Defective DNA injection by alkylated and nonalkylated bacteriophage T7.

DNA injection by alkylated and nonalkylated bacteriophage T7 has been analyzed by a physical method which involved Southern hybridization to identify noninjected regions of DNA. Treatment of phage with methyl methanesulfonate reduced the amount of DNA injected into wild-type Escherichia coli cells. This reduction was correlated with a decreased injection of DNA segments located on the right-hand third of the T7 genome. An essentially identical injection defect was observed when alkylated phage infected E. coli mutant cells unable to repair 3-methyladenine. Furthermore, untreated phage particles were discovered to be naturally injection-defective. Some injected all their DNA except those segments located in the rightmost 15% of the T7 genome, while other injected no DNA at all. In the presence of rifampicin, untreated phages injected only segments from the left end of the genome. These results provide direct physical evidence that T7 DNA injection is strictly unidirectional, starting from the left end of the T7 genome. The injection defect quantified here for alkylated phage is probably partially, if not totally, responsible for phage inactivation, when that inactivation is measured in wild-type E. coli cells. Since alkylated phage injected the same DNA sequences into both wild-type and repair-deficient cells, we conclude that DNA injection is independent of the host-cell's capacity for repair of 3-methyladenine residues.     

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.     

Bacteriophage T7 DNA packaging. I. Plasmids containing a T7 replication origin and the T7 concatemer junction are packaged into transducing particles during phage infection

Bacteriophage T7 DNA is a linear duplex molecule with a 160 base-pair direct repeat (terminal redundancy) at its ends. During replication, large DNA concatemers are formed, which are multimers of the T7 genome linked head to tail through recombination at the terminal redundancy. We define the sequence that results from this recombination, a mature right end joined to the left end of T7 DNA, as the concatemer junction. To study the processing and packaging of T7 concatemers into phage particles, we have cloned the T7 concatemer junction into a plasmid vector. This plasmid is efficiently (at least 15 particles/infected cell) packaged into transducing particles during a T7 infection. These transducing particles can be separated from T7 phage by sedimentation to equilibrium in CsCl. The packaged plasmid DNA is a linear concatemer of about 40 x 10(3) base-pairs with ends at the expected T7 DNA sequences. Thus, the T7 concatemer junction sequence on the plasmid is recognized for processing and packaging by the phage system. We have identified a T7 DNA replication origin near the right end of the T7 genome that is necessary for efficient plasmid packaging. The origin, which is associated with a T7 RNA polymerase promoter, causes amplification of the plasmid DNA during T7 infection. The amplified plasmid DNA sediments very rapidly and contains large concatemers, which are expected to be good substrates for the packaging reaction. When cloned in pBR322, a sequence containing only the mature right end of T7 DNA is sufficient for efficient packaging. Since this sequence does not contain DNA to the right of the site where a mature T7 right end is formed, it was expected that right ends would not form on this DNA. In fact, with this plasmid the right end does not form at the normal T7 sequence but is instead formed within the vector. Apparently, the T7 packaging system can also recognize a site in pBR322 DNA to produce an end for packaging. This site is not recognized solely by a "headful" mechanism, since there can be considerable variation in the amount of DNA packaged (32 x 10(3) to 42 x 10(3) base-pairs). Furthermore, deletion of this region from the vector DNA prevents packaging of the plasmid. The end that is formed in vector DNA is somewhat heterogeneous. About one-third of the ends are at a unique site (nucleotide 1712 of pBR322), which is followed by the sequence 5'-ATCTGT-3'. This sequence is also found adjacent to the cut made in a T7 DNA concatemer to produce a normal T7 right end.     

Bacteriophage T7 DNA packaging. III. A "hairpin" end formed on T7 concatemers may be an intermediate in the processing reaction

An unusual left end (M-end) has been identified on bacteriophage T7 DNA isolated from T7-infected cells. This end has a "hairpin" structure and is formed at a short inverted repeat sequence centered around nucleotide 39,587 of T7, 190 base-pairs to the left of the site where a mature left end is formed on the T7 concatemer. We do not detect the companion right end that would be formed if the M-end is produced by a double-stranded cut on the T7 concatemer. This suggests that the hairpin left end may be generated from a single-stranded cut in the DNA that is used to prime rightward DNA synthesis. The formation of M-end does not require the products of T7 genes 10, 18 or 19, proteins that are essential for the formation of mature T7 ends. During infection with a T7 gene 3 (endonuclease) mutant, phage DNA synthesis is reduced and the concatemers are not processed into unit length DNA molecules, but both M-end and the mature right end are formed on the concatemer DNA. These two ends are also found associated with the large, rapidly sedimenting concatemers formed during a normal T7 infection while the mature left end is present only on unit length T7 DNA molecules. We propose that DNA replication primed from the hairpin end produced by a nick in the inverted repeat sequence provides a mechanism to duplicate the terminal repeat before DNA packaging. Packaging is initiated with the formation of a mature right end on the branched concatemer and, as the phage head is filled, the T7 gene 3 endonuclease may be required to trim the replication forks from the DNA. Concatemer processing is completed by the removal of the 190 base-pair hairpin end to produce the mature left end.     

Formation of the right before the left mature DNA end during packaging-cleavage of bacteriophage T7 DNA concatemers.

During bacteriophage T7 morphogenesis in a T7-infected cell, mature length T7 DNA molecules join end-to-end to form concatemers that are subsequently both packaged in the T7 capsid and cut to mature size. In the present study, the kinetics of the appearance in vivo of the mature right and left T7 DNA ends have been analyzed. To perform this analysis, the intercalating dye proflavine is used to interrupt DNA packaging. When used at 0.5 to 8.0 micrograms/ml, proflavine progressively inhibits events in the T7 DNA packaging pathway, without either altering protein synthesis or degrading intracellular T7 DNA. Restriction endonuclease kinetic analysis reveals that proflavine (8 micrograms/ml) completely blocks formation of the mature T7 DNA left end, but only partially blocks formation of the mature T7 DNA right end. Both these and other observations are explained by the hypothesis that, in the T7 DNA packaging pathway, events occur in the following sequence: (1) formation of a mature right end; (2) packaging of at least some of the genome; (3) formation of the mature left end.     

Electron microscopic analysis of partially replicated bacteriophage T7 DNA.

Partially replicated bacteriophage T7 DNA was isolated from Escherichia coli infected with UV-irradiated T7 bacteriophage and was analyzed by electron microscopy. The analysis determined the distribution of eye forms and forks in the partially replicated molecules. Eye forms and forks in unit length molecules were aligned with respect to the left end of the T7 genome, and segments were scored for replication in each molecule. The resulting histogram showed that only the left 25 to 30% of the molecules was replicated. Several different origins of DNA replication were used to initiate replication in the UV-irradiated experiments in which 32P-labeled progeny DNA from UV-irradiated phage was annealed with ordered restriction fragments of T7 DNA (K. B. Burck and R. C. Miller, Jr., Proc. Natl. Acad. Sci. U.S.A. 75:6144--6148, 1978). Both analyses support partial-replica hypotheses (N. A. Barricelli and A. H. Doermann, Virology 13:460--476, 1961; Doermann et al., J. Cell. comp. Physiol. 45[Suppl.]:51--74, 1955) as an explanation for the distribution of marker rescue frequencies during cross-reactivation; i.e., replication proceeds in a bidirectional manner from an origin to a site of UV damage, and those regions of the genome which replicate most efficiently are rescued most efficiently by a coinfecting phage. In addition, photoreactivation studies support the hypothesis that thymine dimers are the major UV damage blocking cross-reactivation in the right end of the T7 genome.     

T7 single strand DNA binding protein but not T7 helicase is required for DNA double strand break repair

An in vitro system based on Escherichia coli infected with bacteriophage T7 was used to test for involvement of host and phage recombination proteins in the repair of double strand breaks in the T7 genome. Double strand breaks were placed in a unique XhoI site located approximately 17% from the left end of the T7 genome. In one assay, repair of these breaks was followed by packaging DNA recovered from repair reactions and determining the yield of infective phage. In a second assay, the product of the reactions was visualized after electrophoresis to estimate the extent to which the double strand breaks had been closed. Earlier work demonstrated that in this system double strand break repair takes place via incorporation of a patch of DNA into a gap formed at the break site. In the present study, it was found that extracts prepared from uninfected E. coli were unable to repair broken T7 genomes in this in vitro system, thus implying that phage rather than host enzymes are the primary participants in the predominant repair mechanism. Extracts prepared from an E. coli recA mutant were as capable of double strand break repair as extracts from a wild-type host, arguing that the E. coli recombinase is not essential to the recombinational events required for double strand break repair. In T7 strand exchange during recombination is mediated by the combined action of the helicase encoded by gene 4 and the annealing function of the gene 2.5 single strand binding protein. Although a deficiency in the gene 2.5 protein blocked double strand break repair, a gene 4 deficiency had no effect. This argues that a strand transfer step is not required during recombinational repair of double strand breaks in T7 but that the ability of the gene 2.5 protein to facilitate annealing of complementary single strands of DNA is critical to repair of double strand breaks in T7.     

Incomplete entry of bacteriophage T7 DNA into F plasmid-containing Escherichia coli.

The penetration of bacteriophage T7 DNA into F plasmid-containing Escherichia coli cells was determined by measuring Dam methylation of the entering genome. T7 strains that cannot productively infect F-containing cells fail to completely translocate their DNA into the cell before the infection aborts. The entry of the first 44% of the genome occurs normally in an F-containing cell, but the entry of the remainder is aberrant. Bypassing the normal mode of entry of the T7 genome by transfecting naked DNA into competent cells fails to suppress F exclusion of phage development. However, overexpression of various nontoxic T7 1.2 alleles from a high-copy-number plasmid or expression of T3 1.2 from a T7 genome allows phage growth in the presence of F.     

Single-event analysis of the packaging of bacteriophage T7 DNA concatemers in vitro.

Bacteriophage T7 packages its double-stranded DNA genome in a preformed protein capsid (procapsid). The DNA substrate for packaging is a head-to-tail multimer (concatemer) of the mature 40-kilobase pair genome. Mature genomes are cleaved from the concatemer during packaging. In the present study, fluorescence microscopy is used to observe T7 concatemeric DNA packaging at the level of a single (microscopic) event. Metabolism-dependent cleavage to form several fragments is observed when T7 concatemers are incubated in an extract of T7-infected Escherichia coli (in vitro). The following observations indicate that the fragment-producing metabolic event is DNA packaging: 1) most fragments have the hydrodynamic radius (R(H)) of bacteriophage particles (+/-3%) when R(H) is determined by analysis of Brownian motion; 2) the fragments also have the fluorescence intensity (I) of bacteriophage particles (+/-6%); 3) as a fragment forms, a progressive decrease occurs in both R(H) and I. The decrease in I follows a pattern expected for intracapsid steric restriction of 4',6-diamidino-2-phenylindole (DAPI) binding to packaged DNA. The observed in vitro packaging of a concatemer's genomes always occurs in a synchronized cluster. Therefore, the following hypothesis is proposed: the observed packaging of concatemer-associated T7 genomes is cooperative.     

DNA sequence for the T7 RNA polymerase promoter for T7 RNA species II

The DNA sequence for the T7 late region class III promoter for T7 RNA species II has been determined. I have found that the DNA sequence for this promoter presented in an earlier report (Oakley et al., 1979) is incorrect and that this class III promoter contains a 23 base-pair sequence identical to those present in all other T7 class III promoters (Rosa, 1979). The T7 RNA species II promoter has been located at 68% on the T7 genome.     

Initiation of DNA replication at cloned origins of bacteriophage T7

Bacteriophage T7 DNA replication is initiated at a site 15% of the distance from the genetic left end of the chromosome. This primary origin contains two tandem T7 RNA polymerase promoters (phi 1.1A and phi 1.1B) followed by an A + T-rich region. When the primary origin region is deleted replication initiates at secondary origins. We have analyzed the ability of plasmids containing cloned fragments of T7 to replicate after infection of Escherichia coli with bacteriophage T7. All cloned T7 fragments that support plasmid replication contain a T7 promoter but a T7 promoter alone is not sufficient for replication. Replication of plasmids containing the primary origin is dependent on T7 DNA polymerase and gene 4 protein (helicase/primase) and a portion of the A + T-rich region. The other T7 fragments that support plasmid replication after T7 infection are promoter regions phi OR, phi 13 and phi 6.5 (secondary origins). When both the primary and secondary origins are present simultaneously on compatible plasmids, replication of each is temporally regulated. Such regulation may play a role during T7 DNA replication.     

Viral DNA sequences from incomplete particles of human adenovirus type 7

Large pools of empty viral capsids accumulate in cells infected by subgroup B human adenoviruses. Such infected cells also yield DNA-containing incomplete particles in larger quantities than cells infected with serotypes representing other adenovirus subgroups. DNA isolated from carefully purified classes of Ad7 incomplete particles was analyzed by restriction endonuclease cleavage, gel electrophoresis and electron microscopy. At least 90% of the DNA molecules in each sample consisted of sequences that extended from the left end of the viral genome map by variable lengths toward the right end. The average length of DNA is linearly related to the average buoyant density of the incomplete particles from which the DNA is isolated. The results indicate that each capsid contains one DNA molecule. There is also a specific association of the left end of the viral genome with assembled or assembling capsids. The characteristic distributions of Ad7 incomplete particles may result from intracellular pools of assembly intermediates in which the incompletely packaged DNA has been fragmented in vivo or by shear during preparative procedures.