The DNA helicase and adenosine triphosphatase activities of yeast Rad3 protein are inhibited by DNA damage. A potential mechanism for damage-specific recognition.

Purified Rad3 protein from the yeast Saccharomyces cerevisiae is a single-stranded DNA-dependent ATPase and also acts as a DNA helicase on partially duplex DNA. In this study we show that the DNA helicase activity is inhibited when a partially duplex circular DNA substrate is exposed to ultraviolet (UV) radiation. Inhibition of DNA helicase activity is sensitive to the particular strand of the duplex region which carries the damage. Inhibition is retained if the single-stranded circle is irradiated prior to annealing to an unirradiated oligonucleotide, but not if a UV-irradiated oligonucleotide is annealed to unirradiated circular single-stranded DNA. UV irradiation of single-stranded DNA or deoxyribonucleotide homopolymers also inhibits the ability of these polynucleotides to support the hydrolysis of ATP by Rad3 protein. UV radiation damage apparently blocks translocation of Rad3 protein and results in the formation of stable Rad3 protein-UV-irradiated DNA complexes. As a consequence, Rad3 protein remains sequestered on DNA, presumably at sites of base damage. The sensitivity of Rad3 protein to the presence of DNA damage on the strand along which it translocates provides a potential mechanism for damage recognition during nucleotide excision repair and may explain the absolute requirement for Rad3 protein for damage-specific incision of DNA in yeast.     

Production of triple-stranded recombination intermediates by RecA protein, in vitro

During the directional strand exchange that is promoted by RecA protein between linear duplex DNA and circular single-stranded DNA, a triple-stranded DNA intermediate was formed and persisted even after the completion of strand transfer followed by deproteinization. In the deproteinized three-stranded DNA complexes, the sequestered linear third strand resisted digestion by E coli exonuclease I. In relation to polarity of strand exchange which defines the proximal and distal ends of the duplex DNA, when homology was restricted to the distal region of duplex substrate, the joints formed efficiently and were stable even upon complete deproteinization. Enzymatic probing of deproteinized distal joints with nuclease P1 revealed that the joints consist of long three-stranded structures that at neutral pH lack significant single-stranded character in any of the three strands. Instead of circular single-stranded DNA, when a linear single strand is recombined with partially homologous duplex DNA, in the presence of SSB, the formation of homologous joints by RecA protein, is significantly more efficient at distal end than at the proximal. Taken together, these observations suggest that with any single-stranded DNA (circular or linear), RecA protein efficiently promotes the formation of distal joints, from which, however, authentic strand exchange may not occur. Moreover, these joints might represent an intermediate which is trapped into a stable triple stranded state.     

RecA protein reinitiates strand exchange on isolated protein-free DNA intermediates. An ADP-resistant process

Efficient homologous pairing de novo of linear duplex DNA with a circular single strand (plus strand) coated with RecA protein requires saturation and extension of the single strand by the protein. However, strand exchange, the transfer of a strand from duplex DNA to the nucleoprotein filament, which follows homologous pairing, does not require the stable binding of RecA protein to single-stranded DNA. When RecA protein was added back to isolated protein-free DNA intermediates in the presence of sufficient ADP to inhibit strongly the binding of RecA protein to single-stranded DNA, strand exchange nonetheless resumed at the original rate and went to completion. Characterization of the protein-free DNA intermediate suggested that it has a special site or region to which RecA protein binds. Part of the nascent displaced plus strand of the deproteinized intermediate was unavailable as a cofactor for the ATPase activity of RecA protein, and about 30% resisted digestion by P1 endonuclease, which acts preferentially on single-stranded DNA. At the completion of strand exchange, when the distal 5' end of the linear minus strand had been fully incorporated into heteroduplex DNA, a nucleoprotein complex remained that contained all three strands of DNA from which the nascent displaced strand dissociated only over the next 50 to 60 minutes. Deproteinization of this intermediate yielded a complex that also contained three strands of DNA in which the nascent displaced strand was partially resistant to both Escherichia coli exonuclease I and P1 endonuclease. The deproteinized complex showed a broad melting transition between 37 degrees C and temperatures high enough to melt duplex DNA. These results show that strand exchange can be subdivided into two stages: (1) the exchange of base-pairs, which creates a new heteroduplex pair in place of a parental pair; and (2) strand separation, which is the physical displacement of the unpaired strand from the nucleoprotein filament. Between the creation of new heteroduplex DNA and the eventual separation of a third strand, there exists an unusual DNA intermediate that may contain three-stranded regions of natural DNA that are several thousand bases in length.     

Unwinding of unnatural substrates by a DNA helicase

Helicases separate double-stranded DNA into single-stranded DNA intermediates that are required during replication and recombination. These enzymes are believed to transduce free energy available from ATPase activity to unwind the duplex and translocate along the nucleic acid lattice. The nature of enzyme-substrate interactions between helicases and duplex DNA substrates has not been well-defined. Most helicases require a single-stranded DNA overhang adjacent to duplex DNA in order to initiate unwinding. The strand containing the overhang is referred to as the loading strand whereas the complementary strand is referred to as the displaced strand. We have investigated the interactions between a DNA helicase and the DNA substrate by replacing the displaced strand with a nucleic acid mimic, peptide nucleic acid (PNA). PNA is capable of forming duplex structures with DNA according to Watson-Crick base pairing rules, but contains a N-(2-aminoethyl)glycine backbone in place of the deoxyribose phosphates. The PNA-DNA hybrids had higher melting temperatures than their DNA-DNA counterparts. Dda helicase, from bacteriophage T4, was able to unwind the DNA-PNA substrates at similar rates as DNA-DNA substrates. The results indicate that the rate-limiting step for unwinding is relatively insensitive to the chemical nature of the displaced strand and the thermal stability of oligonucleotide substrates.     

Specific oligonucleotide invasion into an end of a DNA duplex

A new phenomenon was described: a double-stranded DNA fragment interacted with a single-stranded oligonucleotide complementary to the terminal region of one strand of the duplex to yield a complex with oligonucleotide invasion. Generation of Holliday junctions by homologous linear DNA fragments was less efficient in the presence of single-stranded oligonucleotides complementary to duplex ends. The effect depended on the oligonucleotide concentration, size, and complementarity to a duplex strand. Sequence-specific complexes with single strand invasion were detected in mixtures containing radiolabeled oligonucleotides and duplexes. A single-stranded oligonucleotide invaded a duplex even when its concentration was far lower than the duplex concentration. Complexes with single strand invasion were analyzed by chemical cleavage of noncanonical base pairs. Analysis showed that an oligonucleotide interacts with the complementary region of one strand of the duplex, gradually displacing the other strand. The extent of oligonucleotide invasion into the duplex considerably varied. Oligonucleotide invasion into duplexes became more efficient with increasing oligonucleotide size.     

Escherichia coli PriA helicase: fork binding orients the helicase to unwind the lagging strand side of arrested replication forks

Escherichia coli PriA is a primosome assembly protein with 3' to 5' helicase activity whose apparent function is to promote resumption of DNA synthesis following replication-fork arrest. Here, we describe how initiation of helicase activity on DNA forks is influenced by both fork structure and by single-strand DNA-binding protein. PriA could recognize and unwind forked substrates where one or both arms were primarily duplex, and PriA required a small (two bases or larger) single-stranded gap at the fork in order to initiate unwinding. The helicase was most active on substrates with a duplex lagging-strand arm and a single-stranded leading-strand arm. On this substrate, PriA was capable of translocating on either the leading or lagging strands to unwind the duplex ahead of the fork or the lagging-strand duplex, respectively. Fork-specific binding apparently orients the helicase domain to unwind the lagging-strand duplex. Binding of single-strand-binding protein to forked templates could inhibit unwinding of the duplex ahead of the fork but not unwinding of the lagging-strand duplex or translocation on the lagging-strand template. While single-strand-binding protein could inhibit binding of PriA to the minimal, unforked DNA substrates, it could not inhibit PriA binding to forked substrates. In the cell, single-strand-binding protein and fork structure may direct PriA helicase to translocate along the lagging-strand template of forked structures such that the primosome is specifically assembled on that DNA strand.     

DNase protection by recA protein during strand exchange. Asymmetric protection of the Holliday structure

When recA protein pairs linear duplex DNA with a homologous duplex molecule that has a single-stranded tail, it produces a recombination intermediate called the Holliday structure and causes reciprocal or symmetric strand exchange, whereas the pairing of a linear duplex molecule with fully single-stranded DNA leads to an asymmetric exchange. To study the location of recA protein on DNA molecules undergoing symmetric exchange, we labeled individually each end of the four strands involved and looked for protection against DNase I or restriction endonucleases. As expected, because of its preferred binding to single-stranded DNA, recA protein protected the single-stranded tails of either substrates, or products. In addition however, strong protection extended into the newly formed heteroduplex DNA along the strand to which recA protein was initially bound. Experiments with uniformly labeled DNA showed a corresponding homology-dependent asymmetry in the protection of the tailed substrate versus its fully duplex partner. Restriction experiments showed that protection extended 50-75 base pairs beyond the point where strand exchange was blocked by a long region of heterology. When compared with earlier observations (Chow, S. A., Honigberg, S. M., Bainton, R. J., and Radding, C. M. (1986) J. Biol. Chem. 261, 6961-6971), the present experiments reveal a pattern of association of recA protein with DNA that suggests a common mechanism of asymmetric and symmetric strand exchange.     

Substrate requirements for duplex DNA translocation by the eukaryal and archaeal minichromosome maintenance helicases

Replicative DNA helicases are ring-shaped hexamers that play an essential role in DNA synthesis by separating the two strands of chromosomal DNA to provide the single-stranded (ss) substrate for replicative polymerases. Biochemical and structural studies suggest that these helicases translocate along one strand of the duplex, which passes through and interacts with the central channel of these ring-shaped hexamers, and displace the complementary strand. A number of these helicases were shown to also encircle both strands simultaneously and then translocate along double-stranded (ds)DNA. In this report it is shown that the Schizosaccharomyces pombe Mcm4,6,7 complex and archaeal minichromosome maintenance (MCM) helicase from Methanothermobacter thermautotrophicus move along duplex DNA. These two helicases, however, differ in the substrate required to support dsDNA translocation. Although the S. pombe Mcm4,6,7 complex required a 3'-overhang ssDNA region to initiate its association with the duplex, the archaeal protein initiated its transit along dsDNA in the absence of a 3'-overhang region, as well. Furthermore, DNA substrates containing a streptavidin-biotin steric block inhibited the movement of the eukaryotic helicase along ss and dsDNAs but not of the archaeal enzyme. The M. thermautotrophicus MCM helicase, however, was shown to displace a streptavidin-biotin complex from ss, as well as dsDNAs. The possible roles of dsDNA translocation by the MCM proteins during the initiation and elongation phases of chromosomal replication are discussed.     

RecA protein of Mycobacterium tuberculosis possesses pH-dependent homologous DNA pairing and strand exchange activities: implications for allele exchange in mycobacteria

To gain insights into inefficient allele exchange in mycobacteria, we compared homologous pairing and strand exchange reactions promoted by RecA protein of Mycobacterium tuberculosis to those of Escherichia coli RecA protein. The extent of single-stranded binding protein (SSB)-stimulated formation of joint molecules by MtRecA was similar to that of EcRecA over a wide range of pH values. In contrast, strand exchange promoted by MtRecA was inhibited around neutral pH due to the formation of DNA networks. At higher pH, MtRecA was able to overcome this constraint and, consequently, displayed optimal strand exchange activity. Order of addition experiments suggested that SSB, when added after MtRecA, was vital for strand exchange. Significantly, with shorter duplex DNA, MtRecA promoted efficient strand exchange without network formation in a pH-independent fashion. Increase in the length of duplex DNA led to incomplete strand exchange with concomitant rise in the formation of intermediates and networks in a pH-dependent manner. Treatment of purified networks with S1 nuclease liberated linear duplex DNA and products, consistent with a model in which the networks are formed by the invasion of hybrid DNA by the displaced linear single-stranded DNA. Titration of strand exchange reactions with ATP or salt distinguished a condition under which the formation of networks was blocked, but strand exchange was not significantly affected. We discuss how these results relate to inefficient allele exchange in mycobacteria.     

Construction and characterization of new coliphage M13 cloning vectors

New single-stranded DNA cloning vectors have been constructed by the insertion of additional DNA fragments into a HaeII restriction site in the bacteriophage M13 duplex replicative form (RF). These inserts into the M13 genome bring a single restriction sites useful for cloning, including PstI, XorII, EcoRI, SstI, XhoI, KpnI, and PvuII. Drug-resistance genes cloned into M13 include the beta-lactamase (bla) gene and the chloramphenicol acetyl transferase (cat) gene. These vectors provide a convenient means of easily obtaining the separated strands of a cloned duplex DNA fragment by cloning the fragment in each of the two possible orientations. Standard cloning techniques commonly applied to double-stranded DNAs can be utilized to insert foreign DNAs into the duplex RF DNAs of these vectors. Cells transformed by chimeric DNAs extrude filamentous phage particles carrying a circular single-stranded copy of the chimeric viral strand. Because M13-infected cells continue to grow and divide, cells can be transformed to yield either plaques or drug-resistant colonies. Specific inserts are readily detected by plaque hybridization techniques using an appropriate probe. Chimeric viral single strands from virus particles in the supernatant of small volumes of infected cultures can be rapidly and sensitively analyzed by agarose gel electrophoresis to determine the size of an insert.     

Concerted strand exchange and formation of Holliday structures by E. coli RecA protein

RecA protein makes stable joint molecules from fully duplex DNA and molecules that are partially single-stranded; the latter may be either duplex molecules with an internal gap in one strand or molecules with single-stranded ends. Stable joint molecules form only when the end of at least one strand is in a homologous region. When RecA protein pairs linear duplex molecules and tailed molecules that share the same sequence end to end, the joints, which are located away from the single-stranded tails in most instances, have the electron microscopic appearance associated with the Holliday structure resulting from the reciprocal exchange of strands. The reaction leading to reciprocal strand exchange involves the concerted displacement of a strand from the end of the duplex molecule. These observations support the view that RecA protein makes stable joint molecules only by transferring strands and not by the side-by-side pairing of duplex regions.     

Presynapsis and synapsis of DNA promoted by the STP alpha and single-stranded DNA-binding proteins from Saccharomyces cerevisiae

We previously purified an activity from meiotic cell extracts of Saccharomyces cerevisiae that promotes the transfer of a strand from a duplex linear DNA molecule to complementary circular single-stranded DNA, naming it Strand Transfer Protein alpha (STP alpha) (Sugino, A., Nitiss, J., and Resnick, M. A. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3683-3687). This activity requires no nucleotide cofactor but is stimulated more than 10-fold by the addition of yeast single-stranded DNA-binding proteins (ySSBs). In this paper, we describe the aggregation and strand transfer of double-stranded and single-stranded DNA promoted by STP alpha and ySSB. There is a good correlation between the aggregation induced by various DNA-binding proteins (ySSBs, DBPs and histone proteins) and the stimulation of STP alpha-mediated DNA strand transfer. This implies that the stimulation by ySSBs and other binding proteins is probably due to the condensation of single-stranded and double-stranded DNA substrates into coaggregates. Within these coaggregates there is a higher probability of pairing between homologous double-stranded and single-stranded DNA, favoring the initiation of strand transfer. The aggregation reaction is rapid and precedes any reactions related to DNA strand transfer. We propose that condensation into coaggregates is a presynaptic step in DNA strand transfer promoted by STP alpha and that pairing between homologous double- and single-stranded DNA (synapsis) occurs in these coaggregates. Synapsis promoted by STP alpha and ySSBs also occurs between covalently closed double-stranded DNA and single-stranded linear DNA as well as linear double-stranded and linear single-stranded DNAs in the absence of any nucleotide cofactors.     

A role for single-stranded templates in cell-free adeno-associated virus DNA replication

Assays have been described in which duplex adeno-associated virus (AAV) DNA can be replicated in HeLa cell extracts with exogenous AAV Rep protein. These assays appear to mimic the AAV DNA replication that occurs in the cell, including the ability of extracts from adenovirus (Ad)-infected cells to replicate duplex AAV DNA templates more efficiently than extracts from uninfected cells can. We showed previously that the Ad-infected extract was able to support a more processive replication than the uninfected extract. When the Ad single-stranded DNA binding protein (Ad-DBP) was added to an uninfected extract, DNA replication became processive. Based on a strand displacement replication model, we hypothesized that the Ad-DBP was stabilizing the displaced single-stranded DNA during strand displacement replication. In this report, we show that in Ad-infected extracts most of the newly replicated duplex DNA is converted into a single-stranded form shortly after synthesis. Using the results of assays for the replication of single-stranded AAV DNA, we show that these single-stranded molecules serve as templates for additional replication. In addition, we identify a class of molecules which are likely to be intermediates of replication on single-stranded templates. We discuss a possible role for replication of single-stranded molecules in the infected cell.     

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.     

Differential ATP requirements distinguish the DNA translocation and DNA unwinding activities of the Escherichia coli PRI A protein

The Escherichia coli primosome is a mobile multiprotein DNA replication-priming apparatus that assembles at a specific site (termed a primosome assembly site (PAS] on single-stranded DNA-binding protein-coated single-stranded DNA. The PRI A protein (factor Y, protein n') is a PAS sequence-specific (d)ATPase as well as a DNA helicase and is believed to direct the assembly of the primosome at a PAS. In this report, the PRI A DNA helicase reaction is dissected in vitro, by use of a strand displacement assay, into three steps with distinct ATP requirements. First, the PRI A protein gains entry to the DNA via an ATP-independent, PAS sequence-specific binding event. Second, the PRI A protein translocates along the single-stranded DNA in the 3'----5' direction at a maximal rate of 90 nucleotides/s. DNA translocation requires ATP hydrolysis. The ATP concentration required to support half of the maximal translocation rate is 100 microM, which is identical to the Km for ATP of the PRI A protein DNA-dependent ATPase activity. Finally, the PRI A protein unwinds duplex DNA. The ATP concentration required for duplex DNA unwinding depends upon the length of the duplex region to be unwound. Displacement of a 24-nucleotide long oligomer required no more ATP than that required for the translocation of PRI A protein along single-stranded DNA, whereas displacement of a 390-nucleotide long DNA fragment required a 10-fold higher concentration of ATP than that required for oligomer displacement.     

Initiation of adenovirus DNA replication. II. Structural requirements using synthetic oligonucleotide adenovirus templates

Adenovirus (Ad) virions contain a 55-kDa terminal protein covalently linked to both 5'-ends of the linear duplex DNA genome. The origin of DNA replication is contained within the terminal 50 base pair of the inverted terminal repeats. In the accompanying paper (Kenny, M. K., Balogh, L. A., and Hurwitz, J. (1988) J. Biol. Chem. 263, 9801-9808), it was demonstrated that synthetic oligonucleotide templates which contain the Ad origin, but lack the 55-kDa terminal protein, can serve as templates for the initiation of Ad DNA replication. Partially duplex oligonucleotides that lacked up to 14 nucleotides from the 5'-end of the nontemplate (displaced) strand supported initiation as much as 20-fold more efficiently than fully duplex oligonucleotides. The removal of 18 nucleotides or more from the 5'-end of the displaced strand resulted in a sharp decrease in the ability of the DNA templates to support initiation. The poor template efficiency of certain DNAs could be explained by their inability to bind nuclear factor I. The initiation efficiency observed with other DNAs correlated with their ability to bind the preterminal protein-Ad DNA polymerase complex. At low concentrations of the Ad DNA-binding protein, protein-primed initiation was also observed on single-stranded DNAs. The single-stranded template strand of the Ad origin was at least 5-20-fold better at supporting initiation than other single-stranded DNAs. These findings suggest a model in which the 3'-end of the template strand is rendered single-stranded as a prerequisite for initiation of Ad DNA replication.     

DNA replication by bacteriophage T4 proteins. The T4 43, 32, 44--62, And 45 proteins are required for strand displacement synthesis at nicks in duplex DNA.

The T4 bacteriophage gene 43 (T4 DNA polymerase), 32 (DNA helix-destabilizing protein), and 45 proteins and the complex of the gene 44 and 62 proteins are all required for DNA synthesis beginning at single-stranded breaks in duplex DNA. This synthesis occurs by strand displacement and is not dependent on ribonucleotides, the T4 gene 41 protein, or the T4 initiating protein, each of which is required to begin new chains on single-stranded templates. Electron microscopic analysis shows that duplex molecules with long single-stranded branches are the predominant products of this strand displacement synthesis.     

Two-dimensional gel analysis of rolling circle replication in the presence and absence of bacteriophage T4 primase.

The rolling circle DNA replication structures generated by the in vitro phage T4 replication system were analyzed using two-dimensional agarose gels. Replication structures were generated in the presence or absence of T4 primase (gp61), permitting the analysis of replication forks with either duplex or single-stranded tails. A characteristic arc shape was visualized when forks with single-stranded tails were cleaved by a restriction enzyme with the help of an oligonucleotide that anneals to restriction sites in the single-stranded tail. After calibrating the gel system with this well-studied rolling circle replication reaction, we then analyzed the in vivo replication directed by a T4 replication origin cloned within a plasmid. DNA samples were generated from infections with either wild-type or primase-deletion mutant phage. The only replicative arc that could be detected in the wild-type sample corresponded to duplex Y forms, consistent with very efficient lagging strand synthesis. Surprisingly, we obtained evidence for both duplex and single-stranded DNA tails in the samples from the primase-deficient infection. We conclude that a relatively inefficient mechanism primes lagging strand DNA synthesis in vivo when gp61 is absent.