Investigation of the role of individual tryptophan residues in the binding of Escherichia coli single-stranded DNA binding protein to single-stranded polynucleotides. A study by optical detection of magnetic resonance and site-selected mutagenesis

Fluorescence and optical detection of triplet state magnetic resonance (ODMR) spectroscopy have been employed to study the complexes formed between single-stranded polynucleotides and Escherichia coli ssb gene products (SSB) in which tryptophans 40, 54, and 88 are selectively, one residue at a time, replaced by phenylalanine using site-specific oligonucleotide mutagenesis. Fluorescence titrations and ODMR results indicate that tryptophans 40 and 54 are the only tryptophan residues in E. coli single-stranded DNA binding protein that are involved in stabilizing the protein-nucleic acid complexes via stacking interactions. Wavelength-selected ODMR measurements on E. coli SSB reveal the presence of two spectrally distinct tryptophan sites (Khamis, M. I., Casas-Finet, J. R., and Maki, A. H. (1987) J. Biol. Chem. 262, 1725-1733). Our present results indicate that tryptophan 54 belongs to the blue-shifted site, while tryptophan 40 belongs to the red-shifted site of the protein.     

An IncY plasmid-encoded single-stranded DNA-binding protein from Escherichia coli shows the identical pattern of stacked tryptophan residues as the chromosomal ssb gene product

In an extension of earlier studies on the Escherichia coli plasmid-encoded single-stranded DNA-binding proteins pIP71a SSB, F SSB and R64 SSB [Khamis, M. I., Casas-Finet, J. R., Maki, A. H., Ruvolo, P. P. & Chase, J. W. (1987) Biochemistry 26, 3347-3354; Casas-Finet, J. R., Khamis, M. I., Maki, A. H., Ruvolo, P. P. & Chase, J. W. (1987) J. Biol. Chem. 262, 8574-8593], we have investigated the binding of pIP231a SSB to natural and heavy-atom-derivatized single-stranded homopolynucleotides. Fluorimetric equilibrium binding isotherms indicate that pIP231a SSB has a greater solubility at low ionic strength than any other plasmid SSB protein investigated. Furthermore, its complex with mercurated poly(uridylic acid) [poly(Hg5U)] shows a greater resistance to disruption by salt than the other plasmid SSB complexes. Essentially complete binding of pIP231a SSB to poly(Hg5U) could be achieved, and time-resolved optically detected triplet-state magnetic resonance (ODMR) techniques could be applied to the complex. These methods allowed complete resolution of the three Trp chromophores of pIP231a SSB. Comparison of wavelength-selected ODMR results with those obtained for the poly(Hg5U) complex of a point-mutated chromosomal ssb gene product (Eco SSB) carrying substitutions of Phe for Trp [Khamis, M. I., Casas-Finet, J. R., Maki, A. H., Murphy, J. B. & Chase, J. W. (1987) J. Biol. Chem. 262, 10938-10945] confirm that Trp40 and Trp54 of pIP231a SSB are stacked in the complex, while Trp88 is not. This is the same distribution of stacked Trp residues found in Eco SSB. These results are confirmed further by specific effects observed on the ODMR signals of pIP231a SSB upon binding to poly(Br5U) and poly(dT), which are known to be caused by the stacking of Trp54 with nucleic acid bases.     

Laser cross-linking of nucleic acids to proteins. Methodology and first applications to the phage T4 DNA replication system

Single-pulse (approximately 8 ns) ultraviolet laser excitation of protein-nucleic acid complexes can result in efficient and rapid covalent cross-linking of proteins to nucleic acids. The reaction produces no nucleic acid-nucleic acid or protein-protein cross-links, and no nucleic acid degradation. The efficiency of cross-linking is dependent on the wavelength of the exciting radiation, on the nucleotide composition of the nucleic acid, and on the total photon flux. The yield of cross-links/laser pulse is largest between 245 and 280 nm; cross-links are obtained with far UV photons (200-240 nm) as well, but in this range appreciable protein degradation is also observed. The method has been calibrated using the phage T4-coded gene 32 (single-stranded DNA-binding) protein interaction with oligonucleotides, for which binding constants have been measured previously by standard physical chemical methods (Kowalczykowski, S. C., Lonberg, N., Newport, J. W., and von Hippel, P. H. (1981) J. Mol. Biol. 145, 75-104). Photoactivation occurs primarily through the nucleotide residues of DNA and RNA at excitation wavelengths greater than 245 nm, with reaction through thymidine being greatly favored. The nucleotide residues may be ranked in order of decreasing photoreactivity as: dT much greater than dC greater than rU greater than rC, dA, dG. Cross-linking appears to be a single-photon process and occurs through single nucleotide (dT) residues; pyrimidine dimer formation is not involved. Preliminary studies of the individual proteins of the five-protein T4 DNA replication complex show that gene 43 protein (polymerase), gene 32 protein, and gene 44 and 45 (polymerase accessory) proteins all make contact with DNA, and can be cross-linked to it, whereas gene 62 (polymerase accessory) protein cannot. A survey of other nucleic acid-binding proteins has shown that E. coli RNA polymerase, DNA polymerase I, and rho protein can all be cross-linked to various nucleic acids by the laser technique. The potential uses of this procedure in probing protein-nucleic acid interactions are discussed.     

Structural and functional comparative study of the complexes formed by viral ø29, Nf and GA-1 SSB proteins with DNA

Single-stranded DNA-binding proteins have in common their crucial roles in DNA metabolism, although they exhibit significant differences in their single-stranded DNA binding properties. To evaluate the correlation between the structure of different nucleoprotein complexes and their function, we have carried out a comparative study of the complexes that the single-stranded DNA-binding proteins of three related bacteriophages, ?29, Nf and GA-1, form with single-stranded DNA. Under the experimental conditions used, ?29 and Nf single-stranded DNA-binding proteins are stable monomers in solution, while GA-1 single-stranded DNA-binding protein presents a hexameric state, as determined in glycerol gradients. The thermodynamic parameters derived from quenching measurements of the intrinsic protein fluorescence upon single-stranded DNA binding revealed (i) that GA-1 single-stranded DNA-binding protein occludes a larger binding site (n=51 nt/oligomer) than ?29 and Nf SSBs (n=3.4 and 4.7 nt/monomer, respectively); and (ii) that it shows a higher global affinity for single-stranded DNA (GA-1 SSB, K(eff)=18.6 x 10(5) M(-1); o29 SSB, K(eff)=2.2 x 10(5) M(-1); Nf SSB, K(eff)=2.9 x 10(5) M(-1)). Altogether, these parameters justify the differences displayed by the GA-1 single-stranded DNA-binding protein and single-stranded DNA complex under the electron microscope, and the requirement of higher amounts of ?29 and Nf single-stranded DNA-binding proteins than of GA-1 SSB in gel mobility shift assays to produce a similar effect. The structural differences of the nucleoprotein complexes formed by the three single-stranded DNA-binding proteins with single-stranded DNA correlate with their different functional stimulatory effects in ?29 DNA amplification.     

Limited proteolysis studies on the Escherichia coli single-stranded DNA binding protein. Evidence for a functionally homologous domain in both the Escherichia coli and T4 DNA binding proteins

Limited proteolysis can be used to remove either 42 or 62 amino acids at the COOH terminus of the 18,873-dalton Escherichia coli single-stranded DNA binding protein (SSB). Since poly(dT), but not d(pT)16, increases the rate of this reaction, it appears that cooperative SSB binding to single-stranded DNA (ssDNA) is associated with a conformational change that increases the exposure of the COOH terminus to proteolysis. As a result of this DNA-induced conformational change, we presume that the COOH-terminal region of SSB will become more accessible for interacting with other proteins that utilize the SSB:ssDNA complex as a substrate and that are involved in E. coli DNA replication, repair, and recombination. Removal of this COOH-terminal domain from SSB results in a stronger helix-destabilizing protein which suggests this region may be important for controlling the ability of SSB to denature double-stranded DNA. Since similar results have previously been reported for the bacteriophage T4 gene 32 protein (Williams, K.R., and Konigsberg, W. (1978) J. Biol. Chem. 253, 2463-2470; Hosoda, J., and Moise, H. (1978) J. Biol. Chem. 253, 7547-7555), the acidic, COOH-terminal domains of these two single-stranded DNA binding proteins may be functionally homologous. Preliminary evidence is cited that suggests other prokaryotic and eukaryotic DNA binding proteins may contain similar functional domains essential for controlling their ability to invade double helical DNA.     

Photoaffinity labeling of the thymidine triphosphate binding domain in Escherichia coli DNA polymerase I: identification of histidine-881 as the site of cross-linking

Using the technique of ultraviolet-mediated cross-linking of substrate deoxynucleoside triphosphates (dNTPs) to their acceptor site [Abraham, K. I., & Modak, M. J. (1984) Biochemistry 23, 1176-1182], we have labeled the Klenow fragment of Escherichia coli DNA polymerase I (Pol I) with [alpha-32P]dTTP. Covalent cross-linking of [alpha-32P]dTTP to the Klenow fragment is shown to be at the substrate binding site by the following criteria: (a) the cross-linking reaction requires dTTP in its metal chelate form; (b) dTTP is readily competed out by other dNTPs as well as by substrate binding site directed reagents; (c) labeling with dTTP occurs at a single site as judged by peptide mapping. Under optimal conditions, a modification of approximately 20% of the enzyme was achieved. Following tryptic digestion of the [alpha-32P]dTTP-labeled Klenow fragment, reverse-phase high-performance liquid chromatography demonstrated that 80% of the radioactivity was contained within a single peptide. The amino acid composition and sequence of this peptide identified it as the peptide spanning amino acid residues 876-890 in the primary sequence of E. coli Pol I. Chymotrypsin and Staphylococcus aureus V8 protease digestion of the labeled tryptic peptide in each case yielded a single smaller fragment that was radioactive. Amino acid analysis and sequencing of these smaller peptides further narrowed the dTTP cross-linking site to within the region spanning residues 876-883. We concluded that histidine-881 is the primary attachment site for dTTP in E. coli DNA Pol I, since during amino acid sequencing analysis of all three radioactive peptides loss of the histidine residue at the expected cycle is observed.     

A plasmid vector system for the expression of a triprotein consisting of beta-galactosidase, a collagenase recognition site and a foreign gene product

A plasmid-cloning vector system has been constructed which allows the production of fusion proteins with beta-galactosidase at the N terminus, followed by a recognition sequence for the site-specific protease, collagenase, and the foreign protein at the C terminus. A multicloning site allows the insertion of foreign genes in any translational reading frame. Fusion proteins were isolated by affinity chromatography on APTG-Sepharose. The foreign protein was released from the fusion product by collagenase cleavage. The vector was successfully utilized for the production of Escherichia coli single-stranded (ss) DNA-binding protein (SSB protein). The proteolytically released SSB protein resisted elution from an ss DNA-cellulose column with 1 M NaCl.     

Identification of peptide sequences at the tRNA binding site of Escherichia coli methionyl-tRNA synthetase

Four different structural regions of Escherichia coli tRNAfMet have been covalently coupled to E. coli methionyl-tRNA synthetase (MetRS) by using a tRNA derivative carrying a lysine-reactive cross-linker. We have previously shown that this cross-linking occurs at the tRNA binding site of the enzyme and involves reaction of only a small number of the potentially available lysine residues in the protein [Schulman, L. H., Valenzuela, D., & Pelka, H. (1981) Biochemistry 20, 6018-6023; Valenzuela, D., Leon, O., & Schulman, L. H. (1984) Biochem. Biophys. Res. Commun. 119, 677-684]. In this work, four of the cross-linked peptides have been identified. The tRNA-protein cross-linked complex was digested with trypsin, and the peptides attached to the tRNA were separated from the bulk of the tryptic peptides by anion-exchange chromatography. The tRNA-bound peptides were released by cleavage of the disulfide bond of the cross-linker and separated by reverse-phase high-pressure liquid chromatography, yielding five major peaks. Amino acid analysis indicated that four of these peaks contained single peptides. Sequence analysis showed that the peptides were cross-linked to tRNAfMet through lysine residues 402, 439, 465, and 640 in the primary sequence of MetRS. Binding of the tRNA therefore involves interactions with the carboxyl-terminal half of MetRS, while X-ray crystallographic data have shown the ATP binding site to be located in the N-terminal domain of the protein [Zelwer, C., Risler, J. L., & Brunie, S. (1982) J. Mol. Biol. 155, 63-81].(ABSTRACT TRUNCATED AT 250 WORDS)     

High pressure liquid chromatography purification of UP1 and UP2, two related single-stranded nucleic acid-binding proteins from calf thymus

Two single-stranded nucleic acid-binding proteins, UP1 and UP2, that were originally reported by Herrick and Alberts (Herrick, G., and Alberts, B. (1976) J. Biol. Chem. 251, 2124-2132) have been purified to apparent homogeneity from calf thymus by high performance liquid chromatography. The amino acid sequence of UP1 (Williams, K. R., Stone, K. L., LoPresti, M. B., Merrill, B. M., and Planck, S. R. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 5666-5670) reveals that UP1 contains 195 amino acids, including one dimethylarginine residue near its COOH terminus. Further analysis of this sequence now demonstrates that UP1 contains a 91-residue internal repeat such that when residues 3-93 (the "A" region) are aligned with residues 94-194 (the "B" region), 32% of the amino acids in these two regions are identical and an additional 39% of those changes that are seen could be accomplished by single base changes. The high degree of internal homology between residues 51-61 and 143-152 and in particular the high density of aromatic and positively charged amino acids in these two regions suggest that residues 51-61 and 143-152 may constitute two independent DNA-binding sites. Solid-phase sequencing of three tryptic peptides that together account for 9% of the 39,500-dalton UP2 protein demonstrate that there is a high degree of sequence homology between UP1 and UP2. Of the 34 residues that have been sequenced in UP2, 44% are identical in both UP1 and UP2. The blocked NH2 terminus, amino acid composition, particularly with regard to its high glycine content and the presence of dimethylarginine, and molecular weight of UP2 suggest this protein is related to proteins that have previously been found associated with heterogeneous RNA. Taken together, these data indicate that both UP1 and UP2 belong to a new family of single-stranded nucleic acid-binding proteins that may be closely related to heterogeneous ribonucleoproteins.     

Identification of the SSB Binding Site on E. coli RecQ Reveals a Conserved Surface for Binding SSB's C Terminus

RecQ DNA helicases act in conjunction with heterologous partner proteins to catalyze DNA metabolic activities, including recombination initiation and stalled replication fork processing. For the prototypical Escherichia coli RecQ protein, direct interaction with single-stranded DNA-binding protein (SSB) stimulates its DNA unwinding activity. Complex formation between RecQ and SSB is mediated by the RecQ winged-helix domain, which binds the nine C-terminal-most residues of SSB, a highly conserved sequence known as the SSB-Ct element. Using nuclear magnetic resonance and mutational analyses, we identify the SSB-Ct binding pocket on E. coli RecQ. The binding site shares a striking electrostatic similarity with the previously identified SSB-Ct binding site on E. coli exonuclease I, although the SSB binding domains in the two proteins are not otherwise related structurally. Substitutions that alter RecQ residues implicated in SSB-Ct binding impair RecQ binding to SSB and SSB/DNA nucleoprotein complexes. These substitutions also diminish SSB-stimulated DNA helicase activity in the variants, although additional biochemical changes in the RecQ variants indicate a role for the winged-helix domain in helicase activity beyond SSB protein binding. Sequence changes in the SSB-Ct element are sufficient to abolish interaction with RecQ in the absence of DNA and to diminish RecQ binding and helicase activity on SSB/DNA substrates. These results support a model in which RecQ has evolved an SSB-Ct binding site on its winged-helix domain as an adaptation that aids its cellular functions on SSB/DNA nucleoprotein substrates.     

Mass spectrometric analysis of a UV-cross-linked protein-DNA complex: tryptophans 54 and 88 of E. coli SSB cross-link to DNA

Protein-nucleic acid complexes are commonly studied by photochemical cross-linking. UV-induced cross-linking of protein to nucleic acid may be followed by structural analysis of the conjugated protein to localize the cross-linked amino acids and thereby identify the nucleic acid binding site. Mass spectrometry is becoming increasingly popular for characterization of purified peptide-nucleic acid heteroconjugates derived from UV cross-linked protein-nucleic acid complexes. The efficiency of mass spectrometry-based methods is, however, hampered by the contrasting physico-chemical properties of nucleic acid and peptide entities present in such heteroconjugates. Sample preparation of the peptide-nucleic acid heteroconjugates is, therefore, a crucial step in any mass spectrometry-based analytical procedure. This study demonstrates the performance of four different MS-based strategies to characterize E. coli single-stranded DNA binding protein (SSB) that was UV-cross-linked to a 5-iodouracil containing DNA oligomer. Two methods were optimized to circumvent the need for standard liquid chromatography and gel electrophoresis, thereby dramatically increasing the overall sensitivity of the analysis. Enzymatic degradation of protein and oligonucleotide was combined with miniaturized sample preparation methods for enrichment and desalting of cross-linked peptide-nucleic acid heteroconjugates from complex mixtures prior to mass spectrometric analysis. Detailed characterization of the peptidic component of two different peptide-DNA heteroconjugates was accomplished by matrix-assisted laser desorption/ionization mass spectrometry and allowed assignment of tryptophan-54 and tryptophan-88 as candidate cross-linked residues. Sequencing of those peptide-DNA heteroconjugates by nanoelectrospray quadrupole time-of-flight tandem mass spectrometry identified tryptophan-54 and tryptophan-88 as the sites of cross-linking. Although the UV-cross-linking yield of the protein-DNA complex did not exceed 15%, less than 100 pmole of SSB protein was required for detailed structural analysis by mass spectrometry.     

Saccharomyces cerevisiae SSB1 protein and its relationship to nucleolar RNA-binding proteins.

To better define the function of Saccharomyces cerevisiae SSB1, an abundant single-stranded nucleic acid-binding protein, we determined the nucleotide sequence of the SSB1 gene and compared it with those of other proteins of known function. The amino acid sequence contains 293 amino acid residues and has an Mr of 32,853. There are several stretches of sequence characteristic of other eucaryotic single-stranded nucleic acid-binding proteins. At the amino terminus, residues 39 to 54 are highly homologous to a peptide in calf thymus UP1 and UP2 and a human heterogeneous nuclear ribonucleoprotein. Residues 125 to 162 constitute a fivefold tandem repeat of the sequence RGGFRG, the composition of which suggests a nucleic acid-binding site. Near the C terminus, residues 233 to 245 are homologous to several RNA-binding proteins. Of 18 C-terminal residues, 10 are acidic, a characteristic of the procaryotic single-stranded DNA-binding proteins and eucaryotic DNA- and RNA-binding proteins. In addition, examination of the subcellular distribution of SSB1 by immunofluorescence microscopy indicated that SSB1 is a nuclear protein, predominantly located in the nucleolus. Sequence homologies and the nucleolar localization make it likely that SSB1 functions in RNA metabolism in vivo, although an additional role in DNA metabolism cannot be excluded.     

Study of the binding of single-stranded DNA-binding protein to DNA and poly(rA) using electric field induced birefringence and circular dichroism spectroscopy

Binding of the single-stranded DNA-binding protein (SSB) of Escherichia coli to single-stranded (ss) polynucleotides produces characteristic changes in the absorbance (OD) and circular dichroism (CD) spectra of the polynucleotides. By use of these techniques, complexes of SSB protein and poly(rA) were shown to display two of the binding modes reported by Lohman and Overman [Lohman, T.M., & Overman, L. (1985) J. Biol. Chem. 260, 3594-3603]. The circular dichroism spectra of the "low salt" (10 mM NaCl) and "high salt" (greater than 50 mM NaCl) binding mode are similar in shape, but not in intensity. SSB binding to poly(rA) yields a complexed CD spectrum that shares several characteristics with the spectra obtained for the binding of AdDBP, GP32, and gene V protein to poly(rA). We therefore propose that the local structure of the SSB-poly(rA) complex is comparable to the structures proposed for the complexes of these three-stranded DNA-binding proteins with DNA (and RNA) and independent of the SSB-binding mode. Electric field induced birefringence experiments were used to show that the projected base-base distance of the complex is about 0.23 nm, in agreement with electron microscopy results. Nevertheless, the local distance between the successive bases in the complex will be quite large, due to the coiling of the DNA around the SSB tetramer, thus partly explaining the observed CD changes induced upon complexation with single-stranded DNA and RNA.     

Identification and Characterization of the Single-Stranded DNA-Binding Protein of Bacteriophage P1

The genome of bacteriophage P1 harbors a gene coding for a 162-amino-acid protein which shows 66% amino acid sequence identity to the Escherichia coli single-stranded DNA-binding protein (SSB). The expression of the P1 gene is tightly regulated by P1 immunity proteins. It is completely repressed during lysogenic growth and only weakly expressed during lytic growth, as assayed by an ssb-P1/lacZ fusion construct. When cloned on an intermediate-copy-number plasmid, the P1 gene is able to suppress the temperature-sensitive defect of an E. coli ssb mutant, indicating that the two proteins are functionally interchangeable. Many bacteriophages and conjugative plasmids do not rely on the SSB protein provided by their host organism but code for their own SSB proteins. However, the close relationship between SSB-P1 and the SSB protein of the P1 host, E. coli, raises questions about the functional significance of the phage protein.     

Effect of single-stranded DNA-binding proteins on the helicase and primase activities of the bacteriophage T7 gene 4 protein

Gene 4 protein (gp4) of bacteriophage T7 provides two essential functions at the T7 replication fork, primase and helicase activities. Previous studies have shown that the single-stranded DNA-binding protein of T7, encoded by gene 2.5, interacts with gp4 and modulates its multiple functions. To further characterize the interactions between gp4 and gene 2.5 protein (gp2.5), we have examined the effect of wild-type and altered gene 2.5 proteins as well as Escherichia coli single-stranded DNA-binding (SSB) protein on the ability of gp4 to synthesize primers, hydrolyze dTTP, and unwind duplex DNA. Wild-type gp2.5 and E. coli SSB protein stimulate primer synthesis and DNA-unwinding activities of gp4 at low concentrations but do not significantly affect single-stranded DNA-dependent hydrolysis of dTTP. Neither protein inhibits the binding of gp4 to single-stranded DNA. The variant gene 2.5 proteins, gp2.5-F232L and gp2.5-Delta26C, inhibit primase, dTTPase, and helicase activities proportional to their increased affinities for DNA. Interestingly, wild-type gp2.5 stimulates the unwinding activity of gp4 except at very high concentrations, whereas E. coli SSB protein is highly inhibitory at relative low concentrations.     

Photochemical crosslinking of bacteriophage T4 single-stranded DNA-binding protein (gp32) to oligo-p(dT)8: identification of phenylalanine-183 as the site of crosslinking

Using ultraviolet light, both the 33,000-dalton single-stranded DNA-binding protein from T4 bacteriophage (gp32) as well as a 25,000-dalton limited trypsin cleavage product of gp32 (core gp32*) that retains high affinity for single-stranded DNA can be crosslinked to an oligodeoxynucleotide, p(dT)8. After photolysis, a single tryptic peptide crosslinked to p(dT)8 was isolated by anion-exchange high-performance liquid chromatography. Gas-phase sequencing of this modified peptide gave the following sequence: Gln-Val-Ser-Gly-(X)-Ser-Asn-Tyr-Asp-Glu-Ser-Lys, which corresponds to residues 179-190 in gp32. Based on the absence of the expected phenylthiohydantoin derivative of phenylalanine 183 at cycle 5 (X) we infer that crosslinking has occurred at this position and that phenylalanine 183 is at the interface of the gp32:p(dT)8 complex in an orientation that allows covalent bond formation with the thymine radical produced by ultraviolet irradiation.     

Characterization of the nucleic acid binding region of adenovirus DNA binding protein by partial proteolysis and photochemical cross-linking.

The nucleic acid binding domain of the adenovirus type 2 (or type 5) DNA-binding protein (DBP) was characterized by using limited proteolysis and photochemical cross-linking. Three proteases were used to generate fragments of DBP which retained the ability to bind to single-stranded DNA. One fragment, a 35-kDa tryptic product, was partially sequenced and found to contain amino acid residues 153 to approximately 470. This fragment further defines the minimum region of the protein which is required for nucleic acid binding. The DNA binding pocket of DBP was defined by using ultraviolet irradiation to cross-link covalently the carboxyl-terminal portion of the protein to the oligonucleotide p(dT)14. Cross-linked complexes were digested with trypsin, and peptides which were associated with the oligonucleotide were isolated by anion-exchange and reverse-phase ion-pairing high performance liquid chromatography. Two DBP peptides comprised of residues 294-308 and 415-434 were isolated by this approach. Sequence analysis indicated that methionine 299 and phenylalanine 418 were probable sites of cross-linking between their respective peptides and the oligonucleotide; hence these residues may represent contact points between DBP and single-stranded DNA. Both residues are highly conserved and are near, but not identical to, regions of the protein implicated previously in DNA binding.     

The effect of the T7 and Escherichia coli DNA-binding proteins at the replication fork of bacteriophage T7

In this paper we compare the effect of single-stranded DNA-binding proteins of bacteriophage T7 (gene 2.5 protein) and of Escherichia coli (SSB) at the T7 replication fork. The T7 gene 4 protein acts processively as helicase to promote leading strand synthesis and distributively as primase to initiate lagging strand synthesis by T7 DNA polymerase. On a nicked double-stranded template, the formation of a replication fork requires partial strand displacement so that gene 4 protein may bind to the displaced strand and unwind the helix catalytically. Both the T7 gene 2.5 protein and E. coli SSB act stoichiometrically to promote this initial strand displacement step. Once initiated, processive leading strand synthesis is not greatly stimulated by the single-stranded DNA-binding proteins. However, the T7 gene 2.5 protein, but not E. coli SSB, increases the frequency of initiation of lagging strand synthesis by greater than 10-fold. The results suggest a specific interaction of the T7 gene 2.5 protein with the T7 replication apparatus.