Assembly of Bacillus subtilis phage phi29. 1. Mutants in the cistrons coding for the structural proteins.

The effect of mutations in the cistrons coding for the phage structural proteins has been studied by analyzing the phage-related structures accumulated after restrictive infection. Infection with susmutants in cistron 8, lacking both the major head and the fiber protein, does not produce any phage-related structure, suggesting a single route for the assembly of phage phi29; infection with ts mutants in this cistron produces isometric particles. Mutants is cistron 9, coding for the tail protein, TP1, produce DNA-free prolate heads with an internal core; these particles are abortive and contain the head proteins HPO, HP1 and HP3, the upper collar protein NP2 and the nonstructural proteins p7, p15 and p16. Mutants in cistron 10, coding for the upper collar protein, NP2, produce DNA-free isometric heads also with an internal core; they contain the head proteins and the nonstructural protein p7, suggesting that this protein forms the internal core. Mutants in cistrons 11 and 12, coding for the lower collar protein, NP3, and the neck appendages, NP1, respectively, give rise to the formation of DNA-containing normal capsids and DNA-free prolate particles, more rounded at the corners than the normal capsids and with an internal core; the DNA-containing 11-particles are formed by the head proteins and the upper collar protein; the DNA-free 11-particles contain, besides these proteins, the nonstructural protein p7 and a small amount of proteins p15 and 16. The DNA-containing 12-particles have all the normal phage structural proteins except the neck appendages, formed by protein NP1; the DNA-free particles are similar to the DNA-free 11-particles. After restricitive infection mutant sus14(1241) has a delayed lysis phenotype and produces a phage burst higher than normal, after artificial lysis. It produces DNA-containing particles, identical to wild-type phage, which have all the normal phage structural proteins, and DNA-free prolate particles, more rounded at the corners than the final phage particles and with an internal core; the last particles contain the same proteins as the DNA-free 11 or 12-particles. These particles could represent a prohead state, ready for DNA encapsulation. None of the DNA-containing particles have the nonstructural proteins p7, p15 or p16, suggesting that these proteins are released from the proheads upon DNA encapsulation.     

T4-Like genome organization of the Escherichia coli O157:H7 lytic phage AR1

We report the genome organization and analysis of the first completely sequenced T4-like phage, AR1, of Escherichia coli O157:H7. Unlike most of the other sequenced phages of O157:H7, which belong to the temperate Podoviridae and Siphoviridae families, AR1 is a T4-like phage known to efficiently infect this pathogenic bacterial strain. The 167,435-bp AR1 genome is currently the largest among all the sequenced E. coli O157:H7 phages. It carries a total of 281 potential open reading frames (ORFs) and 10 putative tRNA genes. Of these, 126 predicted proteins could be classified into six viral orthologous group categories, with at least 18 proteins of the structural protein category having been detected by tandem mass spectrometry. Comparative genomic analysis of AR1 and four other completely sequenced T4-like genomes (RB32, RB69, T4, and JS98) indicated that they share a well-organized and highly conserved core genome, particularly in the regions encoding DNA replication and virion structural proteins. The major diverse features between these phages include the modules of distal tail fibers and the types and numbers of internal proteins, tRNA genes, and mobile elements. Codon usage analysis suggested that the presence of AR1-encoded tRNAs may be relevant to the codon usage of structural proteins. Furthermore, protein sequence analysis of AR1 gp37, a potential receptor binding protein, indicated that eight residues in the C terminus are unique to O157:H7 T4-like phages AR1 and PP01. These residues are known to be located in the T4 receptor recognition domain, and they may contribute to specificity for adsorption to the O157:H7 strain.     

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.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage p22. I. Genes, proteins, structures and DNA maturation

The functions of ten known late genes are required for the intracellular assembly of infectious particles of the temperate Salmonella phage P22. The defective phenotypes of mutants in these genes have been characterized with respect to DNA metabolism and the appearance of phage-related structures in lysates of infected cells. In addition, proteins specified by eight of the ten late genes were identified by sodium dodecyl sulfate/polyacrylamide gel electrophoresis; all but two are found in the mature phage particle. We do not find cleavage of these proteins during morphogenesis.The mutants fall into two classes with respect to DNA maturation; cells infected with mutants of genes 5, 8, 1, 2 and 3 accumulate DNA as a rapidly sedimenting complex containing strands longer than mature phage length. 5^? and 8^? lysates contain few phage-related structures. Gene 5 specifies the major head structural protein; gene 8 specifies the major protein found in infected lysates but not in mature particles. 1^?, 2^? and 3^? lysates accumulate a single distinctive class of particle (“proheads”), which are spherical and not full of DNA, but which contain some internal material. Gene 1 protein is in the mature particle, gene 2 protein is not.Cells infected with mutants of the remaining five genes (10, 26, 16, 20 and 9) accumulate mature length DNA. 10^? and 26^? lysates accumulate empty phage heads, but examination of freshly lysed cells shows that many were initially full heads. These heads can be converted to viable phage by in vitro complementation in concentrated extracts. 16^? and 20^? lysates accumulate phage particles that appear normal but are non-infectious, and which cannot be rescued in vitro.From the mutant phenotypes we conclude that an intact prohead structure is required to mature the virus DNA (i.e. to cut the overlength DNA concatemer to the mature length). Apparently this cutting occurs as part of the encapsulation event.     

Head Proteins from T-Even Bacteriophage: I. Molecular Weight Characterization 1

T-even bacteriophage capsid proteins were separated on 6% agarose columns by use of 6 m guanidine hydrochloride containing 5 mm dithiothreitol both to dissociate and to elute the proteins. The head capsids of T2H, T4B, T4B01, T4D, and T6r(+) contained at least three structural proteins with molecular weights of 40,000, 18,000, and 11,000 daltons, amounting to 76, 2, and 8%, respectively, of the total capsid protein. On the other hand, T2L head capsids contained only two structural proteins with molecular weights of 40,000 and 18,000 daltons (81 and 2.5%, respectively, of the total protein). A discussion of the possible role of these structural head proteins and a T-even phage head model suggesting a structural arrangement of the 40,000 dalton subunit are presented.     

Inactivation of T4D Bacteriophage by Antiserum Against Bacteriophage Dihydrofolate Reductase

Antiserum was prepared against highly purified T4D bacteriophage-induced dihydrofolate reductase (DFR). This serum not only inactivated the enzyme but also inactivated all strains of T4D examined. T6 was inactivated to a lesser extent, and T2L, T2H, and T5 were unaffected by the antiserum. The phage-killing power of the serum could be blocked by prior incubation with partially purified T4D dfr obtained from host cells unable to make phage structural proteins. These observations confirm earlier results that the phage dfr is a structural component of the phage particle, and they offer new evidence on the manner in which this enzyme in incorporated into the tail structure.     

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.     

Model for DNA packaging into bacteriophage T4 heads.

The mechanism of DNA packaging into bacteriophage T4 heads in vivo was investigated by glucosylation of hydroxymethylcytosine residues in a conditionally glucose-deficient host. Cytoplasmic DNA associated with partially packaged ts49 heads can be fully glucosylated, whereas DNA already packaged into these heads is shown to be resistant to glucosylation. After temperature shift and completion of arrested packaging into the reversible temperature-sensitive ts49 head, the structure of the DNA in the mature ts49 phage was investigated by restriction enzyme digestion, autoradiography, and other techniques. Such mature DNA appears to be fully glucosylated along part of its length and nonglucosylated on the remainder. Its structure suggests that the DNA is run into the head linearly and unidirectionally from one mature end and that there is little sequence specificity in that portion of the T4 DNA which first enters the capsid. This technique should be useful in investigation of the three-dimensional structure of first- and last-packaged DNA within the head; preliminary studies including autoradiography of osmotically shocked phage suggest that the DNA which first enters the head is deposited toward the center of the capsid and that the end of the DNA which first enters the head exits first upon injection. In conjunction with studies of the structure of condensed DNA, the positions and functions of T4 capsid proteins in DNA packaging, and the order of T4 packaging functions [Earnshaw and Harrison, Nature (London) 268:598-602, 1977; Hsiao and Black, Proc. Natl. Acad. Sci. U.S.A. 74:3652-3656, 1977; Müller-Salamin et al., J. Virol. 24:121-134, 1977; Richards et al., J. Mol. Biol. 78:255-259, 1973], the features described above suggest the following model: the first DNA end is fixed to the proximal apex of the head at p20 and the DNA is then pumped into the head enzymatically by proteins (p20 + p17) which induce torsion in the DNA molecule.     

Primary structure of internal peptide VII of T-even bacteriophages

As first shown by Hershey (1955,1957), osmotic rupture of the head of bacteriophage T2 releases, together with the DNA, an acid-insoluble protein fraction and an acid-soluble peptide fraction. Subsequent chromatographic analysis of the acid-soludle fraction of bacteriophage T4-infected Escherichia coli resolved two peptides, designated II and VII, corresponding to the peptide fraction of T2 described by Hershey (Eddleman &; Champe, 1966). Both peptides were found to be composed largely of acidic residues with only a limited number of other amino acids. The amino acid compositions predicted minimum molecular weights of 3900 (33 residues) and 2700 (23 residues) for peptides II and VII, respectively, consistent with their retardation on Sephadex G25 (Champe &; Eddleman, 1967). The formation of these peptides in T4-infected cells parallels the synthesis of late proteins. Pulse-labelling experiments showed, however, that the internal peptides are derived from acid-insoluble precursors, suggesting the probable involvement of proteolytic cleavage in their formation. The role of these peptides, if any, in phage replication is unclear. Eddleman &; Champe (1966) suggested that they may be inactive remnants of a core protein whose elimination is required for assembly. Alternatively, Laemmli &; Favre (1973) have proposed that the internal peptides may function to facilitate packaging of the DNA in the phage head.     

Bacteriophage T4 head morphogenesis: host DNA enzymes affect frequency of petite forms

Petite T4 phage particles have a shorter head than normal T4 phage and contain less DNA. They are not viable in single infections but are able to complement each other in multiply infected cells. Such particles normally make up 1 to 3% of T4 lysates. We show here that lysates of T4 grown on Escherichia coli H560 (end-A^?, pol-A^?) contain 33% of such petite particles. These particles are identical in physical and biological properties to those described previously, only their high frequency is abnormal. The frequency of petite particles in lysates grown on H560 is controlled by the presence or absence of the gene for DNA polymerase I (pol-A1) and apparently also a gene for endonuclease I (end-A). The involvement of these host DNA enzymes with T4 head morphology and DNA content indicates that DNA is directly involved in head morphogenesis. Such an involvement is incompatible with models of T4 head morphogenesis in which dimensionally stable, preformed empty heads are precursors of filled heads. The processing or repair of DNA apparently helps decide whether the assembly of T4 head subunits produces normal or petite heads.     

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.     

Membrane-associated assembly of a phage T4 DNA entrance vertex structure studied with expression vectors

The DNA entrance vertex of the phage head is critical for prohead assembly and DNA packaging. A single structural protein comprises this dodecameric ring substructure of the prohead. Assembly of the phage T4 prohead occurs on the cytoplasmic membrane through a specific attachment at or near the gp20 DNA entrance vertex. An auxiliary head assembly gene product, gp40, was hypothesized to be involved in assembling the gp20 substructure. T4 genes 20, 40 and 20 + 40 were cloned into expression vectors under lambda pL promoter control. The corresponding T4 gene products were synthesized in high yield and were active as judged by their ability to complement the corresponding infecting T4 mutants in vivo. The cloned T4 gene 20 and gene 40 products were inserted into the cytoplasmic membrane as integral membrane proteins; however, gp20 was inserted into the membrane only when gp40 was also synthesized, whereas gp40 was inserted in the presence or absence of gp20. The gp20 insertion required a membrane potential, was not dependent upon the Escherichia coli groE gene, and assumed a defined membrane-spanning conformation, as judged by specific protease fragments protected by the membrane. The inserted gp20 structure could be probed by antibody binding and protein A-gold immunoelectron microscopy. The data suggest that a specific gp20-gp40-membrane insertion structure constitutes the T4 prohead assembly initiation complex.     

Bacteriophage-host interaction and restriction of nonglucosylated T6.

Nonglucosylated T6 phage (T6gtam 16am30, hereafter called T6alpha gt-) were found to have two structural anomalies when compared with wild-type T6. The DNA of T6alpha gt- phage contains single-strand interruptions. These can be seen both during infection, in the pool of replicating DNA, and in DNA extracted from purified phage. In addition, the sodium dodecyl sulfate-polyacrylamide gel pattern of T6alpha gt- phage structural proteins reveals a protein band not found in T6. The altered protein has a mobility slightly faster than that of the major head protein, and it is not removed by osmotic shock. The restriction activity of Escherichia coli B directed against T6alpha gt- phage is abolished by preinfection of the cells for 4 min with T4 im m2. The shut-off of restriction is observed either by the rescue of superinfecting T6alpha gt- or by the failure to detect degradation of incoming T6alpha gt- DNA. This effect is resistant to rifampin and chloramphenicol.     

Gene 68, a new bacteriophage T4 gene which codes for the 17K prohead core protein is involved in head size determination

We have identified the gene for a major component of the prohead core of bacteriophage T4, the 17K protein. The gene, which we call gene 68, lies between genes 67 and 21 in the major cluster of T4 head genes. All of the genes in this region of the T4 genome have overlapping initiation and termination codons with the sequence T-A-A-T-G. We present the DNA sequence of the gene and show that it codes for a protein containing 141 amino acids with an acidic amino-terminal half and a basic carboxyl terminus. Antibodies prepared against the 17K protein were used to show that it is cleaved by the phage-coded gp21 protease during head maturation and that most of the protein leaves the head after cleavage. A frameshift mutation of the gene was constructed in vitro and recombined back into the phage genome. The mutated phages had a drastically reduced burst size and about half of the particles produced were morphologically abnormal, having isometric rather than prolate heads. Thus, the 17K protein is involved in head shape determination but is only semi-essential for T4 growth.     

Regulation of Expression of Cloned Bacteriophage T4 Late Gene 23

The parameters governing the activity of the cloned T4 gene 23, which codes for the major T4 head protein, were analyzed. Suppressor-negative bacteria carrying wild-type T4 gene 23 cloned into plasmid pCR1 or pBR322 were infected with T4 gene 23 amber phage also carrying mutations in the following genes: (i) denA and denB (to prevent breakdown of plasmid DNA after infection) and (ii) denA, denB, and, in addition, 56 (to generate newly replicated DNA containing dCMP) and alc/unf (because mutations in this last gene allow late genes to be expressed in cytosine-containing T4 DNA). Bacteria infected with these phage were labeled with (14)C-amino acids at various times after infection, and the labeled proteins were separated by one-dimensional gel electrophoresis so that the synthesis of plasmid-coded gp23 could be compared with the synthesis of other, chromosome-coded T4 late proteins. We analyzed the effects of additional mutations that inactivate DNA replication proteins (genes 32 and 43), an RNA polymerase-binding protein (gene 55), type II topoisomerase (gene 52), and an exonuclease function involved in recombination (gene 46) on the synthesis of plasmid-coded gp23 in relation to chromosome-coded T4 late proteins. In the denA:denB:56:alc/unf genetic background, the phage chromosome-borne late genes followed the same regulatory rules (with respect to DNA replication and gp55 action) as in the denA:denB genetic background. The plasmid-carried gene 23 was also under gp55 control, but was less sensitive than the chromosomal late genes to perturbations of DNA replication. Synthesis of plasmid-coded gp23 was greatly inhibited when both the type II T4 topoisomerase and the host's DNA gyrase are inactivated. Synthesis of gp23 was also substantially affected by a mutation in gene 46, but less strongly than in the denA:denB genetic background. These observations are interpreted as follows. The plasmid-borne T4 gene 23 is primarily expressed from a late promoter. Expression of gene 23 from this late promoter responds to an activation event which involves some structural alteration of DNA. In these respects, the requirements for expressing the plasmid-borne gene 23 and chromosomal late genes are very similar (although in the denA:denB:56:alc/unf genetic background, there are significant quantitative differences). For the plasmid-borne gene 23, activation involves the T4 gp46, a protein which is required for DNA recombination. However, for the reasons presented in the accompanying paper (Jacobs et al., J. Virol. 39:31-45, 1981), we conclude that the activation of gene 23 does not require a complete breakage-reunion event which transposes that gene to a later promoter on the phage chromosome. Ways in which gp46 may actually be involved in late promoter activation on the plasmid are discussed.     

Assembly of Bacillus subtilis phage phe29. 2. Mutants in the cistrons coding for the non-structural proteins.

The effect on phage morphogenesis of sus mutations in the cistrons coding for nonstructural proteins has been studied. Mutants in three cistrons analyzed that are involved in phage DNA synthesis, as well as in cistron 16 which codes for a late nonstructural protein, produce prolate capsids which are more rounded at the corners than complete phage heads and have an internal core; they contain the head proteins, the upper collar protein and protein p7, not present in mature phage particles. Mutants in cistron 7 do not produce capsids nor other phage-related structures; this result and the presence of p7 in phage capsids suggest an essential role in capsid assembly for this protein. The protein product of cistron 13 is probably needed for a stable DNA encapsulation since mutants in this cistron produce mainly DNA-free complete phage particles and only about 10% of uninfective DNA-containing complete phage. Cistron 15 codes for a late, partially dispensable, nonstructural protein which is present in the DNA-free capsids produced after infection with the delayed-lysis mutant sus14(1242), used as the wild-type control, or with mutants in cistrons 9, 11,12 and 13. Proteins p15 and p16 are probably involved in the encapsulation of viral DNA in a prohead.     

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.     

Zinc uptake and incorporation into proteins in T4D bacteriophage-infected Escherichia coli.

The metabolism of Zn2+ in Escherichia coli infected with T4D bacteriophage and various T4D mutants has been examined. E. coli B infected with T4D, and all T4D mutants except T4D 12-, took up zinc ions at a rate identical to that of uninfected cells. E. coli B infected with T4D 12- had a markedly decreased rate of zinc uptake. The incorporation of zinc into proteins of infected cells has also been studied. T4D phage infection was found to shut off the synthesis of all bacterial host zinc metalloproteins while allowing the formation of viral-induced zinc proteins. The amount of zinc incorporated into viral proteins was affected by the absence of various T4D gene products. Cells infected with T4D 12-, and to a much less extent those infected with T4D 29-, incorporated the least amount of zinc into proteins, while cells infected with T4D 11- and T4D 51- incorporated increased amounts of zinc into the zinc metalloproteins. In cells infected with T4D 11- and 51- most of the zinc protein was found to be the product of gene 12. The marked effect of infection of E. coli with T4D 12- on both zinc uptake and zinc incorporation into protein supports the conclusion that T4D gene 12 protein is a zinc metalloprotein. Additionally, these observations have indicated that this metalloprotein interacts with host cell membrane.     

Genetic Control of Capsid Length in Bacteriophage T4 I. Isolation and Preliminary Description of Four New Mutants

Four new mutants are described whose phenotypic expression affects the length of the head of bacteriophage T4D. All mutants produce some phenotypically normal phage particles. Mutant pt21-34 also produces at least two size classes of phage particle which have heads that are shorter than normal. The other three mutants, ptg19-2, ptg19-80, and ptg191, produce, in addition to phages with normal and with shorter-than-normal heads, giant phages with heads from 1.5 to at least 10 times the normal length. All mutations are clustered near gene 23. Giant phage particles have the following properties: they are infectious and contain and inject multiple genomes as a single continuous bihelical DNA molecule of greater-than-unit length. Their frequency, relative to the total plaque-former population, increases late in the infectious cycle. They have a normal diameter, variable length, and a buoyant density range in CsCl from equal to slightly greater than that of normal phage. The arrangement of capsomers is visible in the capsids, which are composed of cleaved gene 23 protein.