by Raman spectroscopy

Salmonella phage P22, which serves as an assembly paradigm for icosahedral double-stranded DNA viruses, packages its viral genome through a capsid channel (portal) comprising 12 copies of a 725-residue subunit. Secondary and tertiary structures of the portal subunit in monomeric and dodecameric states have been investigated by Raman spectroscopy using a His6-tagged recombinant protein that self-assembles in vitro [Moore, S. D., and Prevelige, P. E., Jr. (2001) J. Biol. Chem. 276, 6779-6788]. The portal protein exhibits Raman secondary structure markers typical of a highly alpha-helical subunit fold that is little perturbed by assembly. On the other hand, Raman markers of subunit side chains change dramatically with assembly, an indication of extensive changes in side chain environments. The cysteinyl Raman signature of the portal consists of a complex pattern of sulfhydryl stretching bands, revealing diverse hydrogen-bonding states for the four S-H groups per subunit (Cys 153, Cys 173, Cys 283, and Cys 516). Upon assembly, the population of strongly hydrogen-bonded S-H groups decreases, while the population of weakly hydrogen-bonded S-H groups increases, implying that specific intrasubunit S-H.X hydrogen bonds must be weakened to effect dodecamer assembly and that the molecular mechanism involves reorganization of subunit domains without appreciable changes in domain conformations. Comparison with other viral protein assemblies suggests an assembly process not requiring metastable intermediates. The recently published X-ray structure of the phi29 portal [Simpson, A. A., et al. (2000) Nature 408, 745-750] shows that residues 125-225 lining the channel surface form alpha-helical modules spaced by short beta-strands and turns; a surprisingly close secondary structure homology is predicted for residues 240-350 of the P22 portal, despite no apparent sequence homology. This motif is proposed as an evolutionarily conserved domain involved in DNA translocation.

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.

Role of the UL25 gene product in packaging DNA into the herpes simplex virus capsid: location of UL25 product in the capsid and demonstration that it binds DNA

Recent studies have suggested that the herpes simplex type 1 (HSV-1) UL25 gene product, a minor capsid protein, is required for encapsidation but not cleavage of replicated viral DNA. This study set out to investigate the potential interactions of UL25 protein with other virus proteins and determine what properties it has for playing a role in DNA encapsidation. The UL25 protein is found in 42 +/- 17 copies per B capsid and is present in both pentons and hexons. We introduced green fluorescent protein (GFP) as a fluorescent tag into the N terminus of UL25 protein to identify its location in HSV-1-infected cells and demonstrated the relocation of UL25 protein from the cytoplasm into the nucleus at the late stage of HSV-1 infection. To clarify the cause of this relocation, we analyzed the interactions of UL25 protein with other virus proteins. The UL25 protein associates with VP5 and VP19C of virus capsids, especially of the penton structures, and the association with VP19C causes its relocation into the nucleus. Gel mobility shift analysis shows that UL25 protein has the potential to bind DNA. Moreover, the amino-terminal one-third of the UL25 protein is particularly important in DNA binding and forms a homo-oligomer. In conclusion, the UL25 gene product forms a tight connection with the capsid being linked with VP5 and VP19C, and it may play a role in anchoring the genomic DNA.

Structure of the coat protein-binding domain of the scaffolding protein from a double-stranded DNA virus

Scaffolding proteins are required for high fidelity assembly of most high T number dsDNA viruses such as the large bacteriophages, and the herpesvirus family. They function by transiently binding and positioning the coat protein subunits during capsid assembly. In both bacteriophage P22 and the herpesviruses the extreme scaffold C terminus is highly charged, is predicted to be an amphipathic alpha-helix, and is sufficient to bind the coat protein, suggesting a common mode of action. NMR studies show that the coat protein-binding domain of P22 scaffolding protein exhibits a helix-loop-helix motif stabilized by a hydrophobic core. One face of the motif is characterized by a high density of positive charges that could interact with the coat protein through electrostatic interactions. Results from previous studies with a truncation fragment and the observed salt sensitivity of the assembly process are explained by the NMR structure.

Folding defects caused by single amino acid substitutions in a subunit are not alleviated by assembly

Significant stabilization of a protein often occurs when it is assembled into an oligomer. Bacteriophage P22 contains 420 monomers of coat protein that are stabilized by the assembly and maturation processes. The effects of eight single amino acid substitutions in coat protein that each cause a temperature-sensitive-folding defect were investigated to determine if the conformational differences previously observed in the monomers could be alleviated by assembly or maturation. Several techniques including differential scanning calorimetry, heat-induced expansion, urea denaturation, and sensitivity to protease digestion were used to explore the effects of the amino acid substitutions on the conformation of coat protein, once assembled. Each of the amino acid substitutions caused a change in the conformation as compared to wild-type coat protein, observed by at least one of the probes used. Thus, neither assembly nor expansion entirely corrected the conformational defects in the monomeric subunits of the folding mutants.

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.

GroEL and GroES control of substrate flux in the in vivo folding pathway of phage P22 coat protein

Our present understanding of the action of the chaperonins GroEL/S on protein folding is based primarily on in vitro studies, whereas the folding of proteins in the cellular milieu has not been as thoroughly investigated. We have developed a means of examining in vivo protein folding and assembly that utilizes the coat protein of bacteriophage P22, a naturally occurring substrate of GroEL/S. Here we show that amino acid substitutions in coat protein that cause a temperature-sensitive-folding (tsf) phenotype slowed assembly rates upon increasing the temperature of cell growth. Raising cellular concentrations of GroEL/S increased the rate of assembly of the tsf mutant coat proteins to nearly that of wild-type (WT) coat protein by protecting a thermolabile folding intermediate from aggregation, thereby increasing the concentration of assembly-competent coat protein. The rate of release of the tsf coat proteins from the GroEL/S-coat protein ternary complex was approximately 2-fold slower at non-permissive temperatures when compared with the release of WT coat protein. However, the rate of release of WT or tsf coat proteins at each temperature remained constant regardless of GroEL/S levels. Thus, raising the cellular concentration of GroEL/S increased the amount of assembly-competent tsf coat proteins not by altering the rates of folding but by increasing the probability of GroEL/S-coat protein complex formation.

Functional domains of bacteriophage P22 scaffolding protein

Assembly of the bacteriophage P22 requires a 303 amino acid residue scaffolding protein. Two scaffolding protein deletion mutants, consisting of residues 141 to 303 and 141 to 292, have been described. We report here that the 141-303 fragment, but not the 141-292 fragment, promoted procapsid assembly in vitro, bound to preformed shells of coat protein, and bound to a coat protein affinity column. These findings suggest that the carboxyl-terminal half of the scaffolding protein is sufficient for promoting assembly, and that the 11 amino acid residues at the extreme carboxyl terminus are required for binding to the coat protein. Analysis of the products of in vitro assembly reactions suggests that the maximum amount of scaffolding protein that can pack into a procapsid is dictated by the internal volume of the procapsid rather than by a finite number of binding sites. However, when the amount of scaffolding protein was reduced to limiting values, both the wild-type protein and the 141-303 fragment assembled procapsids with the same number, rather than the same mass, of scaffolding protein molecules. When the 141-292 fragment was added to a mixture of coat and scaffolding proteins, the initial phase of procapsid assembly was inhibited, but the final yield and composition of the procapsids were not affected. Assembly by a covalent dimeric mutant scaffolding protein (R74C/L177I) was not inhibited by the 141-292 fragment, which suggests that the inhibition is due to the formation of inactive heterodimers between the 141-292 fragment and the monomeric scaffolding protein. The 141-303 fragment, which has less tendency to self-associate than the wild-type protein, formed aberrant species as well as normal procapsid-like particles when the rate of assembly was high, suggesting that scaffolding protein dimerization may play a role in ensuring fidelity of assembly. Alternatively, residues 1 to 140 may play a direct structural role in preventing inappropriate scaffolding/coat protein interactions.

A helical coat protein recognition domain of the bacteriophage P22 scaffolding protein

The scaffolding protein of bacteriophage P22 directs the assembly of an icosahedral procapsid, a metastable shell that is the precursor for DNA packaging. The full-length protein has been shown previously to exist in a monomer-dimer-tetramer equilibrium of elongated and predominantly alpha-helical molecules. Two deletion-mutant fragments of the scaffolding protein, comprising amino acid residues 141 to 303 and 141 to 292, respectively, have been constructed, overexpressed in Escherichia coli, and purified. Removal of residues 1 to 140 yields a protein that is assembly-active both in vitro and in vivo, while the removal of the C-terminal 11 residues (293 to 303) leads to complete loss of scaffolding activity. Sedimentation analysis reveals that both scaffolding fragments exist in a monomer-dimer equilibrium governed by apparent dissociation constants Kd(141-303)=640 microM and Kd(141-292)=880 microM. Tetramer formation is not observed for either fragment; thus, the tetramerization domain of the scaffolding subunit resides in the N-terminal portion of the polypeptide chain. Examination of both fragments by circular dichroism, Raman and NMR spectroscopies indicates a highly alpha-helical fold in each case. Nonetheless, pronounced differences are observed between spectral signatures of the two fragments. Notably, Raman spectra of fragments 141-292 and 141-303 indicate that elimination of residues 293 to 303 results in unfolding of an alpha-helical coat protein "recognition" domain encompassing about 20 to 30 residues. The thermostability of fragment 141-303, monitored over a wide concentration range by circular dichroism and Raman spectroscopy, indicates a broad denaturation transition for the monomeric (low concentration) form, while more cooperative unfolding is observed for the dimeric (high concentration) form. A lesser increase in cooperativity upon dimerization is obtained for fragment 141-292. Additionally, the C-terminal recognition domain constitutes the most stable and cooperative unit in the 141-303 fragment. Measurement of hydrogen-isotope exchange kinetics in scaffolding fragments by time-resolved Raman spectroscopy shows that the C terminus is the only protected segment of the polypeptide chain. On the basis of the measured hydrodynamic and spectroscopic properties, a domain structure is proposed for the scaffolding subunit. The roles of these domains in P22 procapsid assembly are discussed.

Role of the scaffolding protein in P22 procapsid size determination suggested by T = 4 and T = 7 procapsid structures

Assembly of bacteriophage P22 procapsids requires the participation of approximately 300 molecules of scaffolding protein in addition to the 420 coat protein subunits. In the absence of the scaffolding, the P22 coat protein can assemble both wild-type-size and smaller size closed capsids. Both sizes of procapsid assembled in the absence of the scaffolding protein have been studied by electron cryomicroscopy. These structural studies show that the larger capsids have T = 7 icosahedral lattices and appear the same as wild-type procapsids. The smaller capsids possess T = 4 icosahedral symmetry. The two procapsids consist of very similar penton and hexon clusters, except for an increased curvature present in the T = 4 hexon. In particular, the pronounced skewing of the hexons is conserved in both sizes of capsid. The T = 7 procapsid has a local non-icosahedral twofold axis in the center of the hexon and thus contains four unique quasi-equivalent coat protein conformations that are the same as those in the T = 4 procapsid. Models of how the scaffolding protein may direct these four coat subunit types into a T = 7 rather than a T = 4 procapsid are presented.

Mechanisms of virus assembly probed by Raman spectroscopy: the icosahedral bacteriophage P22

A microdialysis flow cell has been developed for time-resolved Raman spectroscopy of biological macromolecules and their assemblies. The flow cell permits collection of Raman spectra concurrent with the efflux of small solute molecules into a solution of macromolecules and facilitates real-time spectroscopic detection of structural transitions induced by the effluent. Additionally, the flow cell is well suited to the investigation of hydrogen-isotope exchange phenomena that can be exploited as dynamic probes of viral protein folding and solvent accessibility along the assembly pathway. Here, we describe the application of the Raman dynamic probe to the maturation of the icosahedral capsid of bacteriophage P22, a double-stranded DNA virus. The P22 virion is constructed from a capsid precursor (procapsid) consisting of 420 coat subunits (gp5) in an outer shell and a few hundred scaffolding subunits (gp8) within. Capsid maturation involves expulsion of scaffolding subunits coupled with shell expansion at the time of DNA packaging. Raman static and dynamic probes reveal that the scaffolding subunit is highly alpha-helical and highly thermolabile, and lacks a typical hydrophobic core. When bound within the procapsid, the alpha-helical fold of gp8 is thermostabilized; however, this stabilization confers no apparent protection against peptide NH-->ND exchange. A molten globule model is proposed for the native scaffolding subunit that functions in procapsid assembly. Accompanying capsid expansion, a small conformational change (alpha-helix-->beta-strand) is also observed in the coat subunit. Domain movement mediated by hinge bending is proposed as the mechanism of capsid expansion. On the basis of these results, a molecular model is proposed for assembly of the P22 procapsid.

Cloning, purification, and preliminary characterization by circular dichroism and NMR of a carboxyl-terminal domain of the bacteriophage P22 scaffolding protein

Assembly of double-stranded DNA viruses and bacteriophages involves the polymerization of several hundred molecules of coat protein, directed by an internal scaffolding protein. A 163-amino acid carboxyl-terminal fragment of the 303-amino acid bacteriophage P22 scaffolding protein was cloned, overexpressed, and purified. This fragment is active in procapsid assembly reactions in vitro. The circular dichroism spectrum of the fragment, as well as the 1D-NMR and 15N-1H HSQC spectra of the uniformly-labeled protein, indicate that stable secondary structure elements are present. Determination of the three dimensional packing of these elements into the folded scaffolding protein fragment is underway. Structure-based drug design targeted at structural proteins required for viral assembly may have potential as a therapeutic strategy.

Head morphogenesis genes of the Bacillus subtilis bacteriophage SPP1

We have identified and characterized the phage cistrons required for assembly of SPP1 heads. A DNA fragment containing most of the head morphogenesis genes was cloned and sequenced. The 3'-end of a previously identified gene (gene 6) and eight complete open reading frames (7 to 15) were predicted. We have assigned genes 7, 8, 9, 11, 12, 13, 14 and 15 to these orfs by correlating genetic and immunological data with DNA and protein sequence information. G7P was identified as a minor structural component of proheads and heads, G11P as the scaffold protein, G12P and G15P as head minor proteins and G13P as the coat protein. Characterization of intermediates in head assembly, which accumulate during infection with mutants deficient in DNA packaging or in morphogenetic genes, allowed the definition of the head assembly pathway. No proteolytic processing of any of the head components was detected. Removal of G11P by mutation leads to the accumulation of prohead-related structures and aberrant particles which are similar to the assemblies formed by purified G13P in the absence of other phage-encoded proteins. The native molecular masses of G11P and G13P are about 350 kDa and larger than 5000 kDa, respectively (predicted molecular masses 23.4 kDa and 35.3 kDa, respectively). G13P, upon denaturation and renaturation, assembles from protomers into some prohead-related structures. The organization of the DNA packaging and head genes of SPP1 resembles the organization of genes in the analogous regions of phage lambda and P22.

Bacteriophage P22 scaffolding protein forms oligomers in solution

The scaffolding protein of Salmonella typhimurium bacteriophage P22 is a 33.6 kDa protein required both in vivo and in vitro for the polymerization of the viral coat protein into closed T = 7 icosahedral procapsids. In vitro assembly reaction kinetics have previously been found to vary between second and third order with respect to scaffolding protein concentration, suggesting that dimers and/or higher-order oligomers may be the active species in assembly. Analytical ultracentrifugation experiments suggest that scaffolding protein undergoes a rapidly-reversible monomer/dimer/tetramer equilibrium, with higher association constants at 4 degrees C than at 20 degrees C. Under conditions in which in vitro assembly reactions are carried out (30 to 1000 microg/ml scaffolding protein, 20 degrees C), monomers are the predominant species, but the concentration of dimers is significant. A mutant scaffolding protein, R74C/L177I, which forms disulfide-linked dimers, catalyzed procapsid assembly at a higher rate than did the wild-type scaffolding protein; preincubation in dithiothreitol had little effect on the wild-type protein, but greatly reduced the activity of the mutant. These findings suggest that dimers and/or higher-order oligomers of scaffolding protein are active species in the assembly of P22.

The folded conformation of phage P22 coat protein is affected by amino acid substitutions that lead to a cold-sensitive phenotype

Three cold-sensitive mutants in phage P22 coat protein have been characterized to determine the effects of the amino acid substitutions that cause cold sensitivity on the folding pathway and the conformation of refolded coat protein. Here we find that the three cold-sensitive mutants which have the threonine residue at position 10 changed to isoleucine (T10I), the arginine residue at position 101 changed to cysteine (R101C), or the asparagine residue at position 414 changed to serine (N414S) were capable of folding from a denatured state into a soluble monomeric species, but in each case, the folded conformation was altered. Changes in the kinetics of folding were observed by both tryptophan and bisANS fluorescence. In contrast to the temperature-sensitive for folding coat protein mutants which can be rescued at nonpermissive temperatures in vivo by the overproduction of molecular chaperones GroEL and GroES [Gordon, C. L., Sather, S. K., Casjens, S., & King, J. (1994) J. Biol. Chem. 269, 27941-27951], the folding defects associated with the cold-sensitive amino acid substitutions were not recognized by GroEL and GroES.

Prevalence of temperature sensitive folding mutations in the parallel beta coil domain of the phage P22 tailspike endorhamnosidase

Temperature sensitive mutations fall into two general classes: tl mutations, which render the mature protein thermolabile, and tsf (temperature sensitive folding) mutations, which destabilize an intermediate in the folding pathway without altering the functions of the folded state. The molecular defects caused by tsf mutations have been intensively studied for the elongated tailspike endorhamnosidase of Salmonella phage P22. The tailspike, responsible for host cell recognition and attachment, contains a 13 strand parallel beta coil domain. A set of tsf mutants located in the beta coil domain have been shown to cause folding defects in the in vivo folding pathway for the tailspike. We report here additional data on 17 other temperature sensitive mutants which are in the beta coil domain. Using mutant proteins formed at low temperature, the essential functions of assembling on the phage head, and binding to the O-antigen lipopolysaccharide (LPS) receptor of Salmonella were examined at high temperatures. All of the mutant proteins once folded at permissive temperature, were functional at restrictive temperatures. When synthesized at restrictive temperature the mutant chains formed an early folding intermediate, but failed to reach the mature conformation, accumulating instead in the aggregated inclusion body state. Thus this set of mutants all have the temperature sensitive folding phenotype. The prevalence of tsf mutants in the parallel beta coil domain presumably reflects properties of its folding intermediates. The key property may be the tendency of the intermediate to associate off pathway to the kinetically trapped inclusion body state.

Interactions between coat and scaffolding proteins of phage P22 are altered in vitro by amino acid substitutions in coat protein that cause a cold-sensitive phenotype

Cold-sensitive mutations in phage P22 coat protein cause the accumulation of precursor capsids in cells growing at the nonpermissive temperature (16 degrees C). The assembly of coat proteins which carry the substitutions threonine at position 10 to isoluecine (T10I), arginine at position 101 to cysteine (R101C), or asparagine at position 414 to serine (N414S) which cause cold-sensitivity has been investigated. All three proteins were found to fold into a monomeric species. Coat proteins carrying the amino acid substitutions T10I and R101C were not able to interact with scaffolding protein appropriately to initiate assembly in vitro while coat protein carrying the substitution N414S was able to assemble; however, capsids formed of this protein had an increased affinity for scaffolding protein. These amino acid substitutions define two regions in coat protein that are essential for the interaction of coat protein with scaffolding protein at different stages in capsid maturation.

Structural transitions in the scaffolding and coat proteins of P22 virus during assembly and disassembly

An in vitro system for investigating the assembly of the Salmonella phage P22 has been exploited to elucidate the structural basis of recognition between scaffolding protein (gp8) and coat protein (gp5) subunits of the viral procapsid. Raman spectroscopy and circular dichroism have been employed to examine structural thermostabilities of both gp8 and gp5 in native procapsids, and to characterize structural changes accompanying scaffolding exit, procapsid expansion, and shell disassembly. It is found that the secondary structure of the isolated gp8 subunit is rich in alpha-helix (approximately 40%), is highly thermolabile, and is characterized by noncooperative unfolding (Tm approximately 49 degrees C). Conversely, the procapsid-bound gp8 subunit exhibits stabilization of its alpha-helical secondary structure, characterized by cooperative unfolding. Because cooperative unfolding of gp8 coincides with exit from the procapsid, the present results suggest that unfolding and release are coupled processes. Structural differences between procapsid-free and procapsid-bound gp8 subunits are also apparent in Raman markers which monitor environments of tyrosine and tryptophan side chains. Temperature-resolved Raman spectroscopy of the empty procapsid shell reveals three distinct structural transitions for the gp5 subunits. The first, which occurs between 50 and 65 degrees C, is attributed to shell expansion and results in an increase in beta-strand secondary structure. The two higher temperature transitions, occurring within intervals of 70-80 and 80-95 degrees C, respectively, are attributed to partial unfolding of the shell subunit and subsequent shell disassembly. The same gp5 structure transitions are detected for procapsids which contain scaffolding protein. On the basis of the observed thermodynamic coupling between gp8 unfolding and its release from the procapsid, we propose a model for P22 procapsid assembly. Implications of the model for in vivo assembly of dsDNA viruses are discussed.

Rbl2p, a yeast protein that binds to beta-tubulin and participates in microtubule function in vivo

Genetic configurations resulting in high ratios of beta-tubulin to alpha-tubulin are toxic in S. cerevisiae, causing microtubule disassembly and cell death. We identified three non-tubulin yeast genes that, when overexpressed, rescue cells from excess beta-tubulin. One, RBL2, rescues beta-tubulin lethality as efficiently as does alpha-tubulin. Rbl2p binds to beta-tubulin in vivo. Deficiencies or excesses of either Rbl2p or alpha-tubulin affect microtubule-dependent functions in a parallel fashion. Rbl2p has functional homology with murine cofactor A, a protein important for in vitro assays of beta-tubulin folding. The results suggest that Rbl2p participates in microtubule morphogenesis but not in the assembled polymer.

Stability of wild-type and temperature-sensitive protein subunits of the phage P22 capsid

Temperature-sensitive folding (tsf) mutants of the phage P22 coat protein prevent newly synthesized polypeptide chains from reaching the conformation competent for capsid assembly in cells, and can be rescued by the GroEL chaperone (Gordon, C., Sather, S., Casjens, S., and King, J. (1994) J. Biol. Chem. 269, 27941-27951). Here we investigate the stabilities of wild-type and four tsf mutant unpolymerized subunits. Wild-type coat protein subunits denatured at 40 degrees C, with a calorimetric enthalpy of approximately 600 kJ/mol. Comparison with coat protein denaturation within the shell lattice (Tm = 87 degrees C, delta H approximately 1700 kJ/mol) (Galisteo, M.L., and King, J. (1993) Biophys. J. 65, 227-235) indicates that protein-protein interactions within the capsid provide enormous stabilization. The melting temperatures of the subunits carrying tsf substitutions were similar to wild-type. At low temperatures, the tsf mutants, but not the wild-type, formed non-covalent dimers, which were dissociated at temperatures above 30 degrees C. Spectroscopic and calorimetric studies indicated that the mutant proteins have reduced amounts of ordered structure at low temperature, as compared to the wild-type protein. Although complex, the in vitro phenotypes are consistent with the in vivo finding that the mutants are defective in folding, rather than subunit stability. These results suggest a role for incompletely folded subunits as precursors in viral capsid assembly, providing a mechanism of reaching multiple conformations in the polymerized form.

Electron microscopic studies on intracellular phage development--history and perspectives

This review is centered on the applications of thin sections to the study of intracellular precursors of bacteriophage heads. Results obtained with other preparation methods are included in so far as they are essential for the comprehension of the biological problems. This type of work was pioneered with phage T4, which contributed much to today's understanding of morphogenesis and form determination. The T4 story is rich in successes, but also in many fallacies. Due to its large size, T4 is obviously prone to preparation artefacts such as emptying, flattening and others. Many of these artefacts were first encountered in T4. Artefacts are mostly found in lysates, however, experience shows that they are not completely absent from thin sections. This can be explained by the fact that permeability changes induced by fixatives occur. The information gained from T4 was profitably used for the study of other phages. They are included in this review as far as electron microscopic studies played a major role in the elucidation of their morphogenetic pathways. Research on phage assembly pathways and form determination is a beautiful illustration for the power of the integrated approach which combines electron microscopy with biochemistry, genetics and biophysics. As a consequence, we did not restrict ourselves to the review of electron microscopic work but tried to integrate pertinent data which contribute to the understanding of the molecular mechanisms acting in determining the form of supramolecular structures.

The size and symmetry of B capsids of herpes simplex virus type 1 are determined by the gene products of the UL26 open reading frame

Herpes simplex virus type 1 (HSV-1) B capsids are composed of seven proteins, designated VP5, VP19C, 21, 22a, VP23, VP24, and VP26 in order of decreasing molecular weight. Three proteins (21, 22a, and VP24) are encoded by a single open reading frame (ORF), UL26, and include a protease whose structure and function have been studied extensively by other investigators. The protease encoded by this ORF generates VP24 (amino acids 1 to 247), a structural component of the capsid and mature virions, and 21 (residues 248 to 635). The protease also cleaves C-terminal residues 611 to 635 of 21 and 22a, during capsid maturation. Protease activity has been localized to the N-terminal 247 residues. Protein 22a and probably the less abundant protein 21 occupy the internal volume of capsids but are not present in virions; therefore, they may form a scaffold that is used for B capsid assembly. The objective of the present study was to isolate and characterize a mutant virus with a null mutation in UL26. Vero cells were transformed with plasmid DNA that encoded ORF UL25 through UL28 and screened for their ability to support the growth of a mutant virus with a null mutation in UL27 (K082). Four of five transformants that supported the growth of the UL27 mutant also supported the growth of a UL27-UL28 double mutant. One of these transformants (F3) was used to isolate a mutant with a null mutation in UL26. The UL26 null mutation was constructed by replacement of DNA sequences specifying codons 41 through 593 with a lacZ reporter cassette. Permissive cells were cotransfected with plasmid and wild-type virus DNA, and progeny viruses were screened for their ability to grow on F3 but not Vero cells. A virus with these growth characteristics, designated KUL26 delta Z, that did not express 21, 22a, or VP24 during infection of Vero cells was isolated. Radiolabeled nuclear lysates from infected nonpermissive cells were layered onto sucrose gradients and subjected to velocity sedimentation. A peak of radioactivity for KUL26 delta Z that sedimented more rapidly than B capsids from wild-type-infected cells was observed. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the gradient fractions showed that the peak fractions contained VP5, VP19C, VP23, and VP26. Analysis of sectioned cells and of the peak fractions of the gradients by electron microscopy revealed sheet and spiral structures that appear to be capsid shells.(ABSTRACT TRUNCATED AT 400 WORDS)

Conformational transformations in the protein lattice of phage P22 procapsids

During the packaging of double-stranded DNA by bacterial viruses, the precursor procapsid loses its internal core of scaffolding protein and undergoes a substantial expansion to form the mature virion. Here we show that upon heating, purified P22 procapsids release their scaffolding protein subunits, and the coat protein lattice expands in the absence of any other cellular or viral components. Following these processes by differential scanning calorimetry revealed four different transitions that correlated with structural transitions in the coat protein shells. Exit of scaffolding protein from the procapsid occurred reversibly and just above physiological temperature. Expansion of the procapsid lattice, which was exothermic, occurred after the release of scaffolding protein. Partial denaturation of coat subunits within the intact shell structure was detected prior to the major endothermic event. This major endotherm occurred above 80 degrees C and represents particle breakage and irreversible coat protein denaturation. The results indicate that the coat subunits are designed to form a metastable precursor lattice, which appears to be separated from the mature lattice by a kinetic barrier.

Subunit conformational changes accompanying bacteriophage P22 capsid maturation

In double-stranded DNA bacteriophages, packaging of dsDNA requires the transformation of a precursor procapsid into a mature viral capsid. Lattice expansion and release of scaffolding subunits accompanying DNA packaging. Three-dimensional structures of procapsid and mature phage lattices demonstrate that the capsid transformation involves substantial changes in subunit environment. Since this transformation occurs without subunit dissociation, it represents a transition between at least two stable subunit conformations. Using Raman spectroscopy, we have identified changes in coat protein secondary structure and side-chain environments which accompany the capsid transformation. The subunits of procapsid shells contain only 2.0 +/- 0.4% more alpha-helix and less beta-sheet than those of mature capsids; however, numerous side chains are substantially altered by the transformation, including tyrosines, tryptophans, phenylalanines, and aliphatics, which are widely distributed through the subunit sequence. We propose, therefore, that procapsid expansion is accomplished through the relative motion of coat subunit domains with little change in secondary structure. Such hinge-bending conformational transitions may couple ATP-dependent dsDNA condensation with shell expansion.

Molecular genetic analysis of bacteriophage P22 gene 3 product, a protein involved in the initiation of headful DNA packaging

Bacteriophage P22 DNA packaging events occur in processive series on concatemeric phage DNA molecules. At the point where such series initiate, the DNA is recognized at a site called pac, and most molecular left ends are generated within six short regions called end sites, which are present in a 120 base-pair region surrounding the pac site. The bacteriophage P22 genes 2 and 3 proteins are required for successful generation of these ends and DNA packaging during progeny virion assembly. Mutants lacking the 162-amino-acid gene 3 protein replicate DNA and assemble functional procapsids. In this report we describe the nucleotide changes and DNA packaging phenotypes of a number of missense mutations of gene 3, which give the phage a higher than normal frequency of generalized transduction. In cells infected by these mutants, more packaging events initiate on the host chromosome than in wild-type infections, so the mutations are thought to affect the specificity of packaging initiation. In addition to having this phenotype, these mutations affect the process of phage DNA packaging in detectable ways. They may: (1) alter the target site specificity for packaging; (2) make target site recognition more promiscuous; (3) affect end site utilization; (4) alter the pac site; and (5) cause apparent random DNA packaging series initiation on phage DNA.

Nucleotide sequence of the bacteriophage P22 genes required for DNA packaging

The mechanism of DNA packaging by dsDNA viruses is not well understood in any system. In bacteriophage P22 only five genes are required for successful condensation of DNA within the capsid. The products of three of these genes, the portal, scaffolding, and coat proteins, are structural components of the precursor particle, and two, the products of genes 2 and 3, are not. The scaffolding protein is lost from the structure during packaging, and only the portal and coat proteins are present in the mature virus particle. These five genes map in a contiguous cluster at the left end of the P22 genetic map. Three additional genes, 4, 10, and 26, are required for stabilizing of the condensed DNA within the capsid. In this report we present the nucleotide sequence of 7461 bp of P22 DNA that contains the five genes required for DNA condensation, as well as a nonessential open reading frame (ORF109), gene 4, and a portion of gene 10. N-terminal amino acid sequencing of the encoded proteins accurately located the translation starts of six genes in the sequence. Despite the fact that most of these proteins have striking analogs in the other dsDNA bacteriophage groups, which perform highly analogous functions, no amino acid sequence similarity between these analogous proteins has been found, indicating either that they diverged a very long time ago or that they are the products of spectacular convergent evolution.

A pilot protein participates in the initiation of P22 procapsid assembly

The gene 16 protein of the bacteriophage P22 is required as a pilot protein aiding the transfer of DNA from the phage into the Salmonella typhimurium host cell. During assembly 10-20 copies of the 63,000-Da gp 16 protein are incorporated into the procapsid shell prior to DNA packaging. The protein has been purified from isolated procapsids and behaved as a monomer in solution. Upon incubation with purified coat and scaffolding subunits in vitro, it assembled into procapsids with the correct stoichiometry. The addition of physiological quantities of gp 16 resulted in an increased rate of procapsid assembly. Sedimentation of mixtures of coat and gp 16 protein subunits revealed association/dissociation behavior. It is likely that the added gp 16 is acting to stabilize a transient oligomeric coat protein species that functions as the in vitro initiation complex for procapsid 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.

Organization and temporal expression of a flagellar basal body gene in Caulobacter crescentus

Caulobacter crescentus assembles a single polar flagellum at a defined time in the cell cycle. The protein components of the flagellar hook and filament are synthesized just prior to their assembly. We demonstrated that the expression of a gene, flaD, that is involved in the formation of the flagellar basal body is under temporal control and is transcribed relatively early in the cell cycle, before the hook and flagellin genes are transcribed. Thus, the order of flagellar gene transcription reflects the order of assembly of the protein components. A mutation in the flaD gene results in the assembly of a partial basal body which is missing the outermost P and L rings as well as the external hook and filament (K.M. Hahnenberger and L. Shapiro, J. Mol. Biol. 194:91-103, 1987). The flaD gene was cloned and characterized by nucleotide sequencing and S1 nuclease protection assays. In contrast to the protein components of the hook and filament, the protein encoded by the flaD gene contains a hydrophobic leader peptide. The predicted amino acid sequence of the leader peptide of flaD is very similar to the leader peptide of the flagellar basal body P ring of Salmonella typhimurium (M. Homma, Y. Komeda, T. Iino, and R.M. Macnab, J. Bacteriol. 169:1493-1498, 1987).

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.

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.

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.

Analysis in vivo of the bacteriophage P22 headful nuclease

Bacteriophage P22 packages its double-stranded DNA chromosomes from concatemeric replicating DNA in a processive, sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally (rightward) from that point. DNA ends are generated near the pac site before or during the condensation reaction. The right end of the mature chromosome is created by a cut made in the DNA by the "headful nuclease" after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here accurate measurements of the P22 chromosome length (43,400( +/- 750) base-pairs, where the uncertainty is the range in observed lengths), genome length (41,830( +/- 315) base-pairs, where the uncertainty represents the accuracy with which the length is known), the terminal redundancy (1600( +/- 750) base-pairs or 3.8( +/- 1.8)%, where the uncertainty is the observed range) and the imprecision in the headful measuring device ( +/- 750 base-pairs or +/- 1.7%). In addition, we present evidence for a weak nucleotide sequence specificity in the headful nuclease. These findings lend further support to, and extend our understanding of, the sequential series model of P22 DNA packaging.

A late gene product of phage P22 affecting virus infectivity

Gene 14 is a recently discovered late gene of phage P22, mapping between the DNA injection and head completion genes (P. Youderian and M. Susskind (1980), Virology 107, 258-269). The gene 14 product has not been detected in phage particles. We have studied the defective phenotype of amber mutants in gene 14 to determine the role of gp14. The yield of physical particles from 14- infections is normal, but the infectivity of those particles is reduced by 60-80%. The noninfectious particles adsorb to but do not kill the host cell, as if they were defective in DNA injection. No differences in morphology, DNA composition, DNA permutation, or protein composition have been detected between 14- and wild-type particles. Procapsids, the capsid precursor to DNA packaging, exhibit a similar reduction in viability when isolated from 14- infected cells, assayed by in vitro DNA packaging. This is consistent with the gene 14 product functioning in the assembly or maturation of the procapsid. The three DNA injection proteins, encoded by genes 7, 16, and 20, are assembled into the particle at the procapsid stage. The defect in 14- particles may arise from improper organization or modification of one or more of the three proteins needed for DNA injection.

Bacteriophage P22 tail protein gene expression

We have found that mutations which block bacteriophage P22 head assembly at or before the DNA packaging stage (1-, 2-, 3-, 5-, and 8-) cause up to a 20-fold increase in the amount of tail (gene 9) protein made during infection. This correlation seems strong enough to warrant consideration of a control mechanism in which the failure to package DNA per se causes a large increase in the synthesis of tail protein. Our results indicate that one of the repressors required for maintenance of lysogeny, the mnt gene product, may be partially responsible for this phenomenon.

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.