Site-specific recognition of bacteriophage T4 DNA by T4 type II DNA topoisomerase and Escherichia coli DNA gyrase

The site specificity of bacteriophage T4-induced type II DNA topoisomerase action on double-stranded DNA has been explored by studying the sites where DNA cleavages are induced by the enzyme. Oxolinic acid addition increases the frequency at which phi X174 duplex DNA is cut by the enzyme by about 100-fold, to the point where nearly every topoisomerase molecule causes a double-stranded DNA cleavage event. The effect of oxolinic acid on the enzyme is very similar to its effect on another type II DNA topoisomerase, the Escherichia coli DNA gyrase. A filter-binding method was developed that allows efficient purification of topoisomerase-cleaved DNA fragments by selecting for the covalent attachment of this DNA to the enzyme. Using this method, T4 topoisomerase recognition of mutant cytosine-containing T4 DNA was found to be relatively nonspecific, whereas quite specific recognition sites were observed on native T4 DNA, which contains glucosylated hydroxymethylcytosine residues. The increased specificity of native T4 DNA recognition seems to be due entirely to the glucose modification. In contrast, E. coli DNA gyrase shows a high level of specificity for both the mutant cytosine-containing DNA and native T4 DNA, recognizing about five strong cleavage sites on both substrates. An unexpected feature of DNA recognition by the T4 topoisomerase is that the addition of the cofactor ATP strongly stimulates the topoisomerase-induced cleavage of native T4 DNA, but has only a slight effect on cleavage of cytosine-containing T4 DNA.     

Recognition of DNA substrates by T4 bacteriophage polynucleotide kinase

T4 phage polynucleotide kinase (PNK) displays 5′-hydroxyl kinase, 3′-phosphatase and 2′,3′-cyclic phosphodiesterase activities. The enzyme phosphorylates the 5′ hydroxyl termini of a wide variety of nucleic acid substrates, a behavior studied here through the determination of a series of crystal structures with single-stranded (ss)DNA oligonucleotide substrates of various lengths and sequences. In these structures, the 5′ ribose hydroxyl is buried in the kinase active site in proper alignment for phosphoryl transfer. Depending on the ssDNA length, the first two or three nucleotide bases are well ordered. Numerous contacts are made both to the phosphoribosyl backbone and to the ordered bases. The position, side chain contacts and internucleotide stacking interactions of the ordered bases are strikingly different for a 5′-GT DNA end than for a 5′-TG end. The base preferences displayed at those positions by PNK are attributable to differences in the enzyme binding interactions and in the DNA conformation for each unique substrate molecule.     

Role of recombinational repair in sensitivity to an antitumour agent that inhibits bacteriophage T4 type II DNA topoisomerase

The bacteriophage T4-encoded type II DNA topoisomerase is the major target for the antitumour agent m-AMSA (4-(9-acridinylamino)methanesulphon-m-anisidide) in phage-infected bacterial cells. Inhibition of the purified enzyme by m-AMSA results in formation of a cleavage complex that contains the enzyme covalently attached to DNA on both sides of a double-strand break. In this article, we provide evidence that this cleavage complex is responsible for inhibition of phage growth and that recombinational repair can reduce sensitivity to the antitumour agent, presumably by eliminating the complex (or some derivative thereof). First, topoisomerase-deficient mutants were shown to be resistant to m-AMSA, indicating that m-AMSA inhibits growth by inducing the cleavage complex rather than by inhibiting enzyme activity. Second, mutations in several phage genes that encode recombination proteins (uvsX, uvsY, 46 and 59) increased the sensitivity of phage T4 to m-AMSA, strongly suggesting that recombination participates in the repair of topoisomerase-mediated damage. Third, m-AMSA stimulated recombination in phage-infected bacterial cells, as would be expected from the recombinational repair of DNA damage. Finally, m-AMSA induced the production of cleavage complexes involving the T4 topoisomerase within phage-infected cells.     

Hotspot sites for acridine-induced frameshift mutations in bacteriophage T4 correspond to sites of action of the T4 type II topoisomerase

The type II topoisomerase of bacteriophage T4 is a central determinant of the frequency and specificity of acridine-induced frameshift mutations. Acridine-induced frameshift mutagenesis is specifically reduced in a mutant defective in topoisomerase activity. The ability of an acridine to promote topoisomerase-dependent cleavage at specific DNA sites in vitro is correlated to its ability to produce frameshift mutations at those sites in vivo. The specific phosphodiester bonds cleaved in vitro are precisely those at which frameshifts are most strongly promoted by acridines in vivo. The cospecificity of in vitro cleavage and in vivo mutation implicate acridine-induced, topoisomerase-mediated DNA cleavages as intermediates of acridine-induced mutagenesis in T4.     

Nucleotide-dependent binding of the gene 4 protein of bacteriophage T7 to single-stranded DNA

The gene 4 protein of bacteriophage T7 is a multifunctional enzyme that catalyzes (i) the hydrolysis of nucleoside 5'-triphosphates, (ii) the synthesis of tetraribonucleotide primers at specific recognition sequences on a DNA template, and (iii) the unwinding of duplex DNA. All three activities depend on binding of gene 4 protein to single-stranded DNA followed by unidirectional 5' to 3' translocation of the protein (Tabor, S., and Richardson, C. C. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 205-209). Binding of gene 4 protein to single-stranded DNA, assayed by retention of DNA-protein complexes on nitrocellulose filters, is random with regard to DNA sequence. Although gene 4 protein does not bind to duplex DNAs, the presence of a 240-nucleotide-long single-stranded tail on a 7200-base pair duplex DNA molecule is sufficient for gene 4 protein to cause retention of the DNA on a filter. The binding reaction requires, in addition to MgCl2, the presence of a nucleoside 5'-triphosphate, but binding is not dependent on hydrolysis; nucleoside 5'-diphosphate will substitute for nucleoside 5'-triphosphate. Of the eight common nucleoside triphosphates, dTTP promotes optimal binding. The half-life of the gene 4 protein-DNA complex depends on both the secondary structure of the DNA and on whether or not the nucleoside 5'-triphosphate cofactor can be hydrolyzed. Using the nonhydrolyzable nucleoside 5'-triphosphate analog, beta,gamma-methylene dTTP, the half-life of the gene 4 protein-DNA complex is greater than 80 min. In the presence of the hydrolyzable nucleoside 5'-triphosphate, dTTP, the half-life of the gene 4 protein-DNA complex using circular M13 DNA is at least 4 times longer than that observed using linear M13 DNA.     

Recognition of chemically damaged DNA by the gene 32 protein from bacteriophage T4

We have used fluorescence spectroscopy to investigate the binding of gene 32 protein from bacteriophage T4 to DNA which has been chemically modified with carcinogens or antitumor drugs. This protein exhibits a high specificity for single-stranded nucleic acids and binds more efficiently to DNA modified either with cis-diaminodichloroplatinum(II) or with aminofluorene derivatives than to native DNA. This increased affinity is related to the formation of locally unpaired regions which are strong binding sites for the single-strand binding protein. In contrast, gene 32 protein has the same affinity for native DNA, DNA containing methylated purines and DNA that has reacted with trans-diaminodichloroplatinum(II) or with chlorodiethylenetriaminoplatinum(II) chloride. These types of damage do not induce a sufficient structural change to allow gene 32 protein binding. Depurination of DNA does not create binding sites for the T4 gene 32 protein but nicked apurinic sites are strong ligands for the protein. This T4 single-strand binding protein does not exhibit a significantly increased affinity for nicked DNA as compared with native DNA. These results are discussed with respect to the recognition of DNA damage by proteins involved in DNA repair and to the possible role of single-strand binding proteins in DNA repair mechanisms.     

Common sites for recombination and cleavage mediated by bacteriophage T4 DNA topoisomerase in vitro

We have previously shown that purified T4 DNA topoisomerase promotes illegitimate recombination between two lambda DNA molecules, or between lambda and plasmid DNA in vitro (Ikeda, H. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 922-926). Since the recombinant DNA contains a duplication or deletion, it is inferred that the cross-overs take place between nonhomologous sequences of lambda DNA. In this paper, we have examined the sequences of the recombination junctions produced by the recombination between two lambda DNA molecules mediated by T4 DNA topoisomerase. We have shown that there is either no homology or there are 1-5-base pair homologies between the parental DNAs in seven combinations of lambda recombination sites, indicating that homology is not essential for the recombination. Next, we have shown an association of the recombination sites with the topoisomerase cleavage sites, indicating that a capacity of the topoisomerase to make a transient double-stranded break in DNA plays a role in the illegitimate recombination. A consensus sequence for T4 topoisomerase cleavage sites, RNAY decreases NNNNRTNY, was deduced. The cleavage experiment showed that T4 topoisomerase-mediated cleavage takes place in a 4-base pair staggered fashion and produces 5'-protruding ends.     

Structure calculations for single-stranded DNA complexed with the single-stranded DNA binding protein GP32 of bacteriophage T4: a remarkable DNA structure

In this study it is established by calculation which regular conformations single-stranded DNA and RNA can adopt in the complex with the single-stranded DNA binding protein GP32 of bacteriophage T4. In order to do so, information from previous experiments about base orientations and the length and diameter of the complexes is used together with knowledge about bond lengths and valence angles between chemical bonds. It turns out that there is only a limited set of similar conformations which are in agreement with experimental data. The arrangement of neighboring bases is such that there is ample space for aromatic residues of the protein to partly intercalate between the bases, which is in agreement with a previously proposed model for the binding domain of the protein [Prigodich, R. V., Shamoo, Y., Williams, K. R., Chase, J. W., Konigsberg, W. H., & Coleman, J. E. (1986) Biochemistry 25, 3666-3671]. Both C2'endo and C3'endo sugar conformations lead to calculated DNA conformations that are consistent with experimental data. The orientation of the O2' atoms of the sugars in RNA can explain why the binding affinity of GP32 for polyribonucleotides is lower than for polydeoxyribonucleotides.     

Increasing the length of the single-stranded overhang enhances unwinding of duplex DNA by bacteriophage T4 Dda helicase

Dda has been shown previously to be active as a monomer for DNA unwinding [Nanduri et al. (2002) Proc. Natl. Acad. Sci. U.S.A. 99, 14722] and streptavidin displacement [Byrd and Raney (2004) Nat. Struct. Mol. Biol. 11, 531]. However, its activity for streptavidin displacement increased as a function of the length of single-stranded DNA. We investigated whether Dda exhibited enhanced DNA unwinding of partially duplex DNA substrates as a function of increasing the length of the single-stranded overhangs. DNA substrates were prepared containing 16 base pairs and single-stranded overhangs of 4, 6, 8, 12, 16, 20, and 24 nucleotides. Under single turnover conditions in the presence of excess enzyme, the quantity of DNA unwound increased significantly as the length of the single strand overhang increased. Increased processivity was observed when the DNA substrate contained longer single-stranded overhangs. Equilibrium binding studies indicated that Dda bound to the substrates containing the longer overhangs significantly better than the shorter overhangs. To determine whether the increased processivity for unwinding was due to multiple molecules of Dda or due to the increased binding affinity to the longer overhangs, DNA unwinding was conducted under pre-steady-state conditions, which favor binding of monomeric Dda. Under pre-steady-state conditions, the quantity of product decreased somewhat as the single-stranded length increased, from 12 to 24 nucleotides. Thus, when monomeric Dda is required to translocate longer distances prior to unwinding, processivity is lowered. Taken together, these results indicate that enhanced binding to the longer single-stranded overhangs was not responsible for enhanced processivity under conditions of excess enzyme. Rather, multiple molecules of Dda bound to the same substrate exhibit greater processivity for DNA unwinding.     

Crystallization of a tryptic core of the single-stranded DNA binding protein of bacteriophage T4

A tryptic core (residues 22 to 253) of the single-stranded DNA binding protein, or gene 32 protein, of bacteriophage T4 has been crystallized in four different crystal forms. One of these forms appears suitable for high-resolution X-ray crystallographic studies. It is triclinic, space group PI, with $\text{a = 67.7}\text{A}\text{?}\text{, b = 67.8}\text{A}\text{?}\text{, c = 66.0}\text{A}\text{?}\text{, α = 101.6 °, β = 107.0 °, γ = 105.2 °}$. There appear to be three protein protomers in a near-rhombohedral packing in the unit cell.     

Template-independent ligation of single-stranded DNA by T4 DNA ligase

T4 DNA ligase is one of the workhorses of molecular biology and used in various biotechnological applications. Here we report that this ligase, unlike Escherichia coli DNA ligase, Taq DNA ligase and Ampligase, is able to join the ends of single-stranded DNA in the absence of any duplex DNA structure at the ligation site. Such nontemplated ligation of DNA oligomers catalyzed by T4 DNA ligase occurs with a very low yield, as assessed by quantitative competitive PCR, between 10(-6) and 10(-4) at oligonucleotide concentrations in the range 0.1-10 nm, and thus is insignificant in many molecular biological applications of T4 DNA ligase. However, this side reaction may be of paramount importance for diagnostic detection methods that rely on template-dependent or target-dependent DNA probe ligation in combination with amplification techniques, such as PCR or rolling-circle amplification, because it can lead to nonspecific background signals or false positives. Comparison of ligation yields obtained with substrates differing in their strandedness at the terminal segments involved in ligation shows that an acceptor duplex DNA segment bearing a 3'-hydroxy end, but lacking a 5'-phosphate end, is sufficient to play a role as a cofactor in blunt-end ligation.     

Nucleotide sequence of a type II DNA topoisomerase gene. Bacteriophage T4 gene 39.

T4 DNA topoisomerase is a type II enzyme and is thought to be required for normal T4 DNA replication T4 gene 39 codes for the largest of the three subunits of T4 DNA topoisomerase. I have determined the nucleotide sequence of a region of 2568 nucleotides of T4 DNA which includes gene 39. The location of the gene was established by the identification of the first fifteen amino acids in the large open reading frame in the DNA sequence as those found at the amino-terminus of the purified 39-protein. The coding region of gene 39 has 1560 bases, and it is followed by two in-frame stop codons. The gene is preceded by a typical Shine-Dalgarno sequence as well as possible promoter sequences for E. coli RNA polymerase. T4 39-protein consists of 520 amino acids, and it has a calculated molecular weight of 58,478. By comparing the amino acid sequences, T4 39-protein is found to share homology with the gyrB subunit of DNA gyrase. This suggests that these topoisomerase subunits may be equivalent functionally. Some of the characteristics of the 39-protein and its structural features predicted from the DNA sequence data are discussed.     

Pauses at positions of secondary structure during in vitro replication of single-stranded fd bacteriophage DNA by T4 DNA polymerase

Since bacteriophage T4 DNA polymerase is unable to use duplex DNA molecules as templates (B. Alberts, J. Barry, M. Brittner, M. Davies, H. Hama-Inaba, C. C. Liu, D. Mace, L. Moran, C. F. Morris, J. Piperno, and N. Sinha, 1977, in Nucleic Acids and Protein Recognition, Vogel, H. J., ed., pp. 31–63, Academic Press, New York), a technique involving synchronous and uniquely primed synthesis of DNA on the single-stranded fd DNA by the T4 DNA polymerase has been developed to probe regions exhibiting secondary structure on this genome. As the polymerase proceeds, the template secondary structure acts as a kinetic barrier to delay the continuous chain extension catalyzed by this enzyme. These kinetic pause sites can be mapped by denaturing agarose gel electrophoresis of replication intermediates and used to generate a secondary structure map. Using this method, we are able to establish a list including at least seven plausible stable helical regions in fd DNA. Two of the most stable secondary structures have been mapped near fd sequence positions 3350 and 5650, respectively. The latter has been reported to be the region where fd DNA replication begins (C. P. Gray, R. Sommer, C. Polke, E. Beck, and H. Schaller, 1978, Proc. Nat. Acad. Sci. USA, 75, 50–53). However, the biological function associated with the former has yet to be investigated. Following a two-state model, we estimate the first-order rate constant for progression through the duplex regions near position 5650 in fd DNA to be about 0.042 min^?1 for fd DNA synthesis by the T4 DNA polymerase under our reaction conditions. A 7.5-fold increase in this rate constant is obtained upon the addition of the T4 DNA helix destabilizing protein (i.e., gene 32 protein). The general pattern of our secondary structure map agrees well with a computer search for duplex regions on the fd genome. Both the stability and the size of a stable secondary structure at a particular position on the fd template determine the time that the newly made DNA molecules spend at that site. A structure with a stem of less than 8 base pairs does not interrupt significantly the procession of the T4 DNA polymerase during the process of fd DNA synthesis.     

Defect in synthesis of deoxyribonucleotides by a bacteriophage T4 nrdB mutant is suppressed on mutation of T4 DNA topoisomerase gene

Bacteriophage T4 infection is known to induce the formation of a complex of enzymes effecting the de novo synthesis of deoxyribonucleoside triphosphates, which in turn are channeled into T4 DNA replication. The first step in this pathway is catalyzed by a ribonucleoside diphosphate reductase, comprised of subunits coded by T4 genes nrdA and nrdB. Maximum rates of synthesis of the pyrimidine deoxyribonucleotides and of DNA replication in vivo also require a type II DNA topoisomerase encoded by T4 genes 39, 52, and 60. We report the identification of a unique mutant, nrdB93, and the suppression of its defective deoxyribonucleotide synthesis by a gene 39 mutation, 39-01. After infection by 39-01, DNA synthesis and plaque formation were temperature-sensitive, but nearly wild type rates of deoxyribonucleotide synthesis were retained at all temperatures. The nrdB93 mutation had a profound effect on deoxyribonucleotide synthesis at 41 degrees C; even at the permissive temperature of 30 degrees C, synthesis was reduced to 30% of that of wild type or 39-01. However, on infection at 30 degrees C by the double mutant, 39-01 nrdB93, the level of deoxyribonucleotide synthesis again reached that of wild type phage infections; involvement of the comparable host enzyme in the suppression process has been excluded. Suppression of the effect of nrdB93 by 39-01 implicates the gene 39 product in the regulation of nrdB expression. The accompanying paper (Cook, K. S., Wirak, D. O., Seasholtz, A. F., and Greenberg, G. R. (1988) J. Biol. Chem. 263, 6202-6208) examines the nature of the suppression process at the molecular level.     

Dual functions of single-stranded DNA-binding protein in helicase loading at the bacteriophage T4 DNA replication fork

Semi-conservative DNA synthesis reactions catalyzed by the bacteriophage T4 DNA polymerase holoenzyme are initiated by a strand displacement mechanism requiring gp32, the T4 single-stranded DNA (ssDNA)-binding protein, to sequester the displaced strand. After initiation, DNA helicase acquisition by the nascent replication fork leads to a dramatic increase in the rate and processivity of leading strand DNA synthesis. In vitro studies have established that either of two T4-encoded DNA helicases, gp41 or dda, is capable of stimulating strand displacement synthesis. The acquisition of either helicase by the nascent replication fork is modulated by other protein components of the fork including gp32 and, in the case of the gp41 helicase, its mediator/loading protein gp59. Here, we examine the relationships between gp32 and the gp41/gp59 and dda helicase systems, respectively, during T4 replication using altered forms of gp32 defective in either protein-protein or protein-ssDNA interactions. We show that optimal stimulation of DNA synthesis by gp41/gp59 helicase requires gp32-gp59 interactions and is strongly dependent on the stability of ssDNA binding by gp32. Fluorescence assays demonstrate that gp59 binds stoichiometrically to forked DNA molecules; however, gp59-forked DNA complexes are destabilized via protein-protein interactions with the C-terminal "A-domain" fragment of gp32. These and previously published results suggest a model in which a mobile gp59-gp32 cluster bound to lagging strand ssDNA is the target for gp41 helicase assembly. In contrast, stimulation of DNA synthesis by dda helicase requires direct gp32-dda protein-protein interactions and is relatively unaffected by mutations in gp32 that destabilize its ssDNA binding activity. The latter data support a model in which protein-protein interactions with gp32 maintain dda in a proper active state for translocation at the replication fork. The relationship between dda and gp32 proteins in T4 replication appears similar to the relationship observed between the UL9 helicase and ICP8 ssDNA-binding protein in herpesvirus replication.     

A single-stranded DNA-binding protein of bacteriophage T7 defective in DNA annealing

The annealing of complementary strands of DNA is a vital step during the process of DNA replication, recombination, and repair. In bacteriophage T7-infected cells, the product of viral gene 2.5, a single-stranded DNA-binding protein, performs this function. We have identified a single amino acid residue in gene 2.5 protein, arginine 82, that is critical for its DNA annealing activity. Expression of gene 2.5 harboring this mutation does not complement the growth of a T7 bacteriophage lacking gene 2.5. Purified gene 2.5 protein-R82C binds single-stranded DNA with a greater affinity than the wild-type protein but does not mediate annealing of complementary strands of DNA. A carboxyl-terminal-deleted protein, gene 2.5 protein-Delta26C, binds even more tightly to single-stranded DNA than does gene 2.5 protein-R82C, but it anneals homologous strands of DNA as well as does the wild-type protein. The altered protein forms dimers and interacts with T7 DNA polymerase comparable with the wild-type protein. Gene 2.5 protein-R82C condenses single-stranded M13 DNA in a manner similar to wild-type protein when viewed by electron microscopy.     

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.     

Illegitimate recombination mediated by T4 DNA topoisomerase in vitro

Summary Illegitimate recombination dependent on T4 DNA topoisomerase in a cell-free system has recently been described. In that work, recombinants between two phage DNA molecules were produced by the topoisomerase alone, without an Escherichia coli extract. In this paper, it is shown that recombination between phage and circular plasmid DNA molecules can also be detected in the presence or absence of an E. coli extract but at frequencies two or three orders of magnitude lower than that observed in the phage-phage cross. The frequency is probably lower because multiple recombination is required in the case of the phage-plasmid cross.