Amino terminal sequence of the bacteriophage T5-coded gene A2 protein

The first twenty-eight amino acid residues from the amino terminal of the T5 phage-coded gene A2 protein were determined. Some evidence is presented which suggests the existence of two forms of the protein; one in the cytoplasm which may have a signal sequence and another form present in the outer membrane. The amino terminal A2 protein sequence shows some sequence homology to the amino terminal region of the T4 phage-coded gene 32 protein. Finally it is important to note that residues ten through twenty-one of the A2 protein are amino acids with low ambiguity codons which should facilitate in the DNA sequencing of the A2 gene.     

Purification and characterization of the bacteriophage T7 gene 2.5 protein. A single-stranded DNA-binding protein.

Bacteriophage T7 gene 2.5 protein has been purified to homogeneity from cells overexpressing its gene. Native gene 2.5 protein consists of a dimer of two identical subunits of molecular weight 25,562. Gene 2.5 protein binds specifically to single-stranded DNA with a stoichiometry of approximately 7 nucleotides bound per monomer of gene 2.5 protein; binding appears to be noncooperative. Electron microscopic analysis shows that gene 2.5 protein is able to disrupt the secondary structure of single-stranded DNA. The single-stranded DNA is extended into a chain of gene 2.5 protein dimers bound along the DNA. In fluorescence quenching and nitrocellulose filter binding assays, the binding constants of gene 2.5 protein to single-stranded DNA are 1.2 x 10(6) M-1 and 3.8 x 10(6) M-1, respectively. Escherichia coli single-stranded DNA-binding protein and phage T4 gene 32 protein bind to single-stranded DNA more tightly by a factor of 25. Fluorescence spectroscopy suggests that tyrosine residue(s), but not tryptophan residues, on gene 2.5 protein interacts with single-stranded DNA.     

The role of bacteriophage T7 gene 2 protein in DNA replication.

The in vivo function of the gene 2 protein of bacteriophage T7 has been examined. The gene 2 protein appears to modulate the activity of the gene 3 endonuclease in order to prevent the premature degradation of any newly-formed DNA concatemers. This modulation is not however a direct interacton between the two proteins. In single-burst experiments rifamycin can substitute for the gene 2 protein, allowing formation of fast-sedimenting replicative DNA intermediates and progeny phage production. This suggests that the sole function of the gene 2 protein is inhibition of the host RNA polymerase and that the latter enzyme directs or promotes the endonucleolytic action of the gene 3 protein.     

Gene 18 protein of bacteriophage T7. Overproduction, purification, and characterization

Genetic and physical analyses indicate that gene 18 protein of bacteriophage T7 is essential for packaging of T7 DNA. T7 DNA is replicated via linear intermediates, culminating in the formation of concatemers many genomes in length which are then packaged into capsids. In infections with phage carrying amber mutations in gene 18, development is blocked at the concatemer stage. Biochemical studies on the role of gene 18 protein in concatemer processing and DNA packaging have been hampered by its low level of expression of gene 18 during T7 infections. We have cloned gene 18 on a plasmid downstream from the bacteriophage lambda PL promoter controlled by the temperature-sensitive lambda repressor encoded by c 1857. Thermal induction leads to the expression of the 10,000-Da gene 18 protein to the extent of approximately 10% of the total protein after 2 h. The overexpressed gene 18 protein is susceptible to proteolytic degradation, a condition that can be alleviated by expression in an Escherichia coli strain carrying the lon100 deletion which reduces production of protease La. Extracts of induced cells will complement an extract of T7-infected cells lacking gene 18 protein for packaging of exogenous T7 DNA. The assay has been used to monitor the purification of gene 18 protein to essential homogeneity. The identity of the purified protein has been confirmed by sequencing of the N terminus. Gel filtration analysis suggests that the native protein is an octomer. Treatment of gene 18 protein with 3 M guanidine hydrochloride denatures it to a monomer. Removal of the denaturing agent by dialysis regenerates the octomeric structure and the ability to complement packaging extracts.     

Cloning and DNA sequence of the 5'-exonuclease gene of bacteriophage T5

The nucleotide sequence of the BalI-PstI fragment of T5 DNA, 1347 bp in length, coding for 5'-exonuclease (D15 gene), has been determined. A coding region of the gene contains 873 bp and is preceded by a typical Shine-Dalgarno sequence. The D15 gene belongs to a cluster, consisting of at least 3 genes, in which a termination codon of a preceding gene overlaps an initiation codon of the following one. The sequence contains an open reading frame for 291 amino acid residues. The molecular mass of the 5'-exonuclease calculated from the predicted amino acid sequence is 33 400 Da.     

Purification and characterization of the gene 1.2 protein of bacteriophage T7

Gene 1.2 of bacteriophage T7, located near the primary origin of DNA replication at position 15.37 on the T7 chromosome, encodes a 10,059-dalton protein that is essential for growth on Escherichia coli optA1 strains (Saito, H., and Richardson, C. C. (1981) J. Virol. 37, 343-351). In the absence of the T7 1.2 and E. coli optA gene products, the degradation of E. coli DNA proceeds normally, and T7 DNA synthesis is initiated at the primary origin. However, T7 DNA synthesis ceases prematurely and the newly synthesized DNA is degraded; no viable phage particles are released. The gene 1.2 protein has been purified to apparent homogeneity from cells in which the cloned 1.2 gene is overexpressed. Purification of the [35S] methionine-labeled protein was followed by monitoring the radioactivity of the protein and by gel electrophoresis. The purified protein has been identified as the product of gene 1.2 on the basis of molecular weight and partial amino acid sequence. We have found that extracts of E. coli optA1 cells infected with T7 gene 1.2 mutants are defective in packaging exogenous T7 DNA when such extracts are prepared late in infection. Purified gene 1.2 protein restores packaging activity to these defective extracts, thus providing a biological assay for gene 1.2 protein. No specific enzymatic activity has been found associated with the purified gene 1.2 protein.     

Interactions of gene 2.5 protein and DNA polymerase of bacteriophage T7.

Bacteriophage T7 gene 2.5 protein has been shown to interact with T7 DNA polymerase (the complex of T7 gene 5 protein and Escherichia coli thioredoxin) by affinity chromatography and fluorescence emission anisotropy. T7 DNA polymerase binds specifically to a resin coupled to gene 2.5 protein and elutes from the resin when the ionic strength of the buffer is raised to 250 mM NaCl. In contrast, T7 gene 5 protein alone binds more weakly to gene 2.5 protein, eluting when the ionic strength of the buffer is 50 mM NaCl. Thioredoxin does not bind to gene 2.5 protein. Steady-state fluorescence emission anisotropy gives a dissociation constant of 1.1 +/- 0.2 microM for the complex of gene 2.5 protein and T7 DNA polymerase, with a ratio of gene 2.5 protein to T7 DNA polymerase in the complex of 1:1. Nanosecond emission anisotropic analysis suggests that the complex contains one monomer each of gene 2.5 protein, gene 5 protein, and thioredoxin. The ability of T7 gene 2.5 protein to stimulate the activity and processivity of T7 DNA polymerase is compared with the ability of three other single-stranded DNA-binding proteins: E. coli single-stranded DNA-binding protein, T4 gene 32 protein, and E. coli recA protein. All except E. coli recA protein stimulate the activity and processivity of T7 DNA polymerase; E. coli recA protein inhibits these activities.     

Role of gene 2 in bacteriophage T7 DNA synthesis.

Studies have been carried out to elucidate the in vivo function of gene 2 in T7 DNA synthesis. In gene 2-infected cells the rate of incorporation of (3-H)thymidine into acid-insoluble material is about 60% that of cells infected with T7 wild type. Gene 2 mutants do not however produce viable phage after infection of the nonpermissive host. In T7 wild type-infected cells, a major portion of the newly alkaline sucrose gradients. The concatemers serve as precursors for the formation of mature T7 DNA as demonstrated in pulse-chase experiments. In similar studies carried out with gene 2-infected cells, concatemers are not detected when the intracellular DNA is analyzed at several different times during the infection process. The DNA made during a gene 2 infection is present as duplex structures with a sedimentation rate close to mature T7 DNA.     

On the role of the single-stranded DNA binding protein of bacteriophage T4 in DNA metabolism. I. Isolation and genetic characterization of new mutations in gene 32 of bacteriophage T4

Summary The product of gene 32 of bacteriophage T4 is a single-stranded DNA binding protein involved in T4 DNA replication, recombination and repair. Functionally differentiated regions of the gene 32 protein have been described by protein chemistry. As a preliminary step in a genetic dissection of these functional domains, we have isolated a large number of missense mutants of gene 32. Mutant isolation was facilitated by directed mutagenesis and a mutant bacterial host which is unusually restrictive for missense mutations in gene 32. We have isolated over 100 mutants and identified 22 mutational sites. A physical map of these sites has been constructed and has shown that mutations are clustered within gene 32. The possible functional significance of this clustering is considered.     

Interaction of a DNA-binding protein, the product of gene D5 of bacteriophage T5, with double-stranded DNA: effects on T5 DNA polymerase functions in vitro.

The gene D5 product (gpD5) of bacteriophage T5 is a DNA-binding protein that binds preferentially to double-stranded DNA and is essential for T5 DNA replication, yet it inhibits DNA synthesis in vitro. Mechanisms of inhibition were studied by using nicked DNA and primed single-stranded DNA as a primer-template. Inhibition of T5 DNA polymerase activity by gpD5 occurred when double-stranded regions of DNA were saturated with gpD5. The 3' leads to 5' exonuclease associated with T5 DNA polymerase was not very active with nicked DNA, but inhibition of hydrolysis of substituents at 3'-hydroxyl termini by gpD5 could be observed. T5 DNA polymerase appears to be capable of binding to the 3' termini even when double-stranded regions are saturated with gpD5. The interaction of gpD5 with the polymerases at the primer terminus is apparently the primary cause of inhibition of polymerization.     

Role of the T5 gene D15 nuclease in the generation of nicked bacteriophage T5 DNA.

The processing of newly replicated concatameric T5 DNA into both single stranded DNA changed of unit length and single-stranded fragments of sizes comparable to those found in mature T5 virion DNA occurs in the absence of late T5 protein synthesis. The formation of unit-length, single-stranded DNA chains does not require the early T5 gene D15 nuclease: however, the subsequent formation of the single-stranded fragments does require that the D15 nuclease be functional. A reexamination of the properties of the purified D15 nuclease under a variety of conditions showed that, in addition to functioning as a 5' leads to 3' exonuclease, the enzyme can also introduce endonucleolytic scissions into mature T5 DNA in a reaction that requires duplex T5 DNA and preexisting, single-stranded interruptions.     

Overexpression, purification, sequence analysis, and characterization of the T4 bacteriophage dda DNA helicase.

The bacteriophage T4 dda protein is a 5'-3' DNA helicase that stimulates DNA replication and recombination reactions in vitro and seems to play a role in the initiation of T4 DNA replication in vivo. Oligonucleotide probes based on NH2-terminal amino acid sequence were used to precisely map the location of the dda gene on the T4 chromosome. Using polymerase chain reaction techniques, the dda gene was then cloned into an expression vector, and the overproduced protein was purified in two chromatography steps. Both the genomic and cloned dda genes were sequenced and found to be identical, encoding a protein of 439 amino acids. The dda protein contains amino acid sequences resembling those of other known helicases, and is most homologous to the Escherichia coli recD protein. Protein affinity chromatography was used to show a direct interaction between the dda protein and the T4 uvsX protein (a rec A-type DNA recombinase).     

Complex of bacteriophage M13 single-stranded DNA and gene 5 protein

Lysates of bacteriophage M13-infected cells contain numerous unbranched filamentous structures approximately 1·1 μm long × 160 Å wide, that is, slightly longer and considerably wider than M13 virions. These structures are complexes of viral single-stranded DNA molecules with M13 gene 5 protein, a non-capsid protein required for single-stranded DNA production. All, or nearly all, of the single-stranded DNA from the infected cells and at least half to two-thirds of the gene 5 protein molecules are found as complex in the lysates. The complex contains about 1300 gene 5 protein molecules per DNA molecule but little if any of the two known capsid proteins. The complex is much less stable than virions in the presence of salt or ionic detergent solutions and in electron micrographs it appears to have a much looser and more open structure. If an excess of M13 single-stranded DNA is added to complex in a lysate, the gene 5 protein molecules from the complex redistribute onto all of the added as well as the original DNA, again suggesting a rather loose association of protein and DNA.By electron microscopy, the complex from infected cells appears to differ structurally from complex formed in vitro between purified single-stranded DNA and purified gene 5 protein. Because of this apparent structural difference and because previous experiments suggested the presence of complex in vivo, we presume that the complex which we have found in lysates of infected cells previously did exist as such inside the cells, but we have been unable to exclude that it formed during or after lysis. If it is assumed that complex does occur in vivo, the results of pulse-chase radioactive labeling experiments on infected cells can be interpreted as showing that with time the single-stranded DNA leaves complex, presumably to be matured into virions, while the gene 5 protein molecules are re-used to form more complex.     

Physical locus of the DNA polymerase gene and genetic maps of bacteriophage T5 mutants.

Segments of DNA that contained the DNA polymerase gene of bacteriophage T5 were isolated. The physical locus of the gene was identified by transforming Escherichia coli with purified DNA fragments generated by restriction enzyme digestions, and the transformed cells were used to rescue amber mutants of T5 with mutations in the gene for DNA polymerase. The method is applicable to any other gene that has mutations with low reversion frequencies. We studied the following mutations of the T5 DNA polymerase gene, reading from left to right by the standard convention (D. J. McCorquodale, Crit. Rev. Microbiol. 4:101-159, 1975): D7, D8, aml, ts5E-ts53, am6, and D9. These loci were found to reside within three pieces of DNA with a total length of 3,600 base pairs. Because the structural gene for T5 DNA polymerase is estimated to be 2,600 base pairs long, the whole structural gene may reside in these segments. These are located 58.3 to 61.3% of the distance from the left end of the DNA. The left-end piece of the DNA (1,100 base pairs) containing the polymerase gene has loci D7 and D8, and the right-end piece (1,600 base pairs) has locus D9, according to the results of the transformation assay. These results are consistent with the genetic map.     

New late gene, dar, involved in the replication of bacteriophage T4 DNA. II. Overproduction of DNA binding protein (gene 32 protein) and further characterization.

We have previously shown that the arrested DNA synthesis of mutant defective in T4 phage gene 59 can be reversed by a mutation in dar. In this paper, we have examined the effect of the dar mutation on the kinetics of gene 32 protein (DNA binding protein) synthesis, DNA packaging, progeny formation, and several other porcesses. Several lines of evidence are presented showing that the regulation of synthesis of gene 32 protein is abnormal in dar 1-infected cells. In these cells, gene 32 protein, an early protein, is also expressed late in the infectious cycle. Our data also indicate that the packaging og DNA into T4 phage heads is delayed in dar mutant-infected cells, and this in turn results in a 6- to 8-min delay in intracellular progeny formation, although the synthesis of late proteins appears to be normal, as shown by gel electrophoresis. We have also studied the phenotypes of the double mutant dar-amC5 (gene 59). The increased sensitivity to hydroxyurea caused by a mutation in the dar gene can be alleviated by a second mutation in gene 59, but an increased sensitivity to UV irradiation caused by a mutation in gene 59 cannot be alleviated by a second mutation in the dar gene. Therefore, the double mutant still exhibits abnormalities in the repair of UV lesions.