Bacteriophage P22 mutants that alter the specificity of DNA packaging

Viral Small Terminase: A Divergent Structural Framework for a Conserved Biological Function

The genome packaging motor of bacteriophages and herpesviruses is built by two terminase subunits, known as large (TerL) and small (TerS), both essential for viral genome packaging. TerL structure, composition, and assembly to an empty capsid, as well as the mechanisms of ATP-dependent DNA packaging, have been studied in depth, shedding light on the chemo-mechanical coupling between ATP hydrolysis and DNA translocation. Instead, significantly less is known about the small terminase subunit, TerS, which is dispensable or even inhibitory in vitro, but essential in vivo. By taking advantage of the recent revolution in cryo-electron microscopy (cryo-EM) and building upon a wealth of crystallographic structures of phage TerSs, in this review, we take an inventory of known TerSs studied to date. Our analysis suggests that TerS evolved and diversified into a flexible molecular framework that can conserve biological function with minimal sequence and quaternary structure conservation to fit different packaging strategies and environmental conditions.

Quinolone resistance genes (qnrA and qnrS) in bacteriophage particles from wastewater samples and the effect of inducing agents on packaged antibiotic resistance genes

OBJECTIVES

This study quantifies quinolone antibiotic resistance genes (qnrA and qnrS) in DNA of phage particles isolated from faecally polluted waters and evaluates the influence of phage inducers on the abundance of antibiotic resistance genes in packaged DNA.

METHODS

qnrA and qnrS were quantified by qPCR in DNA of phage particles isolated from 18 raw urban wastewater samples, 18 river samples and 28 archived samples of animal wastewater. The bacterial fraction of the samples was treated with mitomycin C, ciprofloxacin, EDTA or sodium citrate under different conditions, and the number of resistance genes in DNA of phage particles was compared with the non-induced samples.

RESULTS

qnrA was more prevalent than qnrS, with 100% of positive samples in urban wastewater and river and 71.4% of positive samples in animal wastewater. Densities of qnrA ranged from 2.3 × 10(2) gene copies (GC)/mL in urban wastewater to 7.4 × 10(1) GC/mL in animal wastewater. qnrS was detected in 38.9% of urban wastewater samples, in 22.2% of river samples and only in one animal wastewater sample (3.6%). Despite the lower prevalence, qnrS densities reached values of 10(3) GC/mL. Both qnr genes and other resistance genes assayed (blaTEM and blaCTX-M) showed a significant increase in DNA of phage particles when treated with EDTA or sodium citrate, while mitomycin C and ciprofloxacin showed no effect under the different conditions assayed.

CONCLUSIONS

This study confirms the contribution of phages to the mobilization of resistance genes and the role of the environment and certain inducers in the spread of antibiotic resistance genes by means of phages.

Function and horizontal transfer of the small terminase subunit of the tailed bacteriophage Sf6 DNA packaging nanomotor

Bacteriophage Sf6 DNA packaging series initiate at many locations across a 2kbp region. Our in vivo studies show that Sf6 small terminase subunit (TerS) protein recognizes a specific packaging (pac) site near the center of this region, that this site lies within the portion of the Sf6 gene that encodes the DNA-binding domain of TerS protein, that this domain of the TerS protein is responsible for the imprecision in Sf6 packaging initiation, and that the DNA-binding domain of TerS must be covalently attached to the domain that interacts with the rest of the packaging motor. The TerS DNA-binding domain is self-contained in that it apparently does not interact closely with the rest of the motor and it binds to a recognition site that lies within the DNA that encodes the domain. This arrangement has allowed the horizontal exchange of terS genes among phages to be very successful.

Crystallization of the nonameric small terminase subunit of bacteriophage P22

The packaging of viral genomes into preformed empty procapsids is powered by an ATP-dependent genome-translocating motor. This molecular machine is formed by a heterodimer consisting of large terminase (L-terminase) and small terminase (S-terminase) subunits, which is assembled into a complex of unknown stoichiometry, and a dodecameric portal protein. There is considerable confusion in the literature regarding the biologically relevant oligomeric state of terminases, which, like portal proteins, form ring-like structures. The number of subunits in a hollow oligomeric protein defines the internal diameter of the central channel and the ability to fit DNA inside. Thus, knowledge of the exact stoichiometry of terminases is critical to decipher the mechanisms of terminase-dependent DNA translocation. Here, the gene encoding bacteriophage P22 S-terminase in Escherichia coli has been overexpressed and the protein purified under native conditions. In the absence of detergents and/or denaturants that may cause disassembly of the native oligomer and formation of aberrant rings, it was found that P22 S-terminase assembles into a concentration-independent nonamer of ∼168 kDa. Nonameric S-terminase was crystallized in two different crystal forms at neutral pH. Crystal form I belonged to space group P2(1)2(1)2, with unit-cell parameters a=144.2, b=144.2, c=145.3 Å, and diffracted to 3.0 Å resolution. Crystal form II belonged to space group P2(1), with unit-cell parameters a=76.48, b=100.9, c=89.95 Å, β=93.73°, and diffracted to 1.75 Å resolution. Preliminary crystallographic analysis of crystal form II confirms that the S-terminase crystals contain a nonamer in the asymmetric unit and are suitable for high-resolution structure determination.

Recombination in the Vicinity of Insertions of Transposon Tn 5 in MYXOCOCCUS XANTHUS

To test genetic recombination in the vicinity of insertions of the transposon Tn5, crosses were performed by transduction between M. xanthus strains carrying different insertions of Tn5. One member of each pair carried resistance to kanamycin (Tn5-Km); the other carried resistance to tetracycline (Tn5-Tc). The distance between each pair of Tn5 insertions was also measured by restriction mapping. The physical distance corresponding to each recombination frequency was calculated from the transductional linkage and compared with distance on the restriction map. A good correspondence between the two measures of distance was obtained for a pair of Tn5 insertions near the cglB locus and for another pair near the mgl locus. Correspondence between the two measurements of distance, the observed allelic behavior of Tn5-Km and Tn5 -Tc at the same locus and the finding of the same frequencies of recombinants in reciprocal crosses implied that recombination in the vicinity of Tn 5 was normal.

Genomic and biological analysis of phage Xfas53 and related prophages of Xylella fastidiosa

We report the plaque propagation and genomic analysis of Xfas53, a temperate phage of Xylella fastidiosa. Xfas53 was isolated from supernatants of X. fastidiosa strain 53 and forms plaques on the sequenced strain Temecula. Xfas53 forms short-tailed virions, morphologically similar to podophage P22. The 36.7-kb genome is predicted to encode 45 proteins. The Xfas53 terminase and structural genes are related at a protein and gene order level to P22. The left arm of the Xfas53 genome has over 90% nucleotide identity to multiple prophage elements of the sequenced X. fastidiosa strains. This arm encodes proteins involved in DNA metabolism, integration, and lysogenic control. In contrast to Xfas53, each of these prophages encodes head and DNA packaging proteins related to the siphophage lambda and tail morphogenesis proteins related to those of myophage P2. Therefore, it appears that Xfas53 was formed by recombination between a widespread family of X. fastidiosa P2-related prophage elements and a podophage distantly related to phage P22. The lysis cassette of Xfas53 is predicted to encode a pinholin, a signal anchor and release (SAR) endolysin, and Rz and Rz1 equivalents. The holin gene encodes a pinholin and appears to be subject to an unprecedented degree of negative regulation at both the level of expression, with rho-independent transcriptional termination and RNA structure-dependent translational repression, and the level of holin function, with two upstream translational starts predicted to encode antiholin products. A notable feature of Xfas53 and related prophages is the presence of 220- to 390-nucleotide degenerate tandem direct repeats encoding putative DNA binding proteins. Additionally, each phage encodes at least two BroN domain-containing proteins possibly involved in lysogenic control. Xfas53 exhibits unusually slow adsorption kinetics, possibly an adaptation to the confined niche of its slow-growing host.

A conformational switch in bacteriophage p22 portal protein primes genome injection

Double-stranded DNA (dsDNA) viruses such as herpesviruses and bacteriophages infect by delivering their genetic material into cells, a task mediated by a DNA channel called "portal protein." We have used electron cryomicroscopy to determine the structure of bacteriophage P22 portal protein in both the procapsid and mature capsid conformations. We find that, just as the viral capsid undergoes major conformational changes during virus maturation, the portal protein switches conformation from a procapsid to a mature phage state upon binding of gp4, the factor that initiates tail assembly. This dramatic conformational change traverses the entire length of the DNA channel, from the outside of the virus to the inner shell, and erects a large dome domain directly above the DNA channel that binds dsDNA inside the capsid. We hypothesize that this conformational change primes dsDNA for injection and directly couples completion of virus morphogenesis to a new cycle of infection.

Crystallogenesis of bacteriophage P22 tail accessory factor gp26 at acidic and neutral pH

Gp26 is one of three phage P22-encoded tail accessory factors essential for stabilization of viral DNA within the mature capsid. In solution, gp26 exists as an extended triple-stranded coiled-coil protein which shares profound structural similarities with class I viral membrane-fusion protein. In the cryo-EM reconstruction of P22 tail extracted from mature virions, gp26 forms an approximately 220 angstroms extended needle structure emanating from the neck of the tail, which is likely to be brought into contact with the cell's outer membrane when the viral DNA-injection process is initiated. To shed light on the potential role of gp26 in cell-wall penetration and DNA injection, gp26 has been crystallized at acidic, neutral and alkaline pH. Crystals of native gp26 grown at pH 4.6 diffract X-rays to 2.0 angstroms resolution and belong to space group P2(1), with a dimer of trimeric gp26 molecules in the asymmetric unit. To study potential pH-induced conformational changes in the gp26 structure, a chimera of gp26 fused to maltose-binding protein (MBP-gp26) was generated. Hexagonal crystals of MBP-gp26 were obtained at neutral and alkaline pH using the high-throughput crystallization robot at the Hauptman-Woodward Medical Research Institute, Buffalo, NY, USA. These crystals diffract X-rays to beyond 2.0 angstroms resolution. Structural analysis of gp26 crystallized at acidic, neutral and alkaline pH is in progress.

Preliminary crystallographic analysis of the bacteriophage P22 portal protein

Portal proteins are components of large oligomeric dsDNA pumps connecting the icosahedral capsid of tailed bacteriophages to the tail. Prior to the tail attachment, dsDNA is actively pumped through a central cavity formed by the subunits. We have studied the portal protein of bacteriophage P22, which is the largest connector characterized among the tailed bacteriophages. The molecular weight of the monomer is 82.7 kDa, and it spontaneously assembles into an oligomeric structure of approximately 1.0 MDa. Here we present a preliminary biochemical and crystallographic characterization of this large macromolecular complex. The main difficulties related to the crystallization of P22 portal protein lay in the intrinsic dynamic nature of the portal oligomer. Recombinant connectors assembled from portal monomers expressed in Escherichia coli form rings of different stoichiometry in solution, which cannot be separated on the basis of their size. To overcome this intrinsic heterogeneity we devised a biochemical purification that separates different ring populations on the basis of their charge. Small ordered crystals were grown from drops containing a high concentration of the kosmotropic agent tert-butanol and used for data collection. A preliminary crystallographic analysis to 7.0-A resolution revealed that the P22 portal protein crystallized in space group I4 with unit cell dimensions a=b=409.4A, c=260.4A. This unit cell contains a total of eight connectors. Analysis of the noncrystallographic symmetry by the self-rotation function unambiguously confirmed that bacteriophage P22 portal protein is a dodecamer with a periodicity of 30 degrees. The cryo-EM reconstruction of the dodecahedral bacteriophage T3 portal protein will be used as a model to initiate phase extension and structure determination.

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

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

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

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

Bacteriophage P22 portal protein is part of the gauge that regulates packing density of intravirion DNA

The complex double-stranded DNA bacteriophages assemble DNA-free protein shells (procapsids) that subsequently package DNA. In the case of several double-stranded DNA bacteriophages, including P22, packaging is associated with cutting of DNA from the concatemeric molecule that results from replication. The mature intravirion P22 DNA has both non-unique (circularly permuted) ends and a length that is determined by the procapsid. In all known cases, procapsids consist of an outer coat protein, an interior scaffolding protein that assists in the assembly of the coat protein shell, and a ring of 12 identical portal protein subunits through which the DNA is presumed to enter the procapsid. To investigate the role of the portal protein in cutting permuted DNA from concatemers, we have characterized P22 portal protein mutants. The effects of several single amino acid changes in the P22 portal protein on the length of the DNA packaged, the density to which DNA is condensed within the virion, and the outer radius of the capsid have been determined. The results obtained with one mutant (NT5/1a) indicate no change (+/- 0.5%) in the radius of the capsid, but mature DNA that is 4.7% longer and a packing density that is commensurately higher than those of wild-type P22. Thus, the portal protein is part of the gauge that regulates the length and packaging density of DNA in bacteriophage P22. We argue that these findings make models for DNA packaging less likely in which the packing density is a property solely of the coat protein shell or of the DNA itself.

Rapid mapping in Salmonella typhimurium with Mud-P22 prophages

A new method for mapping mutations in the Salmonella typhimurium chromosome is described and applied to the localization of novel regulatory mutations affecting expression of the nirB (nitrite reductase) gene. The mapping technique is also illustrated by the mapping of mutations in genes affecting carbohydrate catabolism and biosynthetic pathways. The new mapping method involves use of the hybrid phage MudP and MudQ (together referred to as Mud-P22), originally constructed by Youderian et al. (Genetics 118:581-592, 1988). This report describes a set of Mud-P22 lysogens, each member of the set containing a different Mud-P22 insertion. The insertions are scattered along the entire Salmonella genome. These lysogens, when induced by mitomycin C, generate transducing lysates that are enriched (45- to 1,400-fold over the background, generalized transducing particle population) for transducing particles containing bacterial DNA that flanks one side of the insertion. We demonstrate that within the set of lysogens there can be found at least one Mud-P22 insertion that enriches for any particular region of the Salmonella chromosome and that, therefore, all regions of the chromosome are discretely enriched and represented by the collection as a whole. We describe a technique that allows the rapid and facile determination of which lysate contains enriched sequences for the repair of a mutant locus, thereby allowing the determination of the map position of the locus. This technique is applicable to those mutations for which the wild-type allele is selectable. We also describe a procedure whereby any Tn10 insertion can be mapped by selecting for the loss of Tetr.

Restriction endonuclease and genetic mapping studies indicate that the vegetative genome of the temperate, Salmonella-specific bacteriophage, epsilon 15, is circularly-permuted

Data from physical and genetic mapping studies show that the vegetative genome of the temperate, Group E 1 Salmonella bacteriophage, epsilon 15, is circularly-permuted. Preliminary evidence suggests that the circular permutation of the epsilon 15 genome is non-random.

Bacteriophage P1 genes involved in the recognition and cleavage of the phage packaging site (pac)

The packaging of bacteriophage P1 DNA is initiated by cleavage of the viral DNA at a specific site, designated pac. The proteins necessary for that cleavage, and the genes that encode those proteins, are described in this report. By sequencing wild-type P1 DNA and DNA derived from various P1 amber mutants that are deficient in pac cleavage, two distinct genes, referred to as pacA and pacB, were identified. These genes appear to be coordinately transcribed with an upstream P1 gene that encodes a regulator of late P1 gene expression (gene 10). pacA is located upstream from pacB and contains the 161 base-pair pac cleavage site. The predicted sizes of the PacA and PacB proteins are 45 kDa and 56 kDa, respectively. These proteins have been identified on SDS-polyacrylamide gels using extracts derived from Escherichia coli cells that express these genes under the control of a bacteriophage T7 promoter. Extracts prepared from cells expressing both PacA and PacB are proficient for site-specific cleavage of the P1 packaging site, whereas those lacking either protein are not. However, the two defective extracts can complement each other to restore functional pac cleavage activity. Thus, PacA and PacB are two essential bacteriophage proteins required for recognition and cleavage of the P1 packaging site. PacB extracts also contain a second P1 protein that is encoded within the pacB gene. We have identified this protein on SDS-polyacrylamide gels and have shown that it is translated in the same reading frame as is PacB. Its role, if any, in pac cleavage is yet to be determined.

Nucleotide sequence of the bacteriophage P22 genes required for DNA packaging

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

In vitro packaging of bacteriophage phi 29 DNA restriction fragments and the role of the terminal protein gp3

Restriction fragments of bacteriophage phi 29 DNA-gp3 (DNA-gene product 3 complex) were packaged in a completely defined in vitro system that included purified proheads, the DNA packaging protein gp16 and ATP. Both left and right end DNA-gp3 fragments were packaged in this system, in contrast to the oriented and selective packaging of left end DNA-gp3 fragments in extracts; left ends could be packaged quantitatively in the defined system, while the packaging efficiency of right ends was generally about threefold lower. In addition, certain internal (non-end) DNA fragments were packaged at efficiencies of about 10% to 15%. Digestion of the gp3 with trypsin or proteinase K reduced the packaging of whole-length DNA by a factor of 2 or 4, respectively, and removal of the gp3 from whole-length DNA or end fragments with piperidine reduced packaging to the level of internal fragments. Though the terminal protein gp3 was non-essential for DNA translocation in the defined system, it stimulated packaging of left and right end fragments, and stabilized packaging of the left end. The packaging of end and internal DNA fragments of the related phage M2Y into phi 29 proheads was similar to that of phi 29 DNA fragments, and certain fragments of lambda DNA were packaged at the efficiency of the internal phi 29 DNA fragments. Selective packaging of DNA-gp3 left ends was restored by the addition of bacterial cell extracts or glycerol to the defined system, and these packaging conditions discriminated between phi 29 and M2Y DNAs that have distinct terminal proteins.

Molecular analysis of the packaging signal in bacteriophage CP-T1 of Vibrio cholerae

We have previously identified a unique site, pac, from which packaging of precursor concatameric viral DNA into proheads starts during the maturation process of bacteriophage CP-T1. The direction of this packaging was determined from restriction enzyme cleavage patterns of CP-T1 DNA. A restriction enzyme generated fragment containing pac was cloned and the surrounding DNA region sequenced. Analysis of the nucleotide sequence revealed numerous repeat regions related to the consensus sequence PuagttGAT.AAT.aa.t. Within the sequenced region an open reading frame encoding a 12260 Mr protein was also identified. This protein appears to share homology with the binding domains of known DNA binding proteins and may represent a putative Pac terminase possessing the specific endonuclease activity required for cleavage at the pac site. Minicell analysis of deletion derivatives of the pac-containing clone revealed a protein of approximately 12,900 Mr encoded within this same region, confirming that this Pac protein is phage encoded.

Analysis in vivo of the bacteriophage P22 headful nuclease

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

Initiation of bacteriophage P22 DNA packaging series. Analysis of a mutant that alters the DNA target specificity of the packaging apparatus

Bacteriophage P22 is thought to package its double-stranded DNA chromosome from concatemeric replicating DNA in a "processive" sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally from that point. DNA ends are generated near the pac site before or during the condensation reaction. The opposite end of the mature chromosome is created by a cut made in the DNA after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here the identification of a consensus nucleotide sequence for the pac site, and present evidence that supports the idea that the gene 3 protein is a central participant in this recognition event. In addition, we tentatively locate the portion of the gene 3 protein that contacts the pac site during the initiation of packaging.

DNA packaging initiation of Salmonella bacteriophage P22: determination of cut sites within the DNA sequence coding for gene 3

DNA packaging of Salmonella phage P22 starts at a defined site on a concatemer of P22 genomes. The molecular ends formed at the packaging initiation site (pac) map within a region of ca. 120 base pairs and may contain any of the four nucleotides at their 5' end. The determination of the positions of the cuts within the sequence demonstrates a characteristic distribution of cut sites which apparently cannot be attributed to the sequence organization of the involved regions. Symmetric elements of the sequence might serve as signals for a recognition event(s) at pac in a separate process preceding the cutting reaction. The region of packaging initiation is located within the sequence coding for gene 3. The 3 protein is responsible for the site specificity of this process. We find no significant homology to Nu1 protein, which appears to have an analogous or similar function in the DNA maturation of Escherichia coli phage lambda.

Isolation and characterization of bacteriophage T3/T7 hybrids and their use in studies on molecular basis of DNA-packaging specificity

In vitro DNA-packaging systems of bacteriophages T3 and T7 packaged homologous DNA more efficiently than heterologous DNA. Packaging of phage DNA proceeds by way of concatemeric intermediates (H. Fujisawa, J. Miyazaki, and T. Minagawa (1978), Virology 87, 394-400). The conversion of mature homologous and heterologous DNAs to concatemers was efficient in both the T3- and T7-packaging systems. In vitro complementation experiments indicate that the gene 19 product (gp19) specifies which DNA enters the capsid. To identify DNA regions recognized by the packaging systems, T3/T7 hybrids were constructed and physical maps of the hybrid DNAs were determined by restriction enzyme analysis. By comparing restriction maps and in vitro packaging of hybrid DNAs, it is concluded that the sequence responsible for specificity of DNA packaging is confined within 5% of the ends of the T3 and T7 genomes.

A late gene product of phage P22 affecting virus infectivity

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

pac sites are indispensable for in vivo packaging of DNA by phage P22

F' pro+ plasmids were selected and used as donors to prepare P22 transducing phages. Two types of result were observed. pro+ from type I donors cannot be packaged by wild-type P22 to yield transducing particles unless a prophage pac site is introduced into the plasmid. Transposon Tn10 also allows initiation of packaging. pro+ from type II plasmids can be transduced with the same efficiency as pro+ DNA on the chromosome, indicating that a chromosomal pac site was included when the F' pro+ was excised from the Hfr strain. The usefulness of type I plasmids as a test substrate for pac signals is discussed.

Steps in the stabilization of newly packaged DNA during phage P22 morphogenesis

The protein products of three adjacent P22 genes, 4, 10 and 26, are required for the stabilization of DNA newly packaged into P22 phage capsids. We have isolated unstable DNA containing capsids from cells infected with mutants defective in these genes. All three classes could be converted into mature phage in vitro, confirming that they represent intermediates in particle maturation. The first of the three proteins to add to the newly filled capsids is gp4, followed by gp10 and gp26. The active form of gp4 sediments at 3 S, while the active forms of both gp10 and gp26 sediment at 5 S. These soluble subunits appear to polymerize onto the newly filled capsids to form the neck of the mature phage, the channel for DNA injection. Since gp4 is the first protein to act after DNA packaging, the unstable DNA containing capsids from 4- -infected cells must represent the direct product of the packaging of DNA into procapsids. The major fraction of these capsids lost activity with a half-life of 1.1 minutes at 23 degrees C, though they were much more stable at 0 degree C. Electron microscopic observations indicated that the loss of activity was due to the DNA exiting from the incomplete capsids. The marginal stability of the condensed DNA molecules within capsids is consistent with models of ATP-driven condensation and spontaneous DNA ejection. The basis of the stability of these highly condensed molecules remains to be determined.

In vitro packaging of mature phage DNA by Salmonella phage P22

Mature, headful-sized DNA extracted from the Salmonella phages P22 and L, and P22/L-hybrid phages can be encapsulated in vitro by means of a packaging system for exogenous DNA. The probability of packaging reaches about 10(-3) per headful-sized molecule. The absence of in vitro recombination was demonstrated, to eliminate the possibility that such a process had created concatemers. The endonucleolytic cut at the pac site, which initiates sequential packaging in vivo, does not occur with the mature DNA substrate in vitro. The position of pac on the molecule is not important but the pac-recognizing phage protein gp3 is indispensable for in vitro encapsulation.

Physical and genetical analysis of bacteriophage T4 generalized transduction

This report describes a comparison of the efficiency of transduction of genes in E. coli by the generalized transducing bacteriophages T4GT7 and P1CM. Both phages are capable of transducing many genetic markers in E. coli although the frequency of transduction for particular genes varies over a wide range. The frequency of transduction for most genes depends on which transducing phage is used as well as on the donor and recipient bacterial strains. Analysis of T4GT7 phage lysates by cesium chloride density gradient centrifugation shows that transducing phage particles contain primarily bacterial DNA and carry little, if any, phage DNA. In this regard transducing phages P1CM and T4GT7 are similar; both phages package either bacterial or phage DNA but not both DNAs into the same particle.

On the sequential packaging of bacteriophage P22 DNA

Bacteriophage P22 is thought to package daughter chromosomes serially along concatemeric DNA. We present experiments which show that the average DNA packaging series length increases with time after infection, which supports this model. In addition, we have analyzed the effect on average series length of lowering the amount of the various individual proteins involved in DNA packaging. These results support the notion that the protein products of gene 2 and gene 3 are both more stringently required for initiation of sequential DNA packaging series than for their extension, and they are compatible with a model for the control of series length in which that length is determined, at least in part, by a competition between series initiation events and extension events.

Additional restriction endonuclease cleavage sites on the bacteriophage P22 genome

We present complete restriction endonuclease cleavage site maps of the bacteriophage P22 chromosome for 16 enzymes with six base recognition sequences, thereby positioning 116 new sites on the chromosome. Twenty-four such restriction maps for P22 DNA, containing 162 sites, have now been completed, and three enzymes were found that did not cut P22 DNA. Our results are consistent with the ideas that ClaI does not cleave the methylated recognition sequence ATCGA(me)T or A(me)TCGAT and StuI does not cleave the methylated recognition sequence AGGCC(me)T.