Photo-induced cross-linkage of gene-5 protein and bacteriophage fd DNA+

The gene 5 protein, coded for by the bacteriophage fd, forms a complex with single stranded fd-DNA such that one gene 5 protein monomer interacts with four bases. Exposure of this complex to ultraviolet light results in the formation of covalent bonds between 25-30% of the gene 5 protein monomers which are bound to the DNA. In contrast, when the intact fd virion, which is a complex of coat protein and DNA, was exposed to ultraviolet irradiation, no detectable protein DNA cross-links were found.     

Specificity of the binding of fd gene 5 protein to polydeoxyribonucleotides

The long-wavelength circular dichroism (CD) changes induced by binding of fd gene 5 protein to the alternating DNA sequences poly[d(A-C)] and poly[d(C-T)] were similar to those induced by the protein complexed with the homopolymers poly[d(A)], poly[d(C)], and poly[d(T)]. The fd gene 5 protein showed different binding affinities for the various polymers. The affinity for the alternating sequences was not compositionally weighted with respect to the affinities for the homopolymers, indicating that both base composition and base sequence of the template are important for the binding of fd gene 5 protein.     

Complex of fd gene 5 protein and double-stranded RNA

We report the formation of complexes of the single-stranded DNA binding protein encoded by gene 5 of fd virus, with natural double-stranded RNAs. In the first direct visualization of a complex of the fd gene 5 protein with a double-stranded nucleic acid, we show by electron microscopy that the double-stranded RNA complex has a structure which is distinct from that of complexes with single-stranded DNA and is consistent with uniform coating of the exterior of the double-stranded RNA helix by the protein. Circular dichroism spectral data demonstrate that the RNA double helix in the complex is undisrupted, and that perturbation of the 228-nm circular dichroism assigned to protein tyrosines can occur in the absence of intercalation of nucleotide bases with protein aromatic residues. Our findings emphasize the potential importance of interaction with the sugar-phosphate polynucleotide backbone in binding of the fd gene 5 protein to nucleic acids.     

Mechanism and role of cooperative binding of bacteriophage fd gene 5 protein to single-stranded deoxyribonucleic acid

The highly cooperative binding of fd gene 5 to single-stranded DNA was studied kinetically by rapid photo-cross-linking and stopped-flow UV absorption measurements. The observed change in absorbance was shown to be due to the binding by direct evidence of rapid photo-cross-linking of the bound proteins to fd DNA. The bimolecular rate constant obtained for the association was 1.6 X 10(10) M-1 s-1 (in terms of the molecular concentration of DNA), which was concluded to be diffusion controlled. The breakdown of cluster complexes on fd DNA was induced by the addition of large excess amounts of short single-stranded DNA. The breakdown took place in about 1 s. The kinetic process of redistribution of dissociated proteins was monitored by rapid photo-cross-linking and subsequent electrophoresis of the cross-linked complex. The dissociated proteins first formed isolated complexes, but later they were again converted into the cluster. The kinetic results showed that the cooperativity originated from the stabilization of the protein-DNA complex by the cluster formation, not from the accelerated association in the cluster formation. This kind of cooperative binding was shown to perform negative feedback control in the cluster formation. On the basis of the kinetic results obtained, we proposed a model for the regulatory role of the fd gene 5 protein in the synthesis of single-stranded fd DNA.     

Mechanism of stimulation by a specific protein factor of de novo DNA synthesis by mouse DNA replicase with fd phage single stranded circular DNA.

Mouse DNA replicase is a functional multienzyme complex consisting of DNA polymerase and DNA primase. The DNA and initiator RNA syntheses by DNA replicase with single stranded DNA as template are stimulated by a stimulating factor (T. Yagura, T. Kozu and T. Seno, 1982, J. Biochem. (Tokyo).91, 607-618). The action mechanism of the stimulating factor on this novel DNA synthesis with fd phage single stranded circular DNA as template was studied. The stimulating factor directly stimulated initiator RNA synthesis but did not change the length of either initiator RNA (8 to 10 nucleotides long) or the product DNA (300 to 1,000 nucleotides long). Kinetic studies and analysis of the products by neutral agarose gel electrophoresis show that the stimulating factor increased the affinity of DNA replicase for template DNA without changing the apparent Km values for deoxy- and ribonucleotide substrates. Thus, in combination with a sufficient amount of the stimulating factor, DNA replicase quantitatively converted the template DNA to the position of double-stranded circular replicative form II DNA, as shown by agarose gel electrophoresis.     

Interaction of DNA with DNA binding proteins. III. Infectivity of protein-complexed phage fd DNA in Escherichia coli spheroplasts.

Complex formation of circular, single-stranded phage fd DNA with Escherichia coli DNA binding protein HD or phage fd gene 5 protein keeps infection of E. coli spheroplasts at the level of free phage DNA, whereas complexes of this DNA with E. coli DNA unwinding protein show a strongly reduced efficiency of transfection. Displacement of the unwinding protein by HD protein or gene 5 protein also maintains the poor adsorption of the complexes to spheroplasts. Free E. coli DNA unwinding protein and residual amounts of this protein bound to the DNA may interfere with the adsorption and the uptake of the phage genome.     

Tyrosine mutant helps define overlapping CD bands from fd gene 5 protein · nucleic acid complexes

We used a mutant gene 5 protein (g5p) to assign and interpret overlapping CD bands of protein · nucleic acid complexes. The analysis of overlapping protein and nucleic acid CD bands is a common challenge for CD spectroscopists, since both components of the complex may change upon binding. We have now been able to more confidently resolve the bands of nucleic acids complexed with the fd gene 5 protein by exploiting a mutant gene 5 protein that has an insignificant change in tyrosine optical activity at 229 nm upon binding to nucleic acids. We have studied the interactions of the mutant Y34F g5p (Tyr-34 substituted with phenylalanine) with poly[r(A)], poly[d(A)], and fd single-stranded DNA (ssDNA). Our results showed the following: (1) The 205–300 nm spectrum of poly[r(A)] saturated with the Y34F mutant (P/N = 0.25) was essentially the sum of the spectra of poly[r(A)] at a high temperature plus the spectrum of the free protein, except for a minor negative band at 257 nm. (2) The spectra of poly[d(A)] and fd ssDNA saturated with the mutant protein at a P/N = 0.25, minus the spectra of the free nucleic acids at a high temperature, also essentially equaled the spectrum of the free protein in the 205–245 nm region. (3) While the overall secondary structure of the Y34F protein did not change upon binding to any of these nucleic acids, there could be changes in the environment of individual aromatic residues. (4) Nucleic acids complexed with the g5p are unstacked (as if heated) and (in the cases of the DNAs) perturbed as if part of a dehydrated double-stranded DNA. (5) Difference spectra revealed regions of the spectrum specific for the particular nucleic acid, the protein, and whether g5p was bound to DNA or RNA. © 1997 John Wiley and Sons, Inc. Biopoly 42: 337–348, 1997     

The inhibitory effect of dithiothreitol on the assembly of the filamentous phage fd

Assembly of the filamentous phage fd is preceded by the formation of a complex between the viral single-stranded (ss) DNA and the virally coded gene 5 protein (gene 5 protein-ssDNA complex). The presence of 5 mM dithiothreitol in the growth medium prevents phage production; however, phage infection, phage DNA replication and phage genome expression are still observed. In contrast, the gene 5 protein-ssDNA complex is not formed in the presence of dithiothreitol in vivo, although the complex is not affected by the disulfide reducing agent in vitro. Furthermore, host lipid composition is altered by growth in the presence of dithiothreitol. The zwitterionic lipid, phosphatidylethanolamine, increases while the cationic phospholipid content, cardiolipin and phosphatidylglycerol, decreases. This suggests a role for lipids or membranous structures in the process of gene 5 protein-ssDNA complex formation.     

Ionic strength perturbation kinetics of gene 32 protein dissociation from its complex with single-stranded DNA.

Equilibrium and kinetic studies of the interaction of gene 32 protein of T4 phage with single-stranded fd DNA were performed monitoring the changes in protein fluorescence. From the fluorescence titrations, it was estimated that a monomer of gene 32 protein covered six nucleotide bases on the DNA and the lower limit for the apparent association constant was 1.9 x 10(8) M-1 with a cooperative parameter of 10(3) in 0.1 M 2-amino-2-hydroxymethyl-1,3-propanediol hydrochloride (pH 7) at 25 degrees C. When an ionic strength jump was applied to the gene 32 protein-fd DNA complex using a stopped-flow apparatus, the complex underwent a dissociation into its individual components accompanied by an increase in protein fluorescence. The kinetics of the dissociation are not consistent with a single first-order process. The data, however, can be analyzed in terms of a model in which gene 32 protein molecules release cooperatively starting from either one or both ends of a cluster of proteins bound to fd DNA. This type of dissociation of gene 32 protein from single-stranded DNA is very efficient and has interesting implications: it could provide a way to facilitate a rapid "zippering" of the two complementary DNA strands during DNA replication and genetic recombination.     

Specificity of the Binding of fd Gene 5 Protein to Polydeoxyribonucleotides

Abstract

The long-wavelength circular dichroism (CD) changes induced by binding of fd gene 5 protein to the alternating DNA sequences poly[d(A-C)] and poly [d(C-T)] were similar to those induced by the protein complexed with the homopolymers poly[d(A)], poly[d(C)], and poly[d(T)]. The fd gene 5 protein showed different binding affinities for the various polymers. The affinity for the alternating sequences was not compositionally weighted with respect to the affinities for the homopolymers, indicating that both base composition and base sequence of the template are important for the binding of fd gene 5 protein.     

The binding of fd gene 5 protein to polydeoxynucleotides: evidence from CD measurements for two binding modes

Circular dichroism measurements were used to study the binding of fd gene 5 protein to fd DNA, to six polydeoxynucleotides (poly[d(A)], poly[d(T)], poly[d(I)], poly[d(C)], poly[d(A-T)], and the random copolymer poly[d(A,T)]), and to three oligodeoxynucleotides (d(pA)20, d(pA)7, and d(pT)7). Titrations of these DNAs with fd gene 5 protein were generally done in a low ionic strength buffer (5 mM Tris-HCl, pH 7.0 or 7.8) to insure tight binding, needed to obtain stoichiometric endpoints. By monitoring the CD of the nucleic acids above 250 nm, where the protein has no significant intrinsic optical activity, we found that there were two modes of binding, with the number of nucleotides covered by a gene 5 protein monomer (n) being close to either 4 or 3. These stoichiometries depended upon which polymer was titrated as well as upon the protein concentration. Single endpoints at nucleotide/protein molar ratios close to 3 were found during titrations of poly[d(T)] and fd DNA (giving n = 3.1 and 2.8 +/- 0.2, respectively), while CD changes with two apparent endpoints at nucleotide/protein molar ratios close to 4 and approximately 3 were found during titrations of poly[d(A)], poly[d(I)], poly[d(A-T)], and poly[d(A,T)] (with the first endpoints giving n = 4.1 4.0, 4.0, and 4.1 +/- 0.3, respectively). Calculations showed that the CD changes we observed during these latter titrations were consistent with a switch between two non-interacting binding modes of n = 4 and n = 3. We found no evidence for an n = 5 binding mode. One implication of our results is that the Brayer and McPherson model for the helical gene 5 protein-DNA complex, which has 5 nucleotides bound per protein monomer (G. Brayer and A. McPherson, J. Biomol. Struct. and Dyn. 2, 495-510, 1984), cannot be correct for the detailed solution structure of the complex. We interpreted the CD changes above 250 nm upon binding of the gene 5 protein to single-stranded DNAs to be the result of a slight unstacking of the bases, along with a significant alteration of the CD contributions of the individual nucleotides in the case of A-and/or T-containing DNAs. Interestingly, CD contributions attributed to nearest-neighbor interactions in free poly[d(A-T)], poly[d(A,T)], poly[d(A)], and poly[d(T)] were partially maintained in the CD spectra of the protein-saturated polymers, so that neighboring nucleotides, when bound to the protein at 20 degrees C, appeared to interact with one another in much the same manner as in the free polymers at 50 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Filamentous phage replication initiator protein gpII forms a covalent complex with the 5' end of the nick it introduced

Rolling circle type DNA replication is initiated by introduction of a nick in the leading strand of the origin by the initiator protein, which in most cases binds covalently to the 5' end of the nick. In filamentous phage, however, such a covalent complex has not been detected. Using a suitable substrate and short reaction time, we show that filamentous phage initiator gpII forms a covalent complex with nicked DNA, which rapidly dissociates unless gpII is inactivated. A peptide-DNA complex was isolated from trypsin digest of the complex by ion-exchange column chromatography and gel filtration, and its peptide sequence was determined. The result indicated that gpII was linked to DNA by the tyrosine residue at position 197 from the N-terminus. The mutant protein in which this tyrosine was replaced by phenylalanine did not show any detectable activity to complement gene II amber mutant phage in vivo. In vitro, the mutant protein recognized the origin and bent DNA as well as the wild-type does, but failed to introduce a nick and to relax the superhelicity of cognate DNA.     

Photosensitized splitting of thymine dimers in DNA by gene 32 protein from phage T 4

The binding of denatured DNA to the protein coded by gene 32 of phage T 4 is accompanied by a quenching of the fluorescence of the protein tryptophyl residues. Gene 32 protein also binds to UV-irradiated DNA and photosensitizes the splitting of thymine dimers. Thymine bases are regenerated by this photosensitized reaction both in double stranded and in heat denatured DNA. No photosensitized splitting of thymine dimers is observed when the complex formed by gene 32 protein with UV-irradiated DNA is dissociated at high ionic strength. These results are discussed with respect to the possible stacking interaction of tryptophyl residues of gene 32 protein with bases in single stranded DNA.     

Gene 5 protein of bacteriophage fd: A dimer which interacts Co-operatively with DNA

Isolated gene 5 protein from bacteriophage fd-infected Escherichia coli has been shown by sedimentation equilibrium to exist primarily as a dimer under non-denaturing conditions. The dimer was stable under conditions of high ionic strength, extremes in pH, dilution to 0.075 mg/ml, and increased temperature. Gene 5 protein did not undergo the indefinite self-association observed with gene 32 protein.Three lines of evidence for co-operative binding of gene 5 protein to DNA were developed. First, the interaction between gene 5 protein and phage T4 DNA was examined using a nitrocellulose filter assay. Scatchard plots of the binding data indicated that the interaction was co-operative. Similar results were obtained with gene 32 protein. Second, the co-operative binding of both proteins to DNA was shown by the sensitivity of the protein-DNA interaction to increasing ionic strength at various ratios of protein to DNA. Finally, by using the cross-linking agent, dimethyl suberixmidate, oligomeric structures containing at least seven monomers were found when the DNA was less than saturated.The possibility that gene 5 protein dimers undergo indefinite self-association in the presence of oligonucleotides was examined by sedimentation equilibrium. With oligo[d(pT)₄], the protein dimer was complexed with this oligonucleotide but no self-association was observed. With oligo[d(pT)₈], gene 5 protein formed tetramers, but no significant indefinite association was noted. These results do not suggest a DNA-induced conformational change, which results in indefinite association. A model for the co-operative binding of gene 5 protein to DNA is presented.     

DNA binding properties of a 110 kDa nucleolar protein.

A single strand specific DNA binding protein was purified to homogeneity from calf thymus nucleoprotein. The monomeric protein is elongated in shape and has a molecular mass of 110 kDa. Since immunocytochemistry revealed that the protein is predominantly located in the nucleolus we refer to it as the 110 kDa nucleolar protein. The protein binds not only to single stranded DNA but also to single stranded RNA, including homopolymeric synthetic RNA. We have used the single stranded DNA binding properties of the 110 kDa protein in model studies to investigate its effects on the configuration of nucleic acid. Our results are: only 50-55 protein molecules are sufficient to saturate all binding sites on the 6408 nucleotides of phage fd DNA; protein binding cause a compaction of single stranded DNA; large nucleoprotein aggregates are formed in the presence of divalent cations; this is due to protein-protein interactions which occur at moderately high concentrations of magnesium-, calcium or manganese ions; the protein induces the reassociation of complementary nucleic acid sequences. We speculate that the 110 kDa protein performs similar reactions in vivo and may have a function related to the processing and packaging of preribosomal RNA.     

Preferential binding of fd gene 5 protein to tetraplex nucleic acid structures

The gene 5 protein of filamentous bacteriophage fd is a single-stranded DNA-binding protein that binds non-specifically to all single-stranded nucleic acid sequences, but in addition is capable of specific binding to the sequence d(GT(5)G(4)CT(4)C) and the RNA equivalent r(GU(5)G(4)CU(4)C), the latter interaction being important for translational repression. We show that this sequence preference arises from the formation of a tetraplex structure held together by a central block of G-quartets, the structure of which persists in the complex with gene 5 protein. Binding of gene 5 protein to the tetraplex leads to formation of a approximately 170 kDa nucleoprotein complex consisting of four oligonucleotide strands and eight gene 5 protein dimers, with a radius of gyration of 45 A and an overall maximum dimension of 120-130 A. A model of the complex is presented that is consistent with the data obtained. It is proposed that the G-quartet may act as a nucleation site for binding gene 5 protein to adjacent single-stranded regions, suggesting a novel mechanism for translational repression.     

Characterization of a multisubunit human protein which selectively binds single stranded d(GA)n and d(GT)n sequence repeats in DNA.

A protein which selectively binds d(GA)n and d(GT)n sequence repeats in single stranded DNA has been identified in human fibroblasts. This protein, designated PGB, has been purified at least 500-fold by ammonium sulfate precipitation followed by DEAE-Sepharose column chromatography and affinity chromatography in a column of d(GA)-Sepharose. Electrophoretic mobility shift assays revealed that the PGB protein bound most avidly d(GA)n and d(GT)n tracts of n > 5. It also bound other G-rich DNA sequence repeats, including dGn tracts, with lower affinities. It did not manifest significant binding affinities to single stranded M13 DNA, or to the homopolynucleotides poly dA, poly dC and poly dT, or to various DNA sequence repeats which do not contain G residues, such as d(A-C)n and d(TC)n. It did not bind double stranded d(T-C)n.d(GA)n tracts or other double stranded DNA sequences. In glycerol gradient centrifugation assays the d(GA)n- and the d(GT)n-binding activities cosedimented as a homogeneous protein species having an S20,w = 9.4 +/- 0.7 and an estimated native molecular weight of 190,000 +/- 7,000. UV crosslinking assays revealed that the protein contains 33.6 +/- 2.1 kd subunits which bind d(GA)n and d(GT)n sequences. However, SDS-polyacrylamide gel electrophoresis of the purified protein followed by silver staining indicated that it may also contain other subunits that do not contact the DNA. It is proposed that binding of the PGB protein to single stranded d(GA)n or d(GT)n tracts in double stranded topologically restricted DNA may stimulate strand separation and formation of triple helices or other unusual DNA structures.     

Isolation and characterization of transducing coliphage fd carrying a kanamycin resistance gene.

The DNA segment (Tn903) with a size of 3100 nucleotide pairs which carries a gene specifying kanamycin resistance derived from a chimeric plasmid pML21 (Hershfield et al., 1976) was transposed to various sites on the filamentous phage fd DNA. Wild type fd can be restored by excision of Tn903 from the resulting hybrid DNA molecule. The fd DNA carrying Tn903 when converted to the mature phage particle, was capable of transducing the kanamycin marker, and its replicative form DNA could be maintained in a bacterial cell like a plasmid.     

The DNA binding properties of the MutL protein isolated from Escherichia coli.

The mutL gene of Escherichia coli, which is involved in the repair of mispaired and unpaired nucleotides in DNA, has been independently cloned and the gene product purified. In addition to restoring methyl-directed DNA repair in extracts prepared from mutL strains, the purified MutL protein binds to both double and single stranded DNA. The affinity constant of MutL for unmethylated single stranded DNA was twice that of its affinity constant for methylated single stranded DNA and methylated or unmethylated double stranded DNA. The binding of MutL to double stranded DNA was not affected by the pattern of DNA methylation or the presence of a MutHLS-repairable lesion.