Genetic recombination of bacteriophage T7 DNA in vitro. II. Further properties of the in vitro recombination-packaging reaction

In vitro repair of double-strand breaks accompanied by recombination in bacteriophage T7 DNA

A double-strand break in a bacteriophage T7 genome significantly reduced the ability of that DNA to produce viable phage when the DNA was incubated in an in vitro DNA replication and packaging system. When a homologous piece of T7 DNA (either a restriction fragment or T7 DNA cloned into a plasmid) that was by itself unable to form a complete phage was included in the reaction, the break was repaired to the extent that many more viable phage were produced. Moreover, repair could be completed even when a gap of about 900 nucleotides was put in the genome by two nearby restriction cuts. The repair was accompanied by acquisition of a genetic marker that was present only on the restriction fragment or on the T7 DNA cloned into a plasmid. These data are interpreted in light of the double-strand gap repair mode of recombination.

Role of gene 6 exonuclease in the replication and packaging of bacteriophage T7 DNA

When bacteriophage T7 gene 6 exonuclease is genetically removed from T7-infected cells, degradation of intracellular T7 DNA is observed. By use of rate zonal centrifugation, followed by either pulsed-field agarose gel electrophoresis or restriction endonuclease analysis, in the present study, the following observations were made. (1) Most degradation of intracellular DNA requires the presence of T7 gene 3 endonuclease and is independent of DNA packaging; rapidly sedimenting, branched DNA accumulates when both the gene 3 and gene 6 products are absent. (2) A comparatively small amount of degradation requires packaging and occurs at both the joint between genomes in a concatemer and near the left end of intracellular DNA; DNA packaging is only partially blocked and end-to-end joining of genomes is not blocked in the absence of gene 6 exonuclease. (3) Fragments produced in the absence of gene 6 exonuclease are linear and do not further degrade; precursors of the fragments are non-linear. (4) Some, but not most, of the cleavages that produce these fragments occur selectively near two known origins of DNA replication. On the basis of these observations, the conclusion is drawn that most degradation that occurs in the absence of T7 gene 6 exonuclease is caused by cleavage at branches. The following hypothesis is presented: most, possibly all, of the extra branching induced by removal of gene 6 exonuclease is caused by strand displacement DNA synthesis at the site of RNA primers of DNA synthesis; the RNA primers, produced by multiple initiations of DNA replication, are removed by the RNase H activity of gene 6 exonuclease during a wild-type T7 infection. Observation of joining of genomes in the absence of gene 6 exonuclease and additional observations indicate that single-stranded terminal repeats required for concatamerization are produced by DNA replication. The observed selective shortening of the left end indicates that gene 6 exonuclease is required for formation of most, possibly all, mature left ends.

Concatemerization and packaging of bacteriophage T7 DNA in vitro: determination of the concatemers' length and appearance kinetics by use of rotating gel electrophoresis

During its morphogenesis both in intact infected cells (in vivo) and in lysates of infected cells (in vitro), bacteriophage T7 forms end-to-end concatemers of its mature DNA, a linear, nonpermuted, terminally repetitious DNA. During morphogenesis, in vivo T7 concatemers are packaged in preformed capsids and cut to mature size. In the present study the lengths and appearance kinetics of concatemers formed in vitro from mature T7 DNA have been determined. The following procedures are used here for the first time: (a) 20-35% efficient in vitro concatemerization and packaging of T7 DNA; the mixture used for packaging contained two lysates that together had all T7 gene products, and (b) fractionation of concatemers by rotating gel electrophorsis (RGE), which improves the resolution by length of concatemer-length DNA. Concatemerization at 30 degrees was so fast that some other process must be rate limiting for packaging. The concatemers formed were linear and joined left-end to right-end by complementary base pairing, not by blunt-end ligation. Concatemers formed at 30 degrees were reconverted to mature DNA by packaging in vitro. Reducing the temperature to 0 degrees both slowed concatemerization to the time scale (minutes) needed for control of the extent of concatemerization and reduced packaging to insignificant levels, thereby also uncoupling packaging from concatemerization. At both 30 degrees and 0 degrees bands of discrete-length concatemers were observed by RGE. The lengths were n times the length of mature T7 DNA; n was found to be any integer from 2 to 15. The bands were stronger at 0 degrees than they were at 30 degrees in comparison to a background of heterogeneous DNA. No evidence for the favoring of any value of n was found. In addition, it was found by two-dimensional agarose gel electrophoresis that a comparatively small amount of circular DNA was produced in vitro.

Characterization of morphogenetic intermediates and progeny of normal and alkylated bacteriophage T7

Analysis of thin sections of Escherichia coli B cells infected by normal (nonalkylated) or alkylated bacteriophage T7 showed that alkylation altered phage morphogenesis. To understand these morphogenetic alterations, we have isolated phage-related particles from infected-cell lysates by differential and sucrose gradient centrifugation. Cells infected by normal and by alkylated phage produced mature phage particles, empty heads, and proheads; however, production of proheads and mature phage particles was less in the case of alkylated phage. These lysates also contained sedimentable material which migrated more slowly than empty heads on sucrose gradients. In the case of alkylated phage, this peak contained radioactive material in amounts nearly equal to that in either proheads or empty heads; for normal phage, this peak represented a smaller fraction of the total radioactivity. Examination of the gradient fractions by electron microscopy revealed appreciable quantities of phage tails and tail-related particles. The same gradient fractions contained phage tail proteins: gene products (gps) 11, 12, and 17 as well as smaller amounts of gp 8, the head-tail connector. In addition, these fractions contained two other proteins which we believe to be of bacterial origin. These proteins may be related to tail formation or function as part of the phage receptor. On the basis of our data, we propose an alternative morphogenetic pathway for T7 tail formation, a pathway which would involve formation of a complex of tail proteins prior to association with the phage head.

Purification and properties of gene 18 product of bacteriophage T3

Two noncapsid proteins of T3 and T7 phage, the products of gene 18(gp18) and gp19, are required for DNA packaging. By using in vitro complementation for DNA packaging as an assay system, T3 gp18 was purified to near homogeneity from an extract prepared cells infected with a mutant of gene 19(19- extract). The purified gp18 consisted of a single polypeptide having a molecular weight of 10,000, and was eluted as dimers and higher multimers from Sephadex G-75 columns. T7 gp18 was purified by the same procedures as that for T3 gp18 and behaved in the same manner as T3 gp18 throughout all purification steps. Gp18 from either T3 or T7 phage complemented both T3 and T7 18- extract for DNA packaging. These results indicate that, in contrast to gp19 [H. Fujisawa and M. Yamagishi (1981) Prog. Clin. Biol. Res. 64, 239-252], gp18 does not have specificity for T3 or T7 DNA during the in vitro packaging reaction. T3 gp18 was purified from extract containing functional gp19. The gp18 copurified with the gp19 activity. Gp18 and gp19 activities were stable when they were copurified but were unstable when purified separately. These results suggest that gp18 and gp19 function as a complex in the DNA packaging process. The gp18-gp19 preparation had a prohead-stimulated, DNA-dependent ATPase activity.

In vitro recombination of bacteriophage T7 DNA detected by a direct physical assay

We developed a simple, direct, physical assay to detect genetic recombination of bacteriophage T7 DNA in vitro. In this assay two mature T7 DNA molecules, each having a unique restriction enzyme site, are incubated in the presence of a cell-free extract from T7-infected Escherichia coli cells. After extraction of the DNA, restriction enzyme digestion, and agarose gel electrophoresis, genetic recombination is detected by the appearance of a novel recombinant DNA band. Recombination frequencies as high as 13% have been observed. We used this assay to determine the genetic requirements for in vitro recombination. In agreement with results obtained previously with a biological assay, T7 recombination in vitro appears to proceed via two distinct pathways.

Bacteriophage P22 in vitro DNA packaging monitored by agarose gel electrophoresis: rate of DNA entry into capsids

Bacteriophage P22, like other double-stranded DNA bacteriophages, packages DNA in a preassembled, DNA-free procapsid. The P22 procapsid and P22 bacteriophage have been electrophoretically characterized; the procapsid has a negative average electrical surface charge density (sigma) higher in magnitude than the negative sigma of the mature bacteriophage. Dextrans, sucrose, and maltose were shown to have a dramatic stimulatory effect on the in vitro packaging of DNA by the P22 procapsid. However, sedoheptulose, smaller sugars, and smaller polyols did not stimulate in vitro P22 DNA packaging. These and other data suggest that an osmotic pressure difference across some particle, probably a capsid, stimulates P22 DNA packaging. After in vitro packaging was optimized by including dextran 40 in extracts, the entry kinetics of DNA into P22 capsids were measured. Packaged DNA was detected by: (i) DNA-specific staining of intact capsids after fractionation by agarose gel electrophoresis and (ii) agarose gel electrophoresis of DNase-resistant DNA after release of DNase-resistant DNA from capsids. It was found that the first DNA was packaged by 1.5 min after the start of incubation. The data further suggest that either P22 capsids with DNA partially packaged in vitro are too unstable to be detected by the above procedures or entry of DNA into the capsid occurs in less than 0.25 min.

In vitro recombination of bacteriophage T7 DNA damaged by UV radiation

A system capable of in vitro packaging of exogenous bacteriophage T7 DNA has been used to monitor the biological activity of DNA replicated in vitro. This system has been used to follow the effects of UV radiation on in vitro replication and recombination. During the in vitro replication process, a considerable exchange of genetic information occurs between T7 DNA molecules present in the reaction mixture. This in vitro recombination is reflected in the genotype of the T7 phage produced after in vitro encapsulation; depending on the genetic markers selected, recombinants can comprise nearly 20% of the total phage production. When UV-irradiated DNA is incubated in this system, the amount of in vitro synthesis is reduced and the total amount of viable phage produced after in vitro packaging is diminished. In vitro recombination rates are also lower when the participating DNA molecules have been exposed to UV. However, biochemical and genetic measurements confirmed that there is little or no transfer of pyrimidine dimers from irradiated DNA into undamaged molecules.

In vitro packaging of bacteriophate T7 DNA synthesized in vitro

An in vitro DNA packaging system was used to encapsulate T7 DNA that had been synthesized by extracts prepared from gently lysed Escherchia coli infected with bacteriophage T7 carrying amber mutations in gene 3 or in both genes 3 and 6. Isopycnic centrifugation of density-labeled wild-type DNA was employed in an effort to separate product from template; suppressor-free indicator bacteria were used to eliminate contributions from endogenous DNA or contaminating phage. Additional controls indicated that fragmented DNA is packaged in vitro only with very low efficiency and that the frequency of recombination during packaging is too low to affect interpretation of these experiments. T7 DNA replicated by extracts prepared using T7 mutants deficient in both genes 3 and 6 could be packaged in vitro with an efficiency comparable to that found when highly purified virion T7 DNA was used. When T7 deficient in the gene 3 endonuclease but with normal levels of the gene 6 exonuclease was used, fast-sedimentingconcatemer-like DNA structures were formed during in vitro DNA synthesis. Electron microscopy revealed many branched and highly complex DNA structures formed during this reaction. This concatemer-like DNA was encapsulated in vitro with an efficiency significantly greater than that found for DNA the length of a single T7 genome.