Characterization of T-Even Bacteriophage Substructures: II. Tail Plates

Tail plates obtained from T4D amber mutants were examined with respect to sedimentation behavior, subunit molecular weights, amino acid composition, isoelectric points, and morphology. Intact plates had an S_20,w of 77S from pH 5 to 9. The only conformational change noted was that below pH 5 tail plates readily dimerized yielding vis-à-vis dimers with an S_20,w of 124S. Dissociated plates consisted of three major proteins with molecular weights of 53 K ± 5, 31 K ± 3, and 17 K ± 2 daltons. The amino acid analyses indicated that plates had a composition distinct from fibers and tubes and were relatively rich in tryptophan. Degradation studies with dimethyl sulfoxide (DMSO) indicated that tail plates had a unique biological structure. After treatment with DMSO, and to some extent without DMSO, or from lysates of defective mutants, tetrad structures were observed in the electron microscope. These structures had an amino acid content and relative amounts of types of subunits similar but not identical to intact plates. It was proposed that plates were composed of nine such tetrads giving rise to a structure with six- and threefold symmetry.     

Bacteriophage Tail Components: I. Pteroyl Polyglutamates in T-Even Bacteriophages

A pteroylpolyglutamate has been found to be a constituent of all Escherichia coli T-even bacteriophages and has been characterized with regard to its oxidation state, molecular weight, origin, and location on the phage particle. The phage compound has been shown to be a dihydropteroyl penta- or hexaglutamate on the basis of its chemical and physical properties. Analyses of extracts of uninfected and T2L-infected E. coli have indicated that the phage dihydropteroyl polyglutamate was present only in infected cells. Its synthesis was sensitive to the addition of chloramphenicol before infection, and the compound appeared to be specifically induced by phage infection. Analyses of isolated phage ghosts and tail substructures have shown that each phage particle contains between two and six phage-specific pteroyl derivatives and that the juncture of the phage tail plate with the tail tube is the most likely site of binding of the phage-induced pteroyl compound.     

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

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

Template Properties of Glucose-Deficient T-Even Bacteriophage DNA

The vegetative DNA isolated from T4-infected Escherichia coli W4597 (UDPG PPase(-)) was about two to six times more active in stimulating protein synthesis in cell-free extracts than that isolated from T4-infected E. coli B06. This suggested that nonglucosylated vegetative DNA may be a better template than the glucosylated form. This view was supported by experiments measuring RNA synthesis on mature T-even DNAs with a range of glucose contents. The extent of (14)C-GTP polymerization was inversely proportional to the glucose content of the DNA. Differences were also observed in both the kind and quantity of polypeptides produced in response to these DNAs.     

T-Even Bacteriophage-Tolerant Mutants of Escherichia coli B: I. Isolation and Preliminary Characterization

A general procedure is described for isolation of T-even phage-tolerant mutants of Escherichia coli. Two such mutants of E. coli B have been examined in some detail. These mutants adsorb T-even phages but are unable to release viable progeny. Under certain conditions, viability of the cells is completely unaffected by phage infection in one mutant, and there is but a slight decrease in colony-forming ability in the other. Phage deoxyribonucleic acid (DNA) is injected into these cells, as shown by the formation of phage-specific enzymes, but it is not degraded to acid-soluble material. Some phage DNA replication occurs in both strains. The mutants are both more resistant to ultraviolet light than is the parent strain.     

Structural Characterization of the Bacteriophage T7 Tail Machinery

Most bacterial viruses need a specialized machinery, called “tail,” to inject their genomes inside the bacterial cytoplasm without disrupting the cellular integrity. Bacteriophage T7 is a well characterized member of the Podoviridae family infecting Escherichia coli, and it has a short noncontractile tail that assembles sequentially on the viral head after DNA packaging. The T7 tail is a complex of around 2.7 MDa composed of at least four proteins as follows: the connector (gene product 8, gp8), the tail tubular proteins gp11 and gp12, and the fibers (gp17). Using cryo-electron microscopy and single particle image reconstruction techniques, we have determined the precise topology of the tail proteins by comparing the structure of the T7 tail extracted from viruses and a complex formed by recombinant gp8, gp11, and gp12 proteins. Furthermore, the order of assembly of the structural components within the complex was deduced from interaction assays with cloned and purified tail proteins. The existence of common folds among similar tail proteins allowed us to obtain pseudo-atomic threaded models of gp8 (connector) and gp11 (gatekeeper) proteins, which were docked into the corresponding cryo-EM volumes of the tail complex. This pseudo-atomic model of the connector-gatekeeper interaction revealed the existence of a common molecular architecture among viruses belonging to the three tailed bacteriophage families, strongly suggesting that a common molecular mechanism has been favored during evolution to coordinate the transition between DNA packaging and tail assembly.     

Bacteriophage SPO1 structure and morphogenesis. I. Tail structure and length regulation.

Bacteriophage SPO1, a structually complex phage with hydroxymethyl uracil replacing thymine, has been studied by structural and chemical methods with the aim of defining the virion organization. The contractile tail of SPO1 consists of a complex baseplate, a tail tube, and a 140-nm-long sheath composed of stacked disks (4.1 nm repeat), each containing six subunits of molecular weight 60,300. The subunits are arranged in six parallel helices, each with a helical screw angle (omega 0) of 22.5 degrees. The baseplate was shown to undergo a structural rearrangement during tail contraction into a hexameric pinwheel. A mutation in gene 8 which produced unattached heads and tails also produced tails of different lengths. The tail length distribution suggests that the smallest integral length increment is a single disk of subunits. The structural arrangement of subunits in long tails is identical to that of normal tails, and the tails can contract. Many of the long tails showed partial stain penetration within the tail tube to a point which coincides with the top of a unit-length tail. The implications of these findings with respect to tail length regulation are discussed.     

Breakdown and Exclusion of Superinfecting T-Even Bacteriophage in Escherichia coli

In bacterial strains containing the deoxyribonuclease endonuclease I (endonuclease I(+) strains), 70 to 80% of the injected superinfecting T-even phage deoxyribonucleic acid (DNA) is rapidly degraded to oligonucleotides having an average chain length of 8, the same value as that obtained by endonuclease I digestion of purified T-even phage DNA in vitro. In endonuclease I(-) strains, less than 5% of the injected superinfecting T-even phage DNA is degraded to acid-soluble components. The superinfecting phage DNA is, however, fragmented into a large segment having a molecular weight of about 90 x 10(6) and 30 or more small acid-insoluble segments having molecular weights of less than 10(6). In both endonuclease I(+) and endonuclease I(-) strains, over 80% of the DNA from adsorbed primary T2 or T4 phage, but only 50% of the DNA from adsorbed superinfecting T2 or T4 phage, is injected. Superinfecting T4 are genetically excluded as efficiently from endonuclease I(-) strains as they are from endonuclease I(+) strains. The excluded phage cannot complement defects in either early or late gene functions carried by the primary phage. The induction of both superinfection breakdown and superinfection exclusion requires a period of protein synthesis between primary infection and addition of the superinfecting phage. These observations seem best explained by failure of superinfecting DNA to enter the host cell cytoplasm, presumably as a result of changes in the cell envelope induced by the primary phage.     

Structural Aberrations in T-Even Bacteriophage IV. Parameters of Induction and Formation of Lollipops

Previous results from our laboratory have shown that when a T-even bacteriophage-infected bacterial cell was exposed to l-canavanine followed by an l-arginine chase, a monster phage particle, termed a lollipop, was formed. We now describe certain parameters concerning (i) the induction and (ii) the formation of T4 lollipops. The induction step involves a T4 late function, and can require only a 3-min exposure to l-canavanine. Short pulses of l-canavanine result in the formation of shorter lollipops indicating the presence of a possible "precursor substance" which is influenced by l-canavanine. DNA synthesis is inhibited by l-canavanine but is stimulated 20 to 40 min after the addition of l-arginine. Chloramphenicol prevents both responses indicating a possible protein involvement. The appearance of lollipops and phage was noted only after 25 min after the addition of l-arginine.     

Bacteriophage Tail Components: II. Dihydrofolate Reductase in T4D Bacteriophage

The protein component of the T-even bacteriophage coat which binds the phage-specific dihydropteroyl polyglutamate has been identified as the phage-induced dihydrofolate reductase. Dihydrofolate reductase activity has been found in highly purified preparations of T-even phage ghosts and phage substructures after partial denaturation. The highest specific enzymatic activity was found in purified tail plate preparations, and it was concluded that this enzyme was a structural component of the phage tail plate. Phage viability was directly correlated with the enzymological properties of the phage tail plate dihydrofolate reductase. All reactions catalyzed by this enzyme which changed the oxidation state of the phage dihydrofolate also inactivated the phage. Properties of two T4D dihydrofolate reductase-negative mutants, wh1 and wh11, have been examined. Various lines of evidence support the view that the product of the wh locus of the phage genome is normally incorporated into the phage tail structure. The effects of various dihydrofolate reductase inhibitors on phage assembly in in vitro complementation experiments with various extracts of conditional lethal T4D mutants have been examined. These inhibitors were found to specifically block complementation when added to extracts which did not contain preformed tail plates. If tail plates were present, inhibitors such as aminopterin, did not affect further phage assembly. This specific inhibition of tail plate formation in vitro confirms the analytical and genetic evidence that this phage-induced "early" enzyme is a component of the phage coat.     

A Remeasurement of the Molecular Weights of T-Even Bacteriophage Substructural Proteins

T-even bacteriophage substructural proteins were studied by using discontinuous sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It was found that tail fibers are composed of two major proteins of 155,000 and 120,000 daltons molecular weight and four minor proteins of 51,000, 38,000, 27,000, and 23,000 daltons. Tail tubes were composed of one predominant protein of 18,500 daltons and one minor protein of 35,000 daltons molecular weight. Tubular polyheads obtained from a T4D amber mutant and by treatment of T4B-infected cells with L-canavanine were also examined, and no significant differences were noted in the molecular weight of the P23 protein.     

Head Proteins from T-Even Bacteriophages II. Physical and Chemical Characterization

Three classes of structural head proteins, having molecular weights of 43,000, 18,000, and 11,000 daltons, were isolated from the T-even bacteriophages and were characterized. Based on electrophoretic studies, the 43,000-dalton class contained one major protein and one (or two) minor components, the 18,000-dalton class contained two protein components, and the 11,000-dalton class contained one major component. The N-terminal residues for the 43,000- and the 11,000-dalton classes were alanine, and the N-terminal residues for the 18,000-dalton class were methionine and alanine. Of the three classes of proteins, the 18,000-dalton proteins were the most acidic, whereas the 11,000-dalton proteins were the most basic. The amino acid composition of the 11,000-dalton class revealed that methionine and cysteine were absent and lysine, histidine, and tryptophan content was higher in the 11,000-dalton class than in the other two classes of proteins. Estimates of the relative number of the three classes of structural proteins were made and indicated that there were between 1,600 and 2,000 subunits of the 43,000-dalton proteins, 100 to 200 of the 18,000-dalton proteins, and 1,000 to 1,500 of the 11,000-dalton proteins. Evidence was presented that the 43,000-dalton proteins and the 11,000-dalton proteins readily formed aggregates with themselves but not with each other. The significance of these interactions to the structure of the T-even phage head was discussed.     

Basic Characterization of a Pseudomonas aeruginosa Pilus-Dependent Bacteriophage with a Long Noncontractile Tail

Bacteriophage PO4 has been found to depend on the presence of pili for the infection of its host organism, Pseudomonas aeruginosa. Unlike other pilus phages, which either contain RNA and are "spherical" or contain single-stranded DNA and are filamentous, PO4 has a head and a long noncontractile tail. This paper describes its basic characters, and a quantitative study is made of its adsorption to exponential-phase cells of piliated and nonpiliated strains of P. aeruginosa. PO4 is found to contain double-stranded DNA and appears to be virulent towards its two host strains.     

Bacteriophage Tail Components: III. Use of Synthetic Pteroyl Hexaglutamate for T4D Tail Plate Assembly

The assembly of T4D tail plates occurring during in vitro complementation reactions was found to be stimulated by pteroyl hexaglutamate. Neither the pteroyl pentaglutamate nor the pteroyl heptaglutamate substituted for the hexaglutamate. A small stimulation of the rate and amount of T4D tail plate assembly was observed in untreated extracts. A greater stimulation occurred when activated charcoal-treated bacterial extracts were used. Charcoal treatment inhibited complementation only when no preformed tail plates were present in the extracts, and the inhibition was reversed by the addition of 9 x 10(-6)m chemically synthesized pteroyl hexaglutamate. The stimulation is apparently due to a requirement for the pteroyl hexaglutamate for tail plate assembly.     

Biogenesis of a Bacteriophage Long Non-Contractile Tail

Siphoviruses are main killers of bacteria. They use a long non-contractile tail to recognize the host cell and to deliver the genome from the viral capsid to the bacterial cytoplasm. Here, we define the molecular organization of the Bacillus subtilis bacteriophage SPP1 ~ 6.8 MDa tail and uncover its biogenesis mechanisms. A complex between gp21 and the tail distal protein (Dit) gp19.1 is assembled first to build the tail cap (gp19.1-gp21Nter) connected by a flexible hinge to the tail fiber (gp21Cter). The tip of the gp21Cter fiber is loosely associated to gp22. The cap provides a platform where tail tube proteins (TTPs) initiate polymerization around the tape measure protein gp18 (TMP), a reaction dependent on the non-structural tail assembly chaperones gp17.5 and gp17.5* (TACs). Gp17.5 is essential for stability of gp18 in the cell. Helical polymerization stops at a precise tube length followed by binding of proteins gp16.1 (TCP) and gp17 (THJP) to build the tail interface for attachment to the capsid portal system. This finding uncovers the function of the extensively conserved gp16.1-homologs in assembly of long tails. All SPP1 tail components, apart from gp22, share homology to conserved proteins whose coding genes’ synteny is broadly maintained in siphoviruses. They conceivably represent the minimal essential protein set necessary to build functional long tails. Proteins homologous to SPP1 tail building blocks feature a variety of add-on modules that diversify extensively the tail core structure, expanding its capability to bind host cells and to deliver the viral genome to the bacterial cytoplasm.     

Structural Aberrations in T-Even Bacteriophage V. Effects of Canavanine on the Maturation and Utilization of Specific Gene Products

Previous results have shown that when a T-even bacteriophage-infected cell was exposed to l-canavanine followed by an exposure to l-arginine, a monster phage particle, termed a lollipop, was formed. l-Canavanine was necessary for the induction event but l-arginine was required for the maturation of the particle. We now describe the effects of canavanine on the maturation of certain T4 proteins and their role in the induction of lollipops. The cleavage reactions of the head proteins P22, P23, P24, and IPIII are prevented by l-canavanine as shown by the accumulation of the precursor proteins and the failure of the cleaved products to appear. l-Canavanine also prevents the appearance of P12 (tailplate protein) and P20 (head protein) indicating that these proteins may undergo a proteolytic cleavage during normal assembly. The formation of P10 (tailplate protein) and P18 (tail sheath protein) is also affected by l-canavanine. The data suggest that P23 in conjunction with P20 plays a major role in the determination of the length of the phage head.     

Structure and Functions of the Bacteriophage P22 Tail Protein

The product of gene 9 (gp9) of Salmonella typhimurium bacteriophage P22 is a multifunctional structural protein. This protein is both a specific glycosidase which imparts the adsorption characteristics of the phage for its host and a protein which participates in a specific assembly reaction during phage morphogenesis. We have begun a detailed biochemical and genetic analysis of this gene product. A relatively straightforward purification of this protein has been devised, and various physical parameters of the protein have been determined. The protein has an s_20,w of 9.3S, a D_20,w of 4.3 × 10⁻⁷ cm²/s, and a molecular weight, as determined by sedimentation equilibrium, of 173,000. The purified protein appears as a prolate ellipsoid upon electron microscopic examination, with an axial ratio of 4:1, which is similar to the observed shape when it is attached to the phage particle. The molecular weight is consistent with the tail protein being a dimer of gp9 and each phage containing six of these dimers. An altered form of the tail protein has been purified from supF cells infected with a phage strain carrying an amber mutation in gene 9. Phage “tailed” with this altered form of gp9 adsorb to susceptible cells but form infectious centers with a severely reduced efficiency (ca. 1%). Biochemical analysis of the purified wild-type and genetically altered tail proteins suggests that loss of infectivity correlates with a loss in the glycosidase activity of the protein (2.5% residual activity). From these results we propose that the glycosidic activity of the P22 tail protein is not essential for phage assembly or adsorption of the phage to its host but is required for subsequent steps in the process of infection.     

Isolation and Characterization of a New T-Even Bacteriophage, CEV1, and Determination of Its Potential To Reduce Escherichia coli O157:H7 Levels in Sheep

Bacteriophage CEV1 was isolated from sheep resistant to Escherichia coli O157:H7 colonization. In vitro, CEV1 efficiently infected E. coli O157:H7 grown both aerobically and anaerobically. In vivo, sheep receiving a single oral dose of CEV1 showed a 2-log-unit reduction in intestinal E. coli O157:H7 levels within 2 days compared to levels in the controls.     

Isolation and Characterization of Two Basic Internal Proteins from the T-Even Bacteriophages

Two species of basic internal proteins were found in osmotic shock supernatant solutions of bacteriophages T4B, T4D, T2H, T2L, and T6. The major species of protein isolated had a molecular weight of approximately 21,000 daltons, whereas the minor protein molecular weight was near 9,500 daltons. The two protein species exhibited unique isoelectric points and amino acid compositions. The 21,000-dalton protein of T2L showed major electrophoretic and compositional differences from the other 21,000-dalton proteins isolated. Similarities between the 21,000-dalton proteins and phage lysozyme are discussed.