Purification and properties of gene 18 product of bacteriophage T3

A Pseudomonas Lysogenic Bacteriophage Crossing the Antarctic and Arctic, Representing a New Genus of Autographiviridae

Polar regions tend to support simple food webs, which are vulnerable to phage-induced gene transfer or microbial death. To further investigate phage-host interactions in polar regions and the potential linkage of phage communities between the two poles, we induced the release of a lysogenic phage, vB_PaeM-G11, from Pseudomonas sp. D3 isolated from the Antarctic, which formed clear phage plaques on the lawn of Pseudomonas sp. G11 isolated from the Arctic. From permafrost metagenomic data of the Arctic tundra, we found the genome with high-similarity to that of vB_PaeM-G11, demonstrating that vB_PaeM-G11 may have a distribution in both the Antarctic and Arctic. Phylogenetic analysis indicated that vB_PaeM-G11 is homologous to five uncultured viruses, and that they may represent a new genus in the Autographiviridae family, named Fildesvirus here. vB_PaeM-G11 was stable in a temperature range (4-40 °C) and pH (4-11), with latent and rise periods of about 40 and 10 min, respectively. This study is the first isolation and characterization study of a Pseudomonas phage distributed in both the Antarctic and Arctic, identifying its lysogenic host and lysis host, and thus provides essential information for further understanding the interaction between polar phages and their hosts and the ecological functions of phages in polar regions.

The coevolution of large and small terminases of bacteriophages is a result of purifying selection leading to phenotypic stabilization

Genome packaging in many dsDNA phages requires a series of precisely coordinated actions of two phage-coded proteins, namely, large terminase (TerL) and small terminase (TerS) with DNA and ATP, and with each other. Despite the strict functional conservation, TerL and TerS homologs exhibit large sequence variations. We investigated the sequence variability across eight phage types and observed a coevolutionary framework wherein the genealogy of TerL homologs mirrored that of the corresponding TerS homologs. Furthermore, a high purifying selection observed (dN/dS«1) indicated strong structural constraints on both TerL and TerS, and identify coevolving residues in TerL and TerS of phage T4 and lambda. Using the highly coevolving (correlation coefficient of 0.99) TerL and TerS of phage N4, we show that their biochemical features are similar to the phylogenetically divergent phage λ terminases. We also demonstrate using the Surface Plasma Resonance (SPR) technique that phage N4 TerL transiently interacts with TerS.

A T3 and T7 recombinant phage acquires efficient adsorption and a broader host range

It is usually thought that bacteriophage T7 is female specific, while phage T3 can propagate on male and female Escherichia coli. We found that the growth patterns of phages T7M and T3 do not match the above characteristics, instead showing strain dependent male exclusion. Furthermore, a T3/7 hybrid phage exhibits a broader host range relative to that of T3, T7, as well as T7M, and is able to overcome the male exclusion. The T7M sequence closely resembles that of T3. T3/7 is essentially T3 based, but a DNA fragment containing part of the tail fiber gene 17 is replaced by the T7 sequence. T3 displays inferior adsorption to strains tested herein compared to T7. The T3 and T7 recombinant phage carries altered tail fibers and acquires better adsorption efficiency than T3. How phages T3 and T7 recombine was previously unclear. This study is the first to show that recombination can occur accurately within only 8 base-pair homology, where four-way junction structures are identified. Genomic recombination models based on endonuclease I cleavages at equivalent and nonequivalent sites followed by strand annealing are proposed. Retention of pseudo-palindromes can increase recombination frequency for reviving under stress.

Self-association properties of the bacteriophage lambda terminase holoenzyme: implications for the DNA packaging motor

Terminases are enzymes common to complex double-stranded DNA viruses and are required for packaging of viral DNA into a protective capsid. Bacteriophage lambda terminase holoenzyme is a hetero-oligomer composed of the A and Nu1 lambda gene products; however, the self-association properties of the holoenzyme have not been investigated systematically. Here, we report the results of sedimentation velocity, sedimentation equilibrium, and gel-filtration experiments studying the self-association properties of the holoenzyme. We find that purified, recombinant lambda terminase forms a homogeneous, heterotrimeric structure, consisting of one gpA molecule associated with two gpNu1 molecules (114.2 kDa). We further show that lambda terminase adopts a heterogeneous mixture of higher-order structures, with an average molecular mass of 528(+/-34) kDa. Both the heterotrimer and the higher-order species possess site-specific cos cleavage activity, as well as DNA packaging activity; however, the heterotrimer is dependent upon Escherichia coli integration host factor (IHF) for these activities. Furthermore, the ATPase activity of the higher-order species is approximately 1000-fold greater than that of the heterotrimer. These data suggest that IHF bending of the duplex at the cos site in viral DNA promotes the assembly of the heterotrimer into a biologically active, higher-order packaging motor. We propose that a single, higher-order hetero-oligomer of gpA and gpNu1 functions throughout lambda development.

Isolation and characterization of T4 bacteriophage gp17 terminase, a large subunit multimer with enhanced ATPase activity

Phage T4 terminase is a two-subunit enzyme that binds to the prohead portal protein and cuts and packages a headful of concatameric DNA. To characterize the T4 terminase large subunit, gp17 (70 kDa), gene 17 was cloned and expressed as a chitin-binding fusion protein. Following cleavage and release of gp17 from chitin, two additional column steps completed purification. The purification yielded (i) homogeneous soluble gp17 highly active in in vitro DNA packaging ( approximately 10% efficiency, >10(8) phage/ml of extract); (ii) gp17 lacking endonuclease and contaminating protease activities; and (iii) a DNA-independent ATPase activity stimulated >100-fold by the terminase small subunit, gp16 (18 kDa), and modestly by portal gp20 and single-stranded binding protein gp32 multimers. Analyses revealed a preparation of highly active and slightly active gp17 forms, and the latter could be removed by immunoprecipitation using antiserum raised against a denatured form of the gp17 protein, leaving a terminase with the increased specific activity (approximately 400 ATPs/gp17 monomer/min) required for DNA packaging. Analysis of gp17 complexes separated from gp16 on glycerol gradients showed that a prolonged enhanced ATPase activity persisted after exposure to gp16, suggesting that constant interaction of the two proteins may not be required during packaging.

ATPase center of bacteriophage lambda terminase involved in post-cleavage stages of DNA packaging: identification of ATP-interactive amino acids

Terminase is the enzyme that mediates lambda DNA packaging into the viral prohead. The large subunit of terminase, gpA (641 amino acid residues), has a high-affinity ATPase activity (K(m)=5 microM). To directly identify gpA's ATP-interacting amino acids, holoterminase bearing a His(6)-tag at the C terminus of gpA was UV-crosslinked with 8-N(3)-[alpha-(32)P]ATP. Tryptic peptides from the photolabeled terminase were purified by affinity chromatography and reverse-phase HPLC. Two labeled peptides of gpA were identified. Amino acid sequencing failed to show the tyrosine residue of the first peptide, E(43)SAY(46)QEGR(50), or the lysine of the second peptide, V(80)GYSK(84)MLL(87), indicating that Y(46) and K(84) were the 8-N(3)-ATP-modified amino acids. To investigate their roles in lambda DNA packaging, Y(46) was changed to E, A, and F, and K(84) was changed to E and A. Purified His(6)-tagged terminases with changes at residues 46 and 84 lacked the gpA high-affinity ATPase activity, though the cos cleavage and cohesive end separation activities were near to those of the wild-type enzyme. In virion assembly reactions using virion DNA as a packaging substrate, the mutant terminases showed severe defects. In summary, the results indicate that Y(46) and K(84) are part of the high-affinity ATPase center of gpA, and show that this ATPase activity is involved in the post-cos cleavage stages of lambda DNA packaging.

In vitro cleavage of the concatemer joint of bacteriophage T3 DNA

Mature DNA from phage T3 or T7 is a linear duplex DNA with direct repeats at its ends known as "terminally redundant sequences." The DNA of these phages is synthesized as concatemers in which unit length molecules are joined together in a head-to-tail fashion through the terminally redundant sequences and processed to form mature DNA with coupling to DNA packaging. When linearized plasmid DNA carrying a concatemer joint, a terminally redundant sequence and its flanking sequences from the concatemer, was incubated in a defined in vitro system for packaging T3 DNA, composed of purified proheads and packaging proteins (gp 18 and gp 19), DNA was cleaved at the left end of the terminally redundant sequence. The cleavage reaction required all factors necessary for DNA packaging. The DNA fragment with the left end was preferentially protected from DNase I digestion, indicating that the cleavage reaction occurs at the left end of the terminally redundant sequence in the concatemer when DNA is packaged leftward, corresponding to the direction from the right to the left end of the T3 genome. The cleavage reaction was stimulated by high concentrations of NaCl and ATP, a condition in which DNA translocation into the head is slowed down. The cleavage reaction was not specific between T3 and T7. The right end of the concatemer joint was not required for cleavage at the left end. In the absence of ATP, DNA was extensively degraded by gp 19. gp 19 by itself had nonspecific endonuclease activity, making double-stranded breaks. The activity was inhibited by either ATP or gp 18.

Initiation events in in-vitro packaging of bacteriophage phi 29 DNA-gp3

Initiation events in the packaging of bacteriophage phi 29 DNA-gp3 (DNA-gene product 3 complex) were studied in a completely defined in-vitro system that included purified proheads, DNA-gp3 and the DNA packaging protein gp16. In the sequential interactions, gp16 first bound to, and was modified by, the prohead. The prohead-gp16 complex then bound to DNA-gp3, resulting in a second modification of gp16 that permitted binding of ATP. DNA-gp3 aggregates were produced, and the hydrolysis of ATP accompanied DNA-gp3 packaging. Binding and hydrolysis of ATP by gp16 was both prohead- and DNA-gp3-dependent. Interruption of packaging by DNase I addition revealed filled heads but few particles containing partial lengths of DNA, suggesting that following a rate-limiting initiation, the translocation of DNA-gp3 into the prohead was much faster in the defined in-vitro system than in extracts.

Prohead and DNA-gp3-dependent ATPase activity of the DNA packaging protein gp16 of bacteriophage phi 29

The ATPase activity of the DNA packaging protein gp16 (gene product 16) of bacteriophage phi 29 was studied in the completely defined in-vitro assembly system. ATP was hydrolyzed to ADP and Pi in the packaging reaction that included purified proheads, DNA-gp3 and gp16. Approximately one molecule of ATP was used in the packaging of 2 base-pairs of phi 29 DNA, or 9 X 10(3) ATP molecules per virion. The hydrolysis of ATP by gp16 was both prohead and DNA-gp3 dependent. gp16 contained both the "A-type" and the "B-type" ATP-binding consensus sequences (Walker et al., 1982) and the predicted secondary structure for ATP binding. The A-type sequence of gp16 was "basic-hydrophobic region-G-X2-G-X-G-K-S-X7-hydrophobic", and similar sequences were found in the phage DNA packaging proteins gpA of lambda, gp19 of T7 and gp17 of T4. Having both the ATP-binding and potential magnesium-binding domains, all of these proteins probably function as ATPases and may have common prohead-binding capabilities. The phi 29 protein gp3, covalently bound to the DNA, may be analogous in function to proteins gpNul of lambda and gpl of phi 21 that bind the DNA.

Characterization of ATPase activity of a defined in vitro system for packaging of bacteriophage T3 DNA

We have developed a defined in vitro system for packaging phage T3 DNA which is composed of purified proheads and the noncapsid proteins gp18 and gp19, products of genes 18 and 19 (K. Hamada, H. Fujisawa, and T. Minagawa, 1986, Virology 151, 119-123). The in vitro system displayed an ATPase activity. The requirements for ATPase activity were the same as those for DNA packaging. ATPase was inhibited by a nonhydrolyzable ATP analog, adenosine-5'-O-(3'-thiotriphosphate) (ATP-gamma-S). ATPase activity did not display specificity for T3 DNA. A reaction mixture containing 8- proheads, proheads deficient in gp8, a portal protein for DNA entrance, or mature heads had no gp18- gp19-dependent ATPase activity. gp8 itself had no ATPase activity and did not complement 8- proheads for ATPase activity. Photoaffinity labeling of proheads, gp18 and gp19 with 8-azidoadenosine-5'-[alpha-32P]triphosphate([32P]8-N3ATP) resulted in preferential labeling of gp19. Protection from incorporation of [32P]8-N3ATP was afforded by ATP but not by AMP and ADP. From these results, it is concluded that gp19 has an ATP binding site(s). A conserved sequence of ATP-binding site containing Gly-X-Gly-X-X-Gly-X-Val is found in gp19.

Early events in DNA packaging in a defined in vitro system of bacteriophage T3

We have developed a defined in vitro system for packaging phage T3 DNA which is composed of purified proheads and the noncapsid proteins gp18 and gp19, products of genes 18 and 19. The reaction requires Mg2+, ATP, and polyethylene glycol and is inhibited by a nonhydrolyzable ATP analog, adenosine-5'-O-(3'-thiotriphosphate) (ATP-gamma-S) (K. Hamada, H. Fujisawa, and T. Minagawa, 1986, Virology 151, 119-123). About 30% of added mature T3 DNA was packaged into heads in the defined system. A complex with a sedimentation coefficient of about 50 S (50 S complex) accumulated in the reaction mixture containing ATP-gamma-S. The 50 S complex was DNase sensitive and was converted to filled heads by a second reaction in the presence of ATP without addition of DNA, proheads, gp18, and gp19. These results indicate that during early stages of DNA packaging, formation of precursor complexes proceeds by an allosteric mechanism with ATP acting as effector. The movement of DNA into the head is driven by the energy released by hydrolysis of ATP. gp18 formed a complex with DNA without addition of ATP-gamma-S and gp19. gp18-DNA complex was DNase sensitive and did not bind gp19; it was converted to filled heads by way of a second reaction after addition of ATP, gp19, and proheads. gp19 formed a functional complex with prohead in the presence of ATP-gamma-S or ATP. The complex did not bind gp18 but was converted to filled heads by incubation with ATP, gp18, and DNA. In the absence of ATP-gamma-S, gp19 formed complexes with prohead that were abortive in DNA packaging. Formation of the 50 S complex occurred in a reaction mixture containing gp18-DNA and gp19-prohead complexes in the presence of ATP-gamma-S. From these results, we propose details of the molecular mechanism of DNA packaging in the defined in vitro system.

Overproduction and purification of the products of bacteriophage T3 genes 18 and 19, two genes involved in DNA packaging

The products of gene 18 (gp18) and gene 19 (gp19) of bacteriophage T3 are noncapsid proteins involved in DNA packaging. A restriction fragment containing gene 18 or 19 was cloned into the plasmid vector pNT45 under the control of the inducible leftward promoter (PL) of phage lambda. Induction of transcription of gene 18 or 19 by derepression of the PL promoter led to the synthesis of a high level of gp18 or gp19. By using complementation of T3 DNA packaging in vitro as an assay, gp18 and gp19 were purified to near homogeneity. The overall yields of gp18 and gp19 were 1.4 mg and 0.35 mg, respectively, from 1 g wet wt cells. Addition of gp18 to the in vitro DNA packaging system resulted in increased phage production with increasing amounts of gp18 until 10% of the DNA was packaged into infectious phage particles. In contrast, addition of gp19 to the packaging system initially caused an increase in phage production, but increasing amounts of gp19 inhibited DNA packaging.

A defined in vitro system for packaging of bacteriophage T3 DNA

Using purified components, we have constructed an in vitro system for packaging of mature phage T3 DNA. In addition to mature T3 DNA, the system contained T3 proheads and the products of gene 18 (gp18) and gene 19 (gp19). The reaction required Mg2+, ATP, and polyvinyl alcohol. Spermidine was stimulatory but not absolutely required for the packaging reaction. Polyvinyl alcohol could be replaced by polyethylene glycol. The packaging efficiency decreased with decreasing molecular weight of the polymer, and low molecular weight polyols such as sucrose, sorbitol, and glycerol were inactive. The packaging reaction exhibited a sigmoidal relationship with respect to the concentration of ATP with the concentration for half maximal activity about 15 microM. A nonhydrolyzable ATP analog, adenosine 5'-O-(3-thiotriphosphate), inhibited the packaging reaction.