On the sequence similarity of the cohesive ends of coliphage P4, P2, and 186 deoxyribonucleic acid

Pseudotyping Bacteriophage P2 Tail Fibers to Extend the Host Range for Biomedical Applications

Bacteriophages (phages) represent powerful potential treatments against antibiotic-resistant bacterial infections. Antibiotic-resistant bacteria represent a significant threat to global health, with an estimated 70% of infection-causing bacteria being resistant to one or more antibiotics. Developing novel antibiotics against the limited number of cellular targets is expensive and time-consuming, and bacteria can rapidly develop resistance. While bacterial resistance to phage can evolve, bacterial resistance to phage does not appear to spread through lateral gene transfer, and phage may similarly adapt through mutation to recover infectivity. Phages have been identified for all known bacteria, allowing the strain-selective killing of pathogenic bacteria. Here, we re-engineered the Escherichia coli phage P2 to alter its tropism toward pathogenic bacteria. Chimeric tail fibers formed between P2 and S16 genes were designed and generated through two approaches: homology- and literature-based. By presenting chimeric P2:S16 fibers on the P2 particle, our data suggests that the resultant phages were effectively detargeted from the native P2 cellular target, lipopolysaccharide, and were instead able to infect via the proteinaceous receptor, OmpC, the natural S16 receptor. Our work provides evidence that pseudotyping P2 is feasible and can be used to extend the host range of P2 to alternative receptors. Extension of this work could produce alternative chimeric tail fibers to target pathogenic bacterial threats. Our engineering of P2 allows adsorption through a heterologous outer-membrane protein without culturing in its native host, thus providing a potential means of engineering designer phages against pathogenic bacteria from knowledge of their surface proteome.

Tuning knot abundance in semiflexible chains with crowders of different sizes: a Monte Carlo study of DNA chains

We use stochastic simulation techniques to sample the conformational space of linear semiflexible polymers in a crowded medium and study how the knotting properties depend on the crowder size and concentration. The abundance of physical knots in the chains, which for definiteness we model on 10 kb long DNA filaments, is shown to have a non-monotonic, unimodal dependence on the colloid diameter, dc. The maximum incidence of knots occurs when dc is about equal to half of the gyration radius of the isolated chain. The degree of enhancement of knots grows rapidly with the solution density and can be very conspicuous relative to the case of isolated chains with no crowders. For instance, at 30% volume fraction the relative increase is more than fourfold. This dramatic enhancement is shown to originate from the depletion-induced chain compaction over multiple and concurring length scales. The same effect accounts for the variations of the knot length that accompany the changes in knotting probability. The findings suggest that crowded media could be viably used as a passive physical means for controlling and modulating the incidence and length of knots in DNA and other types of semiflexible polymers.

Effective stiffening of DNA due to nematic ordering causes DNA molecules packed in phage capsids to preferentially form torus knots

Observation that DNA molecules in bacteriophage capsids preferentially form torus type of knots provided a sensitive gauge to evaluate various models of DNA arrangement in phage heads. Only models resulting in a preponderance of torus knots could be considered as close to reality. Recent studies revealed that experimentally observed enrichment of torus knots can be qualitatively reproduced in numerical simulations that include a potential inducing nematic arrangement of tightly packed DNA molecules within phage capsids. Here, we investigate what aspects of the nematic arrangement are crucial for inducing formation of torus knots. Our results indicate that the effective stiffening of DNA by the nematic arrangement not only promotes knotting in general but is also the decisive factor in promoting formation of DNA torus knots in phage capsids.

Biopolymer organization upon confinement

Biopolymers in vivo are typically subject to spatial restraints, either as a result of molecular crowding in the cellular medium or of direct spatial confinement. DNA in living organisms provides a prototypical example of a confined biopolymer. Confinement prompts a number of biophysics questions. For instance, how can the high level of packing be compatible with the necessity to access and process the genomic material? What mechanisms can be adopted in vivo to avoid the excessive geometrical and topological entanglement of dense phases of biopolymers? These and other fundamental questions have been addressed in recent years by both experimental and theoretical means. A review of the results, particularly of those obtained by numerical studies, is presented here. The review is mostly devoted to DNA packaging inside bacteriophages, which is the best studied example both experimentally and theoretically. Recent selected biophysical studies of the bacterial genome organization and of chromosome segregation in eukaryotes are also covered.

DNA-DNA interactions in bacteriophage capsids are responsible for the observed DNA knotting

Recent experiments showed that the linear double-stranded DNA in bacteriophage capsids is both highly knotted and neatly structured. What is the physical basis of this organization? Here we show evidence from stochastic simulation techniques that suggests that a key element is the tendency of contacting DNA strands to order, as in cholesteric liquid crystals. This interaction favors their preferential juxtaposition at a small twist angle, thus promoting an approximately nematic (and apolar) local order. The ordering effect dramatically impacts the geometry and topology of DNA inside phages. Accounting for this local potential allows us to reproduce the main experimental data on DNA organization in phages, including the cryo-EM observations and detailed features of the spectrum of DNA knots formed inside viral capsids. The DNA knots we observe are strongly delocalized and, intriguingly, this is shown not to interfere with genome ejection out of the phage.

DNA knots reveal a chiral organization of DNA in phage capsids

Icosahedral bacteriophages pack their double-stranded DNA genomes to near-crystalline density and achieve one of the highest levels of DNA condensation found in nature. Despite numerous studies, some essential properties of the packaging geometry of the DNA inside the phage capsid are still unknown. We present a different approach to the problems of randomness and chirality of the packed DNA. We recently showed that most DNA molecules extracted from bacteriophage P4 are highly knotted because of the cyclization of the linear DNA molecule confined in the phage capsid. Here, we show that these knots provide information about the global arrangement of the DNA inside the capsid. First, we analyze the distribution of the viral DNA knots by high-resolution gel electrophoresis. Next, we perform Monte Carlo computer simulations of random knotting for freely jointed polygons confined to spherical volumes. Comparison of the knot distributions obtained by both techniques produces a topological proof of nonrandom packaging of the viral DNA. Moreover, our simulations show that the scarcity of the achiral knot 4(1) and the predominance of the torus knot 5(1) over the twist knot 5(2) observed in the viral distribution of DNA knots cannot be obtained by confinement alone but must include writhe bias in the conformation sampling. These results indicate that the packaging geometry of the DNA inside the viral capsid is writhe-directed.

Knotting probability of DNA molecules confined in restricted volumes: DNA knotting in phage capsids

When linear double-stranded DNA is packed inside bacteriophage capsids, it becomes highly compacted. However, the phage is believed to be fully effective only if the DNA is not entangled. Nevertheless, when DNA is extracted from a tailless mutant of the P4 phage, DNA is found to be cyclic and knotted (probability of 0.95). The knot spectrum is very complex, and most of the knots have a large number of crossings. We quantified the frequency and crossing numbers of these knots and concluded that, for the P4 tailless mutant, at least half the knotted molecules are formed while the DNA is still inside the viral capsid rather than during extraction. To analyze the origin of the knots formed inside the capsid, we compared our experimental results to Monte Carlo simulations of random knotting of equilateral polygons in confined volumes. These simulations showed that confinement of closed chains to tightly restricted volumes results in high knotting probabilities and the formation of knots with large crossing numbers. We conclude that the formation of the knots inside the viral capsid is driven mainly by the effects of confinement.

Structure-activity relationships of VP-16 analogues

A total of 27 selected analogues of VP-16 and VM-26 were compared with VP-16 and VM-26 for their relative abilities to stabilize the enzyme-substrate intermediate normally formed between eukaryote topoisomerase II and DNA. This activity was compared with cytotoxicity results obtained using the human colon HCT116 cell line and antitumor results obtained after intraperitoneal injection of mice with murine leukemia P388. The most potent analogues were those containing OH groups (demethyl) in either the 3' and 4' or the 3', 4', and 5' positions, the latter being twice as potent as VP-16. VM-26 was only 40% more potent than VP-16 in this assay. It was generally found that the 4'-esters had little activity in vitro, yet were cytotoxic and had antitumor activities. All other analogues with little in vitro activity were not very cytotoxic and had little if any antitumor activity. A very good correlation exists between stabilization of topoisomerase II-DNA intermediates, cytotoxicity, and antitumor activity.

Mechanisms of genome propagation and helper exploitation by satellite phage P4

Temperate coliphage P2 and satellite phage P4 have icosahedral capsids and contractile tails with side tail fibers. Because P4 requires all the capsid, tail, and lysis genes (late genes) of P2, the genomes of these phages are in constant communication during P4 development. The P4 genome (11,624 bp) and the P2 genome (33.8 kb) share homologous cos sites of 55 bp which are essential for generating 19-bp cohesive ends but are otherwise dissimilar. P4 turns on the expression of helper phage late genes by two mechanisms: derepression of P2 prophage and transactivation of P2 late-gene promoters. P4 also exploits the morphopoietic pathway of P2 by controlling the capsid size to fit its smaller genome. The P4 sid gene product is responsible for capsid size determination, and the P2 capsid gene product, gpN, is used to build both sizes. The P2 capsid contains 420 capsid protein subunits, and P4 contains 240 subunits. The size reduction appears to involve a major change of the whole hexamer complex. The P4 particles are less stable to heat inactivation, unless their capsids are coated with a P4-encoded decoration protein (the psu gene product). P4 uses a small RNA molecule as its immunity factor. Expression of P4 replication functions is prevented by premature transcription termination effected by this small RNA molecule, which contains a sequence that is complementary to a sequence in the transcript that it terminates.

Cloning and transposon vectors derived from satellite bacteriophage P4 for genetic manipulation of Pseudomonas and other gram-negative bacteria

We developed transposon and cloning shuttle vectors for genetic manipulation of Pseudomonas and other gram-negative bacteria, exploiting the unique properties and the broad host range of the satellite bacteriophage P4. P4::Tn5 AP-1 and P4::Tn5 AP-2 are suicide transposon vectors which have been used for efficient Tn5 mutagenesis in Pseudomonas putida. pKGB2 is a phasmid vector with a cloning capacity of about 7.5 kb; useful unique cloning sites are SacI and SacII in the streptomycin resistance determinant and PvuI and XhoI in the kanamycin resistance determinant. pKGB4 is a cosmid derived from pKGB2 and carries the additional cloning site SmaI in the kanamycin resistance determinant; its cloning capacity is about 18 kb. These vectors and their recombined derivatives were transferred from Escherichia coli to P. putida by transduction and may be used for other bacterial species susceptible to P4 infection.

Characterization of the cos sites of bacteriophages P2 and P4

A 641-bp cos-containing P2 DNA fragment was sequenced and compared to the P4 cos region. Alignment of the P2 and P4 cos regions shows a homologous region of 55 bp that has only three mismatches and contains a completely conserved region of dyad symmetry. A number of P4- and P2-derived cosmids were tested in an in vivo transduction assay in order to determine the minimal cos region required for packaging. These experiments show that the common region of 55 bp is sufficient for transduction with low frequency, but that a 125-bp cos-containing fragment contains all the information for transduction with optimal frequency.

Regulation of icosahedral virion capsid size by the in vivo activity of a cloned gene product

Determination of icosahedral virion capsid size can be directly studied during helper-dependent lytic development of satellite P4 because the assembly pathway specified by the P2 helper virus is altered to yield smaller-sized capsids. Size determination (sid) mutations identify a P4-encoded function regulating this process. To determine whether the sid gene product is necessary and sufficient to redirect the assembly pathway, we (i) cloned the sid structural gene in a plasmid vector (pMA30) under the control of an inducible promoter and (ii) constructed a packaging substrate (pMA1), a P4 genome-sized plasmid containing only that region of P4, the cos site, necessary for encapsidation. Superinfection by P2 of a host carrying pMA30 under induced conditions resulted in a shift from large to small capsid production. P2 superinfection of a host carrying the cos plasmid pMA1 plus pMA30 under induced conditions yielded pMA1-transducing particles of P4 capsid size. These cloning-based analyses directly demonstrate that sid protein is the only P4 gene product required for small-capsid size determination. In the absence of the P2 O gene product no capsids of any size are assembled during solo infection by P2. Nevertheless, P2 Oam mutant superinfection of a host carrying pMA1 and pMA30 under induced conditions yielded small P4-sized transducing particles. We therefore propose that (i) the sid gene product competes with the O gene product to determine the assembly of small vs. large capsid sizes and (ii) both gene products probably function as temporary scaffolding proteins.

A phasmid shuttle vector for the cloning of complex operons in Salmonella

Phasmid (phage plasmid hybrid) P4 vir1 can be propagated in Escherichia coli as a helper-dependent lytic phage, as a plasmid, or as a prophage. On the basis of an understanding of these modes of propagation, derivatives of P4 have been constructed for use as cloning vectors. In this report we demonstrate that phasmid P4 (i) will propagate as a helper-dependent lytic phage and as a plasmid in Salmonella spp. and (ii) can be used as a high efficiency phage shuttle vector for the reversible transfer of cloned genes between Salmonella spp. and E. coli. For both E. coli and Salmonella spp., P4 phage-mediated gene transfer proved to be only 10-fold lower than plaquing efficiency. For the case of Salmonella spp., this frequency is ca. 10(4)-fold more efficient than is typically found for the transformation of DNA molecules. The usefulness of this cloning vector system for analyses of pathogenic virulence factors is demonstrated by the cloning and expression of both the P pilus adhesin operon and the hemolysin operon of uropathogenic E. coli.

Knotting of DNA molecules isolated from deletion mutants of intact bacteriophage P4

DNA molecules isolated from tailless phage particles (capsids) of bacteriophage P4 virl del10 are known to be knotted. We have found by electron microscopy that 80% of DNA molecules isolated from intact phage particles of P4 virl del10 also contained knots. This observation indicates that the predominant form of P4 virl del10 DNA within the intact phage particle is either knotted or in a configuration that permits knotting upon isolation. In comparison to P4 virl del10 (deleted 1000 basepairs), DNA molecules isolated from intact P4 virl del2 (deleted 650 basepairs) and P4 virl (non-deleted) contained 50% and 15% knots respectively, showing an association of decreased size of deletion of DNA with a decreased fraction of knotted genomes.

Plasmid mode of propagation of the genetic element P4

The satellite bacteriophage P4, in the presence of a helper phage, can enter either the lytic or the lysogenic cycle. In the absence of the helper, P4 can integrate in the bacterial chromosome. In addition, the partially immunity-insensitive mutant P4 vir1 can be maintained as a plasmid. We have found that in the absence of the helper, P4 wt also can be maintained as a plasmid, and that both P4 wt and P4 vir1 have two options for their intracellular propagation: a repressed-integrated or a derepressed-high copy number plasmid mode of maintenance. In the repressed mode, the P4 wt genome is only found integrated into the bacterial chromosome, while the P4 vir1 is found also as a low copy number plasmid coexisting with the integrated P4 vir1 genome. The clones carrying P4 in the derepressed-high copy number plasmid state are obtained at low frequency (0.3%) upon infection with P4 wt, while the vir1 mutation increases this frequency about 300-fold. Such clones can be distinguished easily because of their typical colony morphology (rosettes), due to the presence of filamentous cells. Filamentation of the bacterial host suggests that the presence of derepressed P4 genomes in high copy number interferes with the normal cell division mechanism. The derepressed clones are rather stable, but may revert spontaneously to the repressed state. Spontaneous transition from the repressed to the derepressed state was not observed; however, it can be induced by P2 or P4 vir1 superinfection of P4 wt and P4 vir1 lysogens or by growing the P4 vir1 lysogens up to the late exponential phase. The ability of P4 to choose either of two stable states and the potential to shift between these two modes of propagation indicate that the synthesis of the immunity repressor is regulated.

The bacteriophage P4 alpha gene is the structural gene for bacteriophage P4-induced RNA polymerase

Two temperature-sensitive mutants of satellite phage P4 which do not synthesize P4 DNA at the nonpermissive temperature have been isolated. One of these phage is mutated in the P4 alpha gene. It complements a P4 delta mutant, but not a P4 alpha amber mutant; both mutants are phenotypically identical to alpha amber mutants in all properties studied. They synthesize P4 early proteins 1 and 2 as well as two additional P4-induced early proteins, 5 and 6, which are described here. P4 late proteins are not synthesized by these mutants and cannot be transactivated by helper phage P2. The mutants are unable to transactivate P2 late proteins from a P2 AB mutant. The P4 RNA polymerase activity which has been suggested to be involved in P4 DNA synthesis is not detected at the nonpermissive temperature. The P4 polymerase activity in partially purified extracts prepared from cells infected with the mutant at the permissive temperature is temperature sensitive. Reduced activity is found in vitro when these extracts are preincubated at 41 degrees C or assayed at temperatures higher than 37 degrees C. Thus, the P4 RNA polymerase is the product of the alpha gene. Temperature shift experiments show that the alpha gene product is required until late in the P4 cycle.

Conditionally replicating plasmid vectors that can integrate into the Klebsiella pneumoniae chromosome via bacteriophage P4 site-specific recombination

P4 is a satellite phage of P2 and is dependent on phage P2 gene products for virion assembly and cell lysis. Previously, we showed that a virulent mutant of phage P4 (P4 vir1) could be used as a multicopy, autonomously replicating plasmid vector in Escherichia coli and Klebsiella pneumoniae in the absence of the P2 helper. In addition to establishing lysogeny as a self-replicating plasmid, it has been shown that P4 can also lysogenize E. coli via site-specific integration into the host chromosome. In this study, we show that P4 also integrates into the K. pneumoniae chromosome at a specific site. In contrast to that in E. coli, however, site-specific integration in K. pneumoniae does not require the int gene of P4. We utilized the alternative modes of P4 lysogenization (plasmid replication or integration) to construct cloning vectors derived from P4 vir1 that could exist in either lysogenic mode, depending on the host strain used. These vectors carry an amber mutation in the DNA primase gene alpha, which blocks DNA replication in an Su- host and allows the selection of lysogenic strains with integrated prophages. In contrast, these vectors can be propagated as plasmids in an Su+ host where replication is allowed. To demonstrate the utility of this type of vector, we show that certain nitrogen fixation (nif) genes of K. pneumoniae, which otherwise inhibit nif gene expression when present on multicopy plasmids, do not exhibit inhibitory effects when introduced as merodiploids via P4 site-specific integration.

Knotted DNA from bacteriophage capsids

The majority of the DNA prepared from tailless capsids of bacteriophage P2 by the phenol extraction procedure consists of monomeric rings that have their cohesive ends joined. Electron microscopic and ultracentrifugal studies indicate that these molecules have a complex structure that is topologically knotted; they have a more compact appearance and a higher sedimentation coefficient when compared with regular nicked P2 DNA rings. Linearization of these rings by thermal dissociation or repair of the cohesive ends by DNA polymerase I in the presence of all four deoxynucleoside triphosphates gives molecules that are indistinguishable from normal P2 DNA that has been similarly treated. The knotted nature of the majority of P2 head DNA is further supported by analyzing the products when these molecules are treated with ligase and the ligase-treated molecules are subsequently nicked randomly with DNase I. The data are consistent with the notion that, if such a molecule is first converted to a form that contains only one single-chain scission per molecule, strand separation gives a linear strand and a highly knotted single-stranded ring. The results suggest that the DNA packaged in tailless P2 capsids is arranged in a way that leads to the formation of a complex knot when the ends join. In an intact phage particle, the anchoring of one terminus of the DNA to the head-proximal end of the tail [Chattoraj, D. K. & Inman, R. B. (1974) J. Mol. Biol. 87, 11-22] presumably diminishes or prevents this kind of joining. The novel knotted DNA can be used to assay type II DNA topoisomerases that break and rejoin DNA in a double-stranded fashion.

Novel topologically knotted DNA from bacteriophage P4 capsids: studies with DNA topoisomerases

DNA molecules isolated from bacteriophage P4 are mostly linear with cohesive ends capable of forming circular and concatemeric structures. In contrast, almost all DNA molecules isolated form P4 tailless capsids (heads) are monomeric DNA circles with their cohesive ends hydrogen-bonded. Different form simple DNA circles, such P4 head DNA circles contain topological knots. Gel electrophoretic and electronmicroscopic analyses of P4 head DNA indicate that the topological knots are highly complex and heterogeneous. Resolution of such complex knots has been studied with various DNA topoisomerases. The conversion of highly knotted P4 DNA to its simple circular form is demonstrated by type II DNA topoisomerases which catalyze the topological passing of two crossing double-stranded DNA segments [Liu, L. F., Liu, C. C. & Alberts, B. M. (1980) Cell, 19, 697-707]. The knotted P4 head DNA can be used in a sensitive assay for the detection of a type II DNA topoisomerase even in the presence of excess type I DNA topoisomerases.

Recombinant P4 bacteriophages propagate as viable lytic phages or as autonomous plasmids in Klebsiella pneumoniae

We demonstrate the use of bacteriophage P4 as a molecular cloning vector in Klebsiella pneumoniae. A hybrid P4 phage, constructed in vitro, that contains a K. pneumoniae hisDG DNA fragment can be propagated either as a lytic viable specialized transducing phage or as an autonomous, self-replicating plasmid. Hybrid P4 genomes existing as plasmids can be readily converted into non-defective P4-hybrid phage particles by superinfection with helper phage P2. Infection of a K. pneumoniae hisD non-P2 lysogen with P4-hisD hybrid phage results in approximately 90% of the infected cells becoming stably transduced to HisD+. Because P4 interferes with P2 growth, high titre stocks of P4 hybrid phages are relatively free (less than or equal to 10(-6) of P2 contamination. The hisG gene product was detected in ultraviolet light irradiated host cells infected by the P4-hisDG hybrid phage. A mutant of P4 (P4sid1) that directs the packaging of P4 DNA into P2 sized capsids should permit the construction of hybrid phages carrying 26 kilobase inserts.

Genetic analysis of bacteriophage P4 using P4-plasmid ColE1 hybrids

A set of plasmids that contain fragments of the bacteriophage P4 genome has been constructed by deleting portions of a P4-ColE1 hybrid. A P4 genetic map has been established and related to the physical map by examining the ability of these plasmids to rescue various P4 mutations. The P4 virl mutation and P4 genes involved in DNA replication (alpha), activation of P2 helper genes (delta and epsilon), polarity suppression (psu) and head size determination (sid) have been mapped, as has the region responsible for synthesis of a nonessential P4 protein. One of the deleted plasmids contains only 5900 base pairs (52%) of P4 but will form plaques if additional DNA is added to increase its total size to near that of P4. This plasmid is also unique in that it will not form stable associations with P2 lysogens of E. coli which are recA+. P4 alpha mutants can be suppressed as a result of replication under control of the ColE1 part of the hybrid.

Escherichia coli deoxyribonucleic acid synthesis mutants: their effect upon bacteriophage P2 and satellite bacteriophage P4 deoxyribonucleic acid synthesis

Escherichia coli C strains containing different deoxyribonucleic acid (DNA) synthesis mutations have been tested for their support of the DNA synthesis of bacteriophage P2 and its satellite phage P4. Bacteriophage P2 requires functional dnaB, dnaE, and dnaG E. coli gene products for DNA synthesis, whereas it does not require the products of the dnaA, dnaC, or dnaH genes. In contrast, the satellite virus P4 requires functional dnaE and dnaH gene products for DNA synthesis and does not need the products of the dnaA, dnaB, dnaC, and dnaG genes. Thus the P2 and P4 genomes are replicated differently, even though they are packaged in heads made of the same protein.

Characterization of the DNA from bacteriophage P2-186 hybrids and physical mapping of the 186 chromosome

The DNA from two P2-186 hybrid phages and three 186 Insertion mutants have been characterized by heteroduplex analysis and denaturation mapping. The results allow the orientation of the physical and genetic maps of bacteriophage 186 DNA and put physical limits on the chromosomal locations of the phage attachment sites, immunity genes and tail genees.

Expression of phage transcription in P2 lysogens infected with helper-dependent coliphage P4

The DNA of helper-dependent coliphage P4 and the DNA of its helper-P2-show no detectable sequence homology as measured by DNA.DNA hybridization. The lack of cross-hybridization permits direct analysis of P4 as well as of P2 transcription in P4-infected P2 lysogens by RNA.DNA hybridization. P4-transactivated P2 transcription can be detected around 20 min after P4 infection of the P2 lysogen and the rate (per infected cell) of that transcription becomes equal to that of the P4 transcription at the end of the latent period of P4. Furthermore, P4 transcription appears to be stimulated by the presence of the helper. Conceivably, P2 codes for a stimulator of P4 transcription. Rifamycin has been used to investigate the role of the host RNA polymerase during P4 transactivation of P2 transcription. The results exclude the participation of a P4-coded RNA polymerase and indicate that the original host RNA polymerase is responsible for the bulk of P4 and P2 transcription during transactivation.

In vitro packaging of satellite phage P4 DNA

Satellite phage P4 directs the capsid proteins of its helper phage, P2, to form a head which is only one-third the size of the normal P2 head. The P2 head contains a genome of molecular weight 22 x 10(6), while the small P4 head contains a genome with a molecular weight of only 7 x 10(6). We have used in vitro DNA packaging to test whether P2 and P4 phage head sizes are determined by DNA size. The small DNA of satellite phage P4 added to a P2-infected cell extract was packaged primarily into particles containing three copies of the P4 genome. This process occurred with approximately the same efficiency as P2 DNA packaging in the same cell extract. In contrast, the large DNA of P2 was packaged 300-fold less efficiently than the small DNA of P4 in an extract derived from P4-infected, P2-lysogenic cells. These results suggest that DNA size is not sufficient to determine head size. The results are compatible with DNA packaging via the filling of preformed empty capsids.