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

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

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

We have identified and characterized structural intermediates in phage P22 assembly. Three classes of particles can be isolated from P22-infected cells: 500 S full heads or phage, 170 S empty heads, and 240 S “proheads”. One or more of these classes are missing from cells infected with mutants defective in the genes for phage head assembly. By determining the protein composition of all classes of particles from wild type and mutant-infected cells, and examining the time-course of particle assembly, we have been able to define many steps in the pathway of P22 morphogenesis.In pulse-chase experiments, the earliest structural intermediate we find is a 240 S prohead; it contains two major protein species, the products of genes 5 and 8. Gene 5 protein (p5) is the major phage coat protein. Gene 8 protein is not found in mature phage. The proheads contain, in addition, four minor protein species, PI, P16, P20 and PX. Similar prohead structures accumulate in lysates made with mutants of three genes, 1, 2 and 3, which accumulate uncut DNA. The second intermediate, which we identify indirectly, is a newly filled (with DNA) head that breaks down on isolation to 170 S empty heads. This form contains no P8, but does contain five of the six protein species of complete heads. Such structures accumulate in lysates made with mutants of two genes, 10 and 26.Experiments with a temperature-sensitive mutant in gene 3 show that proheads from such 3^? infected cells are convertible to mature phage in vivo, with concomitant loss of P8. The molecules of P8 are not cleaved during this process and the data suggest that they may be re-used to form further proheads.Detailed examination of 8^? lysates revealed aberrant aggregates of P5. Since P8 is required for phage morphogenesis, but is removed from proheads during DNA encapsulation, we have termed it a scaffolding protein, though it may have DNA encapsulation functions as well.All the experimental observations of this and the accompanying paper can be accounted for by an assembly pathway, in which the scaffolding protein P8 complexes with the major coat protein P5 to form a properly dimensioned prohead. With the function of the products of genes 1, 2 and 3, the prohead encapsulates and cuts a headful of DNA from the concatemer. Coupled with this process is the exit of the P8 molecules, which may then recycle to form further proheads. The newly filled heads are then stabilized by the action of P26 and gene 10 product to give complete phage heads.     

Assembly of the head of bacteriophage P22: X-ray diffraction from heads,proheads and related structures

We have used electron microscopy and small-angle X-ray diffraction to study the three principal structures found in the head assembly pathway of Salmonella phage P22. These structures are, in order of their appearance in the pathway: proheads, unstable filled heads (which lose their DNA and become empty heads upon isolation), and phage. In addition, we can convert proheads to an empty head-like form (the empty prohead) in vitro by treating them with 0.8% sodium dodecyl sulfate at room temperature.We have shown that proheads are composed of a shell of coat protein with a radius of 256 Å, containing within it a thick shell or a solid ball (outer radius 215 Å) of a second protein, the scaffolding protein, which does not appear in phage. The three other structures studied are all about 10% larger than proheads, having outer shells with radii of about 285 Å. Empty heads and empty proheads appear identical by small-angle X-ray diffraction to a resolution of 25 Å, both being shells about 40 Å thick. Phage appear to be made up of a protein shell identical to that in empty heads and empty proheads, within which is packed the DNA.Some details of the DNA packing are also revealed by the diffraction pattern of phage. The inter-helix distance is about 28 Å, and the hydration is about 1.5 g of water per g of DNA. Certain aspects of the pattern suggest that the DNA interacts in a specific mariner with the coat protein subunits on the inside edge of the protein shell.Thus, the prohead-to-head transformation involves, in addition to the loss of an internal scaffold and its replacement by DNA, a structural transition in the outer shell. Diffraction from features of the surface organization in these structures indicates that the clustering of the coat protein does not change radically during the expansion. The fact that the expansion occurs in vitro during the formation of empty proheads shows that it is due to the bonding properties of the coat protein alone, although it could be triggered in vivo by DNA -protein interactions. The significance of the structural transition is discussed in terms of its possible role in the control of head assembly and DNA packaging.     

Structural studies of bacteriophage lambda heads and proheads by small angle X-ray diffraction.

We have examined a series of lambda proheads and mature structures by small angle X-ray diffraction. This technique yields spherically averaged density distributions and some information about surface organization of particles in solution.We find that gpE ² of proheads and heads forms shells with one of two radii; A^?, B^?, groE^?, and Nu3^? proheads have shells of radius 246 Å, while mature heads, urea-treated A^? proheads and C^? proheads have a radius of 300 Å. The expansion of proheads to mature heads is accompanied by a corresponding decrease in the thickness of the shell. groE^? proheads contain a core. This core is lost spontaneously from the structure and is only observed if the structures are fixed with glutaraldehyde prior to examination by X-ray diffraction or electron microscopy.C^? proheads expand to mature head size spontaneously. A preparation of C^? proheads which was fixed with glutaraldehyde at an early stage of the purification had the smaller, prohead radius. Unfixed particles from this preparation expanded to the mature head size after further purification and standing in the cold for several days. This result suggests that gpC may be involved in regulating head expansion.The radii of the protein shells of mature heads are identical for a series of phages that contain between 78% and 105% of the wild-type complement of DNA, and this radius is the same as that of proheads expanded in the absence of DNA. These results with phage lambda indicate that assembly of a double shell structure composed of coat and scaffolding protein, followed by expansion to a larger shell containing only coat protein is a general feature of the morphogenesis of dsDNA phages.     

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

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

Maturation of phage T7 involves structural modification of both shell and inner core components

The double-stranded DNA bacteriophages are good model systems to understand basic biological processes such as the macromolecular interactions that take place during the virus assembly and maturation, or the behavior of molecular motors that function during the DNA packaging process. Using cryoelectron microscopy and single-particle methodology, we have determined the structures of two phage T7 assemblies produced during its morphogenetic process, the DNA-free prohead and the mature virion. The first structure reveals a complex assembly in the interior of the capsid, which involves the scaffolding, and the core complex, which plays an important role in DNA packaging and is located in one of the phage vertices. The reconstruction of the mature virion reveals important changes in the shell, now much larger and thinner, the disappearance of the scaffolding structure, and important rearrangements of the core complex, which now protrudes the shell and interacts with the tail. Some of these changes must originate by the pressure exerted by the DNA in the interior of the head.     

Initial cos cleavage of bacteriophage lambda concatemers requires proheads and gpFI in vivo

The development of bacteriophage lambda and double-stranded DNA viruses in general involves the convergence of two separate pathways: DNA replication and head assembly. Clearly, packaging will proceed only if an empty capsid shell, the prohead, is present to receive the DNA, but genetic evidence suggests that proheads play another role in the packaging process. For example, lambda phages with an amber mutation in any head gene or in FI, the gene encoding the accessory packaging protein gpFI, are able to produce normal amounts of DNA concatemers but they are not cut, or matured, into unit length chromosomes for packaging. Similar observations have been made for herpes simplex 1 virus. In the case of lambda, a negative model proposes that in the amber phages, unassembled capsid components are inhibitory to maturation, and a positive model suggests that assembled proheads are required for cutting. We tested the negative model by using a deletion mutant devoid of all prohead genes and FI in an in vivo cos cleavage assay; in this deleted phage, the cohesive ends were not cut. When lambda proheads and gpFI were provided in vivo via a second prophage, cutting was restored, and gpFI was required, results that support the positive model. Phage 21 is a sister phage of lambda, and although its capsid proteins share approximately 60% residue identity with lambda's, phage 21 proheads did not restore cutting, even when provided with the accessory protein gpFI. Models for the role of proheads and gpFI in cos cutting are discussed.     

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.     

The DNA translocating ATPase of bacteriophage T4 packaging motor

In double-stranded DNA bacteriophages the viral DNA is translocated into an empty prohead shell by a powerful ATP-driven motor assembled at the unique portal vertex. Terminases consisting of two to three packaging-related ATPase sites are central to the packaging mechanism. But the nature of the key translocating ATPase, stoichiometry of packaging motor, and basic mechanism of DNA encapsidation are poorly understood. A defined phage T4 packaging system consisting of only two components, proheads and large terminase protein (gp17; 70 kDa), is constructed. Using the large expanded prohead, this system packages any linear double-stranded DNA, including the 171 kb T4 DNA. The small terminase protein, gp16 (18 kDa), is not only not required but also strongly inhibitory. An ATPase activity is stimulated when proheads, gp17, and DNA are actively engaged in the DNA packaging mode. No packaging ATPase was stimulated by the N-terminal gp17-ATPase mutants, K166G (Walker A), D255E (Walker B), E256Q (catalytic carboxylate), D255E-E256D and D255E-E256Q (Walker B and catalytic carboxylate), nor could these sponsor DNA encapsidation. Experiments with the two gp17 domains, N-terminal ATPase domain and C-terminal nuclease domain, suggest that terminase association with the prohead portal and communication between the domains are essential for ATPase stimulation. These data for the first time established an energetic linkage between packaging stimulation of N-terminal ATPase and DNA translocation. A core pathway for the assembly of functional DNA translocating motor is proposed. Since the catalytic motifs of the N-terminal ATPase are highly conserved among >200 large terminase sequences analyzed, these may represent common themes in phage and herpes viral DNA translocation.     

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.     

Amber mutants in gene 67 of phage T4. Effects on formation and shape determination of the head

Two amber mutations in gene 67 of bacteriophage T4 were constructed by oligonucleotide-directed mutagenesis and the resulting mutated genes were recombined back into the phage genome and their phenotype was studied. The 67amK1 mutation is close to the amino terminus of the gene, and phage carrying this mutation are unable to form plaques on suppressor-negative hosts. A second mutation, 67amK2, which lies in the middle of the gene, three codons N-terminal to a proteolytic cleavage site, produces a small number of viable phage particles. In suppressor-negative hosts, both mutants produce polyheads and proheads. 67amK1 assembles only few proheads that have a disorganized core structure, as judged from thin sections of infected cells. The proheads and the mature phages of both mutants are mainly isometric rather than having the usual prolate shape. Depending on the 67 mutant and the host, between 20% and 73% of the particles that are produced are isometric, and 1 to 10% are two-tailed biprolate particles. 67amK2 phages grown on a supD suppressor strain that inserts serine in place of the wild-type leucine do not contain gp67* derived from gene product 67 (gp67) by proteolytic cleavage. This demonstrates the importance of the correct amino acid at this position in the protein. Other abnormalities in these 67amK2 phages are the presence of uncleaved scaffolding core proteins (IPIII and gp68), indicating a structural alteration in the prohead scaffold, resulting in only partial cleavage. In wild-type phages these proteins are found in the head only in the cleaved form. With double-mutants of 67 with mutations in the major shell protein gp23 no naked scaffolding cores were found, confirming the necessity of gp67 for the assembly or persistence of a "normal" core.     

Visualization of the maturation transition in bacteriophage P22 by electron cryomicroscopy

Large-scale conformational transitions are involved in the life-cycle of many types of virus. The dsDNA phages, herpesviruses, and adenoviruses must undergo a maturation transition in the course of DNA packaging to convert a scaffolding-containing precursor capsid to the DNA-containing mature virion. This conformational transition converts the procapsid, which is smaller, rounder, and displays a distinctive skewing of the hexameric capsomeres, to the mature virion, which is larger and more angular, with regular hexons. We have used electron cryomicroscopy and image reconstruction to obtain 15 A structures of both bacteriophage P22 procapsids and mature phage. The maturation transition from the procapsid to the phage results in several changes in both the conformations of the individual coat protein subunits and the interactions between neighboring subunits. The most extensive conformational transformation among these is the outward movement of the trimer clusters present at all strict and local 3-fold axes on the procapsid inner surface. As the trimer tips are the sites of scaffolding binding, this helps to explain the role of scaffolding protein in regulating assembly and maturation. We also observe DNA within the capsid packed in a manner consistent with the spool model. These structures allow us to suggest how the binding interactions of scaffolding and DNA with the coat shell may act to control the packaging of the DNA into the expanding procapsids.     

Membrane Interaction of the Portal Protein gp20 of Bacteriophage T4

Assembly of the bacteriophage T4 head structure occurs at the cytoplasmic face of the inner membrane of Escherichia coli with the formation of proheads. The proheads contain an internal scaffolding core that determines the size and the structure of the capsid. In a mutant where the major shell protein gp23 was compromised, core structures without a shell had been detected. Such core structures were also found in the mutant T4am20am23. Since the mutation in gene 20 is at the N terminus of gp20, it was assumed that these core structures assemble in the absence of gp20. However, sequencing showed that the mutation introduces a new ribosome binding site that leads to a restart at codon 15. Although the mutant protein gp20s lacks the very N-terminal sequence, we found that it still binds to the membrane of the host cell and can initiate prohead assembly. This explains its activity to allow the assembly of core structures and proheads at the membrane surface. With a cross-linking approach, we show here that gp20 and gp20s are escorted by the chaperones DnaK, trigger factor, and GroEL and dock on the membrane at the membrane protein YidC.     

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.     

Evidence that a phage T4 DNA packaging enzyme is a processed form of the major capsid gene product

A phage T4 DNA packaging enzyme appears to arise as a processed form of the major T4 capsid structural protein gp23. The enzyme activity and antigen are missing from all head gene mutants that block the morphogenetic proteolytic processing reactions of the head proteins in vivo. The enzyme antigen can be formed in vitro by T4 (gp21) specific processing of gp23 containing extracts. Enzyme antigen is found in active processed proheads but not in full heads. The enzyme and the major capsid protein show immunological cross-reactivity, produce common peptides upon proteolysis, and share an assembly-conformation-dependent ATP binding site. The packaging enzyme and the mature capsid protein (gp23*) both appear to arise from processing of gp23, the former as a minor product of a specific gp23 structure in the prohead, acting in DNA packaging as a DNA-dependent ATPase, and a headful-dependent terminase.     

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.     

DNA packaging of bacteriophage T4 proheads in vitro. Evidence that prohead expansion is not coupled to DNA packaging

We developed a system for DNA packaging of isolated bacteriophage T4 proheads in vitro and studied the role of prohead expansion in DNA packaging. Biologically active proheads have been purified from a number of packaging-deficient mutant extracts. The cleaved mature prohead is the active structural precursor for the DNA packaging reaction. Packaging of proheads requires ATP, Mg2+ and spermidine, and is stimulated by polyethylene glycol and dextran. Predominantly expanded proheads (ELPs) are produced at 37 degrees C and predominantly unexpanded proheads (ESPs) are produced at 20 degrees C. Both the expanded and unexpanded proheads are active in DNA packaging in vitro. This is based on the observations that (1) both ESPs and ELPs purified by chromatography on DEAE-Sephacel showed DNA packaging activity; (2) apparently homogeneous ELPs prepared by treatment with sodium dodecyl sulfate (which dissociates ESPs) retained significant biological activity; (3) specific precipitation of ELPs with anti-hoc immunoglobulin G resulted in loss of DNA packaging activity; and (4) ESPs upon expansion in vitro to ELPs retained packaging activity. Therefore, contrary to the models that couple DNA packaging to head expansion, in T4 the expansion and packaging appear to be independent, since the already expanded DNA-free proheads can be packaged in vitro. We therefore propose that the unexpanded to expanded prohead transition has evolved to stabilize the capsid and to reorganize the prohead shell functionally from a core-interacting to a DNA-interacting inner surface.     

Synthesis of a trans-Acting Inhibitor of DNA Maturation by Prohead Mutants of Phage λ

Bacteriophage lambda with mutations in genes that control prohead assembly and other head precursors cannot mature their DNA. In this paper we present evidence that the failure of these phage mutants to mature DNA is a reflection of a mechanism that modulates terminase nicking activity during normal phage development. We have constructed plasmids that contain the lambda-cohesive end site (cos) and the genes that code for DNA terminase, the enzyme that matures DNA by cutting at cos. The DNA terminase genes are under control of a thermosensitive cI repressor. These plasmids lack most of the genes involved in prohead morphogenesis and other head precursors. However, when repression is lifted by destruction of the thermosensitive repressor, the terminase synthesized is able to cut almost 100% of the plasmids. Therefore, these plasmids can mature in the absence of proheads and other head gene products. The plasmids are also able to complement mutants of lambda deficient in terminase and DNA maturation. However, in these complementation experiments, if the phage carry mutations in prohead genes E or B, not only is phage DNA maturation blocked, but the plasmid also fails to mature. These experiments show that, in the absence of proheads, phage lambda produces a trans-acting inhibitor of maturation. The genetic determinant of this inhibitor maps in a region extending from the middle of gene B to the end of gene C. A model is proposed in which the nicking activity of DNA-bound terminase is inhibited by the trans-acting inhibitor. Prohead (and other factors) binding to this complex would release the block to allow DNA cleavage and packaging.     

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.