Participation of bacteriophage T4 gene 41 in replication repair

The location of the non-essential T4 mutant uvs79, with defective replication repair, is described. After crosses with double mutants dispersed over the early region of T4, a linkage was observed with the double mutant am41 : am42. For more accurate location, crosses were made with single mutants. Uvs79 proved to be located between mutants amC23 and amN81 in gene 41, as shown by 3-point crosses. No genetic complementation with respect to multiplicity reactivation was found between amN81 and uvs79 after a co-infection of an su^? host. Apparently, mutant amN81 is disturbed as to replication repair and, owing to its lack of DNA synthesis, also in replication-dependent recombination repair. Consequently, the product of gene 41 has a function additional to its RNA-primer induction during replication of undamaged DNA. Presumably, the product of gene 41 induces RNA primers opposite DNA regions containing lesions. This capability is believed to be specifically affected by the uvs79 mutation.     

Characterization of the bacteriophage T4 gene 41 DNA helicase

The T4 gene 41 protein and the gene 61 protein function together as a primase-helicase within the seven protein bacteriophage T4 multienzyme complex that replicates duplex DNA in vitro. We have previously shown that the 41 protein is a 5' to 3' helicase that requires a single-stranded region on the 5' side of the duplex to be unwound and is stimulated by the 61 protein (Venkatesan, M., Silver L. L., and Nossal, N. G. (1982) J. biol. Chem. 257, 12426-12434). The 41 protein, in turn, is required for pentamer primer synthesis by the 61 protein. We now show that the 41 protein helicase unwinds a partially duplex DNA molecule containing a performed fork more efficiently than a DNA molecule without a fork. Optimal helicase activity requires greater than 29 nucleotides of single-stranded DNA on the 3' side of the duplex (analogous to the leading strand template). This result suggests the 41 protein helicase interacts with the leading strand template as well as the lagging strand template as it unwinds the duplex region at the replication fork. As the single-stranded DNA on the 3' side of a short duplex (51 base pairs) is lengthened, the stimulation of the 41 protein helicase by the 61 protein is diminished. However, both the 61 protein and a preformed fork are essential for efficient unwinding of longer duplex regions (650 base pairs). These findings suggest that the 61 protein promotes both the initial unwinding of the duplex to form a fork and subsequent unwinding of longer duplexes by the 41 protein. A stable protein-DNA complex, detected by a gel mobility shift of phi X174 single-stranded DNA, requires both the 41 and 61 proteins and a rNTP (preferably rATP or rGTP, the nucleotides with the greatest effect on the helicase activity). In the accompanying paper, we report the altered properties of a proteolytic fragment of the 41 protein helicase and its effect on in vitro DNA synthesis in the T4 multienzyme replication system.     

Purification and properties of the bacteriophage T4 gene 61 RNA priming protein

The bacteriophage T4 gene 61 protein is required, together with the gene 41 protein and single-stranded DNA, for the synthesis of the pentaribonucleotides that are used as primers for the start of each new Okazaki DNA fragment during T4 DNA replication. Using this priming activity as an assay, we have purified the 61 protein to essential homogeneity in milligram amounts. The priming activity was identified with the product of T4 gene 61 by using two-dimensional polyacrylamide gel electrophoresis to compare all of the T4-induced proteins in wild-type and mutant infections; the purified protein co-migrates with the only detectable protein missing in a 61- mutant infection. The purified 61 protein is shown to bind to the T4 helix-destabilizing protein (gene 32 protein) and to both single-stranded and double-stranded DNA. We have failed to detect any ribonucleotide polymerizing activity in either the 61 protein or the 41 protein alone; both the 61 and 41 proteins must be present to observe any synthesis of oligoribonucleotides.     

Purification and properties of the bacteriophage T4 gene 31 protein required for prehead assembly.

A low molecular weight (approximately 16,000), early protein is characterized as the product of the essential T4 head assembly gene 31. This gene is known to be required to allow formation of any ordered head structure from the major T4 capsid protein, P23 (Laemmli, U.K., Beguin, F., and Gujer-Kellenberger, G. (1970) J. Mol. Biol. 47, 69-85). In wild type infection P31 synthesis ceases at late times; in contrast, P31 is overproduced in certain early or regulatory T4 mutant infections, particularly gene 55 mutant infections. P31 was purified preparatively from Escherichia coli infected with the latter mutant, but could only be obtained for the most part in modified form, possibly due to unusual sensitivity to a proteolytic activity. P31 is not cleaved in vivo during normal head assembly, nor does it become a part of the mature head or any ordered prehead structure as determined by an immunological assay using antiserum prepared against the purified protein. However P31 does appear to become a part of the unordered P23 aggregates (lumps) which accumulate when ordered P23 assembly is prevented. We cound find no evidence for P31 association with T4 DNA or the host membrane. Our experiments favor the hypothesis that P31 directly affects the aggregation state and solubility properties of P23.     

Purification and characterization of the T4 bacteriophage uvsX protein

Gene uvsX of bacteriophage T4 encodes a 40,000-dalton protein that plays a key role in the major pathway for genetic recombination in T4-infected cells. Mutations at the uvsX locus lead to increased sensitivity to various DNA-damaging agents, reduced phage bursts, decreased genetic recombination, and early arrest of DNA synthesis. Like the Escherichia coli recA protein, the purified uvsX protein is a DNA-dependent ATPase that catalyzes pairing between homologous single- and double-stranded DNA molecules in vitro (Yonesaki, T., Ryo, Y., Minagawa, T., and Takahashi, H., (1985) Eur. J. Biochem. 148, 127-134). At physiological salt concentrations, the uvsX protein binds tightly and cooperatively to single-stranded DNA, covering about five nucleotides per protein monomer; at lower salt concentrations, a similar type of binding to double-stranded DNA is detected (Griffith, J., and Formosa, T., (1985) J. Biol. Chem. 260, 4484-4491). We show here that the ATPase activity of this protein is unusual in producing both ADP plus Pi and AMP plus PPi as products. Generating the fully active form of the ATPase is a cooperative process, apparently requiring that a protein monomer be bound to single-stranded DNA while surrounded by other ATP-bound monomers. The catalysis of homologous pairing by the uvsX protein is shown to be greatly stimulated by the presence of the T4 gene 32 protein, a helix-destablizing protein previously studied in this laboratory, and it requires continued ATP hydrolysis. We present a method that allows the purification of the uvsX protein to essential homogeneity. We also describe the complete purification of two proteins that bind to the uvsX protein: the T4 uvsY protein (16,000 daltons) and an E. coli host protein of 32,000 daltons whose gene is unknown. The host protein is likely to play a role in DNA metabolism, because it also binds to the T4 gene 32 protein and to DNA; the sequence of its amino-terminal 29 amino acids has been determined.     

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.     

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.     

Lysis protein T of bacteriophage T4

Summary Lysis protein T of phage T4 is required to allow the phage's lysozyme to reach the murein layer of the cell envelope and cause lysis. Using fusions of the cloned gene t with that of the Escherichia coli alkaline phosphatase or a fragment of the gene for the outer membrane protein OmpA, it was possible to identify T as an integral protein of the plasma membrane. The protein was present in the membrane as a homooligomer and was active at very low cellular concentrations. Expression of the cloned gene t was lethal without causing gross leakiness of the membrane. The functional equivalent of T in phage is protein S. An amber mutant of gene S can be complemented by gene t, although neither protein R of (the functional equivalent of T4 lysozyme) nor S possess any sequence similarity with their T4 counterparts. The murein-degrading enzymes (including that of phage P22) have in common a relatively small size (molecular masses of ca. 18 000) and a rather basic nature not exhibited by other E. coli cystosolic proteins. The results suggest that T acts as a pore that is specific for this type of enzyme.     

Characterization of the DNA-dependent GTPase activity of T4 gene 41 protein, an essential component of the T4 bacteriophage DNA replication apparatus

The product specified by T4 bacteriophage gene 41 is known from genetic analyses to be essential for phage DNA replication in vivo. Correspondingly, the purified gene 41 protein is an essential component of an efficient in vitro DNA replication system reconstructed from seven purified T4 replication proteins; it is required both for the synthesis of short RNA primers (in conjunction with the T4 gene 61 protein) and for the rapid unwinding of the double-helical DNA template at a replication fork. The purified gene 41 protein exhibits a DNA-dependent GTPase (and ATPase) activity. In this report, we have used this associated GTPase activity as a biochemical probe for the analysis of the interactions between DNA and the 41 protein. Our results suggest that, upon binding GTP, the 41 protein monomer is induced to form a dimer, which can them form a tight complex with single-stranded DNA. Driven by the repeated hydrolysis of GTP molecules, the 41 protein dimer appears to run rapidly along the bound DNA chain. Studies with the synthetic GTP analogue, GTP gamma S, suggest that GTP hydrolysis is required for this 41 protein movement, but that it is not essential for the function of the 41 protein in RNA primer synthesis. In sum, our observations suggest that a 41 protein dimer runs along the lagging strand template at a DNA replication fork; from this position, it functions as a DNA helicase and simultaneously interacts with the T4 gene 61 protein to make the pentaribonucleotide primers which initiate Okazaki pieces at specific primer initiation sites.     

Regulation of the synthesis of bacteriophage T4 gene 32 protein

The synthesis of T4 gene 32 product (P32) has been followed by gel electrophoresis of infected cell lysates. In wild-type infections, its synthesis starts soon after infection and begins to diminish about the time late gene expression commences. The absence of functional P32 results in a marked increase in the amount of the non-functional P32 synthesized. For example, infections of T4 mutants which contain a nonsense mutation in gene 32 produce the nonsense fragment at more than ten times the maximum rate of synthesis of the gene product observed in wild-type infections. All of the temperature-sensitive mutants in gene 32 that were tested also overproduce this product at the non-permissive temperature. This increased synthesis of the non-functional product is recessive, since mixed infections (wild-type, gene 32 nonsense mutant) fail to overproduce the nonsense fragment.Mutations in genes required for late gene expression (genes 33 and 53) as well as some genes required for normal DNA synthesis also result in increased production of P32. The overproduction in such infections is dependent on DNA synthesis; in the absence of DNA synthesis no overproduction occurs. This contrasts with the overproduction resulting from the absence of functional P32 which is not dependent on DNA synthesis.These results are compatible with a model for the regulation of expression of gene 32 in which the synthesis of P32 is either directly or indirectly controlled by its own function. Thus, in the absence of P32 function the expression of this gene is increased as is manifest by the high rate of P32 synthesis. It is further suggested that in infections defective in late gene expression and consequently in the maturation of replicated DNA, the increased P32 production is caused by the large expansion of the DNA pool. This DNA is presumed to compete for active P32 by binding it non-specifically to single-stranded regions, thus reducing the amount of P32 free to block gene 32 expression. Similarly, the aberrant DNA synthesized following infections with mutants in genes 41, 56, 58, 60 and 30, although quantitatively less than that produced in the maturation defective infections, can probably bind large quantities of P32 to single-stranded regions resulting in increased P32 synthesis.     

Gamma-T4 hybrid bacteriophage carrying the thymidine kinase gene of bacteriophage T4.

Among 32 lambda-T4 recombinant phages selected for growth on a thymidylate synthetase-deficient (thyA) host, 2 were shown to carry the T4 thymidine kinase (tk) gene. The lambda-T4tk phages contain two T4 HindIII DNA fragments (2.0 and 1.5 kilobases) that hybridize to restriction fragments of T4 DNA, encompassing the tk locus at 60 kilobases on the T4 map. The T4tk insert compensates for the simultaneous host deficiencies of thymidine kinase and thymidylate synthetase in a thymidine kinase-deficient (tdk) host growing in the presence of fluorodeoxyuridine when provided with thymidine and uridine. The lambda-T4tk hybrid phages specified five polypeptides with Mrs of 22,000 (22K), 21K, 14K, 11K, and 9K.     

Identification of the gene encoding an RNA polymerase-binding protein of bacteriophage T4.

One of five bacteriophage T4-specified proteins that bind to host RNA polymerase core has been purified and partially sequenced. A mixed oligonucleotide, based on the amino acid sequence, was used to probe genomic restriction fragments. The gene for this protein, previously designated the 15K protein, has been located between T4 genes 45 and 46 and designated rpbA.     

GTPase activity of bacteriophage T4 sheath protein.

We show by nuclear magnetic resonance studies that, following GTP hydrolysis during phage T4 sheath contraction, GDP remains bound to the sheath protein (gp18), whereas orthophosphate is released. gp18 in the contracted state has GTPase activity and can hydrolyse exogenous GTP; the reaction is calcium-dependent and displays high substrate specificity. The process comprises two steps: (1) displacement of GDP from gp18 by exogenous GTP, and (2) GTP hydrolysis proper. The first step appears to be rate-limiting and to be accelerated when the nucleotide-protein interaction is mechanically disrupted by sonication.