Complex formation between p53 and replication protein A inhibits the sequence-specific DNA binding of p53 and is regulated by single-stranded DNA.

Human replication protein A (RP-A) (also known as human single-stranded DNA binding protein, or HSSB) is a multisubunit complex involved in both DNA replication and repair. Potentially important to both these functions, it is also capable of complex formation with the tumor suppressor protein p53. Here we show that although p53 is unable to prevent RP-A from associating with a range of single-stranded DNAs in solution, RP-A is able to strongly inhibit p53 from functioning as a sequence-specific DNA binding protein when the two proteins are complexed. This inhibition, in turn, can be regulated by the presence of various lengths of single-stranded DNAs, as RP-A, when bound to these single-stranded DNAs, is unable to interact with p53. Interestingly, the lengths of single-stranded DNA capable of relieving complex formation between the two proteins represent forms that might be introduced through repair and replicative events. Increasing p53 concentrations can also overcome the inhibition by steady-state levels of RP-A, potentially mimicking cellular points of balance. Finally, it has been shown previously that p53 can itself be stimulated for site-specific DNA binding when complexed through the C terminus with short single strands of DNA, and here we show that p53 stays bound to these short strands even after binding a physiologically relevant site. These results identify a potential dual role for single-stranded DNA in the regulation of DNA binding by p53 and give insights into the p53 response to DNA damage.     

recA protein promoted DNA strand exchange

recA protein and circular single-stranded DNA form a stable complex in the presence of single-stranded DNA binding protein (SSB), in which one recA protein monomer is bound per two nucleotides of DNA. These complexes are kinetically significant intermediates in the exchange of strands between the single-stranded DNA and an homologous linear duplex. After completion of strand exchange, the recA protein remains tightly associated with the circular duplex product of the reaction and the SSB is bound to the displaced linear single strand. Upon addition of ADP, the recA protein-duplex DNA complex dissociates. RecA protein also interacts with single-stranded DNA in the absence of SSB; however, the amount of recA protein bound is substantially reduced. These findings provide direct physical evidence for the participation of SSB in the formation of the recA protein-single-stranded DNA complexes inferred earlier from kinetic analysis. Moreover, they confirm the ability of recA protein to equilibrate between bound and free forms in the absence of SSB.     

Properties of the PriA helicase domain and its role in binding PriA to specific DNA structures

Primosome assembly protein PriA functions in the assembly of the replisome at forked DNA structures. Whereas its N-terminal DNA binding domain (DBD) binds independently to DNA, the affinity of DBD protein for forked structures is relatively weak. Although the PriA helicase domain (HD) is required for high affinity fork binding, HD protein had very low affinity for DNA. It had only low levels of ATPase activity, and it hydrolyzed ATP when DNA was absent whereas PriA did not. HD catalyzed unwinding of a minimal substrate composed of a duplex with a 3' single-stranded tail. Single-strand binding protein (SSB) bound to the tail of this substrate inhibited this reaction by full-length PriA but enhanced the reaction by HD. SSB stabilized binding of PriA but not of DBD or HD to duplexes with a 5' or 3' single-stranded tail. On forked substrates SSB enhanced helicase action on the lagging-strand arm by PriA but not by HD. The results indicate that synergy of the DBD and HD allows stable binding at the interface between duplex and single-stranded DNA bound by SSB. This mode of binding may be analogous to fork binding, which orients the helicase to act on the lagging-strand side of the fork.     

Low-molecular- weight Rauscher leukemia virus protein with preferential binding for single-stranded RNA and DNA.

A sensitive nitrocellulose filter assay that measures the retention of 125I single-stranded calf thymus DNA has been used to detect and purify DNA-binding proteins that retain a biological function from Rauscher murine leukemia virus. By consecutive purification on oligo (dT)- cellulose and DEAE-Bio-Gel columns and centrifugation in 10 to 30% glycerol gradients, RNA-dependent DNA polymerase has been separated from a second virion DNA-binding protein. The binding of this protein to DNA was strongly affected by NaCl concentration but showed little change in activity over a wide range of temperature or pH. After glycerol gradient purification, polyacrylamide gel electrophoresis of this protein showed one major band with a molecular weight of approximately 9,800. This protein binds about as well as to single-stranded Escherichia coli or calf thymus DNA or 70S type C viral RNA. The binding to 125I single-stranded calf thymus DNA is very efficiently inhibited by unlabeled single-stranded DNA from either E. coli or calf thymus and by 70S murine or feline viral RNA. Much larger amounts of double-stranded DNA are required to produce an equivalent percentage of inhibition. This protein, therefore, shows preferential binding to single-stranded DNA or viral RNA.     

The role of gene A protein and E. coli rep protein in the replication of phi X 174 replicative form DNA

The gene A protein of bacteriophage phi X 174 initiates replication of super-twisted RFI DNA by cleaving the viral (+) strand at the origin of replication and binding to the 5' end. Upon addition of E. coli rep protein (single-stranded DNA dependent ATPase), E. coli single-stranded DNA binding protein and ATP, complete unwinding of the two strands occurs. Electron microscopic analyses of intermediates in the reaction reveal that the unwinding occurs by movement of the 5' end into the duplex, displacing the viral strand in the form of a single-stranded loop. Since unwinding will not occur in the absence of either gene A protein or rep protein, it is presumed that the rep protein interacts to form a complex with the bound gene A protein. Single-stranded DNA binding protein facilitates the unwinding by binding to the exposed single-stranded DNA. Further addition of the four deoxyribotriphosphates and DNA polymerase III holoenzyme to the reaction results in synthesis of viral (+) single-stranded circles in amounts exceeding that of the input template. A model describing the role of gene A protein and rep protein in duplex DNA replication is presented and other properties of gene A protein discussed.     

Preparation of enzyme-conjugated DNA probe and application to the universal probe system.

A general procedure for the cross-linking of enzyme to DNA has been developed for use as a nonradioactive probe. In this method, DNA is transaminated with diaminopropane to introduce primary amino groups into the cytosine residues. Then the amino groups are converted to thiol groups using a heterobifunctional cross-linker. The thiolated DNA is conjugated with the maleimide-introduced enzyme. With this method, alkaline phosphatase was cross-linked to a single-stranded DNA (sspUCRf1). The conjugate was able to detect 5 pg of target DNA (pUCf1 plasmid, 3.2 kbp) fixed onto the nitrocellulose membrane, using a colorimetric assay. The enzyme-conjugated DNA was applied to "the universal probe system," which consisted of two single-stranded DNA probes (a primary probe and a labeled secondary probe). Using alkaline phosphatase-conjugated sspUCRf1 DNA as the secondary probe, the c-myc gene and HBV DNA were detected effectively on Southern and dot-blot hybridization.     

Escherichia coli DNA polymerase II is stimulated by DNA polymerase III holoenzyme auxiliary subunits

DNA polymerase III of Escherichia coli requires multiple auxiliary factors to enable it to serve as a replicative complex. We demonstrate that auxiliary components of the DNA polymerase III holoenzyme, the gamma delta complex and beta subunit, markedly stimulate DNA polymerase II on long single-stranded templates. DNA polymerase II activity is enhanced by single-stranded DNA binding protein, but the stimulation by gamma delta and beta can be observed either in the absence or presence of single-stranded DNA binding protein. In contrast with DNA polymerase III, the requirement of DNA polymerase II for gamma delta cannot be bypassed by large excesses of the beta subunit at low ionic strength in the absence of the single-stranded DNA binding protein. The product of the DNA polymerase II-gamma delta-beta reaction on a uniquely primed single-stranded circle is of full template length; the reconstituted enzyme apparently is incapable of strand displacement synthesis. The possible biological implications of these observations are discussed.     

Rep protein as a helicase in an active, isolatable replication fork of duplex phi X174 DNA

Rep protein as a helicase combines its actions with those of gene A protein and single-stranded DNA binding protein to separate the strands of phi X174 duplex DNA and thereby can generate and advance a replication fork (Scott, J. F., Eisenberg, S., Bertsch, L. L., and Kornberg, A. (1977) Proc. Natl. Acad. Sci. U. S. A. 74, 193-197). Tritium-labeled rep protein is bound in an active gene A protein. phi X174 closed circular duplex supercoiled DNA complex in a 1:1 ratio. Catalytic separation of the strands of the duplex by rep protein, as measured by incorporation of tritium-labeled single-stranded DNA binding protein, requires ATP at a Km value of 8 microM, and hydrolyzes two molecules of ATP for every base pair melted. When coupled to replication in the synthesis of single-strand viral circles, a "looped" rolling-circle intermediate is formed that can be isolated in an active form containing gene A protein, rep protein, single-stranded DNA binding protein, and DNA polymerase III holoenzyme. Unlike the binding of rep protein to single-stranded DNA, where its ATPase activity is distributive, binding to the replicating fork is not affected by ATP, further suggesting a processive action linked to gene A protein. Limited tryptic hydrolysis of rep protein abolishes its replicative activity without affecting significantly its binding of ATP and its ATPase action on single-stranded DNA. These results augment earlier findings by describing the larger role of rep proteins as a helicase, linked in a complex ith other proteins, at the replication fork of a duplex DNA.     

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.     

Fibers of RecA protein and complexes of RecA protein and single-stranded phi X174 DNA as visualized by negative-stain electron microscopy

Monomers of purified RecA protein polymerize into helical fibers whose pitch is 7.2 nm to 7.5 nm and whose diameter is 11 nm. Either short (approximately 0.2 micron), single fibers, or bundles of aligned, longer fibers, can be formed preferentially, by varying the Mg2+ concentration. When RecA protein is bound to circular, single-stranded phi X174 DNA it forms helical fibers of different classes of contour lengths, ranging from 0.98 micron, depending upon the conditions of assembly. Two different helical pitches are found, one of 9.3 nm when the incubation buffer contains, besides the obligatory Mg2+, either ATP gamma S or ATP accompanied by single-strand binding protein, and one of 5.5 nm when the latter additives are omitted. Preformed fibers of the compact type can be converted to open ones of 9.3 nm pitch upon addition of ATP gamma S, even after the removal of unbound RecA. All signs of helicity are obliterated upon glutaraldehyde cross-linking except in those fibers whose assembly has been mediated by ATP gamma S. RecA protein and single-strand binding protein are competitively bound to single-stranded DNA. Composite complexes, however, are not encountered unless ATP gamma S is present. Otherwise, segments of DNA that are coated by one or the other protein are seen as separate regions. When the assembly of complexes of single-stranded DNA and RecA is mediated by single-strand binding protein and ATP, the axial separation between successive bases is 0 X 42 nm, somewhat greater than the axial distance between bases in one strand of duplex DNA in the B form. It is proposed that the bases of the single-stranded DNA in the complex are located near its inner surface, and that base-pairing with double-stranded DNA takes place following invasion of the central cavity of the complex.     

Kinetics of binding of single-stranded DNA binding protein from Escherichia coli to single-stranded nuclei acids

The time course of the reaction of Escherichia coli single-stranded DNA binding protein (E. coli SSB) with poly(dT) and M13mp8 single-stranded DNA has been measured by fluorescence stopped-flow experiments. For poly(dT), the fluorescence traces follow simple bimolecular behavior up to 80% saturation of the polymer with E. coli SSB. A mechanistic explanation of this binding behavior can be given as follows: (1) E. coli SSB is able to translocate very rapidly on the polymer, forming cooperative clusters. (2) In the rate-limiting step of the association reaction, E. coli SSB is bound to the polymer only by one or two of its four contact sites. As compared to poly(dT), association to single-stranded M13mp8 phage DNA is slower by at least 2 orders of magnitude. We attribute this finding to the presence of secondary structure elements (double-stranded structures) in the natural single-stranded DNA. These structures cannot be broken by E. coli SSB in a fast reaction. In order to fulfill its physiological function in reasonable time, E. coli SSB must bind newly formed single-stranded DNA immediately. The protein can, however, bind to such pieces of the newly formed single-stranded DNA which are too short to cover all four binding sites of the E. coli SSB tetramer.     

DNA binding properties of the adenovirus DNA replication priming protein pTP

The precursor terminal protein pTP is the primer for the initiation of adenovirus (Ad) DNA replication and forms a heterodimer with Ad DNA polymerase (pol). Pol can couple dCTP to pTP directed by the fourth nucleotide of the viral genome template strand in the absence of other replication proteins, which suggests that pTP/pol binding destabilizes the origin or stabilizes an unwound state. We analyzed the contribution of pTP to pTP/pol origin binding using various DNA oligonucleotides. We show that two pTP molecules bind cooperatively to short DNA duplexes, while longer DNA fragments are bound by single pTP molecules as well. Cooperative binding to short duplexes is DNA sequence independent and most likely mediated by protein/protein contacts. Furthermore, we observed that pTP binds single-stranded (ss)DNA with a minimal length of approximately 35 nt and that random ssDNA competed 25-fold more efficiently than random duplex DNA for origin binding by pTP. Remarkably, short DNA fragments with two opposing single strands supported monomeric pTP binding. pTP did not stimulate, but inhibited strand displacement by the Ad DNA binding and unwinding protein DBP. These observations suggest a mechanism in which the ssDNA affinity of pTP stabilizes Ad pol on partially unwound origin DNA.     

Radiation-induced binding of DNA from irradiated mammalian cells to hydroxyapatite columns

In experiments designed to measure radiation-induced DNA damage using the DNA unwinding-hydroxyapatite chromatography technique, we observed that under some experimental conditions a significant proportion of the test DNA became tightly bound to the hydroxyapatite (HA) and could not be released even with a high concentration of phosphate buffer. Approximately 5-10% of DNA from unirradiated cells binds to the HA. With increasing radiation doses in air, the fraction of bound DNA increases, reaching about 30% at about 35 Gy. The binding exhibits many of the characteristics of a radiation-induced cell lesion: the proportion of DNA retained by the HA is less when cells are irradiated under hypoxic conditions or in the presence of the thiol radioprotector dithiothreitol; and the binding decreases when an incubation period is allowed between irradiation and harvest of the cells for assay. Studies to determine the nature of the lesion responsible for the binding demonstrated that lesion production requires a component found in cells since no binding was observed with irradiated isolated DNA or nuclear matrix; the binding is not a result of the production of DNA-protein crosslinks; and the bound DNA is single-stranded, based on its sensitivity to nuclease S1. Because of the dose dependence of the binding of DNA to HA, the slopes of the dose-response curves for DNA damage determined with this assay depend on the method used to calculate the fraction of double-stranded DNA. Our demonstration that the bound DNA is single-stranded guides the choice of the method for data analysis.     

Modifying the pH sensitivity of OmpG nanopore for improved detection at acidic pH

The outer membrane protein G (OmpG) nanopore is a monomeric β-barrel channel consisting of seven flexible extracellular loops. Its most flexible loop, loop 6, can be used to host high-affinity binding ligands for the capture of protein analytes, which induces characteristic current patterns for protein identification. At acidic pH, the ability of OmpG to detect protein analytes is hampered by its tendency toward the closed state, which renders the nanopore unable to reveal current signal changes induced by bound analytes. In this work, critical residues that control the pH-dependent gating of loop 6 were identified, and an OmpG nanopore that can stay predominantly open at a broad range of pHs was created by mutating these pH-sensitive residues. A short single-stranded DNA was chemically tethered to the pH-insensitive OmpG to demonstrate the utility of the OmpG nanopore for sensing complementary DNA and a DNA binding protein at an acidic pH.     

Partial purification and properties of a DNA-binding protein from nuclei of cells infected with polyoma virus.

A DNA-binding protein has been purified from nuclei of 3T3 cells infected with polyoma virus. The assay used to detect this activity measures the amount of double-stranded DNA retained on a nitrocellulose membrane filter in the presence of binding protein. The interaction between DNA and protein is salt dependent and occurs optimally at 0.8 M NaCl. The isolated protein can bind to both circular and linear duplex DNA. Incubation of the binding protein with PM2 or polyoma DNA results in the formation of a fast sedimenting DNA structure in neutral sucrose gradients. The isolated binding protein is also capable of producing a considerable stimulation of both Escherichia coli (Pol I) and T4 DNA polymerase activities when either single-stranded or intact, native T7 DNA is used as the template. The binding protein itself is free of detectable DNA polymerase or nuclease activity.     

Interactions of the DNA polymerase and gene 4 protein of bacteriophage T7. Protein-protein and protein-DNA interactions involved in RNA-primed DNA synthesis

Three proteins catalyze RNA-primed DNA synthesis on the lagging strand side of the replication fork of bacteriophage T7. Oligoribonucleotides are synthesized by T7 gene 4 protein, which also provides helicase activity. DNA synthesis is catalyzed by gene 5 protein of the phage, and processivity of DNA synthesis is conferred by Escherichia coli thioredoxin, a protein that is tightly associated with gene 5 protein. T7 DNA polymerase and gene 4 protein associate to form a complex that can be isolated by filtration through a molecular sieve. The complex is stable in 50 mM NaCl but is dissociated by 100 mM NaCl, a salt concentration that does not inhibit RNA-primed DNA synthesis. T7 DNA polymerase forms a stable complex with single-stranded M13 DNA at 50 mM NaCl as measured by gel filtration, and this complex requires 200 mM NaCl for dissociation, a salt concentration that inhibits RNA-primed DNA synthesis. Gene 4 protein alone does not bind to single-stranded DNA. In the presence of MgCl2 and dTTP or beta, gamma-methylene dTTP, a gene 4 protein-M13 DNA complex that is stable at 200 mM NaCl is formed. The affinity of DNA polymerase for both gene 4 protein and single-stranded DNA leads to the formation of a gene 4 protein-DNA polymerase-M13 DNA complex even in the absence of nucleoside triphosphates. However, the binding of each protein to DNA plays an important role in mediating the interaction of the proteins with each other. High concentrations of single-stranded DNA inhibit RNA-primed DNA synthesis by diluting the amount of proteins bound to each template and reducing the frequency of protein-protein interactions. Preincubation of gene 4 protein, DNA polymerase, and M13 DNA in the presence of dTTP forms protein-DNA complexes that most efficiently catalyze RNA-primed DNA synthesis in the presence of excess single-stranded competitor DNA.     

The RecOR proteins modulate RecA protein function at 5' ends of single-stranded DNA.

The Escherichia coli RecF, RecO and RecR pro teins have previously been implicated in bacterial recombinational DNA repair at DNA gaps. The RecOR-facilitated binding of RecA protein to single-stranded DNA (ssDNA) that is bound by single-stranded DNA-binding protein (SSB) is much faster if the ssDNA is linear, suggesting that a DNA end (rather than a gap) facilitates binding. In addition, the RecOR complex facilitates RecA protein-mediated D-loop formation at the 5' ends of linear ssDNAs. RecR protein remains associated with the RecA filament and its continued presence is required to prevent filament disassembly. RecF protein competes with RecO protein for RecR protein association and its addition destabilizes RecAOR filaments. An enhanced function of the RecO and RecR proteins can thus be seen in vitro at the 5' ends of linear ssDNA that is not as evident in DNA gaps. This function is countered by the RecF/RecO competition for association with the RecR protein.     

Membrane association and role in DNA uptake of the Bacillus subtilis PriA anaiogue ComF1

The late competence protein ComF1 is required for genetic transformation in Bacillus subtilis. Because of the sequence similarities of ComF1 to known ATP-dependent DNA helicases and translocases, we have hypothesized that this protein either unwinds bound double-stranded DNA or helps in the translocation of the transforming single-stranded DNA across the cell membrane. Two important implications of this hypothesis (the association of ComF1 with the membrane and its specific requirement for DNA uptake) have been tested in this report. Using cell fractionation techniques and Western blotting analysis, we show that ComF1 is located almost exclusively on the cell membrane and that it is membrane-targeted independently of other competence proteins. Moreover, ComF1 behaves like an integral membrane protein in extractability and detergent partition assays. We also show that this protein is required for the DNA-uptake step during transformation but not for DNA binding to the ceil surface. DNA uptake is blocked in strains with null mutations or in-frame deletions in comF1 but also in strains that overproduce the ComF1 protein under competence conditions. This last observation suggests that ComF1 expression must be balanced with that of other competence proteins, with which it may interact to form a multisubunit complex for DNA uptake.     

Reovirus protein sigmaNS binds in multiple copies to single-stranded RNA and shares properties with single-stranded DNA binding proteins

Reovirus nonstructural protein sigmaNS interacts with reovirus plus-strand RNAs in infected cells, but little is known about the nature of those interactions or their roles in viral replication. In this study, a recombinant form of sigmaNS was analyzed for in vitro binding to nucleic acids using gel mobility shift assays. Multiple units of sigmaNS bound to single-stranded RNA molecules with positive cooperativity and with each unit covering about 25 nucleotides at saturation. The sigmaNS protein did not bind preferentially to reovirus RNA over nonreovirus RNA in competition experiments but did bind preferentially to single-stranded over double-stranded nucleic acids and with a slight preference for RNA over DNA. In addition, sigmaNS bound to single-stranded RNA to which a 19-base DNA oligonucleotide was hybridized at either end or near the middle. When present in saturative amounts, sigmaNS displaced this oligonucleotide from the partial duplex. The strand displacement activity did not require ATP hydrolysis and was inhibited by MgCl(2), distinguishing it from a classical ATP-dependent helicase. These properties of sigmaNS are similar to those of single-stranded DNA binding proteins that are known to participate in genomic DNA replication, suggesting a related role for sigmaNS in replication of the reovirus RNA genome.