RecA Nucleoprotein Filament Research Articles

Peptide nucleic acid (PNA) facilitates multistranded hybrid formation between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded DNA probes.

RecA protein-coated single-stranded DNA probes, known as RecA nucleoprotein filaments, bind specifically to homologous DNA sequences within double-stranded DNA targets, forming multistranded probe-target DNA hybrids. This DNA hybridization reaction can be used for sequence-specific gene capture, gene modification, and gene regulation. Thus, factors that enhance the efficiency of the hybridization reaction are of significant practical importance. We show here that the hybridization of a peptide nucleic acid (PNA) within or adjacent to the probe-target homology region significantly enhances the yield of hybrid DNA formed in the reaction between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded (css)DNA probes. The possible mechanisms and the advantages of using RecA nucleoprotein filaments in combination with PNA for genomic DNA cloning and mutagenesis are presented.

Facile synthesis of a fluorescent deoxycytidine analogue suitable for probing the RecA nucleoprotein filament.

We report the synthesis of the fluorescent 2'-deoxycytidine analogue 5-methylpyrimidin-2-one nucleoside, its incorporation at three specified sites in a single 60-nucleotide DNA molecule, and the use of its total and polarized intrinsic fluorescence to characterize RecA-DNA complexes. [reaction: see text]

Physical interactions between DinI and RecA nucleoprotein filament for the regulation of SOS mutagenesis.

The Escherichia coli dinI gene is one of the LexA-regulated genes, which are induced upon DNA damage. Its overexpression conferred severe UV sensitivity on wild-type cells and resulted in the inhibition of LexA and UmuD processing, reactions that are normally dependent on activated RecA in a complex with single-stranded (ss)DNA. Here, we study the mechanism by which DinI inhibits the activities of RecA. While DinI neither binds to ssDNA nor prevents the formation of RecA nucleoprotein filament, it binds to active RecA filament, thereby inhibiting its coprotease activity but not the ATPase activity. Furthermore, even under in vitro conditions where UmuD cleavage dependent on RecA-ssDNA-adeno sine-5'-(3-thiotriphosphate) is blocked in the presence of DinI, LexA is cleaved normally. This result, taken together with electron microscopy observations and linear dichroism measurements, indicates that the ternary complex remains intact in the presence of DinI, and that the affinity to the RecA filament decreases in the order LexA, DinI and UmuD. DinI is thus suited to modulating UmuD processing so as to limit SOS mutagenesis.

Lesion Bypass by the Escherichia coli DNA Polymerase V Requires Assembly of a RecA Nucleoprotein Filament

Translesion replication is carried out in Escherichia coli by the SOS-inducible DNA polymerase V (UmuC), an error-prone polymerase, which is specialized for replicating through lesions in DNA, leading to the formation of mutations. Lesion bypass by pol V requires the SOS-regulated proteins UmuD' and RecA and the single-strand DNA-binding protein (SSB). Using an in vitro assay system for translesion replication based on a gapped plasmid carrying a site-specific synthetic abasic site, we show that the assembly of a RecA nucleoprotein filament is required for lesion bypass by pol V. This is based on the reaction requirements for stoichiometric amounts of RecA and for single-stranded gaps longer than 100 nucleotides and on direct visualization of RecA-DNA filaments by electron microscopy. SSB is likely to facilitate the assembly of the RecA nucleoprotein filament; however, it has at least one additional role in lesion bypass. ATPgammaS, which is known to strongly increase binding of RecA to DNA, caused a drastic inhibition of pol V activity. Lesion bypass does not require stoichiometric binding of UmuD' along RecA filaments. In summary, the RecA nucleoprotein filament, previously known to be required for SOS induction and homologous recombination, is also a critical intermediate in translesion replication.

Phe217 Regulates the Transfer of Allosteric Information across the Subunit Interface of the RecA Protein Filament

Background: ATP-mediated cooperative assembly of a RecA nucleoprotein filament activates the protein for catalysis of DNA strand exchange. RecA is a classic allosterically regulated enzyme in that ATP binding results in a dramatic increase in ssDNA binding affinity. This increase in ssDNA binding affinity results almost exclusively from an ATP-mediated increase in cooperative filament assembly rather than an increase in the inherent affinity of monomeric RecA for DNA. Therefore, certain residues at the subunit interface must play an important role in transmitting allosteric information across the filament structure of RecA. Results: Using electron microscopic analysis of RecA polymer formation in the absence of DNA, we show that while wild-type RecA undergoes a slight decrease in filament length in the presence of ATP, a Phe217Tyr substitution results in a dramatic ATP-induced increase in cooperative filament assembly. Biosensor DNA binding measurements reveal that the Phe217Tyr mutation increases ATP-mediated cooperative interaction between RecA subunits by more than 250-fold. Conclusions: These studies represent the first identification of a subunit interface residue in RecA (Phe217) that plays a critical role in regulating the flow of ATP-mediated information throughout the protein filament structure. We propose a model by which conformational changes that occur upon ATP binding are propagated through the structure of a RecA monomer, resulting in the insertion of the Phe217 side chain into a pocket in the neighboring subunit. This event serves as a key step in intersubunit communication leading to ATP-mediated cooperative filament assembly and high affinity binding to ssDNA.

A robust algorithm for the reconstruction of helical filaments using single-particle methods

Some of the earliest methods for three-dimensional reconstruction from electron microscopic images were developed for helical objects. Single-particle methods have been used with great success for the three-dimensional reconstruction of macromolecular assemblies that have no internal symmetry or closed point group symmetries. An approach is presented for the application of single-particle methods to helical filaments that surmounts many of the difficulties of helical image analysis, including indexing, unbending and the need to find long helically symmetric filament segments. It is shown using both human Rad51 and E. coli RecA nucleoprotein filaments that this approach converges without user intervention to a stable solution, and that it has the potential to overcome many of the problems associated with image analysis of disordered helical polymers. The method can be applied transparently to structures where Bessel overlap would greatly complicate helical analysis. In addition, the procedure allows for the ab initio determination of helical symmetry, when no prior knowledge exists.

Visualization of two binding sites for the Escherichia coli UmuD′ 2C complex (DNA pol V) on RecA-ssDNA filaments

The heterotrimeric UmuD′ 2C complex of Escherichia coli has recently been shown to possess intrinsic DNA polymerase activity (DNA pol V) that facilitates error-prone translesion DNA synthesis (SOS mutagenesis). When overexpressed in vivo, UmuD′ 2C also inhibits homologous recombination. In both activities, UmuD′ 2C interacts with RecA nucleoprotein filaments. To examine the biochemical and structural basis of these reactions, we have analyzed the ability of the UmuD′ 2C complex to bind to RecA-ssDNA filaments in vitro. As estimated by a gel retardation assay, binding saturates at a stoichiometry of approximately one complex per two RecA monomers. Visualized by cryo-electron microscopy under these conditions, UmuD′ 2C is seen to bind uniformly along the filaments, such that the complexes are completely submerged in the deep helical groove. This mode of binding would impede access to DNA in a RecA filament, thus explaining the ability of UmuD′ 2C to inhibit homologous recombination. At sub-saturating binding, the distribution of UmuD′ 2C complexes along RecA-ssDNA filaments was characterized by immuno-gold labelling with anti-UmuC antibodies. These data revealed preferential binding at filament ends (most likely, at one end). End-specific binding is consistent with genetic models whereby such binding positions the UmuD′ 2C complex (pol V) appropriately for its role in SOS mutagenesis.

The bacteriophage P1 HumD protein is a functional homolog of the prokaryotic UmuD'-like proteins and facilitates SOS mutagenesis in Escherichia coli.

The Escherichia coli umuD and umuC genes comprise an operon and encode proteins that are involved in the mutagenic bypass of normally replication-inhibiting DNA lesions. UmuD is, however, unable to function in this process until it undergoes a RecA-mediated cleavage reaction to generate UmuD'. Many homologs of umuDC have now been identified. Most are located on bacterial chromosomes or on broad-host-range R plasmids. One such putative homolog, humD (homolog of umuD) is, however, found on the bacteriophage P1 genome. Interestingly, humD differs from other umuD homologs in that it encodes a protein similar in size to the posttranslationally generated UmuD' protein and not UmuD, nor is it in an operon with a cognate umuC partner. To determine if HumD is, in fact, a bona fide homolog of the prokaryotic UmuD'-like mutagenesis proteins, we have analyzed the ability of HumD to complement UmuD' functions in vivo as well as examined HumD's physical properties in vitro. When expressed from a high-copy-number plasmid, HumD restored cellular mutagenesis and increased UV survival to normally nonmutable recA430 lexA(Def) and UV-sensitive DeltaumuDC recA718 lexA(Def) strains, respectively. Complementing activity was reduced when HumD was expressed from a low-copy-number plasmid, but this observation is explained by immunoanalysis which indicates that HumD is normally poorly expressed in vivo. In vitro analysis revealed that like UmuD', HumD forms a stable dimer in solution and is able to interact with E. coli UmuC and RecA nucleoprotein filaments. We conclude, therefore, that bacteriophage P1 HumD is a functional homolog of the UmuD'-like proteins, and we speculate as to the reasons why P1 might require the activity of such a protein in vivo.

Modulation of RecA Nucleoprotein Function by the Mutagenic UmuD′C Protein Complex

The RecA, UmuC, and UmuD' proteins are essential for error-prone, replicative bypass of DNA lesions. Normally, RecA protein mediates homologous pairing of DNA. We show that purified Umu(D')2C blocks this recombination function. Biosensor measurements establish that the mutagenic complex binds to the RecA nucleoprotein filament with a stoichiometry of one Umu(D')2C complex for every two RecA monomers. Furthermore, Umu(D')2C competitively inhibits LexA repressor cleavage but not ATPase activity, implying that Umu(D')2C binds in or proximal to the helical groove of the RecA nucleoprotein filament. This binding reduces joint molecule formation and even more severely impedes DNA heteroduplex formation by RecA protein, ultimately blocking all DNA pairing activity and thereby abridging participation in recombination function. Thus, Umu(D')2C restricts the activities of the RecA nucleoprotein filament and presumably, in this manner, recruits it for mutagenic repair function. This modulation by Umu(D')2C is envisioned as a key event in the transition from a normal mode of genomic maintenance by "error-free" recombinational repair, to one of "error-prone" DNA replication.

The function of the secondary DNA-binding site of RecA protein during DNA strand exchange.

RecA protein features two distinct DNA-binding sites. During DNA strand exchange, the primary site binds to single-stranded DNA (ssDNA), forming the helical RecA nucleoprotein filament. The weaker secondary site binds double-stranded DNA (dsDNA) during the homology search process. Here we demonstrate that this site has a second important function. It binds the ssDNA strand that is displaced from homologous duplex DNA during DNA strand exchange, stabilizing the initial heteroduplex DNA product. Although the high affinity of the secondary site for ssDNA is essential for DNA strand exchange, it renders DNA strand exchange sensitive to an excess of ssDNA which competes with dsDNA for binding. We further demonstrate that single-stranded DNA-binding protein can sequester ssDNA, preventing its binding to the secondary site and thereby assisting at two levels: it averts the inhibition caused by an excess of ssDNA and prevents the reversal of DNA strand exchange by removing the displaced strand from the secondary site.

Interaction of Escherichia coli RecA Protein with LexA Repressor: I. LexA REPRESSOR CLEAVAGE IS COMPETITIVE WITH BINDING OF A SECONDARY DNA MOLECULE

Essential to the two distinct cellular events of genetic recombination and SOS induction in Escherichia coli, RecA protein promotes the homologous pairing and exchange of DNA strands and the proteolytic cleavage of the LexA repressor, respectively. Since both of these activities require single-stranded DNA (ssDNA) and ATP, the inter-relationship between these reactions was investigated and found to display many parallels. The extent of active complex formed between RecA protein and M13 ssDNA, as measured by both ATP hydrolysis and LexA proteolysis, is stimulated in a similar manner by either a reduction in magnesium ion concentration or the presence of single-stranded DNA binding (SSB) protein. However, unexpectedly, SSB protein inhibits both LexA proteolysis and ATP hydrolysis (in assays containing repressor) at concentrations of RecA protein that are substoichiometric to the ssDNA, arguing that LexA repressor affects the competition between RecA and SSB proteins for limited ssDNA binding sites. Additionally, attenuation of LexA repressor cleavage in the presence of double-stranded DNA or by an excess of ssDNA suggests that interaction of the RecA nucleoprotein filament with either LexA repressor or a secondary DNA molecule is mutually exclusive. The significance of these results is discussed in the context of both the regulation of inducible responses to DNA damage, and the competitive relationship between the processes of SOS induction and genetic recombination.

The DNA Binding Site(s) of the Escherichia coli RecA Protein

Photochemical cross-linking has been used to identify residues in the Escherichia coli RecA protein that are proximal to and may directly mediate binding of DNA. Ultraviolet irradiation promotes specific and efficient cross-linking of the RecA protein to poly(deoxythymidylic) acid. Cross-linked peptides remaining covalently attached to the polynucleotide following proteolytic digestion with trypsin correspond to amino acids 61-72, 178-183, and 233-243 of the RecA protein primary sequence. Their location and surface accessibility in the crystal structure, along with the behavior of various recA mutants, support the assignment of the cross-linked regions to the DNA binding site(s) of the RecA protein. Functional overlap of amino acids 61-72 with an element of the ATP binding site suggests a structural mechanism by which nucleotide cofactors allosterically affect the RecA nucleoprotein filament.

RecA Protein Dynamics in the Interior of RecA Nucleoprotein Filaments

We characterize aspects of the conformation and dynamic state of RecA filaments when bound to dsDNA that are specifically linked to the presence of the second of the two bound DNA strands. Filaments bound to dsDNA exhibit a facile exchange between free and bound RecA monomers or oligomers in the filament interior that is not seen on ssDNA. The RecA mutant K72R, which binds but does not hydrolyze ATP, forms mixed filaments with wild type RecA protein under some conditions. In the presence of dATP, mixed filaments are formed on dsDNA or ssDNA in which the RecA K72R content approximately reflects the proportion of the K72R mutant in the total RecA protein present when the filament is formed. In the presence of ATP, mixed filaments are formed on dsDNA, but the mutant protein strongly inhibits the binding of wtRecA protein to single-stranded DNA. When RecA K72R is added to pre-formed filaments containing only wild-type RecA protein on single-stranded DNA, little of the mutant protein exchanges into the filament. Exchange occurs readily, however, when the filament is bound to double-stranded DNA. The presence of a second DNA strand in RecA-dsDNA filaments produces as altered and more dynamic filament state relative to filaments formed on single-stranded DNA. The results point to a substantial alteration in filament state when synapsis occurs during RecA protein-mediated DNA strand exchange.

Evidence for the Coupling of ATP Hydrolysis to the Final (Extension) Phase of RecA Protein-mediated DNA Strand Exchange

RecA protein promotes a limited DNA strand exchange reaction, without ATP hydrolysis, that typically results in formation of short (1-2 kilobase pairs) regions of hybrid DNA. This nascent hybrid DNA is extended in a reaction that can be coupled to ATP hydrolysis. When ATP is hydrolyzed, the extension phase is progressive and its rate is 380 +/- 20 bp min-1 at 37 degrees C. A single RecA nucleoprotein filament can participate in multiple DNA strand exchange reactions concurrently (involving duplex DNA fragments that are homologous to different segments of the DNA within a nucleoprotein filament), with no effect on the observed rate of ATP hydrolysis. The ATP hydrolytic and hybrid DNA extension activities exhibit a dependence on temperature between 25 and 45 degrees C that is, within experimental error, identical. This provides new evidence that the two processes are coupled. Arrhenius activation energies derived from the work are 13.3 +/- 1.1 kcal mole-1 for DNA strand exchange, and 14.4 +/- 1.4 kcal mole-1 for ATP hydrolysis during strand exchange. The rate of branch movement in the extension phase (base pair min-1) is related to the kcat for ATP hydrolysis during strand exchange (min-1) by a factor equivalent to 18 bp throughout the temperature range examined. The 18-base pair factor conforms to a quantitative prediction derived from a model in which ATP hydrolysis is coupled to a facilitated rotation of the DNA substrates. RecA filaments possess an intrinsic capacity for DNA strand exchange, mediated by binding energy rather than ATP hydrolysis, that is augmented by an ATP-dependent molecular motor.

Quantitative RecA protein binding to the hybrid duplex product of DNA strand exchange.

Following a DNA strand exchange reaction, RecA protein remains bound to the hybrid DNA product. DNA strand exchange reactions were carried out under optimal conditions in the presence of both RecA protein and SSB protein. As monitored by a sensitive DNA underwinding assay, all of the RecA protein present in the RecA nucleoprotein filament that initiates the strand exchange reaction can be accounted for on the hybrid DNA. As shown elsewhere, the SSB is bound to the displaced single DNA strand. Previous studies showed that RecA protein will dissociate from dsDNA when ADP levels build up, or transfer from dsDNA to ssDNA when the latter is not bound by SSB. The present work (done with ATP regeneration and SSB) shows that efficient strand exchange occurs in the absence of a net dissociation or transfer of RecA monomers from the filament. Such a dissociation or transfer is therefore not a mechanistic requirement for DNA strand exchange. The results provide evidence against some models proposed for the DNA strand exchange mechanism.

Uptake and processing of duplex DNA by RecA nucleoprotein filaments: insights provided by a mixed population of dynamic and static intermediates.

In the polarized strand exchange that is promoted by Escherichia coli RecA protein, when the initiating end of a duplex DNA molecule is blocked by heterology, the homologous distal end nonetheless forms a joint with single-stranded DNA, but strand exchange in that joint cannot be completed because the strand that would otherwise be displaced lacks a free 5' end. Instead, 2/3 to 3/4 of such distal joints cyclically form and dissociate. Dissociation requires the hydrolysis of ATP (Burnett et al., 1994). Observations on DNase protection revealed that consistent with their dynamic nature, these joints were heterogeneous in length, extending from the labeled distal end of the duplex up to 600 base pairs within the homologous region. Switching of base pairs was undetectable in this fraction of distal joints. However, the other 1/3 to 1/4 of distal joints, which did not cycle, were as long as the entire homologous region (6 kb), and underwent complete switching of base pairs. The formation of these static joints occurred at a rate in excess of 100 bp per second, without requiring hydrolysis of ATP. These and earlier observations suggest that the RecA filament containing single-stranded DNA rapidly incorporates duplex DNA into a coaxial three-stranded helix by a passive process, whereas additional energy is required to convert the three-stranded intermediate into products or back into substrates, both of which involve the unwinding of many turns of three-stranded helix.

In vitro inhibition of RecA-mediated homologous pairing by UmuD'C proteins

The process of SOS mutagenesis in Escherichia coli requires: i) the replisome enzymes; ii) RecA protein; and iii) the formation of the UmuD'C protein complex which appears to help the replisome to resume DNA synthesis across a lesion. It has recently been shown that the UmuD'C complex, if overproduced, inhibits recombinational repair of a UV-damaged plasmid DNA as well as homologous recombination in an Hfr x F- cross. Since UmuD'C proteins might inhibit an early recombination step by interacting with a RecA nucleo-protein filament, we checked whether UmuD'C proteins will inhibit RecA promoted homologous pairing in vitro. We tested the inhibitory action of UmuD'C proteins in a crude bacterial extract containing possible cofactors such as chaperone proteins that ensure the proper folding of UmuC and the assembly of the UmuD'C complex in vivo. We used a novel recombination assay in which RecA protein promotes the formation of a stable plectonemic joint between a circular single-stranded DNA immobilized onto a membrane and an incoming homologous linear duplex DNA. Under these conditions we show that UmuD'C proteins inhibit the formation of joint molecules.

Dissociation of RecA filaments from duplex DNA by the RuvA and RuvB DNA repair proteins.

The RuvA and RuvB proteins of Escherichia coli act late in recombination and DNA repair to catalyze the branch migration of Holliday junctions made by RecA. In this paper, we show that addition of RuvAB to supercoiled DNA that is bound by RecA leads to the rapid dissociation of the RecA nucleoprotein filament, as determined by a topological assay that measures DNA underwinding and a restriction endonuclease protection assay. Disruption of the RecA filament requires RuvA, RuvB, and hydrolysis of ATP. These findings suggest several important roles for the RuvAB helicase during genetic recombination and DNA repair: (i) displacement of RecA filaments from double-stranded DNA, (ii) interruption of RecA-mediated strand exchange, (iii) RuvAB-catalyzed branch migration, and (iv) recycling of RecA protein.

Substrate specificity of the Escherichia coli RuvC protein. Resolution of three- and four-stranded recombination intermediates.

The specificity of the Escherichia coli RuvC Holliday junction resolvase has been investigated in vitro. RuvC protein cleaves synthetic DNA substrates that model three- or four-stranded recombination intermediates but fails to act upon Y junctions, G/A mismatches, heterologous loop structures, or two-stranded branched junctions. RuvC therefore differs from endonuclease VII of bacteriophage T4 which exhibits broad range specificity. Using related three- and four-stranded synthetic DNA junctions, we show that RuvC cleaves both junctions at the same DNA sequence and requires a region of homology at the junction point. The action of RuvC on three- and four-stranded recombination intermediates made by RecA was also investigated. We found that RuvC fails to resolve three-stranded intermediates in the presence of RecA, although four-stranded intermediates are resolved under the same conditions. However, both three- and four-stranded intermediates are substrates for the nuclease after removal of RecA. We interpret these differences in terms of the contiguity of the RecA nucleoprotein filament which may, under certain conditions, limit access to the Holliday junction resolvase.

A chimeric Rec-A protein that implicates non-Watson-Crick interactions in homologous pairing.

The helical filament formed by RecA protein on single-stranded DNA plays an important role in homologous recombination and pairs with a complementary single strand or homologous duplex DNA. The RecA nucleoprotein filament also recognizes an identical single strand. The chimeric protein, RecAc38, forms a nucleoprotein filament that recognizes a complementary strand but is defective in recognition of duplex DNA, and is associated with phenotypic defects in repair and recombination. As described here, RecAc38 nucleoprotein filament is also defective in recognition of an identical strand, either when the filament has within it a single strand or duplex DNA. A model that postulates three DNA binding sites rationalizes these observations and suggests that the third binding site mediates non-Watson-Crick interactions that are instrumental in recognition of homology in duplex DNA.