Equilibrium, kinetic, and footprinting studies of the Tus-Ter protein-DNA interaction.

Arrest of DNA replication in the terminus region of the Escherichia coli chromosome is mediated by protein-DNA complexes composed of the Tus protein and 23 base pair sequences generically called Ter sites. We have characterized the in vitro binding of purified Tus protein to a 37-base pair oligodeoxyribonucleotide containing the TerB sequence. The measured equilibrium binding constant (KD) for the chromosomal TerB site in KG buffer (50 mM Tris-Cl, 150 mM potassium glutamate, 25 degrees C, pH 7.5, 0.1 mM dithiothreitol, 0.1 mM EDTA, and 100 micrograms/ml bovine serum albumin) was 3.4 x 10(-13) M. Kinetic measurements in the same buffer revealed that the Tus-TerB complex was very stable, with a half-life of 550 min, a dissociation rate constant of 2.1 x 10(-5) s-1, and an association rate constant of 1.4 x 10(8) M-1 s-1. Similar measurements of Tus protein binding to the TerR2 site of the plasmid R6K showed an affinity 30-fold lower than the Tus-TerB interaction. This difference was due primarily to a more rapid dissociation of the Tus-TerR2 complex. Using standard chemical modification techniques, we also examined the DNA-protein contacts of the Tus-TerB interaction. Extensive contacts between the Tus protein and the TerB sequence were observed in the highly conserved 11 base-pair "core" sequence common to all identified Ter sites. In addition, protein-DNA contact sites were observed in the region of the Ter site where DNA replication is arrested. Projection of the footprinting data onto B-form DNA indicated that the majority of the alkylation interference and hydroxyl radical-protected sites were arranged on one face of the DNA helix. We also observed dimethyl sulfate protection of 2 guanine residues on the opposite side of the helix, suggesting that part of the Tus protein extends around the double helix. The distribution of contacts along the TerB sequence was consistent with the functional polarity of the Tus-Ter complex and suggested possible mechanisms for the impediment of protein translocation along DNA.     

Flanking sequences affect replication arrest at the Escherichia coli terminator TerB in vivo.

We have analyzed the effect of flanking sequences on Tus-induced replication arrest. pBR322 plasmid derivatives which carry the Escherichia coli replication terminator TerB at different locations were used. Efficiency of the replication arrest was estimated from the plasmid copy number and transformation frequency of tus+ cells. We found that flanking sequences do affect replication arrest efficiency, a weak arrest being correlated with the presence of an AT-rich region which is replicated just before TerB. Some sequences located after the replication terminator can also affect replication termination. We propose that the AT-rich regions might impair binding of the Tus protein to the TerB sequence or facilitate helicase-induced unwinding of DNA and Tus displacement from the TerB site.     

Use of electrospray ionization mass spectrometry to study binding interactions between a replication terminator protein and DNA

Tus protein binds tightly to specific DNA sequences (Ter) on the Escherichia coli chromosome halting replication. We report here conditions for detecting the 1 : 1 Tus-Ter complex by electrospray ionization mass spectrometry (ESI-MS). ESI mass spectra of a mixture of Tus and nonspecific DNA showed ions predominantly from uncomplexed Tus protein, indicating that the Tus-Ter complex observed in the gas phase was the result of a specific interaction rather than nonspecific associations in the ionization source. The Tus-Ter complex was very stable using a spray solvent of 10 mM ammonium acetate at pH 8.0, and initial attempts to distinguish binding affinities of Tus and mutant Tus proteins for Ter DNA were unsuccessful. Increasing the ammonium acetate concentration in the electrospray solvent (800 mM at pH 8.0) increased the dissociation constants sufficiently such that relative orders of binding affinity for Tus and various mutant Tus proteins for various DNA sequences could be determined. These were in agreement with the dissociation constants determined in solution studies. A dissociation constant of 700 x 10(-9) M for the binding of the mutant Tus protein A173T (where residue 173 is changed from alanine to threonine) to Ter DNA was estimated, compared with a value of 相似文献   

Zinc finger of replication protein A, a non-DNA binding element, regulates its DNA binding activity through redox.

Eukaryotic replication protein A (RPA) is a single-stranded DNA-binding protein with multiple functions in DNA replication, repair, and genetic recombination. RPA contains an evolutionarily conserved 4-cysteine-type zinc finger motif (X(3)CX(2-4)CX(12-15)CX(2)C) that has a potential role in regulation of DNA replication and repair (Dong, J., Park, J-S., and Lee, S-H. (1999) Biochem. J. 337, 311-317 and Lin, Y.-L., Shivji, M. K. K., Chen, C., Kolodner, R., Wood, R. D., and Dutta, A. (1998) J. Biol. Chem. 273, 1453-1461), even though the zinc finger itself is not essential for its DNA binding activity (Kim, D. K., Stigger, E., and Lee, S.-H. (1996) J. Biol. Chem. 271, 15124-15129). Here, we show that RPA single-stranded DNA (ssDNA) binding activity is regulated by reduction-oxidation (redox) through its zinc finger domain. RPA-ssDNA interaction was stimulated 10-fold by the reducing agent, dithiothreitol (DTT), whereas treatment of RPA with oxidizing agent, diazene dicarboxylic acid bis[N,N-dimethylamide] (diamide), significantly reduced this interaction. The effect of diamide was reversed by the addition of excess DTT, suggesting that RPA ssDNA binding activity is regulated by redox. Redox regulation of RPA-ssDNA interaction was more effective in the presence of 0.2 M NaCl or higher. Cellular redox factor, thioredoxin, was able to replace DTT in stimulation of RPA DNA binding activity, suggesting that redox protein may be involved in RPA modulation in vivo. In contrast to wild-type RPA, zinc finger mutant (cysteine to alanine mutation at amino acid 486) did not require DTT for its ssDNA binding activity and is not affected by redox. Together, these results suggest a novel function for a putative zinc finger in the regulation of RPA DNA binding activity through cellular redox.     

Comparison of operator-specific and nonspecific DNA binding of the lambda cI repressor: [KCl] and pH effects.

The effects of proton and KCl activity on the nonspecific lambda cI repressor-DNA interactions and on the site-specific repressor-O(R) interactions were compared, in order to assess their roles in site specificity. The repressor-O(R) interactions were studied by using DNase I footprint titration. The Gibbs free energy changes for binding and for cooperativity were determined between 25 and 300 mM KCl, from individual-site isotherms for the binding of repressor to O(R) and to reduced-valency mutants. The proton-linked effects on repressor-O(R) interactions have been published [Senear, D. F., & Ackers, G. K. (1990) Biochemistry 29, 6568-6577; Senear, D. F., & Bolen, D. W. (1991) Methods Enzymol. (in press)]. Nonspecific binding was studied by using a nitrocellulose filter binding assay, which proved advantageous in this case, due to the relatively weak nonspecific binding, and precipitation of repressor-DNA complexes. Filter binding provided measurements at low binding density where precipitation did not occur. The data provide estimates of the Gibbs free energy changes for nonspecific, intrinsic binding, but not for cooperativity. The KCl concentration dependencies of the intrinsic binding constants indicate that ion release plays similar roles in distinguishing between the operators and in discriminating operator from nonoperator DNA. Binding to DNA is accompanied by net proton absorption. Near neutral pH, proton linkages to operator and nonoperator binding are the same. Differences at acid and at basic pH implicate the same ionizable repressor groups in distinguishing between the operators and in discriminating operator from nonoperator DNA. The results indicate similar overall modes of operator and nonoperator binding of repressor, but implicate indirect effects of DNA sequence as important contributors to sequence recognition.     

Quantitative analysis of the binding of simian virus 40 large T antigen to DNA

SV40 large T antigen (T-ag) is a multifunctional protein that successively binds to 5'-GAGGC-3' sequences in the viral origin of replication, melts the origin, unwinds DNA ahead of the replication fork, and interacts with host DNA replication factors to promote replication of the simian virus 40 genome. The transition of T-ag from a sequence-specific binding protein to a nonspecific helicase involves its assembly into a double hexamer whose formation is likely dictated by the propensity of T-ag to oligomerize and its relative affinities for the origin as well as for nonspecific double- and single-stranded DNA. In this study, we used a sensitive assay based on fluorescence anisotropy to measure the affinities of wild-type and mutant forms of the T-ag origin-binding domain (OBD), and of a larger fragment containing the N-terminal domain (N260), for different DNA substrates. We report that the N-terminal domain does not contribute to binding affinity but reduces the propensity of the OBD to self-associate. We found that the OBD binds with different affinities to its four sites in the origin and determined a consensus binding site by systematic mutagenesis of the 5'-GAGGC-3' sequence and of the residue downstream of it, which also contributes to affinity. Interestingly, the OBD also binds to single-stranded DNA with an approximately 10-fold higher affinity than to nonspecific duplex DNA and in a mutually exclusive manner. Finally, we provide evidence that the sequence specificity of full-length T-ag is lower than that of the OBD. These results provide a quantitative basis onto which to anchor our understanding of the interaction of T-ag with the origin and its assembly into a double hexamer.     

The DNA replication fork blocked at the Ter site may be an entrance for the RecBCD enzyme into duplex DNA.

In Escherichia coli, eight kinds of chromosome-derived DNA fragments (named Hot DNA) were found to exhibit homologous recombinational hotspot activity, with the following properties. (i) The Hot activities of all Hot DNAs were enhanced extensively under RNase H-defective (rnh) conditions. (ii) Seven Hot DNAs were clustered at the DNA replication terminus region on the E. coli chromosome and had Chi activities (H. Nishitani, M. Hidaka, and T. Horiuchi, Mol. Gen. Genet. 240:307-314, 1993). Hot activities of HotA, -B, and -C, the locations of which were close to three DNA replication terminus sites, the TerB, -A, and -C sites, respectively, disappeared when terminus-binding (Tau or Tus) protein was defective, thereby suggesting that their Hot activities are termination event dependent. Other Hot groups showed termination-independent Hot activities. In addition, at least HotA activity proved to be dependent on a Chi sequence, because mutational destruction of the Chi sequence on the HotA DNA fragment resulted in disappearance of the HotA activity. The HotA activity which had disappeared was reactivated by insertion of a new, properly oriented Chi sequence at the position between the HotA DNA and the TerB site. On the basis of these observations and positional and orientational relationships between the Chi and the Ter sequences, we propose a model in which the DNA replication fork blocked at the Ter site provides an entrance for the RecBCD enzyme into duplex DNA.     

Large T-antigen mutants define multiple steps in the initiation of simian virus 40 DNA replication.

The biochemical activities of a series of transformation-competent, replication-defective large T-antigen point mutants were examined. The assays employed reflect partial reactions required for the in vitro replication of simian virus 40 (SV40) DNA. Mutants which failed to bind specifically to SV40 origin sequences bound efficiently to single-stranded DNA and exhibited nearly wild-type levels of helicase activity. A mutation at proline 522, however, markedly reduced ATPase, helicase, and origin-specific unwinding activities. This mutant bound specifically to the SV40 origin of replication, but under certain conditions it was defective in binding to both single-stranded DNA and the partial duplex helicase substrate. This suggests that additional determinants outside the amino-terminal-specific DNA-binding domain may be involved in nonspecific binding of T antigen to single-stranded DNA and demonstrates that origin-specific DNA binding can be separated from binding to single-stranded DNA. A mutant containing a lesion at residue 224 retained nearly wild-type levels of helicase activity and recognized SV40 origin sequences, yet it failed to function in an origin-specific unwinding assay. This provides evidence that origin recognition and helicase activities are not sufficient for unwinding to occur. The distribution of mutant phenotypes reflects the complex nature of the initiation reaction and the multiplicity of functions provided by large T antigen.     

Partial purification and characterization of a cellular protein that binds to the SV40 core origin of DNA replication

A monkey cell factor that interacts specifically with double- and single-stranded DNA sequences in the early domain of the simian virus 40 (SV40) core origin of replication was identified using gel-retention assays. The protein was enriched over 1200-fold using ion-exchange and affinity chromatography on single-strand DNA cellulose. Binding of protein to mutant origin DNA restriction fragments was correlated with replication activity of the mutant DNAs. Exonuclease footprint experiments on single-stranded DNA revealed prominent pause sites in the early domain of the core origin. The results suggest that this cellular protein may be involved in SV40 DNA replication.     

Partial purification and characterization of a cellular protein that binds to the SV40 core origin of DNA replication

A monkey cell factor that interacts specifically with double- and single-stranded DNA sequences in the early domain of the simian virus 40 (SV40) core origin of replication was identified using gel-retention assays. The protein was enriched over 1200-fold using ion-exchange and affinity chromatography on single-strand DNA cellulose. Binding of protein to mutant origin DNA restriction fragments was correlated with replication activity of the mutant DNAs. Exonuclease footprint experiments on single-stranded DNA revealed prominent pause sites in the early domain of the core origin. The results suggest that this cellular protein may be involved in SV40 DNA replication.     

Involvement of residues of the 29 terminal protein intermediate and priming domains in the formation of a stable and functional heterodimer with the replicative DNA polymerase

Bacteriophage Φ29 genome consists of a linear double-stranded DNA with a terminal protein (TP) covalently linked to each 5' end (TP-DNA) that together with a specific sequence constitutes the replication origins. To initiate replication, the DNA polymerase forms a heterodimer with a free TP that recognizes the origins and initiates replication using as primer the hydroxyl group of TP residue Ser232. The 3D structure of the DNA polymerase/TP heterodimer allowed the identification of TP residues that could be responsible for interaction with the DNA polymerase. Here, we examined the role of TP residues Arg158, Arg169, Glu191, Asp198, Tyr250, Glu252, Gln253 and Arg256 by in vitro analyses of mutant derivatives. The results showed that substitution of these residues had an effect on either the stability of the TP/DNA polymerase complex (R158A) or in the functional interaction of the TP at the polymerization active site (R169A, E191A, Y250A, E252A, Q253A and R256A), affecting the first steps of Φ29 TP-DNA replication. These results allow us to propose a role for these residues in the maintenance of the equilibrium between TP-priming domain stabilization and its gradual exit from the polymerization active site of the DNA polymerase as new DNA is being synthesized.     

Differential inhibition of the DNA translocation and DNA unwinding activities of DNA helicases by the Escherichia coli Tus protein.

Binding of the Escherichia coli Tus protein to its cognate nonpalindromic binding site on duplex DNA (a Ter sequence) is sufficient to arrest the progression of replication forks in a Ter orientation-dependent manner in vivo and in vitro. In order to probe the molecular mechanism of this inhibition, we have used a strand displacement assay to investigate the effect of Tus on the DNA helicase activities of DnaB, PriA, UvrD (helicase II), and the phi X-type primosome. When the substrate was a short oligomer hybridized to a circular single-stranded DNA, strand displacement by DnaB, PriA, and the primosome (in both directions), but not UvrD, was blocked by Tus in a polar fashion. However, no inhibition of either DnaB or UvrD was observed when the substrate carried an elongated duplex region. With this elongated substrate, PriA helicase activity was only inhibited partially (by 50%). On the other hand, both the 5'----3' and 3'----5' helicase activities of the primosome were inhibited almost completely by Tus with the elongated substrate. These results suggest that while Tus can inhibit the translocation of some proteins along single-stranded DNA in a polar fashion, this generalized effect is insufficient for the inhibition of bona fide DNA helicase activity.     

A molecular mousetrap determines polarity of termination of DNA replication in E. coli

During chromosome synthesis in Escherichia coli, replication forks are blocked by Tus bound Ter sites on approach from one direction but not the other. To study the basis of this polarity, we measured the rates of dissociation of Tus from forked TerB oligonucleotides, such as would be produced by the replicative DnaB helicase at both the fork-blocking (nonpermissive) and permissive ends of the Ter site. Strand separation of a few nucleotides at the permissive end was sufficient to force rapid dissociation of Tus to allow fork progression. In contrast, strand separation extending to and including the strictly conserved G-C(6) base pair at the nonpermissive end led to formation of a stable locked complex. Lock formation specifically requires the cytosine residue, C(6). The crystal structure of the locked complex showed that C(6) moves 14 A from its normal position to bind in a cytosine-specific pocket on the surface of Tus.     

Identification of simian virus 40 T-antigen residues important for specific and nonspecific binding to DNA and for helicase activity.

We have previously identified three regions (called elements) in the DNA-binding domain of simian virus 40 large tumor (T) antigen which are critical for binding of the protein to the recognition pentanucleotides GAGGC at the viral replication origin. These are elements A (residues 147 to 159), B1 (185 to 187), and B2 (203 to 207). In this study, we generated mutants of simian virus 40 in order to make single-point substitution mutations at nearly every site in these three elements. Each mutation was tested for its effect on virus replication, and T antigen was produced from all replication-negative mutants. The mutant proteins were assayed for binding to several different DNA substrates and for helicase activity. We found that within each element, mutations at some sites had major effects on DNA binding while mutations at other sites had moderate, mild, or minimal effects, suggesting that some residues are more important than others in mediating DNA binding. Furthermore, we provide evidence that certain residues in elements A and B2 (Ala-149, Phe-159, and His-203) participate in nonspecific double-stranded and helicase substrate (single-stranded) DNA binding while others (Ser-147, Ser-152, Asn-153, Thr-155, Arg-204, Val-205, and Ala-207) are involved in sequence-specific binding at the origin. The residues in element B1 (primarily Ser-185 and His-187) take part only in nonspecific DNA binding. The amino acids important for nonspecific DNA binding are also required for helicase activity, and we hypothesize that they make contact with the sugar-phosphate backbone of DNA. On the other hand, those involved in sequence-specific binding are not needed for helicase activity. Finally, our analysis showed that three residues (Asn-153 and Thr-155 in element A and Arg-204 in element B2) may be the most important for sequence-specific binding. They are likely to make direct or indirect contacts with the pentanucleotide sequences at the origin.     

A dimeric mutant of the homotetrameric single-stranded DNA binding protein from Escherichia coli

A single amino acid substitution (Y78R) at the dimer-dimer interface of homotetrameric single stranded DNA binding protein from E. coli (EcoSSB) renders the protein a stable dimer. This dimer can bind single-stranded DNA albeit with greatly reduced affinity. In vivo this dimeric SSB cannot replace homotetrameric EcoSSB. Amino acid changes at the rim of the dimer-dimer interface nearby (Q76K, Q76E) show an electrostatic interaction between a charged amino acid at position 76 and bound nucleic acid. In conclusion, nucleic acid binding to homotetrameric SSB must take place across both dimers to achieve functionally correct binding.     

Discrete regions of simian virus 40 large T antigen are required for nonspecific and viral origin-specific DNA binding.

The nondefective adenovirus type 2 (Ad2)-simian virus 40 (SV40) hybrid viruses, Ad2+ND2 and Ad2+ND4, have been used to determine which regions of the SV40 genome coding for the large tumor (T) antigen are involved in specific and nonspecific DNA binding. Ad2+ND2 encodes 45,000 M4 (45K) and 56,000 Mr (56K) T antigen-related polypeptides. The 45K polypeptide did not bind to DNA, but the 56K polypeptide bound nonspecifically to calf thymus DNA, Ad2+ND4 encodes 50,000 Mr (60K), 66,000 Mr (66K), 70,000 Mr (70K), 74,000 Mr (74K), and 90,000 Mr (90K) T antigen-related polypeptides, all of which bound nonspecifically to calf thymus DNA. However, in more stringent assays, where tight binding to viral origin sequences was tested, only the 90K protein specified by Ad2A+ND4 showed specific high affinity for sequences at the viral origin of replication. From these results and previously published experiments describing the SV40 DNA integrated into these hybrid viruses, it was concluded that SV40 early gene sequences located between 0.39 and 0.44 SV40 map units contribute to nonspecific DNA binding, whereas sequences located between 0.50 and 0.63 SV40 map units are necessary for specific binding to the viral origin of replication.     

Defective replication activity of a dominant-lethal dnaB gene product from Escherichia coli.

dnaB protein of Escherichia coli is an essential replication protein. A missense mutant has been obtained which results in replacement of an arginine residue with cysteine at position 231 of the protein (P. Shrimankar, L. Shortle, and R. Maurer, unpublished data). This mutant displays a dominant-lethal phenotype in strains that are heterodiploid for dnaB. Biochemical analysis of the altered form of dnaB protein revealed that it was inactive in replication in several purified enzyme systems which involve specific and nonspecific primer formation on single-stranded DNAs, and in replication of plasmids containing the E. coli chromosomal origin. Inactivity in replication appeared to be due to its inability to bind to single-stranded DNA. The altered dnaB protein was inhibitory to the activity of wild type dnaB protein in replication by sequestering dnaC protein which is also required for replication. By contrast, it was not inhibitory to dnaB protein in priming of single-stranded DNA by primase in the absence of single-stranded DNA binding protein. Sequestering of dnaC protein into inactive complexes may relate to the dominant-lethal phenotype of this dnaB mutant.