SOS-inducible DNA repair proteins, RuvA and RuvB, of Escherichia coli: functional interactions between RuvA and RuvB for ATP hydrolysis and renaturation of the cruciform structure in supercoiled DNA.

The ruv operon is induced by treatments that damage DNA and is regulated by the LexA repressor. It encodes two proteins, RuvA and RuvB, that are involved in DNA repair, recombination in RecE and RecF pathways, and mutagenesis. RuvB protein was previously purified and has ATP-binding activity and weak ATPase activity. To study the biochemical properties of RuvA and its interaction with RuvB, we purified RuvA protein to near homogeneity from an over-producing strain. RuvA bound more efficiently to single-stranded DNA than to double-stranded DNA. RuvA bound to DNA greatly enhanced the ATPase activity of RuvB; the enhancing effect of various forms of DNA was in the order of supercoiled DNA greater than single-stranded DNA greater than linear double-stranded DNA. UV irradiation further enhanced the ATPase stimulatory effect of supercoiled DNA dose dependently. The RuvA-RuvB complex has an activity that renatures the cruciform structure in supercoiled DNA. From these experiments and previous work, we infer that the RuvA-RuvB complex may promote branch migration in recombination and may correct irregular structures in DNA, such as cruciforms and hairpins, to facilitate DNA repair using ATP as the energy source.     

RuvA and RuvB proteins of Escherichia coli exhibit DNA helicase activity in vitro.

The SOS-inducible ruvA and ruvB gene products of Escherichia coli are required for normal levels of genetic recombination and DNA repair. In vitro, RuvA protein interacts specifically with Holliday junctions and, together with RuvB (an ATPase), promotes their movement along DNA. This process, known as branch migration, is important for the formation of heteroduplex DNA. In this paper, we show that the RuvA and RuvB proteins promote the unwinding of partially duplex DNA. Using single-stranded circular DNA substrates with annealed fragments (52-558 nucleotides in length), we show that RuvA and RuvB promote strand displacement with a 5'-->3' polarity. The reaction is ATP-dependent and its efficiency is inversely related to the length of the duplex DNA. These results show that the ruvA and ruvB genes encode a DNA helicase that specifically recognizes Holliday junctions and promotes branch migration.     

Interaction of Escherichia coli RuvA and RuvB proteins with synthetic Holliday junctions.

The RuvA, RuvB, and RuvC proteins of Escherichia coli are required for the recombinational repair of ultraviolet light- or chemical-induced DNA damage. In vitro, RuvC protein interacts with Holliday junctions in DNA and promotes their resolution by endonucleolytic cleavage. In this paper, we investigate the interaction of RuvA and RuvB proteins with model Holliday junctions. Using band-shift assays, we show that RuvA binds synthetic Holliday structures to form specific protein-DNA complexes. Moreover, in the presence of ATP, the RuvA and RuvB proteins act in concert to promote dissociation of the synthetic Holliday structures. The dissociation reaction requires both RuvA and RuvB and a nucleotide cofactor (ATP or dATP) and is rapid (40% of DNA molecules dissociate within 1 min). The reaction does not occur when ATP is replaced by either ADP or the nonhydrolyzable analog of ATP, adenosine 5'-[gamma-thio]triphosphate. We suggest that the RuvA and RuvB proteins play a specific role in the branch migration of Holliday junctions during postreplication repair of DNA damage in E. coli.     

RecA protein filaments can juxtapose DNA ends: an activity that may reflect a function in DNA repair.

To further characterize the role of RecA protein-DNA filaments in general recombination and DNA repair, we have examined interactions of these filaments with themselves following formation. When linear double-stranded DNA was incubated with RecA in the presence of Mg2+ and adenosine 5'-[gamma-thio]triphosphate, monomer-length (1n) nucleoprotein filaments were observed. Following continued incubation, filaments having 2n, 3n, ... lengths were observed, indicating that an end-to-end joining of the monomer-length filaments had occurred. When linear single-stranded DNA was covered by RecA protein under several conditions, the ends of the resulting filaments joined together rapidly, producing circular filaments. The end-to-end joining of single-stranded DNA-RecA filaments appeared to require that 3' DNA ends be juxtaposed with 5' DNA ends, because double-stranded DNA molecules having long single-stranded DNA tails with only 3' or 5' termini did not join end-to-end. However, when both 5' and 3' ends were present in the reaction, joining was observed. We suggest that this end-to-end joining activity may help explain the role of RecA protein in both the protection of damaged DNA ends and the repair of double-stranded DNA breaks.     

RecA.oligonucleotide filaments bind in the minor groove of double-stranded DNA.

Escherichia coli RecA protein, in the presence of ATP or its analog adenosine 5'-[gamma-thio]triphosphate, polymerizes on single-stranded DNA to form nucleoprotein filaments that can then bind to homologous sequences on duplex DNA. The three-stranded joint molecule formed as a result of this binding event is a key intermediate in general recombination. We have used affinity cleavage to examine this three-stranded joint by incorporating a single thymidine-EDTA.Fe (T*) into the oligonucleotide part of the filament. Our analysis of the cleavage patterns from the joint molecule reveals that the nucleoprotein filament binds in the minor groove of an extended Watson-Crick duplex.     

Domain structure and dynamics in the helical filaments formed by RecA and Rad51 on DNA

Both the bacterial RecA protein and the eukaryotic Rad51 protein form helical nucleoprotein filaments on DNA that catalyze strand transfer between two homologous DNA molecules. However, only the ATP-binding cores of these proteins have been conserved, and this same core is also found within helicases and the F1-ATPase. The C-terminal domain of the RecA protein forms lobes within the helical RecA filament. However, the Rad51 proteins do not have the C-terminal domain found in RecA, but have an N-terminal extension that is absent in the RecA protein. Both the RecA C-terminal domain and the Rad51 N-terminal domain bind DNA. We have used electron microscopy to show that the lobes of the yeast and human Rad51 filaments appear to be formed by N-terminal domains. These lobes are conformationally flexible in both RecA and Rad51. Within RecA filaments, the change between the "active" and "inactive" states appears to mainly involve a large movement of the C-terminal lobe. The N-terminal domain of Rad51 and the C-terminal domain of RecA may have arisen from convergent evolution to play similar roles in the filaments.     

Nucleosomes on linear duplex DNA allow homologous pairing but prevent strand exchange promoted by RecA protein.

To understand the molecular basis of gene targeting, we have studied interactions of nucleoprotein filaments comprised of single-stranded DNA and RecA protein with chromatin templates reconstituted from linear duplex DNA and histones. We observed that for the chromatin templates with histone/DNA mass ratios of 0.8 and 1.6, the efficiency of homologous pairing was indistinguishable from that of naked duplex DNA but strand exchange was repressed. In contrast, the chromatin templates with a histone/DNA mass ratio of 9.0 supported neither homologous pairing nor strand exchange. The addition of histone H1, in stoichiometric amounts, to chromatin templates quells homologous pairing. The pairing of chromatin templates with nucleoprotein filaments of RecA protein-single-stranded DNA proceeded without the production of detectable networks of DNA, suggesting that coaggregates are unlikely to be the intermediates in homologous pairing. The application of these observations to strategies for gene targeting and their implications for models of genetic recombination are discussed.     

Polarity of DNA strand exchange promoted by recombination proteins of the RecA family

Homologs of Escherichia coli RecA recombination protein, which have been found throughout the living kingdom, promote homologous pairing and strand exchange. The nucleoprotein filament, within which strand exchange occurs, has been conserved through evolution, but conservation of the polarity of exchange and the significance of that directionality has not been settled. Using oligonucleotides as substrates, and assays based on fluorescence resonance energy transfer (FRET), we distinguished the biased formation of homologous joints at either end of duplex DNA from the subsequent directionality of strand exchange. As with E. coli RecA protein, the homologous Rad51 proteins from both Homo sapiens (HsRad51) and Saccharomyces cerevisiae (ScRad51) propagated DNA strand exchange preferentially in the 5′ to 3′ direction. The data suggest that 5′ to 3′ polarity is a conserved intrinsic property of recombination filaments.     

Targeting of the UmuD, UmuD'', and MucA'' mutagenesis proteins to DNA by RecA protein.

In addition to its critical role in genetic recombination, the Escherichia coli RecA protein plays a pivotal role in SOS-induced mutagenesis. This role can be separated genetically into three steps: (i) depression of the SOS regulon by mediating the posttranslational cleavage of the LexA repressor, (ii) activation of UmuD'-like proteins by mediating cleavage of the UmuD-like proteins, and (iii) a direct step, possibly to interact with and to target the Umu-like mutagenesis proteins to lesions in DNA. We have analyzed RecA's third role biochemically using protein affinity chromatography and an agarose-based DNA mobility-shift assay. RecA730 protein from a crude cell extract was specifically retained on UmuD and UmuD' protein affinity columns, suggesting that these proteins physically interact. Normally, neither UmuD nor UmuD' shows any affinity for DNA. In the presence of RecA protein, however, UmuD and UmuD' were targeted to DNA. RecA1730 protein, which is defective for UmuD' but proficient for MucA'-promoted mutagenesis, showed a dramatically reduced capacity to target UmuD' to DNA but was able to target a significant portion of MucA' to DNA. These data support the suggestion that the direct role of RecA protein in SOS-induced mutagenesis is to interact with and target the Umu-like mutagenesis proteins to DNA.     

Ability of RecA protein to promote a search for rare sequences in duplex DNA.

RecA nucleoprotein filaments found homologous targets even when the latter was mixed with 200,000 times as much heterologous duplex DNA. By contrast, mixing of the single-stranded probe with only 100 times as much heterologous single strands markedly reduced the rate of finding homologous duplex molecules. Titration of the reaction with different proportions of homologous single-stranded DNA distinguished a condition under which the search for homology itself was rate limiting from a condition under which some later step was limiting. Less than 1 min was required to scan 6.4 kilobase pairs of duplex DNA for homology to a RecA-coated single strand of the same size, but these experiments revealed that rapid searching by RecA nucleoprotein filaments was largely confined to neighboring duplex molecules. These observations provide guidelines for the use of RecA protein in locating rare sequences in complex mixtures of duplex DNA, and we describe a simple protocol by which rare sequences can be rapidly enriched at least a thousandfold.     

Stable three-stranded DNA made by RecA protein.

When RecA protein, in the form of a nucleoprotein filament containing circular single-stranded DNA (plus strand only), reacts with homologous linear duplex DNA, a directional transfer ensues of a strand from the duplex DNA to the nucleoprotein filament, resulting in the displacement of the linear plus strand in the 5' to 3' direction. The initial homologous synapsis, however, can occur at either end of the duplex DNA, or anywhere in between, and when homology is restricted to different regions of the duplex DNA, the joint molecules that form in each region show striking differences in stability upon deproteinization: distal joints greater than proximal joints much greater than medial joints. In the deproteinized distal joints, which are thermostable, 2000 nucleotide residues of the circular plus strand are resistant to P1 nuclease; both strands of the original duplex DNA remain resistant to P1 nuclease, and the potentially displaceable linear plus strand, which has a 3' homologous end, remains resistant to Escherichia coli exonuclease I. These observations suggest that RecA protein promotes homologous pairing and strand exchange via long three-stranded DNA intermediates and, moreover, that, once formed, such triplex structures in natural DNA are stable even when RecA protein has been removed.     

Predicting DNA duplex stability from the base sequence.

We report the complete thermodynamic library of all 10 Watson-Crick DNA nearest-neighbor interactions. We obtained the relevant thermodynamic data from calorimetric studies on 19 DNA oligomers and 9 DNA polymers. We show how these thermodynamic data can be used to calculate the stability and predict the temperature-dependent behavior of any DNA duplex structure from knowledge of its base sequence. We illustrate our method of calculation by using the nearest-neighbor data to predict transition enthalpies and free energies for a series of DNA oligomers. These predicted values are in excellent agreement with the corresponding values determined experimentally. This agreement demonstrates that a DNA duplex structure thermodynamically can be considered to be the sum of its nearest-neighbor interactions. Armed with this knowledge and the nearest-neighbor thermodynamic data reported here, scientists now will be able to predict the stability (delta G degree) and the melting behavior (delta H degree) of any DNA duplex structure from inspection of its primary sequence. This capability should prove valuable in numerous applications, such as predicting the stability of a probe-gene complex; selecting optimal conditions for a hybridization experiment; deciding on the minimum length of a probe; predicting the influence of a specific transversion or transition on the stability of an affected DNA region; and predicting the relative stabilities of local domains within a DNA duplex.     

Formation of base triplets by non-Watson-Crick bonds mediates homologous recognition in RecA recombination filaments.

Whereas complementary strands of DNA recognize one another by forming Watson-Crick base pairs, the way in which RecA protein enables a single strand to recognize homology in duplex DNA has remained unknown. Recent experiments, however, have shown that a single plus strand in the RecA filament can recognize an identical plus strand via bonds that, by definition, are non-Watson-Crick. In experiments reported here, base substitutions had the same qualitative and quantitative effects on the pairing of two identical strands in the RecA filament as on the recognition of duplex DNA by a third strand, indicating that similar non-Watson-Crick interactions govern both reactions.     

Activity of the purified mutagenesis proteins UmuC, UmuD'', and RecA in replicative bypass of an abasic DNA lesion by DNA polymerase III.

The introduction of a replication-inhibiting lesion into the DNA of Escherichia coli generates the induced, multigene SOS response. One component of the SOS response is a marked increase in mutation rate, dependent on RecA protein and the induced mutagenesis proteins UmuC and UmuD. A variety of previous indirect approaches have indicated that SOS mutagenesis results from replicative bypass of the DNA lesion by DNA polymerase III (pol III) holoenzyme in a reaction mediated by RecA, UmuC, and a processed form of UmuD termed UmuD'. To study the biochemistry of SOS mutagenesis, we have reconstituted replicative bypass with a defined in vitro system containing purified protein and a DNA substrate with a single abasic DNA lesion. The replicative bypass reaction requires pol III, UmuC, UmuD', and RecA. The nonprocessed UmuD protein does not replace UmuD' but inhibits the bypass activity of UmuD', perhaps by sequestering UmuD' in a heterodimer. Our experiments demonstrate directly that the UmuC-UmuD' complex and RecA act to rescue an otherwise stalled pol III holoenzyme at a replication-blocking DNA lesion.     

RecBCD-dependent joint molecule formation promoted by the Escherichia coli RecA and SSB proteins.

We describe the formation of homologously paired joint molecules in an in vitro reaction that is dependent on the concerted actions of purified RecA and RecBCD proteins and is stimulated by single-stranded DNA-binding protein (SSB). RecBCD enzyme initiates the process by unwinding the linear double-stranded DNA to produce single-stranded DNA, which is trapped by SSB and RecA. RecA uses this single-stranded DNA to catalyze the invasion of a supercoiled double-stranded DNA molecule, forming a homologously paired joint molecule. At low RecBCD enzyme concentrations, the rate-limiting step is the unwinding of duplex DNA by RecBCD, whereas at higher RecBCD concentrations, the rate-limiting step is RecA-catalyzed strand invasion. The behavior of mutant RecA proteins in this in vitro reaction parallels their in vivo phenotypes, suggesting that this reaction may define biochemical steps that occur during homologous recombination by the RecBCD pathway in vivo.     

Recognition and repair of UV lesions in loop structures of duplex DNA by DASH-type cryptochrome

DNA photolyases and cryptochromes (cry) form a family of flavoproteins that use light energy in the blue/UV-A region for the repair of UV-induced DNA lesions or for signaling, respectively. Very recently, it was shown that members of the DASH cryptochrome subclade repair specifically cyclobutane pyrimidine dimers (CPDs) in UV-damaged single-stranded DNA. Here, we report the crystal structure of Arabidopsis cryptochrome 3 with an in-situ-repaired CPD substrate in single-stranded DNA. The structure shows a binding mode similar to that of conventional DNA photolyases. Furthermore, CPD lesions in double-stranded DNA are bound and repaired with similar efficiency as in single-stranded DNA if the CPD lesion is present in a loop structure. Together, these data reveal that DASH cryptochromes catalyze light-driven DNA repair like conventional photolyases but lack an efficient flipping mechanism for interaction with CPD lesions within duplex DNA.     

Specific association between the human DNA repair proteins XPA and ERCC1.

Processing of DNA damage by the nucleotide-excision repair pathway in eukaryotic cells is most likely accomplished by multiprotein complexes. However, the nature of these complexes and the details of the molecular interactions between DNA repair factors are for the most part unknown. Here, we demonstrate both in vivo, using the two-hybrid system, and in vitro, using recombinant proteins, that the human repair factors XPA and ERCC1 specifically interact. In addition, we report an initial determination of the domains in ERCC1 and XPA that mediate this interaction. These results suggest that XPA may play a role in the localization or loading of an incision complex, composed of ERCC1 and possibly other repair factors, onto a damaged site.     

Superstructure of linear duplex DNA.

The superstructure of a covalently closed circular DNA (of bacteriophage PM 2) was compared by electron microscopy with that of a linear duplex DNA (of bacteriophage T7) when ionic strength and benzyldimethylalkylammonium chloride concentration were varied. In parallel studies the sedimentation behavior of these DNAs was studied by analytical ultracentrifugation, but for technical reasons these had to be without benzyldimethylalkylammonium chloride. By combining the information from the two methods one has to conclude that with increasing ionic strength the linear duplex T7 DNA spontaneously forms a structure similar to that of the superhelical structure of closed circular PM 2 DNA. The superstructure is destroyed under premelting conditions and in the presence of an excess of ethidium bromide.     

Strand-invasion of duplex DNA by peptide nucleic acid oligomers.

Polyamide oligomers, termed peptide nucleic acids (PNAs), bind with high affinity to both DNA and RNA and offer both antisense and antigene approaches for regulating gene expression. When a PNA binds to a complementary sequence in a double-stranded DNA, one strand of the duplex is displaced, and a stable D-loop is formed. Unlike oligodeoxynucleotides for which binding polarity is determined by the deoxyribose sugar, the unrestrained polyamide backbone of the PNA could permit binding to a DNA target in an orientation-independent manner. We now provide evidence that PNAs can, in fact, bind to their complementary sequence in DNA independent of the DNA-strand polarity--that is, a PNA binds to DNA in both "parallel" and "antiparallel" fashion. With a mixed-sequence 15-mer PNA, kinetic studies of PNA.DNA interactions revealed that D-loop formation was rapid and the complex was stable for several hours. However, when measured either by gel-mobility-shift analysis or RNA polymerase II-elongation termination, D-loop formation was salt dependent, but PNA-strand dissociation was not salt dependent. We observed that D-loop-containing DNA fragments had anomalous gel mobilities that varied as a function of the position of the D-loop relative to the DNA termini. On the basis of permutation analysis, the decreased mobility of the PNA.DNA complex was attributed to a bend in the DNA at or near the D-loop.