Purification and characterization of bacteriophage P22 Xis protein

The temperate bacteriophages λ and P22 share similarities in their site-specific recombination reactions. Both require phage-encoded integrase (Int) proteins for integrative recombination and excisionase (Xis) proteins for excision. These proteins bind to core-type, arm-type, and Xis binding sites to facilitate the reaction. λ and P22 Xis proteins are both small proteins (λ Xis, 72 amino acids; P22 Xis, 116 amino acids) and have basic isoelectric points (for P22 Xis, 9.42; for λ Xis, 11.16). However, the P22 Xis and λ Xis primary sequences lack significant similarity at the amino acid level, and the linear organizations of the P22 phage attachment site DNA-binding sites have differences that could be important in quaternary intasome structure. We purified P22 Xis and studied the protein in vitro by means of electrophoretic mobility shift assays and footprinting, cross-linking, gel filtration stoichiometry, and DNA bending assays. We identified one protected site that is bent approximately 137 degrees when bound by P22 Xis. The protein binds cooperatively and at high protein concentrations protects secondary sites that may be important for function. Finally, we aligned the attP arms containing the major Xis binding sites from bacteriophages λ, P22, L5, HP1, and P2 and the conjugative transposon Tn916. The similarity in alignments among the sites suggests that Xis-containing bacteriophage arms may form similar structures.     

Tailspike Interactions with Lipopolysaccharide Effect DNA Ejection from Phage P22 Particles in Vitro

Initial attachment of bacteriophage P22 to the Salmonella host cell is known to be mediated by interactions between lipopolysaccharide (LPS) and the phage tailspike proteins (TSP), but the events that subsequently lead to DNA injection into the bacterium are unknown. We used the binding of a fluorescent dye and DNA accessibility to DNase and restriction enzymes to analyze DNA ejection from phage particles in vitro. Ejection was specifically triggered by aggregates of purified Salmonella LPS but not by LPS with different O-antigen structure, by lipid A, phospholipids, or soluble O-antigen polysaccharide. This suggests that P22 does not use a secondary receptor at the bacterial outer membrane surface. Using phage particles reconstituted with purified mutant TSP in vitro, we found that the endorhamnosidase activity of TSP degrading the O-antigen polysaccharide was required prior to DNA ejection in vitro and DNA replication in vivo. If, however, LPS was pre-digested with soluble TSP, it was no longer able to trigger DNA ejection, even though it still contained five O-antigen oligosaccharide repeats. Together with known data on the structure of LPS and phage P22, our results suggest a molecular model. In this model, tailspikes position the phage particles on the outer membrane surface for DNA ejection. They force gp26, the central needle and plug protein of the phage tail machine, through the core oligosaccharide layer and into the hydrophobic portion of the outer membrane, leading to refolding of the gp26 lazo-domain, release of the plug, and ejection of DNA and pilot proteins.     

Regulation of Bacteriophage P22 DNA synthesis and repressor levels in P22cly infections.

A rifampin-resistant mutant of Salmonella typhimurium carries an altered RNA polymerase. Wild-type (c+) phage P22 displays clear plaques and a reduced lysogenization frequency on this mutant host. The cly mutants of P22 were isolated on the basis of their ability to lysogenize such mutant hosts. Two classes of regulatory events, both of which are dependent on P22 gene c1 activity, are necessary for the establishment of lysogeny in P22. The positive events culminate in repressor synthesis; the negative events cause a retardation in phage DNA synthesis. Neither the positive nor the negative events are observed in P22c+ infections of the mutant host. Both effects are found in P22cly infections of the mutant host. Observable results of both the negative and the positive events are exaggerated in P22cly infections of wild-type hosts as compared to P22c+ infections. The cly mutation apparently increases the positive and negative regulatory events so that they are detectable in the mutant host and exaggerated in wild-type hosts. Possible mechanisms that result in the high frequency of lysogenization that characterizes the cly mutation and the nature of the cly mutation are discussed.     

Identification of the 9-aminoacridine/DNA complex responsible for photodynamic inactivation of P22

Acridine dyes bound to the condensed DNA within phage particles sensitize them to inactivation by visible light. The mechanism involves absorption of photons by an acridine/DNA complex, generating singlet oxygen, which covalently damages nearby proteins needed for DNA injection [Bryant, J., & King, J. (1985) J. Mol. Biol. 180, 837-863]. Acridines and related dyes interact with double-stranded DNA through a number of binding modes. To determine in condensed phage DNA the binding mode responsible for this inactivation, we have studied the formation of the DNA/acridine target complexes for photoinactivation. Analysis of the kinetics of 9-aminoacridine binding to Salmonella phage P22 particles revealed the formation of two binding species, one of which appeared more rapidly and was apparently an intermediate in the formation of the second. The rapidly forming species represented DNA sites with intercalated acridines, while the more slowly forming species represented the subsequent binding of additional acridine molecules to the DNA backbone of sites already containing intercalated dye. The rates of photoinactivation correlated with the rate of binding of 9-aminoacridine to the DNA backbone. This suggests that the most effective species for sensitizing phage to light-induced damage has acridine molecules stacked alongside the backbone of a region with intercalated molecules.     

Oligopeptidase A is required for normal phage P22 development.

The opdA gene of Salmonella typhimurium encodes an endoprotease, oligopeptidase A (OpdA). Strains carrying opdA mutations were deficient as hosts for phage P22. P22 and the closely related phages L and A3 formed tiny plaques on an opdA host. Salmonella phages 9NA, KB1, and ES18.h1 were not affected by opdA mutations. Although opdA strains displayed normal doubling times and were infected by P22 as efficiently as opdA+ strains, the burst size of infectious particles from an opdA host was less than 1/10 of that from an opdA+ host. This decrease resulted from a reduced efficiency of plating of particles from an opdA infection. In the absence of a functional opdA gene, most of the P22 particles are defective. To identify the target of OpdA action, P22 mutants which formed plaques larger than wild-type plaques on an opdA mutant lawn were isolated. Marker rescue experiments using cloned fragments of P22 DNA localized these mutations to a 1-kb fragment. The nucleotide sequence of this fragment and a contiguous region (including all of both P22 gene 7 and gene 14) was determined. The mutations leading to opdA independence affected the region of gene 7 coding for the amino terminus of gp7, a protein required for DNA injection by the phage. Comparison of the nucleotide sequence with the N-terminal amino acid sequence of gp7 suggested that a 20-amino-acid peptide is removed from gp7 during phage development. Further experiments showed that this processing was opdA dependent and rapid (half-life, less than 2 min) and occurred in the absence of other phage proteins. The opdA-independent mutations lead to mutant forms of gp7 which function without processing.     

The Tip of the Tail Needle Affects the Rate of DNA Delivery by Bacteriophage P22

The P22-like bacteriophages have short tails. Their virions bind to their polysaccharide receptors through six trimeric tailspike proteins that surround the tail tip. These short tails also have a trimeric needle protein that extends beyond the tailspikes from the center of the tail tip, in a position that suggests that it should make first contact with the host’s outer membrane during the infection process. The base of the needle serves as a plug that keeps the DNA in the virion, but role of the needle during adsorption and DNA injection is not well understood. Among the P22-like phages are needle types with two completely different C-terminal distal tip domains. In the phage Sf6-type needle, unlike the other P22-type needle, the distal tip folds into a “knob” with a TNF-like fold, similar to the fiber knobs of bacteriophage PRD1 and Adenovirus. The phage HS1 knob is very similar to that of Sf6, and we report here its crystal structure which, like the Sf6 knob, contains three bound L-glutamate molecules. A chimeric P22 phage with a tail needle that contains the HS1 terminal knob efficiently infects the P22 host, Salmonella enterica, suggesting the knob does not confer host specificity. Likewise, mutations that should abrogate the binding of L-glutamate to the needle do not appear to affect virion function, but several different other genetic changes to the tip of the needle slow down potassium release from the host during infection. These findings suggest that the needle plays a role in phage P22 DNA delivery by controlling the kinetics of DNA ejection into the host.     

Inhibitory Effect of Bacteriophage P22 Infection on Host Cell Deoxyribonuclease Activity

Infection of Salmonella typhimurium with phage P22 causes a decrease in the activity of host deoxyribonuclease which degrades single-stranded deoxyribonucleic acid (DNA). This decrease is reversed when the infecting phage is P22c(+); it is not reversed if the infecting phage kills the cell. The decrease does not occur in infections with P22ts25.1 (which only adsorbs and injects DNA) or in infections of a lysogen by a nonvirulent phage. It does occur, however, after infections with other phages which are blocked in phage DNA synthesis. Inhibiting protein synthesis with chloramphenicol does not in itself cause the decrease in uninfected cells, but it does prevent infected cells from showing this effect.     

Selective transduction of recombinant plasmids with cloned pac sites by Salmonella phage P22

Summary Recombinant plasmids having PstI fragments of P22 DNA inserted in the vector pBR322 can be transduced efficiently by Salmonella phage P22, irrespective of the cloned phage sequences. When the rec function of the donor cells and the corresponding recombination system erf of the infecting phage are simultaneously inactivated, only plasmids containing the P22 pac site can be transduced. By this selective, generalized transduction an EcoRV DNA fragment of the P22 related phage L has been identified that carries a base sequence recognized by phage P22 as a packaging signal. Experiments in which only one of the two recombination systems was inactivated, showed that the bacterial rec system obviously promotes cointegrate formation between plasmid and phage DNA much more efficiently than the phage-coded erf system, allowing the specialized plasmid transduction observed by Orbach and Jackson (1982).     

Dimerization specificity of P22 and 434 repressors is determined by multiple polypeptide segments.

The repressor protein of bacteriophage P22 binds to DNA as a homodimer. This dimerization is absolutely required for DNA binding. Dimerization is mediated by interactions between amino acids in the carboxyl (C)-terminal domain. We have constructed a plasmid, p22CT-1, which directs the overproduction of just the C-terminal domain of the P22 repressor (P22CT-1). Addition of P22CT-1 to DNA-bound P22 repressor causes the dissociation of the complex. Cross-linking experiments show that P22CT-1 forms specific heterodimers with the intact P22 repressor protein, indicating that inhibition of P22 repressor DNA binding by P22CT-1 is mediated by the formation of DNA binding-inactive P22 repressor:P22CT-1 heterodimers. We have taken advantage of the highly conserved amino acid sequences within the C-terminal domains of the P22 and 434 repressors and have created chimeric proteins to help identify amino acid regions required for dimerization specificity. Our results indicate that the dimerization specificity region of these proteins is concentrated in three segments of amino acid sequence that are spread across the C-terminal domain of each of the two phage repressors. We also show that the set of amino acids that forms the cooperativity interface of the P22 repressor may be distinct from those that form its dimer interface. Furthermore, cooperativity studies of the wild-type and chimeric proteins suggest that the location of cooperativity interface in the 434 repressor may also be distinct from that of its dimerization interface. Interestingly, changes in the dimer interface decreases the ability of the 434 repressor to discriminate between its wild-type binding sites, O(R)1, O(R)2, and O(R)3. Since 434 repressor discrimination between these sites depends in large part on the ability of this protein to recognize sequence-specific differences in DNA structure and flexibility, this result indicates that the C-terminal domain is intimately involved in the recognition of sequence-dependent differences in DNA structure and flexibility.     

Control of the Replication Complex of Bacteriophage P22

A replication complex for the vegetative synthesis of the deoxyribonucleic acid (DNA) of the temperate phage P22 previously has been described. This complex is an association of parental phage DNA, most of the newly synthesized phage DNA made during pulses with (3)H-thymidine, and other cell constituents, and has a sedimentation rate in neutral sucrose gradients of at least 1,000S. The complex is one of the intermediates, intermediate I, in the synthesis and maturation of phage P22 DNA after infection or induction. Evidence supporting the replicative nature of intermediate I is presented. Phage replication is repressed in lysogenic bacteria. On superinfection of P22 lysogens with nonvirulent phage, little association of the input phage DNA with a rapidly sedimenting fraction is demonstrable. However, after induction with ultraviolet light, the superinfecting parental phage DNA quickly acquires the rapid sedimentation rate characteristic of intermediate I; phage DNA synthesis follows; and progeny phages are produced. Infection with a virulent mutant of P22 produces progeny phages in lysogens. Its DNA associates with intermediate I. In mixed infection with the virulent phage, replication of nonvirulent phage P22 is still repressed, even though the virulent replicates normally. The nonvirulent input DNA does not associate with intermediate I. The repressor of the lysogenic cell prevents replication by interfering with the physical association of template material with intermediate I. A phage function is required for association of phage template with the replication machinery.     

Oligonucleotide synthesis by Escherichia coli dnaG primase in conjunction with phage P22 gene 12 protein

The phage P22 gene 12 protein was found to be like the Escherichia coli dnaB protein in that it stimulated phiX174 DNA synthesis in heat-inactivated extracts of dnaB temperature-sensitive cells (see preceding paper, Wickner, S. (1984) J. Biol. Chem. 259, 14038-14043). phiX174 replication catalyzed by the purified P22 12 protein also by-passed the normal requirement for dnaC protein. However, synthesis still required dnaG primase and the DNA polymerase III holoenzyme components. This DNA synthesis reaction has been reconstituted with purified proteins and found to require P22 12 protein, dnaG protein, DNA polymerase III holoenzyme components, 4 dNTPs, Mg2+, any one of ATP, GTP, UTP, or CTP and single-stranded DNA. The reaction has been dissected into partial reactions: (a) in a prepriming reaction, P22 12 protein binds to single-stranded DNA in an ATP-dependent reaction (Wickner, S. (1984) J. Biol. Chem. 259, 14038-14043); (b) in a priming reaction requiring at least one rNTP and the other dNTPs or rNTPs, dnaG primase catalyzes oligonucleotide synthesis dependent on the P22 12 protein-DNA complex; (c) finally, DNA polymerase III holoenzyme components catalyze DNA elongation of the primer.     

DNA injection proteins are targets of acridine-sensitized photoinactivation of bacteriophage P22

Viruses and other nucleoprotein complexes are inactivated on exposure to white light in the presence of acridine and related dyes. The mechanism is thought to involve generation of singlet oxygen or related species, but the actual molecular targets of the inactivating event have not been well defined. We have re-examined the mechanism of dye-sensitized photoinactivation taking advantage of the well characterized bacteriophage P22. Though the inactivated phage absorb to their host cells, the cells are not killed and genetic markers cannot be rescued from the inactivated phage. These observations indicate that the chromosome is not injected into the host cell. However, the DNA of the damaged particles shows no evidence of double-stranded breaks or crosslinking.The DNA injection process of P22 requires three particle-associated proteins, the products of genes 7, 16 and 20. Gp16, which can act in trans during injection, is inactivated in the killed particles. Sodium dodecyl sulfate/polyacrylamide gel analysis reveals that gp16, gp7 and gp20 are progressively covalently damaged during photoinactivation. However, this damage does not occur in particles lacking DNA, indicating that it is DNA-mediated. Similar findings were obtained with acridine orange, acridine yellow, proflavin and acriflavin.These results indicate that the actual targets for inactivation are the DNA injection proteins, and that the lethal events represent absorption of photons by acridine molecules stacked in a region of DNA closely associated with the injection proteins.     

Purification and properties of phage P22 c2 repressor.

The c2 repressor of phage P22 has been purified to homogeneity. It specifically binds to lambdaimm21 and P22 DNA. Its affinity for the presumed operator mutant P22 virB is reduced. The initial dissociation rates of the complex between c2 repressor and lambdaimm21 DNA are 0.02 min-1 at 0 degrees C, 0.08 min-1 at 20 degrees C and 0.17 min-1 at 32 degrees C. The dissociation rates of complexes formed between the c2 repressor and the lambdaimm21 operators OR, OL and OR vira were measured and compared to the corresponding rates obtained with 21 cI repressor.     

Host RecJ is required for growth of P22 erf bacteriophage.

Growth of bacteriophage P22 erf is known to require host RecA recombination function. We show that the RecA function is necessary but not sufficient to restore the plaque-forming ability of phage P22 erf; such mutant phage also requires host RecJ function. The residual efficiency of plaquing of P22 erf in a recJ background (0.03%) is completely abolished in recJ recB hosts (< 0.001%), suggesting that the RecBCD nuclease can provide an alternative function allowing phage growth. One tentative explanation is that circularization of P22 erf DNA mostly proceeds through the RecF pathway of recombination; however, less efficient circularization via the RecBCD pathway may also occur. In a recJ background, lysates obtained upon induction of an erf prophage show reduced yield (10%), suggesting that growth of P22 erf may require host RecJ in a step(s) other than circularization of phage DNA.     

UV sensitivity of a nonrepressor regulatory protein of bacteriophage P22.

The product of phage P22 gene c1 has two functions: it promotes synthesis of P22 repressor and it retards expression of some lytic genes. We present evidence that this product is inactivated in UV-irradiated hosts. The conditions for inactivation of c1 product include a functional DNA recombination system involving the host recA gene.     

Comparison of permuted region lengths in the genomes of relatedSalmonella typhimurium phages P22 and L

Lengths of permuted regions in the P22 and L phage genomes were estimated from the relative yields of DNA in many electrophoretic bands obtained using several restriction endonucleases. It was found that 3.6 kb (8.7%) of P22-DNA and 7.2 kb (17.8%) of L-DNA were circularly permuted. In both phages the sequential packaging process proceeded in the same direction and four headful-size DNA molecules were, on the average, cleaved in one packaging series. The differences in circular permutation may originate from different genome lengths because their average headful portions are very similar (42.5 kb in P22 and 42.3 kb in L).     

Interaction of DNA with DNA-binding proteins: protein exchange and complex stability.

The competition of the DNA-binding proteins I and II of Escherichia coli and of the phage fd DNA-binding protein for single-stranded DNA was investigated. Their roles in cells might be judged from their binding affinities to DNA and their mutual exchange in the DNA . protein complexes. Strongest binding on single strands was found for the phage protein. DNA-binding protein II displaced half of the protein I in the complex with single-stranded DNA when no double-stranded DNA was present. Protein-complexed single strands were protected against degradation. The protection is less pronounced for protein II which can increase the stability of the fd DNA complex with DNA-binding protein I against nucleolytic cleavage.     

A Salmonella Phage-P22 Mutant Defective in Abortive Transduction

In the course of a lytic infection the Salmonella phage P22 occasionally encapsulates bacterial DNA instead of phage DNA. Thus, phage lysates include two classes of viral particles. Phage particles carrying bacterial DNA are referred to as transducing particles and deliver this DNA to a host as efficiently as particles carrying phage DNA. Once injected, the transduced DNA can either recombine with the recipient chromosome to form a ``complete'''' transductant, or it can establish itself as an expressible, nonreplicating genetic element and form an ``abortive'''' transductant. In this work, we describe a P22-phage mutant with reduced ability to form abortive transductants. The mutation responsible for this phenotype, called tdx-1, was found as one of two mutations contributing to the high-transducing phenotype of the P22-mutant HT12/4. In addition, the tdx-1 mutation is lethal when combined with an erf-am mutation. The tdx-1 mutation has been mapped to a region of the P22 genome that encodes several injected proteins and may involve more than one mutant locus. The phenotypes of the tdx-1 mutation suggest that the Tdx protein(s) normally assist in the circularization of the P22 genome and also contribute to the formation of DNA circles thought to be required for abortive transduction.     

A Novel P22 Prophage in Salmonella typhimurium

Under several sets of conditions, all of which seem to perturb purine metabolism, Salmonella typhimurium releases a variety of phages which were not known to be present in the strain. These cryptic phages are not induced by UV irradiation. Furthermore, the induction process does not require a functional recA gene product. While phages of several phenotypic classes have been recovered, including both turbid and clear plaque formers, all appear to be variants of P22 because all show DNA restriction patterns indistinguishable from that of P22. The variety of types suggests that the cryptic prophage is mutagenized as a consequence of the induction process. All the temperature phages tested are capable of transducing a variety of chromosomal markers with high efficiency. The phages induced in this novel way are capable of forming plaques on the strains that gave rise to them. Since the strains releasing phage are not immune to P22, the parental lysogens must not express immunity and the phage must be held in a cryptic state by a novel mechanism. The released phage possess an intact P22 immunity system because many can form standard immune lysogens after reinfection of Salmonella. These results raise the possibility that Salmonella typhimurium harbors cryptic phages that are subject to a novel system of global control related to purine metabolism. Preliminary evidence suggests that the regulation system may involve DNA modification.